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Showing STK10LOK is a alias.

STK10

Serine/threonine-protein kinase 10 · UniProt O94804

Length
968 aa
Mass
112.1 kDa
Annotated
2026-06-10
31 papers in source corpus 18 papers cited in narrative 18 extracted findings
Cross-family judge vs UniProt: Affinage preferred faithfulness: 6/6 claims corpus-supported (100%)

Mechanistic narrative

Synthesis pass · prose summary of the discoveries below

STK10 (LOK) is a STE20-family serine/threonine kinase whose principal characterized function is acting as a major ERM (ezrin/radixin/moesin) kinase that couples plasma-membrane signaling to cortical actin organization, cell adhesion, and migration (PMID:19255442, PMID:23209304). It autophosphorylates and uses an N-terminal kinase domain to directly phosphorylate the regulatory C-terminal threonine of ERM proteins with distinctive substrate specificity, and its loss reduces ERM phosphorylation by more than half in lymphocytes while enhancing chemokine-driven migration and polarization (PMID:9278426, PMID:19255442). STK10 achieves spatial fidelity through a multi-step wedge mechanism in which PIP2 binding primes ezrin, the kinase's C-terminal domain inserts to separate the membrane- and actin-binding lobes, and the kinase domain then accesses a non-consensus phosphosite, ensuring phosphorylation occurs only at the membrane (PMID:28430576); the same C-terminal domain dimerizes, binds anionic phospholipids, resembles an inverse-BAR domain, and drives apical colocalization with ezrin in epithelial cells (PMID:41958020, PMID:23209304). Beyond ERM regulation, STK10 negatively regulates LFA-1 clustering and lymphocyte adhesion (PMID:10692593), associates with and phosphorylates PLK1 as a polo-like kinase kinase (PMID:12639966), and in platelets is activated downstream of calcium/PKC/PI3K signaling to directly phosphorylate integrin-linked kinase (ILK) at Ser343, controlling aggregation, granule release, integrin activation, and both arterial-type and deep-vein thrombosis (PMID:41055696, PMID:41791658). STK10 also suppresses NF-κB activity and promotes apoptosis, an activity attenuated by lymphoma-associated missense mutations (PMID:23842845). In tumor settings, host STK10 supports anti-tumor cytotoxic T-cell activity and restrains tumor angiogenesis (PMID:36421382).

Mechanistic history

Synthesis pass · year-by-year structured walk · 12 steps
  1. 1997 Medium

    Established the basic biochemical identity of STK10/LOK, answering whether it was a tyrosine or serine/threonine kinase and where it sat among kinase families.

    Evidence In vitro kinase assays on generic substrates and co-expression in COS7 cells

    PMID:9278426

    Open questions at the time
    • No physiological substrate identified
    • No cellular function defined
    • MAP kinase pathways explicitly excluded but true effectors unknown
  2. 2000 Medium

    Connected STK10 to lymphocyte adhesion by showing it negatively regulates LFA-1 clustering, giving the kinase its first in vivo cellular role.

    Evidence LOK knockout mice with ICAM-1 binding and aggregation assays

    PMID:10692593

    Open questions at the time
    • No molecular substrate linking the kinase to LFA-1 regulation
    • Mechanism of clustering control unknown
  3. 2003 Medium

    Identified STK10 as a candidate cell-cycle regulator acting upstream of PLK1, addressing whether the kinase had mitotic functions.

    Evidence Co-immunoprecipitation, in vitro kinase assay, and dominant-negative expression in NIH-3T3 cells

    PMID:12639966

    Open questions at the time
    • PLK1 phosphosite not mapped
    • Physiological relevance of PLK1 activation in cycling cells not established
  4. 2009 High

    Defined STK10's central function as a major ERM kinase, answering what its key physiological substrate is and linking it to lymphocyte migration.

    Evidence In vitro peptide kinase assay with specificity profiling, MS localization, and LOK knockout mice

    PMID:19255442

    Open questions at the time
    • Residual ERM phosphorylation indicates redundant kinases
    • How membrane enrichment restricts activity not yet defined
  5. 2012 High

    Showed how STK10 (with SLK) enforces spatial control of ERM activation, restricting ezrin phosphorylation to the apical/microvillar domain.

    Evidence RNAi, drug-resistant kinase rescue variants, and localization in polarized epithelial cells

    PMID:23209304

    Open questions at the time
    • Molecular basis of local activation not resolved at this stage
    • Functional overlap between LOK and SLK not fully separated
  6. 2017 High

    Resolved the mechanistic basis for membrane-restricted ERM phosphorylation through a PIP2-dependent multi-step wedge mechanism.

    Evidence In vitro reconstitution, domain mapping, mutagenesis, and lipid-binding assays

    PMID:28430576

    Open questions at the time
    • Structure of the kinase-ezrin complex not solved
    • Regulation of the kinase by upstream signals not addressed
  7. 2026 Medium

    Defined the structural and biophysical properties of the LOK C-terminal domain that target the kinase to ezrin at membranes.

    Evidence Lipid-binding and dimerization assays, MD simulations, and cell-based colocalization

    PMID:41958020

    Open questions at the time
    • IBAR-like assignment based on prediction/simulation rather than experimental structure
    • Membrane curvature sensing not directly demonstrated
  8. 2013 Medium

    Linked STK10 to NF-κB suppression and apoptosis and to lymphoma-associated mutations, addressing a possible tumor-suppressive role.

    Evidence NF-κB reporter and dexamethasone apoptosis assays with site-directed PTCL mutants

    PMID:23842845

    Open questions at the time
    • No direct biochemical target in the NF-κB pathway identified
    • Overexpression-based, kinase substrate unknown
  9. 2021 High

    Provided structural tools and chemical probes for STK10, addressing the lack of selective inhibitors and SLK/STK10 discrimination.

    Evidence X-ray crystallography of inhibitor complexes with cellular target engagement (extended by a 2025 macrocycle co-structure)

    PMID:34463505 PMID:41256983

    Open questions at the time
    • Probes characterize binding, not in vivo pathway consequences
    • Selectivity beyond SLK not exhaustively profiled
  10. 2021 Medium

    Extended STK10's ERM and migration role to cancer cells, showing knockout alters migration/proliferation via p38 and phospho-ERM.

    Evidence CRISPR knockout in DU145 prostate cancer cells with phospho-signaling and phenotype readouts

    PMID:34149897

    Open questions at the time
    • Mechanism linking STK10 to p38 not defined
    • Single cell line
  11. 2022 Medium

    Defined a host immune role for STK10 in anti-tumor immunity through cytotoxic T-cell activity and angiogenesis control.

    Evidence Stk10 knockout mice with tumor implantation and immune cell phenotyping

    PMID:36421382

    Open questions at the time
    • Cell-intrinsic vs systemic contributions not separated
    • No substrate linking STK10 to CTL or vessel phenotypes
  12. 2026 High

    Identified a direct, physiologically validated STK10 substrate in platelets (ILK Ser343) and placed STK10 in hemostasis and arterial/venous thrombosis.

    Evidence Platelet-specific conditional KO, phosphoproteomics, IP-MS, in vitro kinase assay, and DVT/thrombosis models

    PMID:41055696 PMID:41791658

    Open questions at the time
    • How ILK Ser343 phosphorylation drives downstream integrin/granule responses not fully resolved
    • Relationship between ERM and ILK substrate functions in platelets unclear

Open questions

Synthesis pass · forward-looking unresolved questions
  • How STK10's distinct activities — ERM phosphorylation, ILK phosphorylation, PLK1 activation, and NF-κB suppression — are integrated within single cell types and which upstream signals select among them remains unresolved.
  • No unified model linking substrate choice to cellular context
  • Upstream activating signals defined only for platelet (Ca/PKC/PI3K) and ERK-tail inhibition contexts

Mechanism profile

Synthesis pass · controlled-vocabulary classification · explore literature graph →
Molecular activity
GO:0140096 catalytic activity, acting on a protein 4 GO:0016740 transferase activity 3 GO:0008289 lipid binding 2
Localization
GO:0005886 plasma membrane 3 GO:0005856 cytoskeleton 2
Pathway
R-HSA-109582 Hemostasis 2 R-HSA-168256 Immune System 2
Partners
EZRILKMSNPLK1

Evidence

Reading pass · 18 per-paper findings extracted from the source corpus
Year Finding Method Journal Conf PMIDs
1997 LOK (STK10) is a serine/threonine kinase (not tyrosine kinase) that autophosphorylates and phosphorylates myelin basic protein and histone IIA; it belongs to the STE20 family with an N-terminal kinase domain and C-terminal coiled-coil/proline-rich region; it does not activate ERK, JNK, or p38 MAP kinases when co-expressed in COS7 cells. In vitro kinase assay, co-expression in COS7 cells, Western blot The Journal of biological chemistry Medium 9278426
2000 LOK-deficient mice show enhanced LFA-1 clustering and accelerated LFA-1/ICAM-mediated T cell aggregation upon mitogen stimulation, without changes in total LFA-1 or ICAM levels, indicating LOK negatively regulates LFA-1 clustering and lymphocyte adhesion. LOK knockout mouse model, soluble ICAM-1 binding assay, flow cytometry FEBS letters Medium 10692593
2002 Overexpression of LOK attenuates MEKK1-induced and Raji/SEE-induced CD28RE/AP1 reporter gene activation and IL-2 production in Jurkat T cells, indicating LOK opposes MEKK1 in the CD28 signaling pathway. Luciferase reporter assay, co-transfection in Jurkat cells, IL-2 measurement The Biochemical journal Low 11903060
2003 STK10 (human LOK) associates with PLK1 in cells and phosphorylates PLK1 in vitro; dominant-negative STK10 expression in NIH-3T3 cells causes increased DNA content, suggesting STK10 functions as a polo-like kinase kinase regulating PLK1. Co-immunoprecipitation, in vitro kinase assay, engineered NIH-3T3 cell lines with flow cytometry cell cycle analysis The Journal of biological chemistry Medium 12639966
2009 LOK is a major ERM kinase in lymphocytes: it is enriched at the plasma membrane near ERM proteins, directly phosphorylates moesin at its C-terminal threonine in vitro with preferential specificity (including unusual preference for Tyr at P-2), and LOK knockout mice show >50% reduction in ERM phosphorylation; loss of LOK enhances lymphocyte migration and polarization in response to chemokine. Mass spectrometry localization, immunofluorescence, in vitro peptide kinase assay, LOK kinase domain transfection, LOK knockout mouse model Proceedings of the National Academy of Sciences of the United States of America High 19255442
2012 LOK and SLK are the relevant kinases driving apical restriction of ezrin in polarized epithelial cells; both kinases are enriched in microvilli and locally activated there; drug-resistant LOK/SLK variants are sufficient to restrict ezrin to the apical domain, while expression of their regulatory regions inhibits local ezrin phosphorylation by endogenous kinases. Proteomic approaches, RNAi knockdown, drug-resistant kinase variants, immunofluorescence localization The Journal of cell biology High 23209304
2013 Wild-type STK10 suppresses NF-κB activity and potentiates dexamethasone-induced apoptosis; PTCL-associated missense mutations (R634H, L85P, K277E) reduce this pro-apoptotic activity, with L85P and K277E having more profound anti-apoptotic effects than R634H. NF-κB reporter assay, apoptosis assay (dexamethasone), site-directed mutagenesis, transfection Oncology reports Medium 23842845
2016 In Drosophila GSCs, DNA damage activates Lok kinase, which is required for GSC loss and progeny differentiation defects; elimination of Lok or its kinase activity rescues these phenotypes; Lok-dependent signaling decreases expression of differentiation factor Bam. Genetic epistasis (lok knockout/kinase-dead), heat-shock I-CreI endonuclease and X-ray irradiation, immunofluorescence, Drosophila ovary model Development (Cambridge, England) Medium 27729408
2017 LOK activates ezrin through a multi-step mechanism: (1) PIP2 binding to ezrin induces a conformational change; (2) the LOK C-terminal domain inserts to wedge apart the ezrin membrane- and F-actin-binding domains; (3) the LOK N-terminal kinase domain accesses a site 40 residues distal from the consensus sequence to phosphorylate the correct threonine. This ensures ezrin is only phosphorylated at the plasma membrane. In vitro reconstitution system, biochemical domain-mapping, mutagenesis, lipid-binding assays eLife High 28430576
2021 STK10 knockout in prostate cancer DU145 cells inhibits cell migration and promotes proliferation; these effects are mediated via inhibition of p38 MAPK activation and reduced ERM protein phosphorylation. CRISPR-Cas9 knockout, Western blot (phospho-ERM, phospho-p38), migration and proliferation assays Experimental and therapeutic medicine Medium 34149897
2021 Crystal structures of SLK and STK10 with maleimide-scaffold inhibitors were determined, revealing the binding mode and structural basis for selectivity between SLK and STK10; cellular target engagement assays confirmed inhibitor binding to STK10 in cells. X-ray crystallography, cellular target engagement assay (NanoBRET or similar), medicinal chemistry SAR Journal of medicinal chemistry High 34463505
2022 Host Stk10 knockout in mice results in increased tumor growth associated with decreased activated/effector cytotoxic T lymphocytes and increased vessel density in the tumor microenvironment, indicating STK10 modulates anti-tumor immunity through CTL activity and angiogenesis regulation. Stk10 knockout mouse model, tumor implantation assay, immunofluorescence/flow cytometry of tumor-infiltrating immune cells Biology Medium 36421382
2024 Knockdown of STK10 in K562 cells inhibits erythroid differentiation and promotes apoptosis, associated with inhibition of ribosome biogenesis, reduced ribosome levels, and activation of the p53 signaling pathway. shRNA knockdown in K562 cells, erythroid differentiation assay, ribosome profiling, Western blot (p53 pathway) Annals of hematology Low 38761185
2025 A co-crystal structure of a macrocyclic inhibitor bound to STK10 revealed a unique back-pocket binding mode distinct from SLK, providing structural basis for selective STK10 inhibition; compound 23 showed nanomolar STK10 activity in cells. X-ray co-crystallography, biophysical assays, cellular activity assays ACS medicinal chemistry letters High 41256983
2026 STK10 in platelets is phosphorylated upon activation; platelet-specific STK10 knockout mice show impaired hemostasis, reduced platelet aggregation, α-granule release, αIIbβ3 activation, procoagulant activity, spreading, and clot retraction; STK10 directly phosphorylates integrin-linked kinase (ILK) at Ser343 as identified by immunoprecipitation-mass spectrometry and confirmed by in vitro phosphorylation assay; upstream, STK10 phosphorylation is regulated by calcium, PKC, and PI3K signaling. Platelet-specific conditional KO mice, quantitative phosphoproteomics, immunoprecipitation-mass spectrometry, in vitro kinase assay, platelet functional assays Blood High 41055696
2026 The LOK C-terminal domain (LOK-CTD) mediates colocalization of LOK with ezrin at the apical surface of epithelial cells; the LOK-CTD forms dimers, binds negatively charged phospholipids, and shares structural similarity to inverse BAR (IBAR) domains; these properties are required for LOK-ezrin colocalization. Biochemical assays (lipid binding, dimerization), predictive bioinformatics, molecular dynamics simulations (atomistic and coarse-grained), human cell-based colocalization assays Biophysical journal Medium 41958020
2026 Platelet STK10 deletion reduces deep vein thrombus formation in mice; STK10 phosphorylation and ILK (Ser343) phosphorylation are increased in platelets during DVT development; STK10 KO inhibits platelet-neutrophil interactions, NET formation, and platelet procoagulant activity in venous thrombi. Platelet-specific STK10 KO mice, inferior vena cava ligation DVT model, immunofluorescence, in vitro NET assay, phosphoprotein analysis Journal of thrombosis and haemostasis Medium 41791658
2025 ERK phosphorylates the C-terminal tail of LOK, inhibiting LOK's activation of Ezrin in the cell body; this releases Ezrin's inhibition of Rho (via ARHGAP18) and promotes stress fiber assembly and cell migration, placing LOK in an ERK→LOK→Ezrin→ARHGAP18→Rho pathway. Cell-based phosphorylation assays, genetic epistasis, Rho activity assays, stress fiber imaging, Ezrin activity assays bioRxivpreprint Medium bio_10.1101_2025.11.15.688645

Source papers

Stage 0 corpus · 31 papers · ranked by NIH iCite citations
Year Title Journal Citations PMID
2009 LOK is a major ERM kinase in resting lymphocytes and regulates cytoskeletal rearrangement through ERM phosphorylation. Proceedings of the National Academy of Sciences of the United States of America 127 19255442
2012 Local phosphocycling mediated by LOK/SLK restricts ezrin function to the apical aspect of epithelial cells. The Journal of cell biology 88 23209304
1997 LOK is a novel mouse STE20-like protein kinase that is expressed predominantly in lymphocytes. The Journal of biological chemistry 69 9278426
2017 Ezrin activation by LOK phosphorylation involves a PIP2-dependent wedge mechanism. eLife 54 28430576
2003 Stk10, a new member of the polo-like kinase kinase family highly expressed in hematopoietic tissue. The Journal of biological chemistry 52 12639966
2016 DNA damage-induced Lok/CHK2 activation compromises germline stem cell self-renewal and lineage differentiation. Development (Cambridge, England) 33 27729408
2000 Deficiency of a STE20/PAK family kinase LOK leads to the acceleration of LFA-1 clustering and cell adhesion of activated lymphocytes. FEBS letters 27 10692593
2002 Opposing roles of serine/threonine kinases MEKK1 and LOK in regulating the CD28 responsive element in T-cells. The Biochemical journal 21 11903060
2021 STK10 knockout inhibits cell migration and promotes cell proliferation via modulating the activity of ERM and p38 MAPK in prostate cancer cells. Experimental and therapeutic medicine 19 34149897
2013 Migration of a Hem-o-Lok Clip to the Ureter Following Laparoscopic Partial Nephrectomy Presenting With Lower Urinary Tract Symptoms. International neurourology journal 19 23869274
1999 Molecular cloning of the human gene STK10 encoding lymphocyte-oriented kinase, and comparative chromosomal mapping of the human, mouse, and rat homologues. Immunogenetics 19 10199912
2013 STK10 missense mutations associated with anti-apoptotic function. Oncology reports 18 23842845
2019 Design and Analysis of the 4-Anilinoquin(az)oline Kinase Inhibition Profiles of GAK/SLK/STK10 Using Quantitative Structure-Activity Relationships. ChemMedChem 16 31675459
2021 Discovery of a Potent Dual SLK/STK10 Inhibitor Based on a Maleimide Scaffold. Journal of medicinal chemistry 10 34463505
2023 VIRMA promotes neuron apoptosis via inducing m6A methylation of STK10 in spinal cord injury animal models. CNS neuroscience & therapeutics 7 37721438
2020 Migration of Hem-O-Lok in Pelvicaliceal System Mimicking Renal Calculus Following Robotic Nephron-Sparing Surgery: A Case Report with Review of Literature. Journal of endourology case reports 5 32775668
2020 Knockout of STK10 promotes the migration and invasion of cervical cancer cells. Translational cancer research 5 35117313
2026 STK10 regulates platelet function in arterial thrombosis and thromboinflammation. Blood 4 41055696
2023 Kinome profiling identifies MARK3 and STK10 as potential therapeutic targets in uveal melanoma. The Journal of biological chemistry 4 37923138
2022 Stk10 Deficiency in Mice Promotes Tumor Growth by Dysregulating the Tumor Microenvironment. Biology 3 36421382
2018 Transmural migration of azygous vein Hem-O-lok clip causing food bolus 3 months following uneventful minimally invasive oesophagectomy. Acta chirurgica Belgica 3 29969952
2017 Assimilates mobilization, stable canopy temperature and expression of expansin stabilizes grain weight in wheat cultivar LOK-1 under different soil moisture conditions. Botanical studies 3 28510197
2011 Variations in the STK10 gene and possible associations with aspirin-intolerant asthma in a Korean population. Journal of investigational allergology & clinical immunology 2 21905501
2025 Un-LOK-ing a New Approach for Conformational Selective Targeting of STK10 (LOK). ACS medicinal chemistry letters 1 41256983
2016 The Application of Hem-O-Lok Clips Tied with Threads to Improve Surgical View in Retroperitoneal Laparoscopic Surgery for Renal Cell Carcinoma. Journal of laparoendoscopic & advanced surgical techniques. Part A 1 27575462
2011 A Feasible Technique for Transient Vascular Occlusion by Using a Vessel Loop and Hem-o-Lok Clips in Laparoscopic Partial Nephrectomy. Korean journal of urology 1 21927701
2026 Deletion of platelet STK10 impairs deep vein thrombus formation. Journal of thrombosis and haemostasis : JTH 0 41791658
2026 The LOK C-terminus is an IBAR-like domain that facilitates membrane binding and ezrin colocalization. Biophysical journal 0 41958020
2024 STK10 mutations block erythropoiesis in acquired pure red cell aplasia via impairing ribosome biogenesis. Annals of hematology 0 38761185
2024 The clinical efficacy of monolayer suture combined with hem-o-lok clip in partial nephrectomy among patient with renal cell carcinoma: a quasi-experimental study. World journal of surgical oncology 0 39511609
2023 Transurethral Hem-o-lok Clip Ligation of the Distal Ureter in Retroperitoneal Laparoscopic Radical Nephroureterectomy. Urologia internationalis 0 37967543

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