Vaccinia-related Kinases Research Articles

Purification, characterization and functional site prediction of the vaccinia-related kinase 2A small transmembrane domain

Vaccinia-related kinases (VRK) are serine-threonine kinases that regulate several signaling pathways. The isoform-VRK2A of one such kinase VRK2 controls cell stress response by interacting with TAK1, a mitogen-activated protein 3 kinase (MAP3K), via its partly cytosolic C-terminal transmembrane domain (VTMD). To establish the driving force and identify the key residues of the VRK2A-TAK1 interaction, we expressed and purified the standalone 3.6 kDa VTMD in the bacterial system using a unique and atypical two-step approach, when the effort to obtain full-length VRK2A remained unsuccessful. Characterization of biophysical properties demonstrated that VTMD domain maintains its structural integrity. Furthermore, dissecting the VRK2A-TAK1 binding interface using in silico tools provided important cues toward engineering the VRK2A-TAK1 interface to modulate its functions with desired characteristics. Most importantly, this novel purification strategy demonstrates its universal applicability in protein biochemistry research by serving as a model system for obtaining difficult-to-purify small proteins or domains.•VRK2A is a highly disordered transmembrane (TM) kinase, whose TM domain interacts with TAK1 (transforming growth factor-β-activated kinase).•The standalone VRK2A-TM domain (VTMD) was purified using affinity chromatography followed by two-step centricon based approach.•Biophysical and in silico analyses confirmed structural integrity of the domain.

Development of Pyridine-based Inhibitors for the Human Vaccinia-related Kinases 1 and 2.

Vaccinia-related kinases 1 and 2 (VRK1 and VRK2) are human Ser/Thr protein kinases associated with increased cell division and neurological disorders. Nevertheless, the cellular functions of these proteins are not fully understood. Despite their therapeutic potential, there are no potent and specific inhibitors available for VRK1 or VRK2. We report here the discovery and elaboration of an aminopyridine scaffold as a basis for VRK1 and VRK2 inhibitors. The most potent compound for VRK1 (26) displayed an IC50 value of 150 nM and was fairly selective in a panel of 48 human kinases (selectivity score S(50%) of 0.04). Differences in compound binding mode and substituent preferences between the two VRKs were identified by the structure−activity relationship combined with the crystallographic analysis of key compounds. We expect our results to serve as a starting point for the design of more specific and potent inhibitors against each of the two VRKs.

Autism-like behavior caused by deletion of vaccinia-related kinase 3 is improved by TrkB stimulation.

Vaccinia-related kinases (VRKs) are multifaceted serine/threonine kinases that play essential roles in various aspects of cell signaling, cell cycle progression, apoptosis, and neuronal development and differentiation. However, the neuronal function of VRK3 is still unknown despite its etiological potential in human autism spectrum disorder (ASD). Here, we report that VRK3-deficient mice exhibit typical symptoms of autism-like behavior, including hyperactivity, stereotyped behaviors, reduced social interaction, and impaired context-dependent spatial memory. A significant decrease in dendritic spine number and arborization were identified in the hippocampus CA1 of VRK3-deficient mice. These mice also exhibited a reduced rectification of AMPA receptor-mediated current and changes in expression of synaptic and signaling proteins, including tyrosine receptor kinase B (TrkB), Arc, and CaMKIIα. Notably, TrkB stimulation with 7,8-dihydroxyflavone reversed the altered synaptic structure and function and successfully restored autism-like behavior in VRK3-deficient mice. These results reveal that VRK3 plays a critical role in neurodevelopmental disorders and suggest a potential therapeutic strategy for ASD.

Structural characterization of human Vaccinia-Related Kinases (VRK) bound to small-molecule inhibitors identifies different P-loop conformations

The human genome encodes two active Vaccinia-related protein kinases (VRK), VRK1 and VRK2. These proteins have been implicated in a number of cellular processes and linked to a variety of tumors. However, understanding the cellular role of VRKs and establishing their potential use as targets for therapeutic intervention has been limited by the lack of tool compounds that can specifically modulate the activity of these kinases in cells. Here we identified BI-D1870, a dihydropteridine inhibitor of RSK kinases, as a promising starting point for the development of chemical probes targeting the active VRKs. We solved co-crystal structures of both VRK1 and VRK2 bound to BI-D1870 and of VRK1 bound to two broad-spectrum inhibitors. These structures revealed that both VRKs can adopt a P-loop folded conformation, which is stabilized by different mechanisms on each protein. Based on these structures, we suggest modifications to the dihydropteridine scaffold that can be explored to produce potent and specific inhibitors towards VRK1 and VRK2.

Structural characterization of human Vaccinia-Related Kinases (VRK) bound to small-molecule inhibitors identifies different P-loop conformations

Structural characterization of human Vaccinia-Related Kinases (VRK) bound to small-molecule inhibitors identifies different P-loop conformations

Vaccinia-related kinase 1 is required for early uterine development in Caenorhabditis elegans

Protein kinases regulate a multitude of processes by reversible phosphorylation of target molecules. Induction of cell proliferation and differentiation are fundamental to development and rely on tightly controlled kinase activities. Vaccinia-Related Kinases (VRKs) have emerged as a multifunctional family of kinases with essential functions conserved, from nematodes and fruit flies, to humans. VRK substrates include chromatin and transcription factors, whereas deregulation of VRKs is implicated in sterility, cancer and neurological defects. In contrast to previous observations, we describe here that Caenorhabditis elegans VRK-1 is expressed in all cell types, including proliferating and post-mitotic cells. Despite the ubiquitous expression pattern, we find that vrk-1 mutants are particularly impaired in uterine development. Our data show that VRK-1 is required for uterine cell proliferation and differentiation. Moreover, the anchor cell, a specialized uterine cell, fails to fuse with neighboring cells to form the utse syncytium in vrk-1 mutants, thus providing further insight on the role of VRKs in organogenesis.

Molecular genetic analysis of VRK1 in mammary epithelial cells: depletion slows proliferation in vitro and tumor growth and metastasis in vivo

The vaccinia-related kinases (VRKs) comprise a branch of the casein kinase family. VRK1, a ser/thr kinase with a nuclear localization, is the most well-studied paralog and has been described as a proproliferative protein. In lower eukaryotes, a loss of VRK1 activity is associated with severe mitotic and meiotic defects. Mice that are hypomorphic for VRK1 expression are infertile, and depletion of VRK1 in tissue culture cells can impair cell proliferation and alter several signaling pathways. VRK1 has been implicated as part of a ‘gene-expression signature' whose overexpression correlates with poor clinical outcome in breast cancer patients. We present here our investigation of the role of VRK1 in the growth of normal (MCF10) and malignant (MDA-MB-231) human mammary epithelial cells, and demonstrate that shRNA-mediated depletion of VRK1 slows their proliferation significantly. Conversely, stable overexpression of a FLAG-tagged VRK1 transgene imparts a survival advantage to highly malignant MDA-MB-231 cells under conditions of nutrient and growth factor deprivation. Moreover, in a murine orthotopic xenograft model of breast cancer, we demonstrate that tumors depleted of VRK1 show a 50% reduction in size from 4–13 weeks postengraftment. The incidence and burden of distal metastases in the lungs and brain was also significantly reduced in mice engrafted with VRK1-depleted cells. These studies demonstrate that VRK1 depletion or overexpression has an impact on the proliferation and survival of cell lines derived from normal or malignant mammary tissue, and moreover show that depletion of VRK1 in MDA-MB-231 cells reduces their oncogenic and metastatic properties in vivo.

Role of Bivalent Cations in Structural Stabilities of New Drug Targets ——Vacciniarelated Kinases (VRK) from Molecular Dynamics Simulations

Protein kinases, which play an important role in the regulation of the majority of cellular processes, especially those involved in cellular signal transduction, by catalyzing the phosphorylation of specific proteins, are the attractive targets of drug design in pharmaceuticals industry. Interestingly, up to 10% of proteins in the human kinome termed pseudokinases are predicted to be enzymatically inactive, but are still pivotal in regulating diverse cellular processes and thus may be a potential therapeutic target to a certain extent. To study the underlying molecular mechanisms, molecular dynamics simulations were performed to investigate the role of bivalent cations Mg²⁺ and Mn²⁺ in the structural stabilities and dynamical behaviors of vaccinia related kinase 3 (VRK3), which was the first solved crystal structure of the pseudokinase, and that of its closest active relatives VRK1 and VRK2. Toward this end, a series of molecular dynamics simulations have been performed with different divalent cations binding modes in the active site. The simulations suggested that the binding of Mg²⁺ in the active site played a key structural role in the stabilization of VRK1 and VRK2, and Mn²⁺ was slightly required for VRK2. By contrast, the pseudokinase VRK3 was well ordered with lower RMSD values indicating it was rigid and very stable regardless of whether the bivalent cations were bound or not during the simulations. The present study provided evidence for the role of bivalent cations in structural stabilities of VRKs and the proposed simulation model reconciled the interpretation of available experimental structural and thermal denaturation assay data. These results gave us further information on the dynamical behaviors of the active site of VRKs and suggested a mechanism of regulation of their structural stabilities, and might provide a starting point for the more detailed follow- up investigation of drug design.

A Virion-Associated Protein Kinase Induces Apoptosis

Apoptosis and inhibition of host gene expression are often associated with virus infections. Many viral polypeptides modulate apoptosis by direct interaction with highly conserved apoptotic pathways. Some viruses induce apoptosis during late stages of the infection cycle, while others inhibit apoptosis to facilitate replication or maintain persistent infection. In previous work, we showed that Chilo iridescent virus (CIV) or CIV virion protein extract induces apoptosis in spruce budworm and cotton boll weevil cell cultures. Here, we characterize the product of a CIV gene (iridovirus serine/threonine kinase; istk) with signature sequences for S/T kinase and ATP binding. ISTK appears to belong to the superfamily, vaccinia-related kinases (VRKs). The istk gene was expressed in Pichia pastoris vectors. Purified ISTK (48 kDa) exhibited S/T kinase activity. Treatment with ISTK induced apoptosis in budworm cells. A 35-kDa cleavage product of ISTK retaining key signature sequences was identified during purification. Pichia-expressed 35-kDa polypeptide, designated iridoptin, induced apoptosis and inhibition of host protein synthesis in budworm and boll weevil cells. A mutation in the ATP-binding site eliminated both kinase and apoptosis activity of iridoptin, suggesting that kinase activity is essential for induction of apoptosis. Analysis with custom antibody confirmed that ISTK is a structural component of CIV particles. This is the first demonstration of a viral kinase inducing apoptosis in any virus-host system and the first identification of a factor inducing apoptosis or host protein shutoff for the family Iridoviridae.

Substrate profiling of human vaccinia-related kinases identifies coilin, a Cajal body nuclear protein, as a phosphorylation target with neurological implications

Protein phosphorylation by kinases plays a central role in the regulation and coordination of multiple biological processes. In general, knowledge on kinase specificity is restricted to substrates identified in the context of specific cellular responses, but kinases are likely to have multiple additional substrates and be integrated in signaling networks that might be spatially and temporally different, and in which protein complexes and subcellular localization can play an important role. In this report the substrate specificity of atypical human vaccinia-related kinases (VRK1 and VRK2) using a human peptide-array containing 1080 sequences phosphorylated in known signaling pathways has been studied. The two kinases identify a subset of potential peptide targets, all of them result in a consensus sequence composed of at least four basic residues in peptide targets. Linear peptide arrays are therefore a useful approach in the characterization of kinases and substrate identification, which can contribute to delineate the signaling network in which VRK proteins participate. One of these target proteins is coilin; a basic protein located in nuclear Cajal bodies. Coilin is phosphorylated in Ser184 by both VRK1 and VRK2. Coilin colocalizes and interacts with VRK1 in Cajal bodies, but not with the mutant VRK1 (R358X). VRK1 (R358X) is less active than VRK1. Altered regulation of coilin might be implicated in several neurological diseases such as ataxias and spinal muscular atrophies.

Differential Inhibitor Sensitivity between Human Kinases VRK1 and VRK2

Human vaccinia-related kinases (VRK1 and VRK2) are atypical active Ser-Thr kinases implicated in control of cell cycle entry, apoptosis and autophagy, and affect signalling by mitogen activated protein kinases (MAPK). The specific structural differences in VRK catalytic sites make them suitable candidates for development of specific inhibitors. In this work we have determined the sensitivity of VRK1 and VRK2 to kinase inhibitors, currently used in biological assays or in preclinical studies, in order to discriminate between the two proteins as well as with respect to the vaccinia virus B1R kinase. Both VRK proteins and vaccinia B1R are poorly inhibited by inhibitors of different types targeting Src, MEK1, B-Raf, JNK, p38, CK1, ATM, CHK1/2 and DNA-PK, and most of them have no effect even at 100 µM. Despite their low sensitivity, some of these inhibitors in the low micromolar range are able to discriminate between VRK1, VRK2 and B1R. VRK1 is more sensitive to staurosporine, RO-31-8220 and TDZD8. VRK2 is more sensitive to roscovitine, RO 31–8220, Cdk1 inhibitor, AZD7762, and IC261. Vaccinia virus B1R is more sensitive to staurosporine, KU55933, and RO 31–8220, but not to IC261. Thus, the three kinases present a different pattern of sensitivity to kinase inhibitors. This differential response to known inhibitors can provide a structural framework for VRK1 or VRK2 specific inhibitors with low or no cross-inhibition. The development of highly specific VRK1 inhibitors might be of potential clinical use in those cancers where these kinases identify a clinical subtype with a poorer prognosis, as is the case of VRK1 in breast cancer.

Functional Disruption of the Moloney Murine Leukemia Virus Preintegration Complex by Vaccinia-related Kinases

Retroviral integration is executed by the preintegration complex (PIC), which contains viral DNA together with a number of proteins. Barrier-to-autointegration factor (BAF), a cellular component of Moloney murine leukemia virus (MMLV) PICs, has been demonstrated to protect viral DNA from autointegration and stimulate the intermolecular integration activity of the PIC by its DNA binding activity. Recent studies reveal that the functions of BAF are regulated by phosphorylation via a family of cellular serine/threonine kinases called vaccinia-related kinases (VRK), and VRK-mediated phosphorylation causes a loss of the DNA binding activity of BAF. These results raise the possibility that BAF phosphorylation may influence the integration activities of the PIC through removal of BAF from viral DNA. In the present study, we report that VRK1 was able to abolish the intermolecular integration activity of MMLV PICs in vitro. This was accompanied by an enhancement of autointegration activity and dissociation of BAF from the PICs. In addition, in vitro phosphorylation of BAF by VRK1 abrogated the activity of BAF in PIC function. Among the VRK family members, VRK1 as well as VRK2, which catalyze hyperphosphorylation of BAF, could abolish PIC function. We also found that treatment of PICs with certain nucleotides such as ATP resulted in the inhibition of the intermolecular integration activity of PICs through the dissociation of BAF. More importantly, the ATP-induced disruption was not observed with the PICs from VRK1 knockdown cells. Our in vitro results therefore suggest the presence of cellular kinases including VRKs that can inactivate the retroviral integration complex via BAF phosphorylation.

Protein kinase VRK-1 regulates cell invasion and EGL-17/FGF signaling in Caenorhabditis elegans

The vaccinia-related kinases (VRKs) are highly conserved throughout the animal kingdom and phosphorylate several chromatin proteins and transcription factors. In early Caenorhabditis elegans embryos, VRK-1 is required for proper nuclear envelope formation. In this work, we present the first investigation of the developmental role of VRKs by means of a novel C. elegans vrk-1 mutant allele. We found that VRK-1 is essential in hermaphrodites for formation of the vulva, uterus, and utse and for development and maintenance of the somatic gonad and thus the germ line. VRK-1 regulates anchor cell polarity and the timing of anchor cell invasion through the basement membranes separating vulval and somatic gonadal cells during the L3 larval stage. VRK-1 is also required for proper specification and proliferation of uterine cells and sex myoblasts. Expression of the fibroblast growth factor-like protein EGL-17 and its receptor EGL-15 is reduced in vrk-1 mutants, suggesting that VRK-1 might act at least partially through activation of FGF signaling. Expression of a translational VRK-1Colon, two colonsGFP fusion protein in the ventral nerve cord and vulva precursor cells restores vulva and uterus formation, suggesting both cell autonomous and non-autonomous roles of VRK-1.

Emerging biological functions of the vaccinia-related kinase (VRK) family.

The vaccinia-related kinases (VRKs) branched off early from the family of casein kinase (CK) I and compose a relatively uncharacterized family of the kinome. The VRKs were discovered due to their close sequence relation to the vaccinia virus B1R serine/threonine kinase. They were first described in phosphorylation of transcription factors that led to the discovery of an autoregulatory mechanism between VRK and the tumor suppressor transcription factor p53. The relevance of VRKs has broadened recently by introduction of its members as essential regulators in cell signaling, nuclear envelope dynamics, chromatin modifications, apoptosis and cellular stress response. Several phosphorylation substrates have been described, as well as the first positive and negative regulators of VRK. We provide an overview of the VRKs across species and discuss the wide diversity of cellular and organismal requirements for this kinase family.

VRK1 phosphorylates CREB and mediates CCND1 expression

Vaccinia virus B1 kinase plays a key role in viral DNA replication. The homologous mammalian vaccinia-related kinases (VRKs) are also implicated in the regulation of DNA replication, although direct evidence remains elusive. Here we show that VRK1 regulates cell cycle progression in the DNA replication period by inducing cyclin D1 (CCND1) expression. Furthermore, depletion of VRK1 in human cancer cells reduces the fraction of cells in S phase at a given time. VRK1 specifically enhances activity of the cAMP-response element (CRE) in the CCND1 promoter by facilitating the recruitment of phospho-CREB to this locus. VRK1 phosphorylates CREB at Ser133 in vitro and the expression of a kinase-dead mutant of VRK1 or knockdown of VRK1 using siRNA fails to activate CREB and subsequently activate CRE. Finally, we show that VRK1 is a critical link in the CCND1 gene expression pathway stimulated by Myc overexpression. Our results indicate that VRK1 is a novel regulator of CCND1 expression.

BAFfled by Poxviruses?

Successful viruses engage in a dynamic interplay with their hosts, where both utilize diverse strategies to impose their supremacy. In this issue of Cell Host & Microbe, Wiebe and Traktman describe a novel interaction between vaccinia virus and mammalian cells. A host protein called BAF can bind ectopic cytoplasmic DNA and block viral DNA replication, whereas vaccinia in turn counteracts this inhibition with a virus-encoded serine threonine kinase that inactivates BAF.

The Vaccinia-related Kinases Phosphorylate the N′ Terminus of BAF, Regulating Its Interaction with DNA and Its Retention in the Nucleus

The vaccinia-related kinases (VRKs) comprise a branch of the casein kinase family whose members are characterized by homology to the vaccinia virus B1 kinase. The VRK orthologues encoded by Caenorhabditis elegans and Drosophila melanogaster play an essential role in cell division; however, substrates that mediate this role have yet to be elucidated. VRK1 can complement the temperature sensitivity of a vaccinia B1 mutant, implying that VRK1 and B1 have overlapping substrate specificity. Herein, we demonstrate that B1, VRK1, and VRK2 efficiently phosphorylate the extreme N' terminus of the BAF protein (Barrier to Autointegration Factor). BAF binds to both DNA and LEM domain-containing proteins of the inner nuclear membrane; in lower eukaryotes, BAF has been shown to play an important role during the reassembly of the nuclear envelope at the end of mitosis. We demonstrate that phosphorylation of ser4 and/or thr2/thr3 abrogates the interaction of BAF with DNA and reduces its interaction with the LEM domain. Coexpression of VRK1 and GFP-BAF greatly diminishes the association of BAF with the nuclear chromatin/matrix and leads to its dispersal throughout the cell. Cumulatively, our data suggest that the VRKs may modulate the association of BAF with nuclear components and hence play a role in maintaining appropriate nuclear architecture.