Analysis of Jak2 Catalytic Function by Peptide Microarrays: The Role of the JH2 Domain and V617F Mutation

Sanz, Arturo; Ungureanu, Daniela; Pekkala, Tuija; Ruijtenbeek, Rob; Touw, Ivo P.; Hilhorst, Riet; Silvennoinen, Olli

doi:10.1371/journal.pone.0018522

Cited by 33 publications

(33 citation statements)

References 55 publications

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“…5). The wild-type pseudokinasekinase construct was ∼100-fold less active than the kinase domain alone, recapitulating a similar effect reported for JAK2 (14) and indicating that the pseudokinase has a direct role in inhibiting TYK2 enzymatic activity. Comparison of the four TYK2 analogs that mimic JAK-associated mutations showed that all of the mutants were more active than wild type pseudokinasekinase, with the R744G and R901S mutants approaching levels of activity seen for the isolated kinase domain (Fig.…”

Section: Tumor-derived Jak Mutations Cluster Near the Pseudokinase-kisupporting

confidence: 74%

“…Because the TYK2 kinase activation loop is found in an active conformation in our structure, activation loop phosphorylation likely does not have a role in regulating pseudokinase-mediated inhibition. Given that isolated JAK kinase domains are significantly active (14,32,37) and pseudokinase-kinase interface mutations increase kinase activity, we speculate that, in the context of receptor-induced JAK dimerization, a displacement event, direct or perhaps allosteric, relieves the inhibitory influence of the pseudokinase domain, allowing the kinase domain to autophosphorylate and become the active phospho-transfer catalyst required for downstream signaling.…”

Section: Discussionmentioning

confidence: 97%

“…However, these JAK2 phosphorylation sites are not universally conserved in the other JAK family members (13), suggesting this may be a JAK2-specific regulatory pathway. Moreover, the in vitro activity of the isolated JAK2 pseudokinase-kinase protein is reduced and the K m value for ATP increased compared with the kinase domain alone (14), suggesting there may also be a more direct mechanism by which the pseudokinase regulates enzymatic activity.…”

Section: Jak1 | Jak3mentioning

confidence: 99%

“…Functional screening for constitutively active JAK2 alleles has also identified several point mutations in the pseudokinase N-lobe (18). Importantly, JAK2 V617F is a kinase-activating mutation, increasing JAK2 activity in both cell-based assays (17) and in vitro in the context of the isolated JAK2 pseudokinase-kinase module (14). Analogous mutations made in both JAK1 (L653F) and TYK2 (V678F) also activate their respective kinase domains (19).…”

Section: Jak1 | Jak3mentioning

confidence: 99%

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Structure of the pseudokinase–kinase domains from protein kinase TYK2 reveals a mechanism for Janus kinase (JAK) autoinhibition

Lupardus¹,

Ultsch²,

Wallweber³

et al. 2014

Proc. Natl. Acad. Sci. U.S.A.

192

241

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Janus kinases (JAKs) are receptor-associated multidomain tyrosine kinases that act downstream of many cytokines and interferons. JAK kinase activity is regulated by the adjacent pseudokinase domain via an unknown mechanism. Here, we report the 2.8-Å structure of the two-domain pseudokinase-kinase module from the JAK family member TYK2 in its autoinhibited form. We find that the pseudokinase and kinase interact near the kinase active site and that most reported mutations in cancer-associated JAK alleles cluster in or near this interface. Mutation of residues near the TYK2 interface that are analogous to those in cancer-associated JAK alleles, including the V617F and "exon 12" JAK2 mutations, results in increased kinase activity in vitro. These data indicate that JAK pseudokinases are autoinhibitory domains that hold the kinase domain inactive until receptor dimerization stimulates transition to an active state. JAK1 | JAK3H elical bundle cytokines of the interleukin and IFN families regulate a wide variety of immune and cellular growth responses (1). These signaling pathways are initiated by cytokinemediated receptor dimerization and subsequent activation of nonreceptor tyrosine kinases called Janus kinases (JAKs) that are associated with the receptor intracellular domains (2). JAK activation leads to phosphorylation of the receptor and recruitment of STAT family transcription factors, which are then phosphorylated by the JAK and translocated to the nucleus where they induce gene transcription. The JAK family consists of four members (JAK1, JAK2, JAK3, and tyrosine kinase 2 or TYK2), each of which binds a distinct set of cytokine receptor subtypes and hence has a unique gene knockout phenotype, ranging from embryonic lethality due to neuronal and erythropoietic defects (JAK1 and JAK2, respectively) (3-5), to profound immune system deficiencies (JAK3 and TYK2) (6).The JAK kinases are large (∼1,150-aa) multidomain proteins whose primary sequences were initially organized into seven JAK-homology (JH) domains that reflected distinct regions of high sequence homology (7). Subsequent structure predictions indicated that JAKs contain four distinct domains: N-terminal 4.1, Ezrin, Radixin, Moesin (FERM) and Src homology 2 (SH2) domains, followed by C-terminal pseudokinase and kinase domains (7,8) (Fig. 1A). The FERM and SH2 domains constitute the receptor-binding module (2), whereas the pseudokinase, which has a canonical kinase fold but lacks key catalytic residues, is thought to regulate kinase activity. Deletion of the pseudokinase in JAK2 and JAK3 increases basal kinase activity and deregulates signaling through cognate receptors (9, 10). Additionally, the JAK2 pseudokinase and kinase domains have been reported to coimmunoprecipitate, and coexpression of the JAK2 pseudokinase domain inhibits activity of the isolated kinase domain (10). Recent work on the JAK2 pseudokinase domain indicates that it has weak catalytic activity and autophosphorylates two inhibitory sites within the SH2-pseudokinase linker and pseudokinase...

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Section: Tumor-derived Jak Mutations Cluster Near the Pseudokinase-kisupporting

confidence: 74%

Section: Discussionmentioning

confidence: 97%

Section: Jak1 | Jak3mentioning

confidence: 99%

Section: Jak1 | Jak3mentioning

confidence: 99%

See 2 more Smart Citations

Structure of the pseudokinase–kinase domains from protein kinase TYK2 reveals a mechanism for Janus kinase (JAK) autoinhibition

Lupardus¹,

Ultsch²,

Wallweber³

et al. 2014

Proc. Natl. Acad. Sci. U.S.A.

192

241

View full text Add to dashboard Cite

show abstract

“…24 Using the recently solved crystal structure of JH1-JH2 from TYK2, this intramolecular inhibitory interface has been localized near the JH1 catalytic site and is predominantly mediated by the N-lobes of each domain. 25 The JH1-JH2 crystal structure of TYK2 supports an in cis mode of inhibition with the pseudokinase domain inhibiting the directly adjacent kinase domain within the same protein.…”

mentioning

confidence: 99%

JAK kinase targeting in hematologic malignancies: a sinuous pathway from identification of genetic alterations towards clinical indications

2015

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In 2005, several groups reported a unique, acquired, somatic activating mutation of JAK2 (V617F) in 95% of patients with polycythemia vera (PV) and in about half of those with essential thombocythemia (ET) or primary myelofibrosis (MF). [6][7][8][9] The discovery of JAK2 V617F led to screening for JAK mutations in other hematologic neoplasms. Thanks to improvements of sequencing techniques and the conduction of massive sequencing projects, the catalogue of genetic alterations in hematologic malignancies is constantly being updated as ever more new mutational targets are discovered. This review provides an overview of the different molecular mechanisms underlying constitutive activation of the JAK-STAT pathway and their respective frequencies among hematologic neoplasms. The use of JAK inhibitors in the clinic and in ongoing trials, resistance phenomena as well as future challenges are discussed. The review begins by documenting insights into the structural organization of JAK kinases, their mode of activation as well as the role of the different family members in hematopoiesis. Janus kinasesJAK1, JAK2 and TYK2 tyrosine kinases are ubiquitously expressed and non-covalently bound to a distinct, mostly non-overlapping repertory of receptor chains. By contrast, JAK3 expression is restricted to the hematopoietic lineage and it associates exclusively with the common gammachain (γc). Based on their primary sequences, JAK kinases were initially divided into seven highly conserved JAK homology regions (JH1-7, starting from the C-terminal end) but were subsequently organized into four functional domains. 10The N-terminal moiety of JAK kinases constitutes the receptor-binding module with a FERM (band 4.1, ezrin, radixin, moesin) domain (JH4-7) and an atypical SH2 domain (JH3).11 It has been experimentally established that both domains do not exist as individual functional entities but structurally cooperate for non-covalent anchoring to two membrane-proximal regions of defined receptors. 12,13 This was corroborated by a recent crystal structure study showing that the N-terminal part of TYK2 forms a con-JAK kinase targeting in hematologic malignancies haematologica | 2015; 100 (10) 1241 Figure 1. Hematopoiesis. Hematopoiesis originates from a hematopoietic stem cell, which can undergo either self-renewal or hierarchical differentiation into lineage-committed progenitors with decreasing potential that ultimately will give rise to all mature blood cells. Cytokines and their receptor-associated JAK necessary for the progenitors to pass through the different maturation steps are indicated. HSC: hematopoietic stem cell; CMP: common myeloid progenitor; CLP: common lymphoid progenitor; GM: granulocyte macrophage progenitor; BCP: B cell progenitor; TNK: T and natural killer cell progenitor; EP: erythroid progenitor; Mk: megakaryocyte; GP: granulocyte progenitor; MP: macrophage progenitor; TPO: thrombopoietin; SCF: stem cell factor; IL: interleukin; GM-CSF: granulocyte/monocyte colony-stimulating factor; G-CSF: granulocyte c...

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Insight into Janus kinases specificity: From molecular architecture to cancer therapeutics

Wei,

Lu,

Yao

et al. 2024

MedComm – Oncology

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Janus Kinases (JAKs) play a crucial role as therapeutic targets for various cancers. However, the current JAK inhibitors (JAKi) available have limited therapeutic benefits due to their lack of selectivity. This review focuses on the structural analysis to elucidate the molecular determinants of JAKs specificity and the discovery and design of selective JAKi. It includes descriptions and comparison of different JAK structures and their binding sites, a comparative analysis of JAKi and their binding modes, detailed interaction fingerprints (IFPs), and an extensive structure‐selectivity relationship (SSRs). Moreover, the review also explores the challenges and possibilities of using computational structure‐based methods for discovering and designing selective JAKi. Other structure‐based approaches, such as targeting the pseudokinase domain, as well as covalent and allosteric designs, are also covered. Based on this analysis, key determinants corresponding to JAK specificity and rational medicinal chemistry strategies are proposed to facilitate the development of highly selective JAKi. Overall, we aim to enhance the understanding of JAK specificity and explore strategies that can lead to the discovery of effective and selective JAKi in cancer therapy, thus improving the prognosis for cancer patients.

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Analysis of Jak2 Catalytic Function by Peptide Microarrays: The Role of the JH2 Domain and V617F Mutation

Cited by 33 publications

References 55 publications

Structure of the pseudokinase–kinase domains from protein kinase TYK2 reveals a mechanism for Janus kinase (JAK) autoinhibition

Structure of the pseudokinase–kinase domains from protein kinase TYK2 reveals a mechanism for Janus kinase (JAK) autoinhibition

JAK kinase targeting in hematologic malignancies: a sinuous pathway from identification of genetic alterations towards clinical indications

Insight into Janus kinases specificity: From molecular architecture to cancer therapeutics

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