{"type": "root", "children": [{"type": "p", "children": [{"type": "t", "text": "\n Cytoplasmic polyadenylation element‐binding protein 2 (CPEB2) is emerging as a multifaceted translational regulator whose functions span development, cell‐cycle control, neural plasticity, metabolism, and tumorigenesis. In colorectal cancer, for example, CPEB2 is a critical node in microRNA‐regulated networks: one study showed that lncRNA TUG1 promoted methotrexate resistance via a miR‑186/CPEB2 axis"}, {"type": "fg", "children": [{"type": "fg_f", "ref": "1"}]}, {"type": "t", "text": ", while another found that miR‑885‑5p–mediated transcriptional repression of CPEB2 led to upregulation of TWIST1 and enhanced epithelial–mesenchymal transition."}, {"type": "fg", "children": [{"type": "fg_f", "ref": "2"}]}, {"type": "t", "text": ""}]}, {"type": "t", "text": "\n \n "}, {"type": "p", "children": [{"type": "t", "text": "\n In the context of breast cancer, alternative splicing of the CPEB2 transcript plays a pivotal role. Increased inclusion of exon 4 shifts expression toward the CPEB2B isoform, which has been linked to anoikis resistance and metastatic potential in triple‐negative breast cancer"}, {"type": "fg", "children": [{"type": "fg_f", "ref": "3"}]}, {"type": "t", "text": ", and lower expression of the tumor‐suppressive CPEB2A isoform correlates with more aggressive disease."}, {"type": "fg", "children": [{"type": "fg_f", "ref": "4"}]}, {"type": "t", "text": " Moreover, CPEB2 has been implicated in posttranscriptional regulation during mammary gland development and the formation of estrogen receptor–positive tumors."}, {"type": "fg", "children": [{"type": "fg_f", "ref": "5"}]}, {"type": "t", "text": ""}]}, {"type": "t", "text": "\n \n "}, {"type": "p", "children": [{"type": "t", "text": "\n CPEB2 also exerts critical functions in other cellular contexts. In renal cancer, it binds to the cytoplasmic polyadenylation elements in the 3′‐UTR of p53 mRNA and decreases p53 stability and translation, thereby contributing to tumor progression."}, {"type": "fg", "children": [{"type": "fg_f", "ref": "6"}]}, {"type": "t", "text": " In the nervous system, CPEB2 facilitates long‐term synaptic plasticity by enhancing the translation of GRASP1 mRNA to maintain proper AMPA receptor recycling, a process essential for hippocampus‐dependent memory"}, {"type": "fg", "children": [{"type": "fg_f", "ref": "7"}]}, {"type": "t", "text": ", and differential expression of its splice variants suggests overlapping RNA binding specificities with CPEB1 in neurons."}, {"type": "fg", "children": [{"type": "fg_f", "ref": "8"}]}, {"type": "t", "text": ""}]}, {"type": "t", "text": "\n \n "}, {"type": "p", "children": [{"type": "t", "text": "\n During embryonic and developmental processes, CPEB2 is indispensable. It is expressed in diverse tissues (including the testis where it is postmeiotically expressed;"}, {"type": "fg", "children": [{"type": "fg_f", "ref": "9"}]}, {"type": "t", "text": ", and is required for proper tight junction assembly during blastocyst formation by mediating the stabilization and subcellular localization of Tjp1 mRNA."}, {"type": "fg", "children": [{"type": "fg_f", "ref": "10"}]}, {"type": "t", "text": " In lung development, CPEB2 promotes the translation of PDGFRα mRNA in myofibroblast progenitors, thereby facilitating alveolar septation."}, {"type": "fg", "children": [{"type": "fg_f", "ref": "11"}]}, {"type": "t", "text": ""}]}, {"type": "t", "text": "\n \n "}, {"type": "p", "children": [{"type": "t", "text": "\n In trophoblasts, CPEB2 serves as a brake on hypoxia‐induced HIF‑1α translation by binding directly to its 3′‐UTR; this inhibition is relieved upon miR‑210 upregulation under hypoxic conditions, a mechanism that may contribute to the insufficient syncytialization observed in preeclampsia."}, {"type": "fg", "children": [{"type": "fg_f", "ref": "12"}]}, {"type": "t", "text": " In addition, its role during mitosis appears phase‐specific, with CPEB2 being essential for progression through metaphase."}, {"type": "fg", "children": [{"type": "fg_f", "ref": "13"}]}, {"type": "t", "text": ""}]}, {"type": "t", "text": "\n \n "}, {"type": "p", "children": [{"type": "t", "text": "\n In metabolic regulation, CPEB2‐dependent translation is vital for thermogenesis; β3 adrenergic receptor signaling enhances the translation of a long 3′‐UTR isoform of Ucp1 mRNA in brown adipose tissue, and CPEB2 knockout mice display reduced UCP1 levels and impaired thermogenic responses."}, {"type": "fg", "children": [{"type": "fg_f", "ref": "14"}]}, {"type": "t", "text": "\n "}]}, {"type": "t", "text": "\n \n "}, {"type": "p", "children": [{"type": "t", "text": "\n Finally, emerging evidence indicates that oncogenic long noncoding RNAs can subvert CPEB2 function. For instance, the lncRNA EMS interacts with CPEB2 to disrupt its association with p53 mRNA, leading to attenuated p53 translation and promoting tumorigenesis."}, {"type": "fg", "children": [{"type": "fg_f", "ref": "15"}]}, {"type": "t", "text": "\n "}]}, {"type": "t", "text": "\n \n "}, {"type": "p", "children": [{"type": "t", "text": "\n Collectively, these studies underscore CPEB2 as a pivotal posttranscriptional regulator whose context‑dependent activities—ranging from modulation of chemoresistance and metastasis in cancer to maintaining neuronal connectivity, proper embryonic development, and metabolic homeostasis—make it an attractive candidate for targeted therapeutic intervention."}, {"type": "fg", "children": [{"type": "fg_f", "ref": "16"}]}, {"type": "t", "text": "\n "}]}, {"type": "rg", "children": [{"type": "r", "ref": 1, "children": [{"type": "t", "text": "Changfeng Li, Yongjian Gao, Yongchao Li, et al. 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