Targeting STAT5A via CRISPR/Cas9 restores TKI sensitivity in resistant chronic myeloid leukemia cells.

Therapeutic resistance to tyrosine kinase inhibitors (TKIs) remains a major challenge in the clinical management of chronic myeloid leukemia (CML). The transcription factor STAT5A, a principal downstream effector of BCR::ABL1, has emerged as a key transcriptional regulator implicated in the development of TKI resistance. This study aims to functionally validate the role of STAT5A in TKI-resistant CML by employing CRISPR/Cas9-mediated gene knockout and assessing the downstream molecular and phenotypic alterations. We hypothesized that selective disruption of STAT5A would restore apoptotic sensitivity and TKI responsiveness in resistant CML models. Additionally, we sought to integrate bioinformatic transcriptional network analyses to confirm whether STAT5A directly regulates the genes modulated by its deletion, thus reinforcing its mechanistic relevance as a therapeutic target. STAT5A was knocked out using CRISPR/Cas9 in K562 cells and their TKI-resistant derivatives (K562/Ima-Res, K562/Pon-Res). Western blot analysis confirmed effective depletion of STAT5A protein following CRISPR/Cas9 editing, validating that the observed phenotypic and transcriptional changes were attributable to successful STAT5A knockout. Post-editing, XTT assays were performed to assess cell viability, followed by Annexin V/PI staining for apoptosis and PI-based flow cytometry for cell cycle analysis. RT-qPCR was used to quantify the expression of key genes involved in the JAK/STAT pathway (JAK2, STAT3, CISH) and apoptosis/DNA damage responses (TP53, ATM, CASP3, CASP8). In silico analyses were conducted using TRRUST and Harmonizome/ChEA3 to confirm whether the genes modulated by STAT5A deletion were direct transcriptional targets. For additional validation, expression matrices from GSE207627 and GSE208314 were reanalyzed to confirm STAT5A-centered pathway alterations in resistant CML datasets. STAT5A knockout significantly reduced cell viability and induced apoptosis across all CML cell models, accompanied by G0/G1 cell cycle arrest. RT-qPCR revealed altered expression of both JAK/STAT components (JAK2, STAT3, CISH) and apoptosis-related genes (TP53, ATM, CASP3, CASP8). Transcriptional target analysis confirmed that several of these genes-such as CDKN2B, BCL2L1, and CCND1-are direct STAT5A targets, reinforcing the functional consequences of STAT5A loss. Integration of these findings suggests that STAT5A knockout reprograms both intrinsic (CASP3, TP53, ATM) and extrinsic (CASP8, BCL2L1) apoptotic pathways, thereby restoring chemosensitivity. CISH dysregulation further suggested compensatory feedback within the signaling network. CRISPR/Cas9-mediated STAT5A disruption effectively reverses TKI resistance in CML cells by reprogramming apoptotic and proliferative signaling. These findings identify STAT5A as a mechanistically validated and clinically actionable target, supporting its potential for combination strategies with TKIs or STAT5 inhibitors such as pimozide. Integration of transcriptional network analysis supports the mechanistic basis of these effects. STAT5A emerges as a compelling therapeutic target, meriting further investigation in preclinical models and patient-derived samples to evaluate its translational potential. Future validation in patient-derived CD34⁺ CML models may advance STAT5A-based therapeutic design.