{"type": "root", "children": [{"type": "p", "children": [{"type": "t", "text": "\n ATP1B1, which encodes the β₁ subunit of the Na⁺/K⁺-ATPase, plays a multifaceted role in maintaining ion gradients, cell adhesion, and signaling in diverse tissues. In the cardiovascular system, genome‐wide studies have implicated ATP1B1 in myocardial electrophysiology and QT interval regulation."}, {"type": "fg", "children": [{"type": "fg_f", "ref": "1"}]}, {"type": "t", "text": " In the context of neoplasia, ATP1B1 serves as an oncogenic fusion partner with protein kinase A catalytic subunits (PRKACA/PRKACB) in pancreatobiliary lesions, suggesting a role in aberrant kinase signaling and tumorigenesis."}, {"type": "fg", "children": [{"type": "fg_f", "ref": "2"}]}, {"type": "t", "text": " Transcriptional regulators, including ERRα and NRF‑1, modulate ATP1B1 expression; such regulation links ATP1B1 to renal sodium and potassium handling as well as to the tight coupling between neuronal activity and energy metabolism."}, {"type": "fg", "children": [{"type": "fg_f", "ref": "4"}]}, {"type": "t", "text": " In airway epithelia, inflammatory stimuli and cytokines provoke relocalization of ATP1B1 from the basal to the apical membrane where it colocalizes with ATP12A, a redistribution that may affect epithelial fluid pH and host defenses."}, {"type": "fg", "children": [{"type": "fg_f", "ref": "6"}]}, {"type": "t", "text": " In the nervous system, ATP1B1 has been identified as an interacting partner with KIRREL3, implicating it in synaptic signaling and potentially neurodevelopment."}, {"type": "fg", "children": [{"type": "fg_f", "ref": "7"}]}, {"type": "t", "text": ""}]}, {"type": "t", "text": "\n \n "}, {"type": "p", "children": [{"type": "t", "text": "\n Alterations in ATP1B1 expression have prognostic and functional implications in several cancers. Downregulation of ATP1B1—mediated either by epigenetic silencing in renal cell carcinoma"}, {"type": "fg", "children": [{"type": "fg_f", "ref": "8"}]}, {"type": "t", "text": "or by reduced expression in papillary thyroid carcinoma as a PAX8 target gene"}, {"type": "fg", "children": [{"type": "fg_f", "ref": "9"}]}, {"type": "t", "text": "—suggests that normal ATP1B1 levels may contribute to cell–cell adhesion and proper ion transport, and its loss may influence disease progression. In ovarian cancer models, decreased ATP1B1 is associated with resistance to platinum drugs, while restoration of ATP1B1 enhances drug accumulation independently of Na⁺/K⁺-ATPase enzyme activity."}, {"type": "fg", "children": [{"type": "fg_f", "ref": "10"}]}, {"type": "t", "text": " Moreover, high ATP1B1 expression in cytogenetically normal acute myeloid leukemia correlates with poor clinical outcome, further underscoring its relevance as a prognostic marker."}, {"type": "fg", "children": [{"type": "fg_f", "ref": "11"}]}, {"type": "t", "text": "\n "}]}, {"type": "t", "text": "\n \n "}, {"type": "p", "children": [{"type": "t", "text": "\n Post‐transcriptional control of ATP1B1 is also evident; for instance, miR‑192‑5p targets the ATP1B1 mRNA."}, {"type": "fg", "children": [{"type": "fg_f", "ref": "12"}]}, {"type": "t", "text": " Furthermore, ATP1B1 is dispensable for unconventional fibroblast growth factor 2 (FGF2) secretion—a process that depends instead on unassembled ATP1A1—thereby delineating a functionally specific role for the β₁ subunit."}, {"type": "fg", "children": [{"type": "fg_f", "ref": "13"}]}, {"type": "t", "text": " Finally, ATP1B1 contributes to host–pathogen interactions; its cytoplasmic domain directly interacts with influenza virus M2/BM2 proteins, and knockdown of ATP1B1 significantly suppresses viral replication, highlighting its importance in the viral life cycle."}, {"type": "fg", "children": [{"type": "fg_f", "ref": "14"}]}, {"type": "t", "text": "\n "}]}, {"type": "t", "text": "\n \n "}, {"type": "p", "children": [{"type": "t", "text": "\n Collectively, these findings illustrate that ATP1B1 is not only critical for the establishment and maintenance of ionic homeostasis and cell polarity but also plays pivotal roles in diverse physiological and pathological contexts, including cardiac electrophysiology, oncogenesis, epithelial function, neuronal signaling, and host response to infection.\n "}]}, {"type": "rg", "children": [{"type": "r", "ref": 1, "children": [{"type": "t", "text": "Arne Pfeufer, Serena Sanna, Dan E Arking, et al. 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