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MAPKAPK2: the master regulator of RNA-binding proteins modulates transcript stability and tumor progression

Abstract

The p38 mitogen-activated protein kinase (p38MAPK) pathway has been implicated in a variety of pathological conditions including inflammation and metastasis. Post-transcriptional regulation of genes harboring adenine/uridine-rich elements (AREs) in their 3′-untranslated region (3′-UTR) is controlled by MAPK-activated protein kinase 2 (MAPKAPK2 or MK2), a downstream substrate of the p38MAPK. In response to diverse extracellular stimuli, MK2 influences crucial signaling events, regulates inflammatory cytokines, transcript stability and critical cellular processes. Expression of genes involved in these vital cellular cascades is controlled by subtle interactions in underlying molecular networks and post-transcriptional gene regulation that determines transcript fate in association with RNA-binding proteins (RBPs). Several RBPs associate with the 3′-UTRs of the target transcripts and regulate their expression via modulation of transcript stability. Although MK2 regulates important cellular phenomenon, yet its biological significance in tumor progression has not been well elucidated till date. In this review, we have highlighted in detail the importance of MK2 as the master regulator of RBPs and its role in the regulation of transcript stability, tumor progression, as well as the possibility of use of MK2 as a therapeutic target in tumor management.

Background

A variety of stimuli evokes specific responses in cells via p38 mitogen-activated protein kinase (p38MAPK) signal pathway activation. The stress-activated p38MAPK signaling pathway regulates a plethora of cellular processes in particular apoptosis, cell division, cell invasion, and inflammatory response [1]. p38MAPK pathway’s downstream substrate, mitogen-activated protein kinase-activated protein kinase 2 (MAPKAPK2 or MK2) is involved in the post-translational regulation of cytokines as evident in MK2 knockout (MK2−/−) mice showing attenuated production of tumor necrosis factor (TNFα) protein when compared to wild-type mice. The mRNA levels, however, in wild-type mice were quite similar as compared to MK2−/− mice, indicating regulation at the translational level which might be imparted via a MK2 substrate.

In response to stress stimuli, p38MAPK phosphorylates and activates MK2 which further regulates a cascade of biological events and participates in a multitude of processes like cell apoptosis [2], cell cycle [3], movement [4] and response to oxidative stress [5]. MK2 was discovered as an extracellular signal-regulated kinase (ERK1/2)-activated protein kinase that phosphorylates and inactivates heat shock protein (Hsp27) [6]. MK2 has been shown to govern the activation and deactivation of RNA-binding proteins (RBPs) [7]. These RBPs modulate the gene expression of mRNAs encoding several proto-oncogenes, cytokines, chemokines and pro-inflammatory factors that control cell-cycle progression, proliferation, angiogenesis, metastasis, and cell death [8, 9]. Experimental evidence indicates that MK2, the prime target of p38MAPK, regulates the stability of essential genes involved in tumor pathogenesis that harbour adenine/uridine-rich elements (AREs) in their 3′-untranslated region (3′-UTRs) [8].

Systemic side effects like hepatic and cardiac toxicity as well as central nervous system disorders caused by the small molecules p38MAPK inhibitors have hindered their translational use. This might be attributed to the fact that p38MAPK regulates more than sixty substrates and therefore its direct inhibitors have failed in their clinical utility due to undesired side effects [10]. This has prompted researchers to look for novel therapeutic targets in downstream regulators of this signaling pathway, prominent among them being MK2. Hence, insights into the putative role of MK2 in the post-transcriptional regulation of pathogenesis-linked transcripts have become pertinent. In this review, we have highlighted the importance of MK2 as the master regulator of RBPs and its role in the regulation of transcript stability and tumor progression. Furthermore, we have discussed the role of MK2 in various cancers and have also deliberated its significance in various cancer processes. The possibility of employing MK2 as a therapeutic inhibitor has also been reviewed.

p38MAPK signaling pathway

p38MAPKs are key MAPKs involved in the production of important inflammatory mediators, including TNFα and cyclooxygenase-2 (COX-2). Cellular stresses/mitogens interact in a majorly receptor-mediator manner and help trigger the phosphorylation of a MAPK kinase kinase (MAP3K) specifically which further causes the phosphorylation of its downstream substrate MAPK kinase (MAP2K). After MAP2K phosphorylation, its substrate MAPK is subsequently phosphorylated (Fig. 1). Activated MAPKs further leads to the phosphorylation and activation of several downstream protein kinases, proto-oncogenes, and transcription factors [11].

Fig. 1
figure 1

p38MAPK signalling cascade. A multitude of extracellular stimuli and mitogens lead to the activation of p38MAPK signalling pathway consisting of a kinase network as diagrammatically represented in the figure. When activated by p38, MK2 gets exported to the cytoplasm (NLS gets masked and NES is functional) where it controls the transcript stability of tumor pathogenesis related mRNAs harbouring AREs in their 3′-UTRs via regulation of RNA-binding proteins

Major kinases in the p38MAPK signaling pathway

MAPK pathways comprises of an array of three kinases: Firstly, a MAP3K which is responsible to activates a MAP2K that in turn phosphorylates and activates a MAPK which occurs via a dual phosphorylation in the activation motif (Thr-X-Tyr where X could be any amino acid). Mammalian cells are known to express fourteen MAPKs which can be further segregated into groups based on sequence homology. The classical MAPKs are ERK1 and ERK2 with MAP2Ks, MKK1 or MKK2 activating them. Four isoforms of the p38MAPK family are known (p38α, p38β, p38γ, and p38δ), and these are activated by the MAP2Ks, MKK3, and MKK6 [12].

Downstream substrates of the p38MAPK signaling pathway

There are numbers of substrates downstream of p38MAPK signaling pathways. MK2 and MK3 were the first p38MAPK substrates identified [13]. Phosphorylated MK2 or MK3 can activate a variety of substrates, such as small Hsp27 [14], cyclic AMP-responsive element-binding protein (CREB) [15], and tristetraprolin (TTP), a RBP, known to causes mRNA destabilization thus referring at p38MAPK’s role in mRNA stability [16]. It has been shown that p38MAPK modulates MK2 expression both transcriptionally and post-transcriptionally in murine cell lines and embryos while it is lost in p38−/− mice [17].

Mitogen-activated protein kinase-activated protein kinase 2

p38MAPK’s downstream substrate responsible for a plethora of signaling cascades in response to numerous extracellular stimuli ranging from apoptosis, cell division and differentiation, cell motility to inflammation is a Ser/Tyr protein kinase, MK2 [6]. MK2 acts as an important driver in the signaling pathways triggered in reply to DNA damage. A recent report has identified MK2 as protumorigenic with its role been shown in tumor progression [18]. Past reports have elucidated the expression of MK2 in a variety of cell types such as endothelial cells [19], smooth muscle cells [20], and cancers [21].

MK2 substrates

Upon activation MK2 phosphorylates various substrates and leads to regulation of many different biological processes. The first identified MK2 substrates were Hsp25 and Hsp27 [22]. It has been reported that Hsp27 phosphorylation by MK2 causes remodeling of actin cytoskeleton which leads to cell motility [23]. MK2 increases interleukin (IL)-6 and TNF-α production by stabilizing their mRNAs or promoting its translation [24]. MK2 could phosphorylate several important cancer-related proteins, such as cell division cycle 25 (Cdc25B/C) [25], polo-like kinase 1 (Plk1) [26], tuberin (TSC2), and the ARE-binding proteins (AU-rich element RNA-binding protein 1 (AUF1), human antigen R (HuR), TTP), which are responsible in modulating transcript stability of many genes, like TNFα, Cyclin D1, Plk3, c-Fos, c-Myc, and matrix metalloproteinase (MMP) affecting cell metabolism, differentiation, and carcinogenesis [27] (Table 1). The physiological roles of these substrates are quite different, and each contains a unique and specific amino acid motif, such as X-X-Hyd-X-R-X-X-S-X-X (where Hyd is a bulky hydrophobic residue), essential for efficient MK2-mediated phosphorylation [25, 28]. Recent experimental evidence elucidated that MK2 plays an important role in the maintenance of genomic stability by contributing to the G2/M and the mitotic spindle checkpoints [7].

Table 1 MK2 regulates transcript stability via RBPs

Structure and location of MK2

Human MK2, a 400-residue enzyme, contains in its N-terminus two proline-rich regions followed by the kinase and the C-terminal regulatory domain [13]. Except for MK3/4, a very low homology has been shown by the kinase domain with other serine/threonine kinases. On the other hand, no significant homology has been reported in the N-terminal proline-rich and the C-terminal regulatory domain with other non-MAPKAPK proteins. A nuclear export signal (NES) and a bipartite nuclear localization signal (NLS) are located in the C-terminal regulatory domain [29] (Fig. 2). Pull-down assays with MK2 and p38MAPK indicate that the C-terminal region 366–390 represents the p38-docking region [30]. The C-terminal regulatory domain of MK2 (also MK3) contains a functional bipartite NLS, 371–374 and 385–389, respectively which is responsible for MK2’s location predominantly in the nuclei of resting cells. Conversely, a functional NES (a motif with the sequence 356–365) which is located in the N-terminal region to the NLS is responsible for triggering nuclear export following MK2 activation [10, 30] (Fig. 2).

Fig. 2
figure 2

Structure of MK2 and its isoforms. Figure presents the schematic representation of M2 (Isoform 1 and 2) structure with numbers highlighting the amino-acid (a.a.) residues of various domains. N-terminal contains a proline-rich region (10–40 a.a.) followed by catalytic kinase domain (64–325 a.a.) in both the isoforms. The larger isoform (isoform 1, 400 a.a.) consists of a nuclear export signal (NES) (356–365 a.a.) and a bipartite nuclear localization signal (NLS) (371–374 and 385–389 a.a.) located at the C-terminal region. The shorter isoform (isoform 2, 370 a.a.) on the other hand does not have the NES and NLS domain. Figure also clearly indicates that the region 354–370 of isoform 2 is different from isoform 1 (sequence alignment portrayed). The three phosphorylation sites of p38 have also been marked

Before stimulation, both p38MAPK and MK2 are predominantly located in the nucleus, but they quickly translocate after stimulation to the cytoplasm together in a phosphorylation-dependent manner [29, 30]. Phosphorylation of MK2 by p38MAPK occurs in the nucleus and involves the interaction between the enzymatic and catalytic domains of p38MAPK and the NLS of MK2 [31]. Literature reports revealed that two kinase domain residues of MK2 (T222 and S272) and one residue located outside the kinase domain (T334) gets phosphorylated by p38MAPK (Fig. 1). These phosphorylations have been shown to be required for maximal activation of MK2 in vitro in mutagenesis studies [32]. MK2 activation occurs via the selective phosphorylation of T222 and T334. Phosphorylation at T334 abrogates the interaction between kinase and the C-terminal regulatory domain resulting in NES being available for binding to the nuclear receptor as revealed by the crystal structure of MK2 [33]. Once MK2 masks the NLS at the C-terminal end by phosphorylation, it is rapidly exported to the cytoplasm via Exportin 1-dependent mechanism to phosphorylate their downstream cytosolic targets [30] (Fig. 1).

There are many reports in the literature that confirm the role of MK2 phosphorylation at T222 located in the activation loop, S272 (catalytic domain), and T334 (outside the catalytic domain within the C-terminal region) in its activation [32]. It has been proposed that an amphiphilic α-helix motif situated within the C-terminus region of MK2 blocks the binding of MK2 with its substrates [34]. There is a hypothesis that suggests the role of T222 and T334 dual phosphorylation in repositioning this α-helix thereby resulting in an enhanced catalytic activity.

MK2 has been shown to possess different splice variants and protein isoforms (Fig. 3). Sodium dodecyl sulphate-polyacrylamide gel electrophoresis (SDS-PAGE) [6] and chromatography [35] led to the description of two differentially spliced MK2 isoforms which have comparable migration intensity and which might have arisen as a result of limited proteolysis or post-translational modifications of MK2. The first variant, MK2, contains an NES, NLS and a putative p38-docking domain located near the carboxy terminus [6]. The second shorter variant of MK2 (isoform 2) [13] contains an identical N-terminal kinase domain but lacks NES, NLS and a p38-docking domain [29, 30] and bears the substitutive sequence GCLHDKNSDQATWLTRL in place of 354–400 sequence of isoform 1 [10] (Fig. 2). Recently, automated computational analysis and annotation using gene prediction method have shown that there are two more isoforms of MK2 as detailed in Fig. 3.

Fig. 3
figure 3

MK2 variants. Pictorial representation of the chromosomal location of MK2 and its various variants is provided in the figure. Details of all the MK2 variants discovered so far has been provided for in-depth and detailed technical information. The chromosome map is based on Ensembl’s GRCh38.p10 ideogram

MK3

The main focus of our review is MK2, but it is still important to discuss MK3 in brief [36]. This kinase has much lower expression levels as compared to MK2 [37], but possesses high structural identity and shares approximately similar substrate range with MK2 thus implying almost identical functional roles in biological systems [38]. The C-terminus of MK3 contains NLS and NES motifs rendering its unphosphorylated form located in the nucleus until p38MAPK-dependent phosphorylation induces its translocation to the cytoplasm. Additionally, MK3 could control cytokine biosynthesis in addition to MK2 due to its involvement in post-transcriptional changes in the ARE-containing mRNAs targeted by MK2 [39]. Furthermore, as compared to MK2−/−, the double knockout mice (MK2−/−/MK3−/−) had a higher reduction of lipopolysaccharide (LPS)-induced TNFα production [37]. Strikingly, functional dissimilarities among MK2 and MK3 have been portrayed [40].

Copy number variations in MK2

MK2 has been reported to be oncogenic with its involvement shown in growth and invasion of tumors [5]. Hence, genetic variations in MK2 might play a role in susceptibility and prognosis of cancer. Presently, several copy number variations (CNVs) have been shown to be associated with human diseases including cancers [41, 42]. Studies in the past have reported CNVs causing MK2 overexpression to influence prognosis of tumors [43]. Similarly, CNV-30450 which duplicates the MK2 promoter was shown to increase the risk and lead to poor prognosis of lung cancer [44]. The same group further assessed the correlation of this CNV to nasopharyngeal cancer (NPC) risk [45]. Recently, it was demonstrated that there is a loss of MK2 copy number in non-small cell lung cancer (NSCLC) [46]. These studies have highlighted the need of understanding CNVs and other genomic changes in MK2 as they might act as biomarkers for assessing susceptibility, predicting risk and prognosis of cancers.

Biological functions of MK2

The biological functionalities of MK2 have not been well elucidated till date. However, MK2−/− mice showcased a significant decrease in synthesis of TNFα in response to LPS [47]. in vitro studies on MK2-deficient cells have indicated a crucial role of MK2 in pro-inflammatory mediators (TNFα, IL-1β, IL-8, IL-6, and interferon-γ (IFNγ)) production [47]. MK2 was shown to be essential for up-regulation of cytokine mRNA stability and translation which is LPS-induced and hence, for stimulating cytokine biosynthesis which is integral in inflammatory responses [47]. Recently, MK2 has been reported to be intrinsic in control of cell-cycle at CDC25- and p53-dependent checkpoints [25] (Table 1, Fig. 4). DNA damage leads to inhibition of CDC25 by CHK1 and CHK2, and it has been reported that MK2 promotes G2/M checkpoint during stress response [25]. Further, MK2 was shown to phosphorylate and activate human homolog of mouse double minute 2 (HDM2), thereby causing p53 degradation suggesting the role of MK2 in dampening the p53-mediated response to DNA damage/stress [48].

Fig. 4
figure 4

MK2 is the master regulator of tumorigenesis. The figure represents a list of MK2-regulated downstream substrates (with corresponding references highlighted in bracket) in various cellular pathways. The MK2 target genes represented here are play a vital role in cellular processes like cell cycle, inflammation, transcription, tumorigenesis and tumor microenvironment. The list is intended to be an illustration rather than being comprehensive

MK2 orchestrates the post-transcriptional regulation of gene expression by modulating the function of RBPs [49]. It has been demonstrated that MK2 and Hsp27 both modulate cell invasion and MMP-2 activation [50]. Targeting of MK2 could be a more viable option than p38MAPK, due to potentially limited side effects, attributed to limited downstream substrates of MK2 as compared to p38MAPK. Notably, MK2−/− mice are viable and have a normal phenotype [47]. Hence, much of the research has been focussed on utilizing MK2 as a molecular target for developing therapeutics for ailments like alzheimer’s, atherosclerosis, cancer, and rheumatoid arthritis (RA). MK2 modifies the function of RBPs, but MK2’s substrate spectrum is significantly limited than p38MAPK, thereby, MK2 has emerged as an attractive anti-inflammatory and anti-cancer target.

MK2 in cell cycle regulation

Insights into the molecular mechanisms of MK2-mediated post-transcriptional regulation indicated its involvement in cell-cycle control at the CDC25- and p53-dependent checkpoints [25, 51]. Reports have shown that MK2 phosphorylates CDC25B/C at specific sites in ultraviolet (UV)-treated osteosarcoma cells and that MK2−/− causes loss of G2/M checkpoint [25] (Fig. 4). Hence, MK2 can be contemplated as one of the members of the DNA-damage-checkpoint-kinase family which acts in conjunction with CHK1 and CHK2.

p53 (the tumor-suppressor protein) is also reported to be a p38MAPK cascade target. p53 has been shown to be essential for the regulation of cell-cycle at the G1/S phase and further entry into apoptosis [52]. Strikingly, p53 is a direct substrate of p38MAPK, whereas the p53-interacting ubiquitin ligase, HDM2 which is responsible for p53 degradation has been identified as one of the MK2 targets [25]. HDM2 activation occurs as a result of its phosphorylation by MK2 which further leads to increased p53 degradation, thereby, resembling the HDM2 activation by the protein kinase B (PKB)/survival kinase AKT. Hence, it has been hypothesized that MK2 inhibits p53 activity after its stimulation by p38MAPK-mediated phosphorylation, thereby, contributing to the fine regulation of DNA-damage response. Finally, the p38MAPK/MK2 pathway has been shown to activate signaling leading to G2/M checkpoint arrest and further cell survival post-DNA damage caused due to chemotherapeutics, thus responsible for resistance to treatment regimens. Mouse double minute 2 homolog (Mdm2) acts as a p53 post-transcriptional regulator, functioning by inactivating p53 through augmenting its degradation by the proteasome and repressing its transcriptional activity, thereby, down-regulating its protein levels [53]. MK2 portrays a central role in p53 post-transcriptional regulation, as it has been reported that Mdm2 phosphorylation occurs via MK2. Further, MK2−/− cells have elevated p53 levels with reduced Mdm2 phosphorylation [48]. Reinhardt et al. [54] demonstrated that tumors lacking functional p53 can survive the effect of DNA-damage causing chemotherapeutics via a p38MAPK/MK2-dependent route. Meanwhile, in p53-overexpressing cells, this pathway was dispensable for survival post-DNA damage. These reports showcase that MK2 follows different mechanisms for the regulation of cell survival in response to DNA damage.

Post-transcriptional regulation by MK2 in inflammation

Literature suggests that MK2−/− mice have enhanced resistance to endotoxic shock, attributed to impairment in the inflammatory response, in addition to a decreased production of TNFα and IL-6 cytokines upon LPS-stimulation [47]. It is quite evident now that MK2 is the prime downstream substrate of p38MAPK, and this signaling cascade regulates the stability and translation of TNFα and IL-6 mRNAs through AREs involvement in the 3′-UTRs of these transcripts (Fig. 4). TTP is an RBP that has been shown to control TNFα mRNA’s stability and translation and is a direct substrate of MK2 [30]. TTP’s phosphorylation by MK2 increases its stability and binding to 14–3-3 proteins [25] and thereby stimulates TNFα expression.

Role of MK2 in actin remodeling

Hsp27 portrays a crucial role in remodeling of actin and cell migration. In its unphosphorylated state, Hsp27 can function as an actin filament cap-binding protein, leading to inhibition of globular actin polymerization into filamentous actin (F-actin). MK2-mediated Hsp27 phosphorylation [7] blocks capping activity, thus, promoting actin polymerization and remodeling [55] (Fig. 4). Furthermore, Hsp27 phosphorylation inhibits its multimeric self-aggregation, causing loss of its chaperone activity [56]. Association of the MK2/Hsp27 relation in cell migration and remodeling of actin is also crucial for invasion and metastasis of cancer.

Role of MK2 in tumorigenesis and tumor microenvironment

In tumor cells, the emergence of MK2 as an alternative cell-cycle checkpoint, responsible for resistance to apoptosis caused by p53 mutation, has put forward MK2 as an effective target for combination-based cancer therapies [7]. Depending on stimuli, MK2 regulates phosphorylation, mRNA stability, and expression of various proteins involved in actin remodeling [57], cell migration [58], immune responses [47], cell cycle and apoptosis [7] (Fig. 4).

Role in DSS-induced colitis and colorectal cancer

In colorectal carcinoma, epithelial cell proliferation and apoptosis are the key parameters contributing to tumorigenesis. As discussed earlier, one of the most important downstream mediators of MK2’s function is Hsp27, which is phosphorylated by MK2 in response to a variety of stimuli and is strongly associated with cancer progression and metastasis [59]. A recent study on intestinal epithelial cells has shown that MK2 plays a role in progression of colon cancer through downstream activation of Hsp27, which ultimately leads to angiogenesis cytokine mediation, cell proliferation, migration, and apoptosis [60]. This study also emphasized that deletion of MK2 leads to reductions of both tumor size and invasive potential in azoxymethane (AOM)/dextran sodium sulfate (DSS) induced colon cancer in mice [60]. Surprisingly, phosphorylation of Hsp27 is not influenced by MK2 deletion thus indicating that the function of the p38MAPK/MK2/Hsp27 pathway is cell and tissue dependent in colon cancer [60].

Deletion of MK2 in intestinal mesenchymal cells had the most profound effect on tumor multiplicity and size and was found associated with decreased epithelial proliferation, increased apoptosis, and decreased angiogenesis [60]. Furthermore, induction of mesenchymal cells with various MK2 and Hsp27 inducers supported an MK2-dependent functional property of this pathway. Such stimuli which are abundant in the tumor microenvironment, induce the activation of MK2 and subsequently Hsp27, resulting in the downstream production of cytokines, chemokines, and matrix metalloproteinases (MMPs), resulting in modulation of tumor microenvironment and signaling to induce cell differentiation, survival, and growth [60] (Fig. 4). Hence, it is quite evident that MK2 regulates tumor growth and progression in the intestine and could serve as a potential therapeutic target and a promising alternative to p38MAPK inhibition.

Role in skin cancer

Literature reports demonstrate that MK2 is required for the development of skin tumors. It regulates inflammatory response as well as maintains DNA-damaged cells survival caused by 7,12-dimethylbenz[a]anthracene (DMBA) during tumor initiation [61]. MK2-deficient keratinocytes were more prone to carcinogen-induced apoptosis via impaired Mdm2 phosphorylation and subsequently increased p53 stabilization. This suggests an inhibitory role of MK2 in apoptosis induction during tumor promotion. A crucial mediator in response to DNA damage, the p53 protein has been shown to play a pivotal role in apoptosis induction [62].

In a nutshell, MK2 works as a double-edged sword in skin carcinogenesis as it regulates pro-inflammatory cytokine expression as well as apoptosis via the p53-signaling pathway. It has been reported the loss of MK2 on the one hand, causes decreased inflammatory response while on the other hand it increased p53 stabilization, thereby increasing the number of DNA-damaged cells that undergo apoptosis (Fig. 4). In conclusion, MK2 inhibitors could be potential anticancer agents and be employed to inhibit the early stages during carcinoma development.

Role in bladder cancer

MK2 and Hsp27 lead to activation of cell invasion and MMP-2 in prostate cancer [50], with past studies showing MAPK pathways to be activated during growth phase in bladder cancer cells [63]. Further studies have reported that p38MAPK and MK2 regulate the invasion and metastasis of bladder cancer through MMP-2 and MMP-9 mRNA stability modulation [58] (Fig. 4).

Up-regulation of MMPs is one of the processes by which p38MAPK promotes cell migration and invasion in tumors. Past reports have shown high MMP-2/9 activity in HTB9 cells, while in HTB5 cells MMP-9 activity in a basal state was low. Additionally, it has been observed that p38MAPK signaling inhibition reduces MMP-2/9 activity. Hence it could be said that active p38MAPK signaling by modulation of MMP-2/9 activity may regulate the migration/invasion in bladder cancer [58]. Furthermore, the addition of MMP-2/9 antibody led to inhibition of tumor invasion, indicating that MMP expression in bladder cancers is directly responsible for it. These reports suggested that p38MAPK pathway could regulate the activity of MMP independent of tissue inhibitor of metalloproteinases (TIMP) regulation. Indeed, it has been observed that a p38MAPK inhibitor and a dominant-negative kinase-inactive mutant of MK2 led to a significant reduction in MMP-2/9 mRNA half-life. Earlier Xu and colleagues [50] had reported the role of MK2 and Hsp27 in prostate cancer cell lines invasion. Taken together, it can be concluded that the invasion of bladder cancer cells is regulated by p38MAPK-driven MK2 through stabilization of MMP-2/9 transcripts [58].

Role in prostate cancer

Transforming growth factor β (TGFβ) is an important regulator of cell adhesion and motility in a wide range of cell types including prostate and is shown to act in a cell-specific manner [64, 65]. Past studies have shown that TGFβ-mediated increase in cell invasion in human prostate cancer is dependent upon p38MAPK activation [66]. It has also been observed that both Smad3 and p38MAPK are integral for TGFβ-mediated cell adhesion in prostate cancer [66]. Recent studies have suggested that during colorectal cancer progression, TGFβ promotes tumor growth via its involvement in crosstalk with different pathways like p38MAPK and Wnt [67]. A study by Xu et al. demonstrated that in human prostate cancer both MK2 and Hsp27 are important for TGFβ-mediated up-regulation of MMP-2 activity and cell invasion which was inhibited by SB203580, a p38MAPK inhibitor [50]. This clearly indicated a direct role of p38MAPK signalling in prostate cancer through a channelized activation of p38MAPK, MK2 and Hsp27 (Fig. 4).

MK2 and mRNA stability (interplay between MK2, RBPs and target RNAs)

Adenine/uridine-rich elements (AREs)

Cytokines are essential for cell signaling to facilitate responses to various stimuli necessary for the maintenance of homeostasis and survival. Any malfunction in the cytokine signaling network has damaging effects on both the intra-cellular as well as the extracellular environments. An important process in cancer pathogenesis is cytokine and growth factor dysregulation which causes uncontrolled cell growth. Hence, tight regulation of the expression of cytokines at transcriptional and post-transcriptional levels is critical. AREs are conserved sequences located in the 3′-UTR of short-lived transcripts that codes for a multitude of proteins responsible for apoptosis, cellular activation, cytokine signaling, and growth. The stability of cytokine mRNAs has been shown to be altered due to the presence of AREs in their 3′-UTRs.

In 1986, conserved AREs were found in the 3′-UTR of genes encoding short-lived cytokines (granulocyte-macrophage colony-stimulating factor (GM-CSF) and TNFα) [68]. A lot of information about the role of AREs in the post-transcriptional regulation of many cytokines and growth factors is available [69]. AREs act as binding sites for RBPs that regulate mRNA half-life [70]. Most of the RBPs that bind to AREs target them to exosome thereby promoting rapid deadenylation and degradation of their substrate mRNAs (e.g., TTP, AUF1) [71]. Approximately 10–15% of all mRNAs comprising a functionally diverse pool responsible for cellular proliferation, development inflammatory and immune response, RNA metabolism, signaling, and transcription harbour AU-rich sequences [72, 73]. The recently constructed human ARE-containing mRNA database encompasses greater than 1000 transcripts [74]. Within the 3′-UTR, the presence of an ARE is a common link in many unstable mRNAs in mammals which is a part of the regulatory system responsible for the mRNA degradation or stabilization and is linked to interaction with RBPs [75]. The fate of ARE-containing mRNAs is determined by the integration of functionalities of multiple ARE-binding proteins/RBPs [76].

3′-UTR located AREs constitute cis-elements causing rapid degradation of transcripts encoding many cytokines, growth factors, and proto-oncogenes [77]. It has been shown previously and confirmed by findings in MK2−/− mice that the p38MAPK/MK2 pathway facilitates transcript stability of mRNAs that harbour distinct AREs [8, 24, 78]. In comparison, the stability of ARE-deficient mRNAs was not affected [79]. The molecular mechanisms behind the control of ARE-mediated stabilization/decay involve the activity of proteins selectively interacting with ARE, but their mode of action is not well elucidated [80].

AREs comprises of many large clusters of overlapping AUUUA pentamers repeats and UUAUUUAUU nonamers that are specifically recognized by a variety of different ARE-binding proteins and found in transcripts encoding various cell cycle regulators (p16, p21, p27, cyclins, and Cdks), cytokines, epidermal growth factor (EGF), insulin-like growth factor (IGF), proto-oncogenes (c-fos, c-jun, c-myc), TGFβ, and vascular endothelial growth factor (VEGF) [77]. The list has considerably increased as a result of various genome sequencing programs [72]. Continuously active mRNA-decay mechanisms restrict the cytokine expression in resting cells. mRNA stability regulation through AREs is a post-transcriptional control mechanism which allows cells under varying environmental conditions to fine-tune the expression of important gene products (reviewed in [81]).

RNA-binding proteins (RBPs)

RBPs are single or double-stranded RNA binding proteins present in cells which participate in the formation of ribonucleoprotein complexes and portray pivotal roles in processes such as cellular functions, transport, and localization. They are responsible for post-transcriptional control of RNAs, such as pre-mRNA splicing, and polyadenylation, as well as mRNA export, turnover, localization, and translation [82]. Apart from regulating mRNA decay, RBPs mediate other post-transcriptional processes like intracellular localization, pre-mRNA processing, translation, and transport (reviewed in [83]). Various reports have highlighted the function of multiple diverse classes of RBPs in the regulation of mRNA decay and stabilization (reviewed in [84]).

Studies have indicated the role of MK2 in the modification of the stability and translation of IL-6 and TNFα mRNA via activation of RBPs such as TTP, AUF1, and HuR (Table 1). These processes of complex post-transcriptional cytokine synthesis regulation via MK2-mediated RBPs phosphorylation have been discussed in some excellent reviews [85, 86]. A number of proteins having the potential to bind to ARE are known, among them TTP, and AUF1 stimulate target transcript decay by recruiting deadenylases and downstream degradation machinery [87]. By contrast, the embryonic lethal and abnormal vision (ELAV) family member HuR stabilizes its targets by competing with the destabilizing ARE-binding proteins for ARE occupancy (reviewed in [87, 88]). Induction of decay pathways for mRNA allows for the attenuation of cellular cytokines production through interactions with RBPs [89].

During inflammatory responses, cytokine mRNAs are stabilized via complex interactions with RBPs controlled by phosphorylation via multiple signaling pathways including the MAPKs. Activation of p38MAPK stabilizes the COX-2 transcripts via its effect on AUF-1, HuR, and TTP [90]. Substantial evidence has highlighted the relevance of mRNA stability in the regulation of genes [91]. mRNA fate is regulated by the complex interplay among the cis-acting sequences within mRNA and trans-acting nuclear and cytoplasmic factors [92]. The mammalian genome encodes approximately 1000 RBPs which portray important roles in mRNA stability, splicing, localization, nuclear export, and translation. RBPs physically interact with mRNA to exert their functionality in a highly sequence-specific manner. AREs are amongst the well-characterized regions that bind RBPs. Different RBPs have been discovered which function by stabilizing, destabilizing or influencing the translation of ARE-containing mRNAs (Table 1). A possible hypothesis for role of the p38MAPK cascade is that it stimulates the modification of RBPs by phosphorylation. RBPs are rightly called as the master regulators of transcript processing and translation with their expression often found to be aberrant in cancer [93]. In conjunction with much-studied transcription factors, RBPs have emerged as integral components in tumor development. RBPs along with their mRNAs targets form a complex network of post-transcriptional regulation of gene expression that plays a crucial role in tumorigenesis [94].

Tristetraprolin (TTP)

One of the substrates of MK2 is TTP [16, 95]. TTP is a critical anti-inflammatory RBP that presents transcripts to the decay machinery to enhance their mRNA decay [96]. Many essential proteins like cytokines are regulated by post-transcriptional TTP-mediated destabilizing mechanisms (reviewed in [97]). The role of TTP as a trans-acting anti-inflammatory RBP first came into light when TTP−/− mouse showed overexpression of TNFα in macrophages and developed the pro-inflammatory phenotype [98]. TTP confers mRNA instability and degradation by binding the conserved ARE in the 3′-UTR of transcripts [99], which promotes the poly(A) tail shortening reported in GM-CSF and TNFα [100]. TTP shows very low constitutive levels and is an early response gene induced in phagocytes by LPS. It functions as a negative feedback on cytokine mRNAs; hence, mice lacking TTP tend to overproduce cytokines. Contradictorily, TTP expression is influenced by p38MAPK signaling [16]. TTP becomes hyperphosphorylated, with both p38MAPK and MK2 having been implicated in this process [16, 95].

The p38MAPK pathway regulates the mRNA expression, mRNA decay property and protein expression of TTP via MK2 [101]. TTP binds the TNFα ARE and destabilizes the mRNA [99]. Mice null for TTP develop an inflammatory syndrome because they overexpressed TNFα [98]. MK2 phosphorylates 14–3-3 binding sites at Ser52 and Ser178 in TTP [95], causing the protein to be sequestered away from TNFα mRNA and prevents it from recruiting a deadenylase to the bound transcript [102, 103]. These phosphorylations enable complex formation of TTP with multifunction adaptor 14–3-3 proteins resulting in ablation of its function as a transcript destabilizing protein [95], hence, allowing efficient translation via subcellular translocation of the mRNA [51, 104]. Literature suggests that MK2-mediated TTP phosphorylation increases the expression of TTP protein via cytoplasmic retention and exclusion from proteasomal degradation [105]. TTP dephosphorylation causes its movement from the cytoplasm into the nucleus and causes its degradation [101]. The deletion of AREs in the 3′-UTR of TNFα in mice leads to elevated TNFα production and inflammatory disorders [106].

Many studies have shown that TTP overexpression in vitro promoted the decay of mRNAs containing AU-rich sequences from TNFα [99]. In a p38MAPK-dependent manner, TTP directs mRNA stability of IL-6 [107]. The p38MAPK-MK2 axis is responsible for TTP being a mRNA destabilizing factor [100]. Moreover, in head and neck squamous cell carcinoma (HNSCC), TTP down-regulation enhances the stability of mRNAs, promotes IL-6 and VEGF secretion and significantly increases cellular invasion in cancers by increased secretion of IL-6 and MMP-2/9 [108, 109]. Given all these reports, TTP could be considered a therapeutic target as it can concurrently lead to down-regulation of multiple cytokines in HNSCC.

It was recently shown that TTP expression is inversely correlated with invasion in HNSCC [108]. In macrophages, TTP is inactivated by phosphorylation [51]. The mechanism by which TTP mediates invasion of HNSCC has been investigated, and it has been shown that the suppression or p38MAPK-mediated phosphorylation of TTP leads to the promotion of invasion due to enhanced secretion of IL-6 and MMP-2/9. TTP promotes mRNAs degradation by binding to AREs in the 3′-UTR [96, 107]. In macrophages, p38MAPK inactivates TTP via MK2-mediated phosphorylation at two serine sites [51, 103]. Typical targets of TTP are mRNAs regulating tumor growth such as TNFα, COX-2, VEGF, and IL-10 [110] (Table 1). It has been suggested that decreased TTP expression contributes to cancer-related processes, and reports show that TTP-mediated regulation of crucial cancer-related transcripts in breast cancer cell leads to suppression of their invasive potential [111].

Human antigen R (HuR)

HuR, one of the most prominent RBP, is intricately involved in tumorigenesis [112], with its overexpression been observed in a number of cancers including brain, breast, colon, gastric, lung, lymphomas, oral, ovarian, pancreatic, prostate, and skin cancers [113]. In normal cells, HuR is generally localized in the nucleus, but in transformed cells, it often translocates to the cytoplasm [114]. MK2 has been shown to induce the cytoplasmic accumulation of HuR [114]. MK2 has been shown to regulate intercellular adhesion molecule-1 (ICAM-1) and IL-8 expression in acute inflammatory response via HuR [115]. The sub-cellular localization of HuR is governed by post-translational modifications, and all the HuR modifying enzymes are implicated in cancer processes [116]. In the cytoplasm, HuR binds to AREs located in 3′-UTR of target mRNAs. HuR is most often functionally defined as a positive regulator of target mRNAs-stability and translation [112], which generally code for cyclins, favouring cell cycle progression and promoting proliferation of malignant cells [117]. In vivo models suggested a more diverse functional array with multiple complex side-effects [118]. Investigations suggested that elevated cytoplasmic localization of HuR corresponds to high-grade tumor thereby serving as a good prognostic indicator for poor clinical response in many cancers [119].

HuR targets mRNAs which encodes products promoting proliferation, increasing angiogenesis, inhibiting apoptosis, and facilitating invasion and metastasis, viz. COX-2, GM-CSF, IL-6, IL-8, inducible nitric oxide synthase (NOS), TGFβ, TNFα, VEGF, and others [120] (Table 1). IL-1β activates the MK2-HuR pathway which significantly enhances IL-6 mRNA stability and leads to the development of an inflammatory environment in glioblastoma [121]. HuR leads to the promotion of cancer cell survival through stabilization of transcripts encoding anti-apoptotic factors like B-cell lymphoma 2 (Bcl-2), p21, and Sirtuin 1 (SIRT1) [122]. The mechanism behind this feature of HuR is still unclear, but a few studies attribute this to the interplay among HuR and microRNAs [123]. HuR enhances the stability of a set of its target mRNAs by antagonizing their binding to RBPs or microRNAs that destabilizes them [124, 125]. Overexpression of HuR is found in HNSCC, and it leads to increases in the stability of COX2 and VEGF mRNAs [113]. In several cancers (including HNSCC) increased cytoplasmic HuR localization has been found, which contributes to increased COX-2 expression in metastasis and tumorigenesis [126].

AU-rich element RNA-binding protein 1 (AUF1)

AUF1 is a RBP that regulates the mRNA stability of proto-oncogenes, growth factors, cytokines, and cell cycle regulatory genes. AUF1 generally destabilizes transcripts and has been shown to control the stability and translation of GM-CSF, IL-6, TNF-α, VEGF and many other ARE-containing mRNAs [127] (Table 1). AUF1 has been reported to be present in a cytosolic fraction and its overexpression in animal models has been shown to be associated with decreased mRNA stability [128]. It has been shown that a p38MAPK-MK2-Hsp27 signaling axis promotes proteasomal degradation of AUF1, further leading to cytokine ARE-mRNAs stabilization [129].

Correlation between MK2-mediated mRNA stabilization and tumorigenesis

An important determinant in modulating gene expression levels is the regulation of mRNA stability. Numerous studies in the past have demonstrated the importance of mRNA stability-mediated regulation in inflammation and cancer [9, 68, 89]. Modulation of the decay rate of various cytokines, proto-oncogenes, and growth factors, involves AREs in their 3′-UTRs [77]. RBPs tend to fine-tune cellular responses and directly mediate critical inflammatory signals responsible for disease pathogenesis by binding to AREs. It is quite evident that any aberrations in mRNA decay processes can lead to the over-production of certain gene-encoded products that can possibly lead to cancer. Post-transcriptional regulation of gene expression has been shown to be aberrant in tumors with over-expression of ARE-rich mRNAs been reported in multiple cancers [130]. RBPs like HuR have been shown to stabilize VEGF mRNA in various tumors [131]. AREs tend to play a huge role in the post-transcriptional regulation of certain genes involved in carcinogenesis [78]. Mechanistic insights on how AREs fine-tune mRNA stability reveal involvement of specific MK2-regulated RBPs [9, 132]. Past findings have implicated MK2 in mediating tumor invasion via regulating mRNA stability of MMP-2/9 in bladder cancer [58]. Hence, a better understanding of MK2-RBP mediated mechanisms will surely enable us to develop novel therapeutics in combating cancer progression [133].

Therapeutic implications of MK2

As therapeutic target?

MK2 modulates the stability and translation of inflammatory cytokines through phosphorylation of transactivating factors binding to their AREs [51]. Hence, MK2 inhibition could be a target for blocking the production of inflammatory mediators. Traditionally active site inhibitors of the kinases were employed for therapeutic purposes. But the major issue with this approach is that ATP competitive inhibitors of kinases have been known to be inherently cross-reactive, because of the homology shared by kinase active sites, hence, the development of specific active site kinase inhibitors is difficult.

A more viable approach in the development of selective kinase inhibitors is the search of agents that disrupt the docking among kinases, and their upstream and downstream signaling partners. MK2 docking domain comprising peptide is a potent inhibitor of p38MAPK-dependent phosphorylation of MK2. This might also perturb p38MAPK’s interaction with its upstream activators, like MKK3 [134]. Thus a more reasonable approach for inhibiting this pathway would be the development of inhibitors of the docking interactions between p38MAPK and its signaling partners [135].

Inhibitors of MK2: Types, uses and history

Systemic side-effects of p38MAPK inhibitors such as cardiac toxicity, hepatotoxicity and central nervous system (CNS) disorders have been among foremost hurdles against the developed inhibitors to transform into a successful drug. This was the main reason behind their failure in phase III clinical trials [136]. To overcome the issue and for effective inhibition of p38MAPK signalling pathway, researchers prompted toward numerous downstream targets of the pathway such as MK2 [10].

Currently, MK2 is widely considered as a novel disease-modifying anti-rheumatic drug (DMARD) ligand and a promising possible alternative to p38MAPK for the treatment of various inflammatory diseases. Study on the involvement of MK2 in inflammation associated disorders suggested that health of p38−/− mice suffering from embryonic lethality and loss of fertility was more severely affected as compared to the MK2−/− mice [137]. Furthermore, low levels of inflammatory cytokines have been observed in the brain and serum of MK2−/− mice in addition with limited or no symptoms in arthritis and lung sensitization models [10]. Along with it, neuro-protective effect has been observed after MK2 depletion indicated towards the association of neuro-inflammation with neurodegenerative disease such as parkinson’s disease, multiple sclerosis and even alzheimer’s disease. So it has been suggested that this linkage could be directly associated with modulation of MK2 activity [10].

Past studies had indicated that targeting MK2 to block its downstream events could be equivalent to direct inhibition of upstream p38α (responsible for MK2 activation) of the p38MAPK pathway, with the additional advantage of lacking any p38-dependent side effects [138, 139]. This is the reason that MK2 is currently being considered as a more promising target. The inhibitors of the MK2 activity could serve as potential therapeutic agents in the treatment of various inflammation and neuro-inflammation associated diseases. The active involvement of MK2 with Hsp27 may also be used to reduce remodelling and migration of cancer cells and metastasis through its abrogation. Furthermore, considering the capability of MK2 to modulate a cell cycle checkpoint, inhibitors of MK2 are also considered as effective tools to evade DNA repair mechanism induced by chemotherapy and thus resulting in increased sensitivity of tumor cells to chemotherapy [25, 58, 60].

Nearly all of the revealed MK2 inhibitors belong to the type I class of inhibitors (ATP competitive MK2 inhibitors (which binds to the ATP binding site of the kinase) and therefore compete with intra-cellular ATP molecules to block p38MAPK-mediated phosphorylation and activation of the kinase. Several compounds with in vivo efficacy against MK2 have been already reported by other researchers also [140]. After discerning various compounds with minimal to modest in vitro activity towards MK2 [141], researchers have made significant improvements in efficacy and safety as compared to compounds generated earlier. However, low biochemical efficiency (BE) value (generally expressed as the ratio between Ki - the binding affinity of inhibitor molecule to the target protein and its effective concentration 50 (EC50-cellular activity of the inhibitor) has been one of the major drawbacks of the MK2 inhibitors discovered so far.

Void and lacunas in the area of MK2 inhibitor research

Various studies on the mechanism of action of total marketed drugs demonstrate that around two-thirds of them have BE values higher than 0.4 [142]. A study by Swinney et al. [142] reported that BE value higher than 0.4 is an attribute of many approved drugs. If we conclude strictly, the EC50 values for any successful drug should not be more than 2.5-folds higher than its Ki values. Studies indicated that cellular efficacy reports for MK2 inhibitors in a diseased condition are quite inadequate in public domain, and indicated BE values of the tested inhibitors are far below the 0.4 threshold, suggesting the unlikeness of available MK2 inhibitors to become successful drug candidates [140]. Retaining in mind the fact that high concentrations of inhibitor compounds are required to ascertain good cellular efficacy in diseased conditions, their cytotoxicity, non-specificity and side-effects could be aggravated, thus increasing the probability of attrition. Conversely, compounds not competing with intracellular ATP could remain active at comparatively lower concentrations and have a greater probability to be optimized to become a drug. Inopportunely, the currently available uncompetitive and non-ATP competitive MK2 inhibitor compounds do not provide any experimental support to this hypothesis, thus, opening the door of possibilities for experimental validation of already available non-competitive MK2 inhibitors.

The higher affinity of inactive MK2 towards intracellular ATP has been anticipated as the major determinant of lowering the BE values for potential MK2 inhibitors. Consequently, researchers have screened their known inhibitors among the pool of compounds that bind the inactive form of the kinase, have a lesser competition with the high intracellular ATP concentration, and, accordingly, are required at low concentrations to give cellular effects in diseased conditions. By looking into all these factors, the importance of MK2 in modulating inflammatory conditions, cell cycle process, cytoskeleton remodelling and cell motility, non-ATP-competitive and allosteric inhibitors of MK2 are under continuous investigation as negative regulators or modulators of the p38MAPK/MK2 signalling pathway in various disorders [10].

Current insights into MK2 inhibitors

ATP competitive inhibitors

MK2 has been hypothesized as a potent druggable target in inflammatory disorders. The release of 3D structure of MK2 in complex with ADP or other small molecule inhibitors drove the discovery of numerous small molecule ATP-competitive inhibitors (Table 2). Conversely, blocking the MK2 with its ATP binding site in competitive mode gave rise to two important challenging issues. Firstly, the similarity of the ATP-binding site of MK2 with other kinases (MK3, MK5, etc.), interferes with the selectivity of inhibitors. Secondly, low BE value of the ATP-competitive inhibitors either due to high affinity of ATP for its binding site on kinase. Finally, solubility in suitable agents and permeability profiles of inhibitors appropriate for in vivo administration have been very difficult tasks to be addressed [10, 141].

Table 2 List of potent ATP competitive and non-competitive inhibitors of MK2 [151,152,153,154,155,156,157,158,159,160,161,162]

ATP non-competitive inhibitors

In the recent years, due to the inefficiencies associated with ATP-competitive inhibitors, promising inhibitors with non-ATP competitive and ATP-uncompetitive mechanism of action have been identified (Table 2). These compounds have the distinctiveness to interact with a binding site in kinase which is different from that of ATP, thus avoiding issues like selectivity with other kinases and low BE value. Additional advantage associated with them is effectiveness at low concentration. By definition, non-competitive inhibitors are not required to contend with the high ATP concentrations in cells and with high affinity of ATP for the inactive and active forms of MK2, effective lower concentrations of them promises less pronounced side-effects also. Mechanism of action of inhibitor dissimilar to ATP-competitiveness could enhance BE value of potential inhibitors and have better possibilities to be developed as an effective drug candidate against MK2. Thus, inhibitory efficacy of a non-ATP competitive inhibitor is expected to be higher than ATP-competitive inhibitors. Additionally, they could exert higher kinase selectivity profile as a consequence of the fact that they do not bind to similar ATP binding sites among related kinases [10].

Studies have shown that a good BE value enables the efficacy of a drug at lower concentrations with an increase in the therapeutic index, there is a minimum probability of success in clinical studies in case of ATP-competitive MK2 inhibitors. Mourey et al. [140] demonstrated in vivo efficacy of a selective ATP-competitive MK2 inhibitor PF-3644022 despite its biochemical inefficiency (BE 50.03). This inhibitor has been reported to reduce TNFα production in inflammation mice models. Various non-ATP-competitive inhibitors have been reported by Merck [143], and it would be of a topic of great interest to see the progression of this class of compounds in in vivo and clinical studies further (Table 2). As of now, the outcomes of MK2 inhibition can only be assumed and solely depend on the analysis of the efficacy of inhibitors of p38MAPK that target MK2 activation. Along these lines, Watterson et al. [144] have recently demonstrated that the anti-neuroinflammatory efficacy of blood-brain-barrier-permeable p38MAPK inhibitors in the animal model of Alzheimer’s disease correlates with the inhibition of MK2 activity. Recently, CDD-450, also called ATI-450 was developed as an unique inhibitor which possesses the property of selectively blocking p38MAPK-mediated MK2 activation while sparing other p38α substrates. ATI-450 has an efficacy similar to global p38α inhibitors and inhibits IL-6, IL-1β, and TNF-α production thereby decreasing inflammation in preclinical models [145].

Conclusions

MK2 activation generates a plethora of different biological effects targeting diverse cellular processes like cell-cycle progression, cytoskeletal architecture, mRNA stability, and protein translation via regulating the activation and deactivation cycles of RBPs [146, 147]. Improved understanding of MK2’s role in tumor progression could provide new insight into the enigma behind the post-transcriptional gene regulation in tumorigenesis. The complex mechanisms of post-transcriptional of cytokine regulation via MK2-mediated phosphorylation of RBPs play a pivotal role in tumorigenesis [85, 86].

Inhibition of the p38MAPK/MK2 pathway by blocking p38MAPK failed, as none of the inhibitors were found successful in the clinical trials due to the unwanted side effects [10]. Hence, in recent times, MK2 was preferred as a potential candidate for targeted therapies as a p38MAPK alternate to minimize the systemic undesired effects associated with the majority of p38MAPK inhibitors. MK2 remains a promising therapeutic target given the importance of the p38/MK2 pathway in processes like cell-cycle, inflammation, and metastasis.

DNA-damage due to chemotherapeutic agents could be repaired by cancer cells by arresting cell cycle progression and escaping apoptosis. It has been shown that MK2 activity is essential for G2/M arrest, hence; it gives an exciting prospective for the utility of MK2 inhibitors as chemo-sensitizers. Importantly, MK2-depleted mice are viable [47], in contrast to Chk1 and p38MAPK−/− mice [148], suggesting that MK2 inhibition could target cancer cells the same way as Chk1 and p38MAPK inhibitors but with fewer side-effects. Latest reports of MK2 inhibition decreasing production of inflammatory cytokines and subsequently leading to reduced tumor volumes potentiates its use in therapeutics [149, 150].

Pathological roles of MK2 in several diseases has led to a renewed interest in developing drug-like MK2 inhibitors despite the difficulties encountered in this process. The identification of MK2 inhibitors with suitable pharmacodynamics and pharmacokinetics is an attractive question for medicinal chemists [10]. Scientific advances in the area of molecular oncology have opened novel research directions. Nowadays, numerous research endeavours have been concentrated towards developing targeted therapies and unveiling novel molecular markers which could be utilized in predictions of treatment outcome or personalized therapies. It is quite evident that further unraveling the molecular tumorigenesis enigma will surely pave the way forward for novel therapeutics and personalized treatment regimens for the patients.

Abbreviations

3′-UTR:

3′-untranslated region

AOM/DSS:

Azoxymethane/Dextran sodium sulphate

AREs:

Adenine/uridine-rich elements

AUF1:

AU-rich element RNA-binding protein 1

BCL-2:

B-cell lymphoma 2

BE:

Biochemical efficiency

CDC25:

Cell division cycle 25

CNV:

Copy number variation

COX-2:

Cyclooxygenase-2

CREB:

Cyclic AMP-responsive element-binding protein

DMARD:

Disease-modifying anti-rheumatic drug

DMBA:

7,12-dimethylbenz[a]anthracene

EC50:

Effective concentration 50

EGF:

Epidermal growth factor

ELAV:

Embryonic lethal and abnormal vision

ERK:

Extracellular signal-regulated kinase

F-actin:

Filamentous actin

GM-CSF:

Granulocyte-macrophage colony-stimulating factor

HDM2:

Human homolog of mouse double minute 2

HNSCC:

Head and neck squamous cell carcinoma

HSP27:

Heat shock protein

HuR:

Human antigen R

IECs:

Intestinal epithelial cells

IFNγ:

Interferon-γ

IGF:

Insulin-like growth factor

IL:

Interleukin

LPS:

Lipopolysaccharide

MAP2K:

MAPK kinase

MAP3K:

MAPK kinase kinase

MAPKAPK2 or MK2:

Mitogen-activated protein kinase-activated protein kinase 2

MDM2:

Mouse double minute 2 homolog

MK2−/− :

MK2 knockout

MMP:

Matrix metalloproteinase

NES:

Nuclear export signal

NLS:

Nuclear localization signal

NOS:

Nitric oxide synthase

NPC:

Nasopharyngeal cancer

NSCLC:

Non-small cell lung cancer

p38MAPK:

p38 mitogen-activated protein kinase

PKB:

Protein kinase B

PLK1:

Polo-like kinase 1

RA:

Rheumatoid arthritis

RBPs:

RNA-binding proteins

SDS-PAGE:

Sodium dodecyl sulphate-polyacrylamide gel electrophoresis

SIRT1:

Sirtuin 1

TGFβ:

Transforming growth factor β

TIMP:

Tissue inhibitor of metalloproteinases

TNFα:

Tumor necrosis factor

TSC2:

Tuberin

TTP:

Tristetraprolin

UTR:

Untranslated region

UV:

Ultraviolet

VEGF:

Vascular endothelial growth factor

References

  1. Lee JC, Laydon JT, McDonnell PC, Gallagher TF, Kumar S, Green D, McNulty D, Blumenthal MJ, Keys JR, Strickler JE, McLaughlin MM. A protein kinase involved in the regulation of inflammatory cytokine biosynthesis. Nature. 1994;372:739.

    Article  CAS  PubMed  Google Scholar 

  2. Seisenbacher G, Hafen E, Stocker H. MK2-dependent p38b signalling protects Drosophila hindgut enterocytes against JNK-induced apoptosis under chronic stress. PLoS Genet. 2011;7:e1002168.

    Article  CAS  PubMed  PubMed Central  Google Scholar 

  3. Li Y, Inoki K, Vacrasis P, Guan KL. The p38 and MK2 kinase cascade phosphorylates tuberin, the tuberous sclerosis 2 (TSC2) gene product, and enhances its interaction with 14-3-3. J Biol Chem. 2003;278:13663–71.

  4. Wu R, Kausar H, Johnson P, Montoya-Durango DE, Merchant M, Rane MJ. Hsp27 regulates Akt activation and PMN apoptosis by scaffolding MK2 to Akt signal complex. J Biol Chem. 2007;282:21598–608.

  5. Jackson RM, Garcia-Rojas R. Kinase activity, heat shock protein 27 phosphorylation, and lung epithelial cell glutathione. Exp Lung Res. 2008;34:245–62.

    Article  CAS  PubMed  Google Scholar 

  6. Stokoe D, Campbell DG, Nakielny S, Hidaka H, Leevers SJ, Marshall C, Cohen P. MAPKAP kinase-2; a novel protein kinase activated by mitogen-activated protein kinase. EMBO J. 1992;11:3985–94.

    Article  CAS  PubMed  PubMed Central  Google Scholar 

  7. Gurgis FM, Ziaziaris W, Munoz L. Mitogen-activated protein kinase–activated protein kinase 2 in neuroinflammation, heat shock protein 27 phosphorylation, and cell cycle: role and targeting. Mol Pharmacol. 2014;85:345–56.

    Article  PubMed  CAS  Google Scholar 

  8. Winzen R, Kracht M, Ritter B, Wilhelm A, Chen CY, Shyu AB, Müller M, Gaestel M, Resch K, Holtmann H. The p38 MAP kinase pathway signals for cytokine-induced mRNA stabilization via MAP kinase-activated protein kinase 2 and an AU-rich region-targeted mechanism. EMBO J. 1999;18:4969–80.

    Article  CAS  PubMed  PubMed Central  Google Scholar 

  9. Pereira B, Billaud M, Almeida R. RNA-binding proteins in cancer: old players and new actors. Trends Cancer. 2017;3:506–28.

    Article  CAS  PubMed  Google Scholar 

  10. Fiore M, Forli S, Manetti F. Targeting mitogen-activated protein kinase-activated protein kinase 2 (MAPKAPK2, MK2): medicinal chemistry efforts to lead small molecule inhibitors to clinical trials. J Med Chem. 2015;59:3609–34.

    Article  PubMed  PubMed Central  CAS  Google Scholar 

  11. Ashwell JD. The many paths to p38 mitogen-activated protein kinase activation in the immune system. Nat Rev Immunol. 2006;6:532.

    Article  CAS  PubMed  Google Scholar 

  12. Arthur JS, Ley SC. Mitogen-activated protein kinases in innate immunity. Nat Rev Immunol. 2013;13:679.

    Article  CAS  PubMed  Google Scholar 

  13. Zu YL, Wu FY, Gilchrist A, Ai YX, Labadia ME, Huang CK. The primary structure of a human MAP kinase activated protein kinase 2. Biochem Biophys Res Commun. 1994;200:1118–24.

    Article  CAS  PubMed  Google Scholar 

  14. Guay J, Lambert H, Gingras-Breton G, Lavoie JN, Huot J, Landry J. Regulation of actin filament dynamics by p38 map kinase-mediated phosphorylation of heat shock protein 27. J Cell Sci. 1997;110:357–68.

    CAS  PubMed  Google Scholar 

  15. Tan YI, Rouse J, Zhang A, Cariati S, Cohen P, Comb MJ. FGF and stress regulate CREB and ATF-1 via a pathway involving p38 MAP kinase and MAPKAP kinase-2. EMBO J. 1996;15:4629–42.

    Article  CAS  PubMed  PubMed Central  Google Scholar 

  16. Mahtani KR, Brook M, Dean JL, Sully G, Saklatvala J, Clark AR. Mitogen-activated protein kinase p38 controls the expression and posttranslational modification of tristetraprolin, a regulator of tumor necrosis factor alpha mRNA stability. Mol Cell Biol. 2001;21:6461–9.

    Article  CAS  PubMed  PubMed Central  Google Scholar 

  17. Sudo T, Kawai K, Matsuzaki H, Osada H. p38 mitogen-activated protein kinase plays a key role in regulating MAPKAPK2 expression. Biochem Biophys Res Commun. 2005;337:415–21.

    Article  CAS  PubMed  Google Scholar 

  18. Suarez-Lopez L, Sriram G, Kong YW, Morandell S, Merrick KA, Hernandez Y, Haigis KM, Yaffe MB. MK2 contributes to tumor progression by promoting M2 macrophage polarization and tumor angiogenesis. Proc Natl Acad Sci U S A. 2018;115:4236–44.

    Article  Google Scholar 

  19. Dalle-Donne I, Rossi R, Milzani A, Di Simplicio P, Colombo R. The actin cytoskeleton response to oxidants: from small heat shock protein phosphorylation to changes in the redox state of actin itself. Free Radic Biol Med. 2001;31:1624–32.

    Article  CAS  PubMed  Google Scholar 

  20. Hedges JC, Dechert MA, Yamboliev IA, Martin JL, Hickey E, Weber LA, Gerthoffer WT. A role for p38MAPK/HSP27 pathway in smooth muscle cell migration. J Biol Chem. 1999;274:24211–9.

    Article  CAS  PubMed  Google Scholar 

  21. Ray AL, Berggren KL, Restrepo Cruz S, Gan GN, Beswick EJ. Inhibition of MK2 suppresses IL-1β, IL-6, and TNF-α-dependent colorectal cancer growth. Int J Cancer. 2018;142:1702–11.

    Article  CAS  PubMed  Google Scholar 

  22. Stokoe D, Engel K, Campbell DG, Cohen P, Gaestel M. Identification of MAPKAP kinase 2 as a major enzyme responsible for the phosphorylation of the small mammalian heat shock proteins. FEBS Lett. 1992;313:307–13.

    Article  CAS  PubMed  Google Scholar 

  23. Menon MB, Ronkina N, Schwermann J, Kotlyarov A, Gaestel M. Fluorescence-based quantitative scratch wound healing assay demonstrating the role of MAPKAPK-2/3 in fibroblast migration. Cell Motil Cytoskeleton. 2009;66:1041–7.

    Article  CAS  PubMed  Google Scholar 

  24. Neininger A, Kontoyiannis D, Kotlyarov A, Winzen R, Eckert R, Volk HD, Holtmann H, Kollias G, Gaestel M. MK2 targets AU-rich elements and regulates biosynthesis of tumor necrosis factor and interleukin-6 independently at different post-transcriptional levels. J Biol Chem. 2002;277:3065–8.

    Article  CAS  PubMed  Google Scholar 

  25. Manke IA, Nguyen A, Lim D, Stewart MQ, Elia AE, Yaffe MB. MAPKAP kinase-2 is a cell cycle checkpoint kinase that regulates the G2/M transition and S phase progression in response to UV irradiation. Mol Cell. 2005;17:37–48.

    Article  CAS  PubMed  Google Scholar 

  26. Tang J, Yang X, Liu X. Phosphorylation of Plk1 at Ser326 regulates its functions during mitotic progression. Oncogene. 2008;27:6635.

    Article  CAS  PubMed  PubMed Central  Google Scholar 

  27. Ronkina N, Menon MB, Schwermann J, Tiedje C, Hitti E, Kotlyarov A, Gaestel M. MAPKAP kinases MK2 and MK3 in inflammation: complex regulation of TNF biosynthesis via expression and phosphorylation of tristetraprolin. Biochem Pharmacol. 2010;80:1915–20.

    Article  CAS  PubMed  Google Scholar 

  28. Stokoe D, Caudwell B, Cohen PT, Cohen P. The substrate specificity and structure of mitogen-activated protein (MAP) kinase-activated protein kinase-2. Biochem J. 1993;296:843–9.

    Article  CAS  PubMed  PubMed Central  Google Scholar 

  29. Engel K, Kotlyarov A, Gaestel M. Leptomycin B-sensitive nuclear export of MAPKAP kinase 2 is regulated by phosphorylation. EMBO J. 1998;17:3363–71.

    Article  CAS  PubMed  PubMed Central  Google Scholar 

  30. Ben-Levy R, Hooper S, Wilson R, Paterson HF, Marshall CJ. Nuclear export of the stress-activated protein kinase p38 mediated by its substrate MAPKAP kinase-2. Curr Biol. 1998;8:1049–57.

    Article  CAS  PubMed  Google Scholar 

  31. Tanoue T, Maeda R, Adachi M, Nishida E. Identification of a docking groove on ERK and p38 MAP kinases that regulates the specificity of docking interactions. EMBO J. 2001;20:466–79.

    Article  CAS  PubMed  PubMed Central  Google Scholar 

  32. Ben-Levy R, Leighton IA, Doza YN, Attwood P, Morrice N, Marshall CJ, Cohen P. Identification of novel phosphorylation sites required for activation of MAPKAP kinase-2. EMBO J. 1995;14:5920–30.

    Article  CAS  PubMed  PubMed Central  Google Scholar 

  33. Meng W, Swenson LL, Fitzgibbon MJ, Hayakawa K, ter Haar E, Behrens AE, Fulghum JR, Lippke JA. Structure of mitogen-activated protein kinase-activated protein (MAPKAP) kinase 2 suggests a bifunctional switch that couples kinase activation with nuclear export. J Biol Chem. 2002;277:37401–5.

    Article  CAS  PubMed  Google Scholar 

  34. Engel K, Schultz H, Martin F, Kotlyarov A, Plath K, Hahn M, Heinemann U, Gaestel M. Constitutive activation of mitogen-activated protein kinase-activated protein kinase 2 by mutation of phosphorylation sites and an A-helix motif. J Biol Chem. 1995;270:27213–21.

    Article  CAS  PubMed  Google Scholar 

  35. Chevalier D, Allen BG. Two distinct forms of MAPKAP kinase-2 in adult cardiac ventricular myocytes. Biochemistry. 2000;39:6145–56.

    Article  CAS  PubMed  Google Scholar 

  36. McLaughlin MM, Kumar S, McDonnell PC, Van Horn S, Lee JC, Livi GP, Young PR. Identification of mitogen-activated protein (MAP) kinase-activated protein kinase-3, a novel substrate of CSBP p38 MAP kinase. J Biol Chem. 1996;271:8488–92.

    Article  CAS  PubMed  Google Scholar 

  37. Ronkina N, Kotlyarov A, Dittrich-Breiholz O, Kracht M, Hitti E, Milarski K, Askew R, Marusic S, Lin LL, Gaestel M, Telliez JB. The mitogen-activated protein kinase (MAPK)-activated protein kinases MK2 and MK3 cooperate in stimulation of tumor necrosis factor biosynthesis and stabilization of p38 MAPK. Mol Cell Biol. 2007;27:170–81.

    Article  CAS  PubMed  Google Scholar 

  38. Cheng R, Felicetti B, Palan S, Toogood-Johnson I, Scheich C, Barker J, Whittaker M, Hesterkamp T. High-resolution crystal structure of human Mapkap kinase 3 in complex with a high affinity ligand. Protein Sci. 2010;19:168–73.

    CAS  PubMed  Google Scholar 

  39. Ronkina N, Kotlyarov A, Gaestel M. MK2 and MK3–a pair of isoenzymes. Front Biosci. 2008;13:5511–21.

    Article  CAS  PubMed  Google Scholar 

  40. Ehlting C, Ronkina N, Böhmer O, Albrecht U, Bode KA, Lang KS, Kotlyarov A, Radzioch D, Gaestel M, Häussinger D, Bode JG. Distinct functions of mitogen-activated protein kinase-activated protein (MAPKAP) kinases MK2 and MK3: MK2 mediates lipopolysaccharide-induced signal transducers and activators of transcription 3 (STAT3) activation by preventing negative regulatory effects of MK3. J Biol Chem. 2011;286:24113–24.

    Article  CAS  PubMed  PubMed Central  Google Scholar 

  41. McCarroll SA, Altshuler DM. Copy-number variation and association studies of human disease. Nat Genet. 2007;39:S37.

    Article  CAS  PubMed  Google Scholar 

  42. Shlien A, Malkin D. Copy number variations and cancer susceptibility. Curr Opin Oncol. 2010;22:55–63.

    Article  CAS  PubMed  Google Scholar 

  43. Birner P, Beer A, Vinatzer U, Stary S, Höftberger R, Nirtl N, Wrba F, Streubel B, Schoppmann SF. MAPKAP kinase 2 overexpression influences prognosis in gastrointestinal stromal tumors and associates with copy number variations on chromosome 1 and expression of p38 MAP kinase and ETV1. Clin Cancer Res. 2012;18:1879–87.

    Article  CAS  PubMed  Google Scholar 

  44. Liu B, Yang L, Huang B, Cheng M, Wang H, Li Y, Huang D, Zheng J, Li Q, Zhang X, Ji W. A functional copy-number variation in MAPKAPK2 predicts risk and prognosis of lung cancer. Am J Hum Genet. 2012;91:384–90.

    Article  CAS  PubMed  PubMed Central  Google Scholar 

  45. Yang L, Liu B, Qiu F, Huang B, Li Y, Huang D, Yang R, Yang X, Deng J, Jiang Q, Zhou Y. The effect of functional MAPKAPK2 copy number variation CNV-30450 on elevating nasopharyngeal carcinoma risk is modulated by EBV infection. Carcinogenesis. 2013;35:46–52.

    Article  PubMed  CAS  Google Scholar 

  46. Erdem JS, Skaug V, Haugen A, Zienolddiny S. Loss of MKK3 and MK2 copy numbers in non-small cell lung cancer. J Cancer. 2016;7:512.

    Article  CAS  Google Scholar 

  47. Kotlyarov A, Neininger A, Schubert C, Eckert R, Birchmeier C, Volk HD, Gaestel M. MAPKAP kinase 2 is essential for LPS-induced TNF-α biosynthesis. Nature Cell Biol. 1999;1:94.

    Article  CAS  PubMed  Google Scholar 

  48. Weber HO, Ludwig RL, Morrison D, Kotlyarov A, Gaestel M, Vousden KH. HDM2 phosphorylation by MAPKAP kinase 2. Oncogene. 2005;24:1965–72.

    Article  CAS  PubMed  Google Scholar 

  49. Morandell S, Reinhardt HC, Cannell IG, Kim JS, Ruf DM, Mitra T, Couvillon AD, Jacks T, Yaffe MB. A reversible gene-targeting strategy identifies synthetic lethal interactions between MK2 and p53 in the DNA damage response in vivo. Cell Rep. 2013;5:868–77.

    Article  CAS  PubMed  PubMed Central  Google Scholar 

  50. Xu L, Chen S, Bergan RC. MAPKAPK2 and HSP27 are downstream effectors of p38 MAP kinase-mediated matrix metalloproteinase type 2 activation and cell invasion in human prostate cancer. Oncogene. 2006;25:2987.

    Article  CAS  PubMed  Google Scholar 

  51. Stoecklin G, Stubbs T, Kedersha N, Wax S, Rigby WF, Blackwell TK, Anderson P. MK2-induced tristetraprolin: 14-3-3 complexes prevent stress granule association and ARE-mRNA decay. EMBO J. 2004;23:1313–24.

    Article  CAS  PubMed  PubMed Central  Google Scholar 

  52. Bulavin DV, Saito S, Hollander MC, Sakaguchi K, Anderson CW, Appella E, Fornace AJ. Phosphorylation of human p53 by p38 kinase coordinates N-terminal phosphorylation and apoptosis in response to UV radiation. EMBO J. 1999;18:6845–54.

    Article  CAS  PubMed  PubMed Central  Google Scholar 

  53. Ringshausen I, O'Shea CC, Finch AJ, Swigart LB, Evan GI. Mdm2 is critically and continuously required to suppress lethal p53 activity in vivo. Cancer Cell. 2006;10:501–14.

    Article  CAS  PubMed  Google Scholar 

  54. Reinhardt HC, Aslanian AS, Lees JA, Yaffe MB. p53-deficient cells rely on ATM-and ATR-mediated checkpoint signaling through the p38MAPK/MK2 pathway for survival after DNA damage. Cancer Cell. 2007;11:175–89.

    Article  CAS  PubMed  PubMed Central  Google Scholar 

  55. Manetti F. LIM kinases are attractive targets with many macromolecular partners and only a few small molecule regulators. Med Res Rev. 2012;32:968–98.

    Article  CAS  PubMed  Google Scholar 

  56. Rogalla T, Ehrnsperger M, Preville X, Kotlyarov A, Lutsch G, Ducasse C, Paul C, Wieske M, Arrigo AP, Buchner J, Gaestel M. Regulation of Hsp27 oligomerization, chaperone function, and protective activity against oxidative stress/tumor necrosis factor α by phosphorylation. J Biol Chem. 1999;274:18947–56.

    Article  CAS  PubMed  Google Scholar 

  57. Kotlyarov A, Yannoni Y, Fritz S, Laaß K, Telliez JB, Pitman D, Lin LL, Gaestel M. Distinct cellular functions of MK2. Mol Cellular Biol. 2002;22:4827–35.

    Article  CAS  Google Scholar 

  58. Kumar B, Koul S, Petersen J, Khandrika L, Hwa JS, Meacham RB, Wilson S, Koul HK. p38 mitogen-activated protein kinase–driven MAPKAPK2 regulates invasion of bladder cancer by modulation of MMP-2 and MMP-9 activity. Cancer Res. 2010;70:832–41.

    Article  CAS  PubMed  Google Scholar 

  59. Katsogiannou M, Andrieu C, Rocchi P. Heat shock protein 27 phosphorylation state is associated with cancer progression. Front Genet. 2014;5:346.

    Article  PubMed  PubMed Central  CAS  Google Scholar 

  60. Henriques A, Koliaraki V, Kollias G. Mesenchymal MAPKAPK2/HSP27 drives intestinal carcinogenesis. Proc Natl Acad Sci U S A. 2018;115:E5546–55.

    Article  CAS  PubMed  PubMed Central  Google Scholar 

  61. Johansen C, Vestergaard C, Kragballe K, Kollias G, Gaestel M, Iversen L. MK2 regulates the early stages of skin tumor promotion. Carcinogenesis. 2009;30:2100–8.

    Article  CAS  PubMed  Google Scholar 

  62. Riley T, Sontag E, Chen P, Levine A. Transcriptional control of human p53-regulated genes. Nat Rev Mol Cell Biol. 2008;9:402.

    Article  CAS  PubMed  Google Scholar 

  63. Kumar B, Sinclair J, Khandrika L, Koul S, Wilson S, Koul HK. Differential effects of MAPKs signaling on the growth of invasive bladder cancer cells. Int J Oncol. 2009;34:1557–64.

    CAS  PubMed  Google Scholar 

  64. Shi Y, Massagué J. Mechanisms of TGF-β signaling from cell membrane to the nucleus. Cell. 2003;113:685–700.

    Article  CAS  PubMed  Google Scholar 

  65. Attisano L, Wrana JL. Signal transduction by the TGF-β superfamily. Science. 2002;296:1646–7.

    Article  CAS  PubMed  Google Scholar 

  66. Hayes SA, Huang X, Kambhampati S, Platanias LC, Bergan RC. p38 MAP kinase modulates Smad-dependent changes in human prostate cell adhesion. Oncogene. 2003;22:4841.

    Article  CAS  PubMed  Google Scholar 

  67. Cheruku HR, Mohamedali A, Cantor DI, Tan SH, Nice EC, Baker MS. Transforming growth factor-β, MAPK and Wnt signaling interactions in colorectal cancer. EuPA Open Proteom. 2015;8:104–15.

    Article  CAS  Google Scholar 

  68. Shaw G, Kamen R. A conserved AU sequence from the 3′ untranslated region of GM-CSF mRNA mediates selective mRNA degradation. Cell. 1986;46:659–67.

    Article  CAS  PubMed  Google Scholar 

  69. Anderson P. Post-transcriptional regulons coordinate the initiation and resolution of inflammation. Nat Rev Immunol. 2010;10:24.

    Article  CAS  PubMed  Google Scholar 

  70. Audic Y, Hartley RS. Post-transcriptional regulation in cancer. Biol Cell. 2004;96:479–98.

    Article  CAS  PubMed  Google Scholar 

  71. Sanduja S, Dixon DA. Tristetraprolin and E6-AP: killing the messenger in cervical cancer. Cell Cycle. 2010;9:3135–6.

    Article  CAS  PubMed  Google Scholar 

  72. Bakheet T, Williams BR, Khabar KS. ARED 3.0: the large and diverse AU-rich transcriptome. Nucleic Acids Res. 2006;34:D111–4.

    Article  CAS  PubMed  Google Scholar 

  73. Halees AS, El-Badrawi R, Khabar KS. ARED organism: expansion of ARED reveals AU-rich element cluster variations between human and mouse. Nucleic Acids Res. 2007;36:D137–40.

    Article  PubMed  PubMed Central  CAS  Google Scholar 

  74. Khabar KS. The AU-rich transcriptome: more than interferons and cytokines, and its role in disease. J Interf Cytokine Res. 2005;25:1–10.

    Article  CAS  Google Scholar 

  75. DeMaria CT, Brewer G. AUF1 binding affinity to a+ U-rich elements correlates with rapid mRNA degradation. J Biol Chem. 1996;271:12179–84.

    Article  CAS  PubMed  Google Scholar 

  76. Janga SC, Mittal N. Construction, structure and dynamics of post-transcriptional regulatory network directed by RNA-binding proteins. In: RNA infrastructure and networks. Springer: New York; 2011. p. 103–17.

    Chapter  Google Scholar 

  77. Chen CY, Shyu AB. AU-rich elements: characterization and importance in mRNA degradation. Trends Biochem Sci. 1995;20:465–70.

    Article  CAS  PubMed  Google Scholar 

  78. Khabar KS. Hallmarks of cancer and AU-rich elements. Wiley Interdiscip Rev RNA. 2017;8:e1368.

  79. Bollig F, Winzen R, Kracht M, Ghebremedhin B, Ritter B, Wilhelm A, Resch K, Holtmann H. Evidence for general stabilization of mRNAs in response to UV light. Eur J Biochem. 2002;269:5830–9.

    Article  CAS  PubMed  Google Scholar 

  80. Wilusz CJ, Wormington M, Peltz SW. The cap-to-tail guide to mRNA turnover. Nature reviews Mol Cell Biol. 2001;2:237.

    Article  CAS  Google Scholar 

  81. Guhaniyogi J, Brewer G. Regulation of mRNA stability in mammalian cells. Gene. 2001;265:11–23.

    Article  CAS  PubMed  Google Scholar 

  82. Hogan DJ, Riordan DP, Gerber AP, Herschlag D, Brown PO. Diverse RNA-binding proteins interact with functionally related sets of RNAs, suggesting an extensive regulatory system. PLoS Biol. 2008;6:e255.

    Article  PubMed  PubMed Central  CAS  Google Scholar 

  83. Stumpo DJ, Lai WS, Blackshear PJ. Inflammation: cytokines and RNA-based regulation. Wiley Interdiscip Rev RNA 2010;1:60–80.

  84. Khabar KS. Post-transcriptional control during chronic inflammation and cancer: a focus on AU-rich elements. Cell Mol Life Sci. 2010;67:2937–55.

    Article  CAS  PubMed  PubMed Central  Google Scholar 

  85. Cargnello M, Roux PP. Activation and function of the MAPKs and their substrates, the MAPK-activated protein kinases. Microbiol Mol Biol Rev. 2011;75:50–83.

    Article  CAS  PubMed  PubMed Central  Google Scholar 

  86. Gaestel M. What goes up must come down: molecular basis of MAPKAP kinase 2/3-dependent regulation of the inflammatory response and its inhibition. Biol Chem. 2013;394:1301–15.

    Article  CAS  PubMed  Google Scholar 

  87. Ivanov P, Anderson P. Post-transcriptional regulatory networks in immunity. Immunol Rev. 2013;253:253–72.

    Article  PubMed  CAS  PubMed Central  Google Scholar 

  88. Turner M, Hodson DJ. An emerging role of RNA-binding proteins as multifunctional regulators of lymphocyte development and function. In Advances in Immunology, Academic Press. 2012;115:161–85.

    Article  CAS  Google Scholar 

  89. Anderson P. Intrinsic mRNA stability helps compose the inflammatory symphony. Nat Immunol. 2009;10:233.

    Article  CAS  PubMed  Google Scholar 

  90. Sengupta S, Jang BC, Wu MT, Paik JH, Furneaux H, Hla T. The RNA-binding protein HuR regulates the expression of cyclooxygenase-2. J Biol Chem. 2003;278:25227–33.

    Article  CAS  PubMed  Google Scholar 

  91. Hao S, Baltimore D. The stability of mRNA influences the temporal order of the induction of genes encoding inflammatory molecules. Nat Immunol. 2009;10:281.

    Article  CAS  PubMed  PubMed Central  Google Scholar 

  92. Elkon R, Zlotorynski E, Zeller KI, Agami R. Major role for mRNA stability in shaping the kinetics of gene induction. BMC Genomics. 2010;11:259.

    Article  PubMed  PubMed Central  CAS  Google Scholar 

  93. Kim MY, Hur J, Jeong SJ. Emerging roles of RNA and RNA-binding protein network in cancer cells. BMB Rep. 2009;42:125–30.

    Article  CAS  PubMed  Google Scholar 

  94. Silvera D, Formenti SC, Schneider RJ. Translational control in cancer. Nat Rev Cancer. 2010;10:254–66.

    Article  CAS  PubMed  Google Scholar 

  95. Chrestensen CA, Schroeder MJ, Shabanowitz J, Hunt DF, Pelo JW, Worthington MT, Sturgill TW. MAPKAP kinase 2 phosphorylates tristetraprolin on in vivo sites including Ser178, a site required for 14-3-3 binding. J Biol Chem. 2004;279:10176–84.

    Article  CAS  PubMed  Google Scholar 

  96. Carballo E, Lai WS, Blackshear PJ. Evidence that tristetraprolin is a physiological regulator of granulocyte-macrophage colony-stimulating factor messenger RNA deadenylation and stability. Blood. 2000;95:1891–9.

    CAS  PubMed  Google Scholar 

  97. Brooks SA, Blackshear PJ. Tristetraprolin (TTP): interactions with mRNA and proteins, and current thoughts on mechanisms of action. Biochim Biophys Acta Gene Regul Mech. 1829;2013:666–79.

    Google Scholar 

  98. Taylor GA, Carballo E, Lee DM, Lai WS, Thompson MJ, Patel DD, Schenkman DI, Gilkeson GS, Broxmeyer HE, Haynes BF, Blackshear PJ. A pathogenetic role for TNFα in the syndrome of cachexia, arthritis, and autoimmunity resulting from tristetraprolin (TTP) deficiency. Immunity. 1996;4:445–54.

    Article  CAS  PubMed  Google Scholar 

  99. Lai WS, Carballo E, Strum JR, Kennington EA, Phillips RS, Blackshear PJ. Evidence that tristetraprolin binds to AU-rich elements and promotes the deadenylation and destabilization of tumor necrosis factor alpha mRNA. Mol Cell Biol. 1999;19:4311–23.

    Article  CAS  PubMed  PubMed Central  Google Scholar 

  100. Marchese FP, Aubareda A, Tudor C, Saklatvala J, Clark AR, Dean JL. MAPKAP kinase 2 blocks tristetraprolin-directed mRNA decay by inhibiting CAF1 deadenylase recruitment. J Biol Chem. 2010;jbc:M110.

    Google Scholar 

  101. Brook M, Tchen CR, Santalucia T, McIlrath J, Arthur JS, Saklatvala J, Clark AR. Posttranslational regulation of tristetraprolin subcellular localization and protein stability by p38 mitogen-activated protein kinase and extracellular signal-regulated kinase pathways. Mol Cell Biol. 2006;26:2408–18.

    Article  CAS  PubMed  PubMed Central  Google Scholar 

  102. Sun L, Stoecklin G, Van Way S, Hinkovska-Galcheva V, Guo RF, Anderson P, Shanley TP. Tristetraprolin (TTP)-14-3-3 complex formation protects TTP from dephosphorylation by protein phosphatase 2a and stabilizes tumor necrosis factor-α mRNA. J Biol Chem. 2007;282:3766–77.

    Article  CAS  PubMed  Google Scholar 

  103. Clement SL, Scheckel C, Stoecklin G, Lykke-Andersen J. Phosphorylation of tristetraprolin by MK2 impairs AU-rich element mRNA decay by preventing deadenylase recruitment. Mol Cell Biol. 2011;31:256–66.

    Article  CAS  PubMed  Google Scholar 

  104. Sandler H, Stoecklin G. Control of mRNA decay by phosphorylation of tristetraprolin. Biochem Soc Trans. 2008;36:491–6.

    Article  CAS  PubMed  Google Scholar 

  105. Deleault KM, Skinner SJ, Brooks SA. Tristetraprolin regulates TNF TNF-α mRNA stability via a proteasome dependent mechanism involving the combined action of the ERK and p38 pathways. Mol Immunol. 2008;45:13–24.

    Article  CAS  PubMed  Google Scholar 

  106. Kontoyiannis D, Pasparakis M, Pizarro TT, Cominelli F, Kollias G. Impaired on/off regulation of TNF biosynthesis in mice lacking TNF AU-rich elements: implications for joint and gut-associated immunopathologies. Immunity. 1999;10:387–98.

    Article  CAS  PubMed  Google Scholar 

  107. Zhao W, Liu M, D'Silva NJ, Kirkwood KL. Tristetraprolin regulates interleukin-6 expression through p38 MAPK-dependent affinity changes with mRNA 3′ untranslated region. J Interf Cytokine Res. 2011;31:629–37.

    Article  CAS  Google Scholar 

  108. Van Tubergen E, Vander Broek R, Lee J, Wolf G, Carey T, Bradford C, Prince M, Kirkwood KL, D’silva NJ. Tristetraprolin regulates IL-6, which is correlated with tumor progression in patients with head and neck squamous cell carcinoma. Cancer. 2011;117:2677–89.

    Article  PubMed  CAS  Google Scholar 

  109. Van Tubergen EA, Banerjee R, Liu M, Vander Broek RJ, Light E, Kuo S, Feinberg S, Willis AL, Wolf GT, Carey TE, Bradford CR. Inactivation or loss of TTP promotes invasion in head and neck cancer via transcript stabilization and secretion of MMP9, MMP2 and IL-6. Clin Cancer Res. 2013;19:1169–79.

    Article  PubMed  PubMed Central  CAS  Google Scholar 

  110. Lai WS, Parker JS, Grissom SF, Stumpo DJ, Blackshear PJ. Novel mRNA targets for tristetraprolin (TTP) identified by global analysis of stabilized transcripts in TTP-deficient fibroblasts. Mol Cell Biol. 2006;26:9196–208.

    Article  CAS  PubMed  PubMed Central  Google Scholar 

  111. Al-Souhibani N, Al-Ahmadi W, Hesketh JE, Blackshear PJ, Khabar KS. The RNA-binding zinc-finger protein tristetraprolin regulates AU-rich mRNAs involved in breast cancer-related processes. Oncogene. 2010;29:4205.

    Article  CAS  PubMed  PubMed Central  Google Scholar 

  112. Abdelmohsen K, Gorospe M. Posttranscriptional regulation of cancer traits by HuR. Wiley Interdiscip Rev RNA 2010;1:214–229.

  113. Kakuguchi W, Kitamura T, Kuroshima T, Ishikawa M, Kitagawa Y, Totsuka Y, Shindoh M, Higashino F. HuR knockdown changes the oncogenic potential of oral cancer cells. Mol Cancer Res. 2010;8:520–8.

    Article  CAS  PubMed  Google Scholar 

  114. Hasegawa H, Kakuguchi W, Kuroshima T, Kitamura T, Tanaka S, Kitagawa Y, Totsuka Y, Shindoh M, Higashino F. HuR is exported to the cytoplasm in oral cancer cells in a different manner from that of normal cells. Br J Cancer. 2009;100:1943.

    Article  CAS  PubMed  PubMed Central  Google Scholar 

  115. Wu T, Shi JX, Geng S, Zhou W, Shi Y, Su X. The MK2/HuR signaling pathway regulates TNF-α-induced ICAM-1 expression by promoting the stabilization of ICAM-1 mRNA. BMC Pulm Med. 2016;16:84–94.

    Article  PubMed  PubMed Central  CAS  Google Scholar 

  116. Doller A, Pfeilschifter J, Eberhardt W. Signalling pathways regulating nucleo-cytoplasmic shuttling of the mRNA-binding protein HuR. Cell Signal. 2008;20:2165–73.

    Article  CAS  PubMed  Google Scholar 

  117. Guo X, Hartley RS. HuR contributes to cyclin E1 deregulation in MCF-7 breast cancer cells. Cancer Res. 2006;66:7948–56.

    Article  CAS  PubMed  Google Scholar 

  118. Papadaki O, Milatos S, Grammenoudi S, Mukherjee N, Keene JD, Kontoyiannis DL. Control of thymic T cell maturation, deletion and egress by the RNA-binding protein HuR. J Immunol. 2009;182:6779–88.

    Article  CAS  PubMed  Google Scholar 

  119. Heinonen M, Fagerholm R, Aaltonen K, Kilpivaara O, Aittomäki K, Blomqvist C, Heikkilä P, Haglund C, Nevanlinna H, Ristimäki A. Prognostic role of HuR in hereditary breast cancer. Clin Cancer Res. 2007;13:6959–63.

    Article  CAS  PubMed  Google Scholar 

  120. Nabors LB, Gillespie GY, Harkins L, King PH. HuR, a RNA stability factor, is expressed in malignant brain tumors and binds to adenine-and uridine-rich elements within 3′ untranslated regions of cytokine and angiogenic factor mRNAs. Cancer Res. 2001;61:2154–61.

    CAS  PubMed  Google Scholar 

  121. Gurgis FM, Yeung YT, Tang MX, Heng B, Buckland M, Ammit AJ, Haapasalo J, Haapasalo H, Guillemin GJ, Grewal T, Munoz L. The p38-MK2-HuR pathway potentiates EGFRvIII–IL-1β-driven IL-6 secretion in glioblastoma cells. Oncogene. 2015;34:2934–42.

    Article  CAS  PubMed  Google Scholar 

  122. Abdelmohsen K, Lal A, Kim HH, Gorospe M. Posttranscriptional orchestration of an anti-apoptotic program by HuR. Cell Cycle. 2007;6:1288–92.

    Article  CAS  PubMed  Google Scholar 

  123. Meisner NC, Filipowicz W. Properties of the regulatory RNA-binding protein HuR and its role in controlling miRNA repression. In: Regulation of microRNAs. New York: Springer; 2010. p. 106–23.

    Chapter  Google Scholar 

  124. Choi HJ, Yang H, Park SH, Moon Y. HuR/ELAVL1 RNA binding protein modulates interleukin-8 induction by muco-active ribotoxin deoxynivalenol. Toxicol Appl Pharmacol. 2009;240:46–54.

    Article  CAS  PubMed  Google Scholar 

  125. von Roretz C, Gallouzi IE. Decoding ARE-mediated decay: is microRNA part of the equation? J Cell Biol. 2008;181:189–94.

    Article  CAS  Google Scholar 

  126. Cha JD, Li S, Cha IH. Association between expression of embryonic lethal abnormal vision-like protein HuR and cyclooxygenase-2 in oral squamous cell carcinoma. Head Neck. 2011;33:627–37.

    Article  PubMed  Google Scholar 

  127. Gratacós FM, Brewer G. The role of AUF1 in regulated mRNA decay. Wiley Interdiscip Rev RNA. 2010;1:457–473.

  128. Loflin P, Chen CY, Shyu AB. Unraveling a cytoplasmic role for hnRNP D in the in vivo mRNA destabilization directed by the AU-rich element. Genes Dev. 1999;13:1884–97.

    Article  CAS  PubMed  PubMed Central  Google Scholar 

  129. Li ML, Defren J, Brewer G. Hsp27 and F-box protein β-TrCP promote degradation of mRNA decay factor AUF1. Mol Cell Biol. 2013;33:2315–26.

    Article  CAS  PubMed  PubMed Central  Google Scholar 

  130. Hitti E, Bakheet T, Al-Souhibani N, Moghrabi W, Al-Yahya S, Al-Ghamdi M, Al-Saif M, Shoukri MM, Lánczk A, Grépin R, Győrffy B. Systematic analysis of AU-rich element expression in cancer reveals common functional clusters regulated by key RNA-binding proteins. Cancer Res. 2016;76:4068–80.

    Article  CAS  PubMed  Google Scholar 

  131. Yoo PS, Mulkeen AL, Silva T, Schmitz J, Tai N, Uchio EM, Chu E, Cha CH. RNA-binding protein HUR regulates VEGF expression in human colorectal cancer cells. J Surg Res. 2006;130:219–20.

    Article  Google Scholar 

  132. Frevel MA, Bakheet T, Silva AM, Hissong JG, Khabar KS, Williams BR. p38 mitogen-activated protein kinase-dependent and-independent signaling of mRNA stability of AU-rich element-containing transcripts. Mol Cell Biol. 2003;23:425–36.

    Article  CAS  PubMed  PubMed Central  Google Scholar 

  133. Herman AB, Autieri MV. Inflammation-regulated mRNA stability and the progression of vascular inflammatory diseases. Clin Sci. 2017;131:2687–99.

    Article  CAS  Google Scholar 

  134. Chang CI, Xu BE, Akella R, Cobb MH, Goldsmith EJ. Crystal structures of MAP kinase p38 complexed to the docking sites on its nuclear substrate MEF2A and activator MKK3b. Mol Cell. 2002;9:1241–9.

    Article  CAS  PubMed  Google Scholar 

  135. Lukas SM, Kroe RR, Wildeson J, Peet GW, Frego L, Davidson W, Ingraham RH, Pargellis CA, Labadia ME, Werneburg BG. Catalysis and function of the p38α-MK2a signaling complex. Biochemistry. 2004;43:9950–60.

    Article  CAS  PubMed  Google Scholar 

  136. Genovese MC. Inhibition of p38: has the fat lady sung? Arthritis Rheum. 2009;60:317–20.

    Article  PubMed  Google Scholar 

  137. Allen M, Svensson L, Roach M, Hambor J, McNeish J, Gabel CA. Deficiency of the stress kinase p38α results in embryonic lethality: characterization of the kinase dependence of stress responses of enzyme-deficient embryonic stem cells. J Exp Med. 2000;191:859–70.

    Article  CAS  PubMed  PubMed Central  Google Scholar 

  138. Streicher JM, Ren S, Herschman H, Wang Y. MAPKactivated protein kinase-2 in cardiac hypertrophy and cyclooxygenase- 2 regulation in heart. Circ Res. 2010;106:1434–43.

    Article  CAS  PubMed  PubMed Central  Google Scholar 

  139. Vittal R, Fisher A, Gu H, Mickler EA, Panitch A, Lander C, Cummings OW, Sandusky GE, Wilkes DS. Peptidemediated inhibition of MK2 ameliorates bleomycin-induced pulmonary fibrosis. Am J Respir Cell Mol Biol. 2013;49:47–57.

    Article  CAS  PubMed  PubMed Central  Google Scholar 

  140. Mourey RJ, Burnette BL, Brustkern SJ, Daniels JS, Hirsch JL, Hood WF, Meyers MJ, Mnich SJ, Pierce BS, Saabye MJ, Schindler JF. A benzothiophene inhibitor of mitogen-activated protein kinase-activated protein kinase 2 inhibits tumor necrosis factor α production and has oral anti-inflammatory efficacy in acute and chronic models of inflammation. J Pharmacol Exp Ther. 2010;333:797–807.

    Article  CAS  PubMed  Google Scholar 

  141. Edmunds JJ, Talanian RV. MAPKAP kinase 2 (MK2) as a target for anti-inflammatory drug discovery. Anti-Inflammatory Drug Discovery. 2012;26:158.

    Article  CAS  Google Scholar 

  142. Swinney DC. Biochemical mechanisms of drug action: what does it take for success? Nat Rev Drug Discov. 2004;3:801.

    Article  CAS  PubMed  Google Scholar 

  143. Huang X, Zhu X, Chen X, Zhou W, Xiao D, Degrado S, Aslanian R, Fossetta J, Lundell D, Tian F, Trivedi P. A three-step protocol for lead optimization: quick identification of key conformational features and functional groups in the SAR studies of non-ATP competitive MK2 (MAPKAPK2) inhibitors. Bioorganic Med Chem Lett. 2012;22:65–70.

    Article  CAS  Google Scholar 

  144. Watterson DM, Grum-Tokars VL, Roy SM, Schavocky JP, Bradaric BD, Bachstetter AD, Xing B, Dimayuga E, Saeed F, Zhang H, Staniszewski A. Development of novel in vivo chemical probes to address CNS protein kinase involvement in synaptic dysfunction. PLoS One. 2013;8:e66226.

    Article  CAS  PubMed  PubMed Central  Google Scholar 

  145. Wang C, Hockerman S, Jacobsen EJ, Alippe Y, Selness SR, Hope HR, Hirsch JL, Mnich SJ, Saabye MJ, Hood WF, Bonar SL. Selective inhibition of the p38α MAPK–MK2 axis inhibits inflammatory cues including inflammasome priming signals. J Exp Med. 2018;215:1315–25.

    Article  CAS  PubMed  PubMed Central  Google Scholar 

  146. Hitti E, Iakovleva T, Brook M, Deppenmeier S, Gruber AD, Radzioch D, Clark AR, Blackshear PJ, Kotlyarov A, Gaestel M. Mitogen-activated protein kinase-activated protein kinase 2 regulates tumor necrosis factor mRNA stability and translation mainly by altering tristetraprolin expression, stability, and binding to adenine/uridine-rich element. Mol Cell Biol. 2006;26:2399–407.

    Article  CAS  PubMed  PubMed Central  Google Scholar 

  147. Blasius M, Wagner SA, Choudhary C, Bartek J, Jackson SP. A quantitative 14-3-3 interaction screen connects the nuclear exosome targeting complex to the DNA damage response. Genes Dev. 2014;28:1977–82.

    Article  CAS  PubMed  PubMed Central  Google Scholar 

  148. Liu Q, Guntuku S, Cui XS, Matsuoka S, Cortez D, Tamai K, Luo G, Carattini-Rivera S, DeMayo F, Bradley A, Donehower LA. Chk1 is an essential kinase that is regulated by Atr and required for the G2/M DNA damage checkpoint. Genes Dev. 2000;14:1448–59.

    Article  CAS  PubMed  PubMed Central  Google Scholar 

  149. Ray AL, Castillo EF, Morris KT, Nofchissey RA, Weston LL, Samedi VG, Hanson JA, Gaestel M, Pinchuk IV, Beswick EJ. Blockade of MK 2 is protective in inflammation-associated colorectal cancer development. Int J Cancer. 2016;138:770–5.

    Article  CAS  PubMed  Google Scholar 

  150. Berggren K, Cruz SR, Hixon MD, Cowan A, Ozbun MA, Keysar S, Jimeno A, Ness SA, McCance DJ, Beswick EJ, Gan GN. Inhibition of MK2 decreases inflammatory cytokine production and tumor volumes in HPV-positive and HPV-negative models of head and neck squamous cell carcinoma. Int J Radiat Oncol Biol Phys. 2018;100:1372–3.

    Article  Google Scholar 

  151. Barf T, Kaptein A, de Wilde S, van der Heijden R, van Someren R, Demont D, Schultz-Fademrecht C, Versteegh J, van Zeeland M, Seegers N, Kazemier B. Structure-based lead identification of ATP-competitive MK2 inhibitors. Bioorganic Med Chem Lett. 2011;21:3818–22.

    Article  CAS  Google Scholar 

  152. Anderson DR, Meyers MJ, Vernier WF, Mahoney MW, Kurumbail RG, Caspers N, Poda GI, Schindler JF, Reitz DB, Mourey RJ. Pyrrolopyridine inhibitors of mitogen-activated protein kinase-activated protein kinase 2 (MK-2). J Med Chem. 2007;50:2647–54.

    Article  CAS  PubMed  Google Scholar 

  153. Anderson DR, Meyers MJ, Kurumbail RG, Caspers N, Poda GI, Long SA, Pierce BS, Mahoney MW, Mourey RJ, Parikh MD. Benzothiophene inhibitors of MK2. Part 2: improvements in kinase selectivity and cell potency. Bioorganic Med Chem Lett. 2009;19:4882–4.

    Article  CAS  Google Scholar 

  154. Wu JP, Wang J, Abeywardane A, Andersen D, Emmanuel M, Gautschi E, Goldberg DR, Kashem MA, Lukas S, Mao W, Martin L. The discovery of carboline analogs as potent MAPKAP-K2 inhibitors. Bioorganic Med Chem Lett. 2007;17:4664–9.

    Article  CAS  Google Scholar 

  155. Hillig RC, Eberspaecher U, Monteclaro F, Huber M, Nguyen D, Mengel A, Muller-Tiemann B, Egner U. Structural basis for a high affinity inhibitor bound to protein kinase MK2. J Mol Biol. 2007;69:735–45.

    Article  CAS  Google Scholar 

  156. Velcicky J, Feifel R, Hawtin S, Heng R, Huppertz C, Koch G, Kroemer M, Moebitz H, Revesz L, Scheufler C, Schlapbach A. Novel 3-aminopyrazole inhibitors of MK-2 discovered by scaffold hopping strategy. Bioorganic Med Chem Lett. 2010;20:1293–7.

    Article  CAS  Google Scholar 

  157. Revesz L, Schlapbach A, Aichholz R, Dawson J, Feifel R, Hawtin S, Littlewood-Evans A, Koch G, Kroemer M, Möbitz H, Scheufler C. In vivo and in vitro SAR of tetracyclic MAPKAP-K2 (MK2) inhibitors. Part II. Bioorganic Med Chem Lett. 2010;20:4719–23.

    Article  CAS  Google Scholar 

  158. Argiriadi MA, Ericsson AM, Harris CM, Banach DL, Borhani DW, Calderwood DJ, Demers MD, DiMauro J, Dixon RW, Hardman J, Kwak S. 2, 4-Diaminopyrimidine MK2 inhibitors. Part I: observation of an unexpected inhibitor binding mode. Bioorganic Med Chem Lett. 2010;20:330–3.

    Article  CAS  Google Scholar 

  159. Gaoni Y, Mechoulam R. Isolation, structure, and partial synthesis of an active constituent of hashish. J Am Chem Soc. 1964;86:1646–7.

    Article  CAS  Google Scholar 

  160. Winstein S. Bicycloheptadiene dibromides. J Am Chem Soc. 1961;83:1516–7.

    Article  CAS  Google Scholar 

  161. Xiao D, Palani A, Huang X, Sofolarides M, Zhou W. Chen X, Aslanian R, Guo Z, Fossetta J, Tian F, Trivedi P. Conformation constraint of anilides enabling the discovery of tricyclic lactams as potent MK2 non-ATP competitive inhibitors. Bioorganic Med Chem Lett. 2013;23:3262–3266.

  162. Rao AU, Xiao D, Huang X, Zhou W, Fossetta J, Lundell D, Tian F, Trivedi P, Aslanian R, Palani A. Facile synthesis of tetracyclic azepine and oxazocine derivatives and their potential as MAPKAP-K2 (MK2) inhibitors. Bioorganic Med Chem Lett. 2012;22:1068–72.

    Article  CAS  Google Scholar 

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Acknowledgements

The authors would like to thank the Director, CSIR-IHBT, Palampur, India for his constant support and encouragement. SS is immensely thankful to CSIR and PA to Department of Science and Technology, Government of India for providing Ph.D. fellowship. Both SS and PA acknowledge Academy of Scientific and Innovative Research (AcSIR), Tamil Nadu for Ph.D. registration. The authors are apologetic to many research groups whose work could not be cited due to space constraints.

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The authors acknowledge CSIR for financial support (CSIR-IHBT; Project MLP0204).

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SS, PA and YSP conceptualized the manuscript. SS and PA collected the literature, wrote the manuscript and made the figures. YSP edited and made significant revisions to the manuscript. All authors read and approved the final manuscript.

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Correspondence to Yogendra S. Padwad.

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Soni, S., Anand, P. & Padwad, Y.S. MAPKAPK2: the master regulator of RNA-binding proteins modulates transcript stability and tumor progression. J Exp Clin Cancer Res 38, 121 (2019). https://doi.org/10.1186/s13046-019-1115-1

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