SH3 Domain Research Articles

First results of migoprotafib, a potent and highly selective Src homology-2 domain-containing phosphatase 2 (SHP2) inhibitor in patients with advanced solid tumors.

Src homology-2 domain-containing phosphatase 2 (SHP2) promotes RAS-MAPK signaling and tumorigenesis and is a promising therapeutic target for multiple solid tumors. Migoprotafib is a potent and highly selective SHP2 inhibitor designed for the treatment of RAS-MAPK driven cancers, particularly in combination with other targeted agents. Here we report first-in-human study results of single agent migoprotafib in advanced solid tumor patients. We conducted a phase 1a, open-label, multi-center, dose-escalation and expansion study in adult patients with locally advanced or metastatic solid tumors. The key objectives were to evaluate safety, pharmacokinetics, pharmacodynamics (peripheral blood pERK) and preliminary anti-tumor activity. Fifty-six heavily pre-treated patients were treated with migoprotafib (10-150 mg QD). Migoprotafib had a rapid absorption rate (~0.5-2 hours) with dose-dependent increases in exposure and pathway modulation (pERK changes). The maximum tolerated dose was 100 mg and the recommended phase 2 dose (RP2D) was 60 mg daily (QD) based on safety, pharmacokinetics (PK), pharmacodynamics, and anti-tumor activity. Migoprotafib was generally well tolerated with the most frequent adverse events of diarrhea, peripheral edema, dyspnea, anemia, constipation, fatigue, AST increase and platelet count decrease. Stable disease was observed in 10 patients (18%). Migoprotafib had predictable, dose-dependent PK with an effective half-life that supports QD dosing and demonstrated promising safety, tolerability, and clinical activity at the RP2D. Further clinical testing of migoprotafib in combination with other targeted agents is warranted.

The gut microbiota-derived metabolite indole-3-propionic acid enhances leptin sensitivity by targeting STAT3 against diet-induced obesity.

Obesity is associated with the gut microbiome. Here, we report that gut commensal Clostridia bacteria regulate host energy balance through the tryptophan-derived metabolite indole-3-propionic acid (IPA). IPA acts as an endogenous leptin sensitiser to counteract obesity. Mechanistically, IPA is secreted from the gut into the circulation, and then targets to the STAT3 in the hypothalamic appetite regulation centre, promoting its phosphorylation and nuclear translocation, which enhances the body's response to leptin, and regulates the balance between appetite and energy metabolism. The in vitro pull-down assays involving site-directed mutagenesis demonstrate that Trp623 in the SH2 domain is the key binding site for STAT3-IPA interaction. High-fat diet (HFD), rather than genetic factors, induces excessive secretion of antimicrobial peptides by Paneth cells, inhibiting the growth of Clostridia in the gut and resulting in decreased production of the beneficial metabolite IPA. IPA or Clostridium sporogenes supplement effectively controls weight gain, improves glucose metabolism, and reduces inflammation in DIO mice. IPA fails to achieve such effects in ob/ob mice, while exogenous leptin administration restores the therapeutic effect of IPA. Our study suggests that the IPA-based gut-brain axis regulates host metabolism, and supplementation with microbiome-derived IPA could be a promising intervention strategy for treating obesity.

Early life lipid overload in Native American Myopathy is phenocopied by stac3 knockout in zebrafish

Understanding the early stages of human congenital myopathies is critical for proposing strategies for improving musculoskeletal muscle performance, such as restoring the functional integrity of the cytoskeleton. SH3 and cysteine-rich domain 3 (STAC3) are proteins involved in nutrient regulation and are an essential component of the excitation–contraction (EC) coupling machinery for Ca2+ releasing. A mutation in STAC3 causes debilitating Native American Myopathy (NAM) in humans, while loss of this gene in mice and zebrafish (ZF) results in premature death. Clinically, NAM patients demonstrated increased lipids in skeletal muscle, but it is unclear if neutral lipids are associated with altered muscle function in NAM. Using a CRISPR/Cas9 induced stac3-/- knockout (KO) zebrafish model, we determined that loss of stac3 leads to delayed larval hatching which corresponds with muscle weakness and decreased whole-body Ca2+ level during early skeletal development. Specifically, we observed defects in the cytoskeleton in F-actin and slow muscle fibers at 5 and 7 days post-fertilizations (dpf). Myogenesis regulators such as myoD and myf5, mstnb were significantly altered in stac3-/- larvae. These muscle alterations were associated with elevated neutral lipid levels starting at 5 dpf and persisting beyond 7 dpf. Larva lacking stac3 had reduced viability with no larva knockouts surviving past 11 dpf. This data suggests that our stac3-/- zebrafish serve as an alternative model to study the diminished muscle function seen in NAM patients. The data gathered from this new model over time supports a mechanistic view of lipotoxicity as a critical part of the pathology of NAM and the associated loss of function in muscle.

A Novel Method to Profile Transcripts Encoding SH2 Domains in the Patiria miniata Mature Egg Transcriptome.

The critical mechanism to restart zygote metabolism and prevent polyspermy during fertilization is the intracellular Ca2+ increase. All of the signaling molecules leading to the Ca2+ rise are not fully known in any species. In the sea star Patiria miniata, SFK1, SFK3, and PLCγ participate in this fertilization Ca2+ increase. These proteins share common regulatory features, including signaling via tyrosine phosphorylation and their SH2 domains. In this study, we explore two different bioinformatic strategies to identify transcripts in the Patiria miniata mature egg transcriptome (Accession PRJNA398668) that code for proteins possessing an SH2 domain. The first identified the longest open reading frame for each transcript and then utilized similarity searching tools to provide identities for each transcript. The second, novel, method involved a six-frame translation of the entire transcriptome to identify SH2 domain-containing proteins. The identified transcripts were aligned against the NCBI non-redundant database and the SwissProt database. Eighty-two transcripts that encoded SH2 domains were identified. Of these, 33 were only found using the novel method. This work furthers research into egg activation by providing possible target proteins for future experiments and a novel method for identifying specific proteins of interest within a de novo transcriptome.

Generating and validating renewable affimer protein binding reagents targeting SH2 domains

Despite SH2 domains, being pivotal in protein interactions linked to various diseases like cancer, we lack specific research tools for intracellular assays. Understanding SH2-mediated interactions and creating effective inhibitors requires tools which target individual protein domains. Affimer reagents exhibit promise, yet their potential against the extensive SH2 domain family remains largely unexplored. Our study aimed to bridge this gap by identifying Affimer reagents that selectively bind to 22 out of 41 SH2 domains. These reagents enabled a medium-throughput screening approach resembling siRNA studies, shedding light on their functionality. Notably, select Affimers demonstrated the ability to curtail the nuclear translocation of pERK, with Grb2 being a prominent target. Further analyses revealed that these Grb2-specific Affimer reagents displayed competitive inhibition with impressive metrics: IC50s ranging from 270.9 nM to 1.22 µM, together with low nanomolar binding affinities. Moreover, they exhibited the ability to pull down endogenous Grb2 from cell lysates, illustrating their efficacy in binding the Grb2 SH2 domain. This comprehensive assessment underscores the potential of Affimer reagents as domain-specific inhibitors. Their viability for medium/high-throughput phenotypic screening presents a promising avenue via which to identify and characterize potential drug targets within the SH2 domain family.

Structural Insights into the Mechanism of a Polyketide Synthase Thiocysteine Lyase Domain.

Polyketide synthases (PKSs) are renowned for the structural diversity of the polyketide natural products they produce, but sulfur-containing functionalities are rarely installed by PKSs. We previously characterized thiocysteine lyase (SH) domains involved in the biosynthesis of the leinamycin (LNM) family of natural products, exemplified by LnmJ-SH and guangnanmycin (GnmT-SH). Here we report a detailed investigation into the PLP-dependent reaction catalyzed by the SH domains, guided by a 1.8 Å resolution crystal structure of GnmT-SH. A series of elaborate substrate mimics were synthesized to answer specific questions garnered from the crystal structure and from the biosynthetic logic of the LNM family of natural products. Through a combination of bioinformatics, molecular modeling, in vitro assays, and mutagenesis, we have developed a detailed model of acyl carrier protein (ACP)-tethered substrate-SH, and interdomain interactions, that contribute to the observed substrate specificity. Comparison of the GnmT-SH structure with archetypical PLP-dependent enzyme structures revealed how Nature, via evolution, has modified a common protein structural motif to accommodate an ACP-tethered substrate, which is significantly larger than any of those previously characterized. Overall, this study demonstrates how PLP-dependent chemistry can be incorporated into the context of PKS assembly lines and sets the stage for engineering PKSs to produce sulfur-containing polyketides.

Allosteric regulation of the tyrosine phosphatase PTP1B by a protein-protein interaction.

Protein-protein interactions are critical for cell signaling. The interaction between the phosphatase PTP1B and adaptor protein Grb2 co-localizes PTP1B with its substrates, thereby enhancing their dephosphorylation. We show that Grb2 binding also directly modulates PTP1B activity through an allosteric mechanism involving the proline-rich region of PTP1B. Our study reveals a novel mode of PTP1B regulation through a protein-protein interaction that is likely to be exploited by other cellular interactors of this important signaling enzyme.

AAV1.tMCK.NT-3 gene therapy improves phenotype in Sh3tc2-/- mouse model of Charcot-Marie-Tooth Type 4C.

Charcot-Marie-Tooth Type 4C (CMT4C) is associated with mutations in the SH3 domain and tetratricopeptide repeats 2 (SH3TC2) gene, primarily expressed in Schwann cells (SCs). Neurotrophin-3 (NT-3) is an important autocrine factor for SC survival and differentiation, and it stimulates neurite outgrowth and myelination. In this study, scAAV1.tMCK.NT-3 was delivered intramuscularly to 4-week-old Sh3tc2-/- mice, a model for CMT4C, and treatment efficacy was assessed at 6-month post-gene delivery. Efficient transgene production was verified with the detection of NT-3 in serum from the treated cohort. NT-3 gene therapy improved functional and electrophysiological outcomes including rotarod, grip strength and nerve conduction velocity. Qualitative and quantitative histopathological studies showed that hypomyelination of peripheral nerves and denervated status of neuromuscular junctions at lumbrical muscles were also improved in the NT-3-treated mice. Morphometric analysis in mid-sciatic and tibial nerves showed treatment-induced distally prominent regenerative activity in the nerve and an increase in the estimated SC density. This indicates that SC proliferation and differentiation, including the promyelination stage, are normal in the Sh3tc2-/- mice, consistent with the previous findings that Sh3tc2 is not involved in the early stages of myelination. Moreover, in size distribution histograms, the number of myelinated axons within the 3- to 6-µm diameter range increased, suggesting that treatment resulted in continuous radial growth of regenerating axons over time. In conclusion, this study demonstrates the efficacy of AAV1.NT-3 gene therapy in the Sh3tc2-/- mouse model of CMT4C, the most common recessively inherited demyelinating CMT subtype.

Effects of changes in SHP2 expression on liver fibrosis by influencing the apoptosis of hepatic stellate cells.

Accumulating research has revealed that src-homology domain 2-containing protein tyrosine phosphatase-2 (SHP2), an oncogenic protein tyrosine phosphatase, is associated with liver fibrosis. Currently, it is still unclear whether SHP2 affects liver fibrosis by influencing the apoptosis of hepatic stellate cells (HSC). In present study, we investigate effects of SHP2 expression changes on liver fibrosis, with special emphasis on the apoptosis of HSC. Using adenovirus vector, wild-type SHP2 gene and short hairpin RNA targeting SHP2 were introduced into rats with liver fibrosis and LX-2 cells in vitro. The expressions of type I and III collagen, pathological and functional changes, collagen deposition in rat liver and apoptosis of LX-2 cells were detected by immunohistochemical and HE staining, automated biochemical analyzer, Masson trichrome staining, and TUNEL. This study showed that overexpression of SHP2 exacerbated dysfunction, inflammatory damage, collagen deposition and increased expression of type I and III collagen in rat liver reduced apoptosis of LX-2 cells. On the contrary, low expression of SHP2 alleviated the aforementioned detection indicators of rats and promoted apoptosis of LX-2 cells. In conclusion, the downregulation of SHP2 expression alleviates liver fibrosis by inducing the apoptosis of HSC, while overexpressed SHP2 exacerbates liver fibrosis by inhibiting the apoptosis of HSC.

Aloe Emodin Alleviates Radiation-Induced Heart Disease via Blocking P4HB Lactylation and Mitigating Kynurenine Metabolic Disruption.

Aloe emodin is an anthraquinone of traditional Chinese medicine monomer, which plays a protective action in cardiovascular diseases. However, the regulatory mechanisms of aloe emodin in the protection of radiation-induced heart damage (RIHD) are unclear. As a novel post-translational modification, lactylation is considered as a critical mediator in inflammatory cascade and cardiac injury. Here, using a cross of differential omics and 4D label-free lactylation omics, protein disulfide-isomerase (P4HB) is identified as a novel target for lactylation, and aloe emodin inhibits the binding of lactate to the K311 site of P4HB. Aloe emodin stabilizes kynurenine metabolism through inhibition of aspartate aminotransferase (GOT2) accumulation on damaged mitochondria. Mechanistically, aloe emodin inhibits phosphorylated glycogen synthase kinase 3B (p-GSK3B) transcription in the nucleus to repress the interaction of prostaglandin G/H synthase 2 (PTGS2) with SH3 domain of SH3 domain-containing GRB2-like protein B1 (SH3GLB1), thereby disrupting the functions of mitochondrial complexes and reducing SH3GLB1-mediated mitoROS accumulation, eventually suppressing calcium-binding and coiled-coil domain-containing protein 2 (NDP52)-induced mitophagy. This study unveils the regulatory role of aloe emodin in RIHD alleviation through PTGS2/SH3GLB1/NDP52 axis, indicates aloe emodin stabilizes GOT2-mediated kynurenine metabolism through P4HB lactylation. Collectively, this study provides novel insights into the regulatory mechanisms underlying the protective role of aloe emodin in cardiac injury, and opens new avenues for therapeutic strategies of aloe emodin in preventing RIHD by regulating lactylation.

Synthesis of a 13C/2H Labeled Building Block to Probe the Phosphotyrosine Interactome Using Biomolecular NMR Spectroscopy.

Phosphotyrosine (pTyr) recognition coordinates the assembly of protein complexes, thus controlling key events of cell cycle, cell development and programmed cell death. Although many aspects of membrane receptor function and intracellular signal transduction have been deciphered in the last decades, the details of how phosphorylation alters protein-protein interaction and creates regulating switches of protein activity and localization often remains unclear. We developed a synthetic route to a protected phophotyrosine building block with isolated 13C-1H spins in the aromatic ring. The compound can be used for solid phase peptide synthesis (SPPS) and readily applied to study affinity, dynamics and interactions on an atomic level using NMR spectroscopy. As a first example, we prepared an isotopologue of a pTyr containing 12mer peptide (pY1021) as part of the platelet-derived growth factor to analyze the binding to the phospholipase C-γ (PLCγ-1) SH2 domain.

A ZO-2 scaffolding mechanism regulates the Hippo signalling pathway.

Contact inhibition of proliferation is a critical cell density control mechanism governed by the Hippo signalling pathway. The biochemical signalling underlying cell density-dependent cues regulating Hippo signalling and its downstream effectors, YAP, remains poorly understood. Here, we reveal that the tight junction protein ZO-2 is required for the contact-mediated inhibition of proliferation. We additionally determined that the well-established molecular players of this process, namely Hippo kinase LATS1 and YAP, are regulated by ZO-2 and that the scaffolding function of ZO-2 promotes the interaction with and phosphorylation of YAP by LATS1. Mechanistically, YAP is phosphorylated when ZO-2 brings LATS1 and YAP together via its SH3 and PDZ domains, respectively, subsequently leading to the cytoplasmic retention and inactivation of YAP. In conclusion, we demonstrate that ZO-2 maintains Hippo signalling pathway activation by promoting the stability of LATS1 to inactivate YAP.

Adapting to change: resolving the dynamic and dual roles of NCK1 and NCK2.

Adaptor proteins play central roles in the assembly of molecular complexes and co-ordinated activation of specific pathways. Through their modular domain structure, the NCK family of adaptor proteins (NCK1 and NCK2) link protein targets via their single SRC Homology (SH) 2 and three SH3 domains. Classically, their SH2 domain binds to phosphotyrosine motif-containing receptors (e.g. receptor tyrosine kinases), while their SH3 domains bind polyproline motif-containing cytoplasmic effectors. Due to these functions being established for both NCK1 and NCK2, their roles were inaccurately assumed to be redundant. However, in contrast with this previously held view, NCK1 and NCK2 now have a growing list of paralog-specific functions, which underscores the need to further explore their differences. Here we review current evidence detailing how these two paralogs are unique, including differences in their gene/protein regulation, binding partners and overall contributions to cellular functions. To help explain these contrasting characteristics, we then discuss SH2/SH3 structural features, disordered interdomain linker regions and post-translational modifications. Together, this review seeks to highlight the importance of distinguishing NCK1 and NCK2 in research and to pave the way for investigations into the origins of their interaction specificity.

Myosin-5a facilitates stress granule formation by interacting with G3BP1

Stress granules (SGs) are non-membranous organelles composed of mRNA and proteins that assemble in the cytosol when the cell is under stress. Although the composition of mammalian SGs is both cell-type and stress-dependent, they consistently contain core components, such as Ras GTPase activating protein SH3 domain binding protein 1 (G3BP1). Upon stress, living cells rapidly assemble micrometric SGs, sometimes within a few minutes, suggesting that SG components may be actively transported by the microtubule and/or actin cytoskeleton. Indeed, SG assembly has been shown to depend on the microtubule cytoskeleton and the associated motor proteins. However, the role of the actin cytoskeleton and associated myosin motor proteins remains controversial. Here, we identified G3BP1 as a novel binding protein of unconventional myosin-5a (Myo5a). G3BP1 uses its C-terminal RNA-binding domain to interact with the middle portion of Myo5a tail domain (Myo5a-MTD). Suppressing Myo5a function in mammalian cells, either by overexpressing Myo5a-MTD, eliminating Myo5a gene expression, or treatment with myosin-5 inhibitor, inhibits the arsenite-induced formation of both small and large SGs. This is different from the effect of microtubule disruption, which abolishes the formation of large SGs but enhances the formation of small SGs under stress conditions. We therefore propose that, under stress conditions, Myo5a facilitates the formation of SGs at an earlier stage than the microtubule-dependent process.

Endosomal actin branching, fission, and receptor recycling require FCHSD2 recruitment by MICAL-L1.

Endosome fission is required for the release of carrier vesicles and the recycling of receptors to the plasma membrane. Early events in endosome budding and fission rely on actin branching to constrict the endosomal membrane, ultimately leading to nucleotide hydrolysis and enzymatic fission. However, our current understanding of this process is limited, particularly regarding the coordination between the early and late steps of endosomal fission. Here we have identified a novel interaction between the endosomal scaffolding protein, MICAL-L1, and the human homologue of the Drosophila Nervous Wreck (Nwk) protein, FCH and double SH3 domains protein 2 (FCHSD2). We demonstrate that MICAL-L1 recruits FCHSD2 to the endosomal membrane, where it is required for ARP2/3-mediated generation of branched actin, endosome fission and receptor recycling to the plasma membrane. Because MICAL-L1 first recruits FCHSD2 to the endosomal membrane, and is subsequently responsible for recruitment of the ATPase and fission protein EHD1 to endosomes, our findings support a model in which MICAL-L1 orchestrates endosomal fission by connecting between the early actin-driven and subsequent nucleotide hydrolysis steps of the process.

Fluorescent Labeling Can Significantly Perturb Measured Binding Affinity and Selectivity of Peptide-Protein Interactions.

Peptide-based drugs are powerful inhibitors of therapeutically relevant protein-protein interactions. Their affinity and selectivity for target proteins are commonly assessed using fluorescence-based assays such as anisotropy/polarization or quantitative microarrays. This study reveals that labeling can perturb peptide/protein binding by more than 1 order of magnitude. We have recently developed inhibitors targeted to the N-terminal Src homology 2 (SH2) domain of oncogenic phosphatase SHP2. Despite their high activity and selectivity, these molecules demonstrated an undesired interaction with the SH2 domain of another protein, known as APS, in a fluorescence microarray assay. Fluorescence anisotropy measurement in solution showed that the dissociation constant was significantly influenced by labeling (∼10 times), and the effect depended on the specific fluorophore and SH2 domain. Notably, displacement assays performed with unlabeled peptides were successfully used to eliminate these artifacts, demonstrating that the inhibitors' affinity for their target is over 1,000 times higher than for APS.

The I7L protein of African swine fever virus is involved in viral pathogenicity by antagonizing the IFN-γ-triggered JAK-STAT signaling pathway through inhibiting the phosphorylation of STAT1.

Cell-passage-adapted strains of African swine fever virus (ASFV) typically exhibit substantial genomic alterations and attenuated virulence in pigs. We have indicated that the human embryonic kidney (HEK293T) cells-adapted ASFV strain underwent genetic alterations and the I7L gene in the right variable region was deleted compared with the ASFV HLJ/2018 strain (ASFV-WT). A recent study has revealed that the deletion of the I7L-I11L genes results in attenuation of virulent ASFV in vivo, but the underlying mechanism remains largely unknown. Therefore, we hypothesized that the deletion of the I7L gene may be related to the pathogenicity of ASFV in pigs. We generated the I7L gene-deleted ASFV mutant (ASFV-ΔI7L) and found that the I7L gene deletion does not influence the replication of ASFV in primary porcine alveolar macrophages (PAMs). Using transcriptome sequencing analysis, we identified that the differentially expressed genes in the PAMs infected with ASFV-ΔI7L were mainly involved in antiviral immune responses induced by interferon gamma (IFN-γ) compared with those in the ASFV-WT-infected PAMs. Meanwhile, we further confirmed that the I7L protein (pI7L) suppressed the IFN-γ-triggered JAK-STAT signaling pathway. Mechanistically, pI7L interacts with STAT1 and inhibits its phosphorylation and homodimerization, which depends on the tyrosine at position 98 (Y98) of pI7L, thereby preventing the nuclear translocation of STAT1 and leading to the decreased production of IFN-γ-stimulated genes. Importantly, ASFV-ΔI7L exhibited reduced replication and virulence compared with ASFV-WT in pigs, likely due to the increased production of IFN-γ-stimulated genes, indicating that pI7L is involved in the virulence of ASFV. Taken together, our findings demonstrate that pI7L is associated with pathogenicity and antagonizes the IFN-γ-triggered JAK-STAT signaling pathway via inhibiting the phosphorylation and homodimerization of STAT1 depending on the Y98 residue of pI7L and the Src homology 2 domain of STAT1, which provides more information for understanding the immunoevasion strategies and designing the live attenuated vaccines against ASFV infection.

Protein-Sequence-Based Search of Nonreceptor ITAM-Like Regions to Identify Cytosolic Syk-Recruiting Proteins.

The recruitment of the protein spleen tyrosine kinase (Syk) to membrane-bound immune receptors is an essential step in initiating an immune response mediated through the activated receptors. Syk recognizes intracellular phosphorylated regions of membrane receptors known as immunoreceptor tyrosine-based activation motifs (ITAMs) defined by a sequence with two tyrosine (Y) amino acids separated by a certain spacing of six to eight residues: YXX(I/L)X6-8YXX(I/L). Syk with doubly phosphorylated ITAM is high-affinity and negatively regulated when Syk itself becomes phosphorylated. While the role of Syk in immune signaling is well characterized, recent information affords new functionality to Syk related to cytoplasmic processes, including the clearance of stress granules and P-bodies, both formed by liquid-liquid phase separation. Little to nothing is known about the molecular interactions involving Syk in these cytoplasmic processes. Given the essential role of receptor ITAMs in recruiting and localizing Syk for immune signaling, we explore here the possibility of a similar localization mechanism occurring for cytoplasmic processes by searching sequences of proteins related to Syk cytoplasmic function for regions that resemble receptor ITAMs. Protein sequence databases were generated from a Syk-dependent phosphoproteome and from genes related to P-bodies. A search of these databases for ITAM-like sequences yielded 102 unique hits, and 33 of these were synthesized and tested experimentally for binding to Syk tandem SH2 domains. The equilibrium dissociation constants were 0.1-50 μM for 28 peptides, and binding was negatively regulated by phosphorylation for many peptides. These results identify cytoplasmic proteins with potential for regulating the localization of Syk in a phosphorylation-dependent manner to nonmembrane cellular regions.

Cocrystallization of the Src-Family Kinase Hck with the ATP-Site Inhibitor A-419259 Stabilizes an Extended Activation Loop Conformation.

Hematopoietic cell kinase (Hck) is a member of the Src kinase family and is a promising drug target in myeloid leukemias. Here, we report the crystal structure of human Hck in complex with the pyrrolopyrimidine inhibitor A-419259, determined at a resolution of 1.8 Å. This structure reveals the complete Hck active site in the presence of A-419259, including the αC-helix, the DFG motif, and the activation loop. A-419259 binds at the ATP-site of Hck and induces an overall closed conformation of the kinase with the regulatory SH3 and SH2 domains bound intramolecularly to their respective internal ligands. A-419259 stabilizes the DFG-in/αC-helix-out conformation observed previously with Hck and the pyrazolopyrimidine inhibitor PP1 (PDB: 1QCF). However, the activation loop conformations are distinct, with PP1 inducing a folded loop structure with the tyrosine autophosphorylation site (Tyr416) pointing into the ATP binding site, while A-419259 stabilizes an extended loop conformation with Tyr416 facing out into the solvent. Autophosphorylation also induces activation loop extension and significantly reduces the Hck sensitivity to PP1 but not A-419259. In cancer cells where Hck is constitutively active, the extended autophosphorylation loop may render Hck more sensitive to inhibitors like A-419259 which prefer this kinase conformation. More generally, these results provide additional insight into targeted kinase inhibitor design and how conformational preferences of inhibitors may impact selectivity and potency.

The downregulation of SASH1 expression promotes breast cancer occurrence and invasion accompanied by the activation of PI3K-Akt-mTOR signaling pathway

SASH1 (SAM and SH3 domain containing 1) has been increasingly reported as a tumor suppressor gene. However, there is limited research on the role of SASH1 in breast cancer. This manuscript aims to investigate the mechanism of SASH1 in the occurrence, development, and prognosis of breast cancer. Firstly, we obtained RNA-sequencing data of the tumors from the Genomic Data Commons data portal website, along with the corresponding clinical information of patients. Pan-cancer analysis was performed to analyze the expression of SASH1 across all tumors. Univariate Cox regression analysis was used to assess the correlation between SASH1 expression and the prognosis of breast cancer patients. Then, immunohistochemistry was utilized to evaluate the expression levels of SASH1, p-Akt, p-PI3K, and p-mTOR in breast cancer tissue. Finally, a cell assay was employed to analyze the impact of SASH1 on the proliferation and invasion of breast cancer cells (MDA-MB-231). The results revealed that SASH1 expression is decreased in BRCA, LUSC, LUAD, CESC, ESCA, and COAD. Meta-analysis also found that SASH1 is downregulated in most tumor tissues, and the expression level of SASH1 in breast cancer was significantly lower than that in the control group (OR = 0.14, 95% CI = 0.08–0.25; P < 0.001). Further experimental validation showed that SASH1 expression is significantly downregulated in breast cancer tissue (38.33%, 23/60), and the overexpression of SASH1 can inhibit the proliferation and invasion of breast cancer cells accompanied by the suppression of PI3K-Akt-mTOR signaling pathway. Additionally, SASH1 overexpression can improve OS and RFS of breast cancer patients.