Genome-wide identification of BAG co-chaperones in wheat (Triticum aestivum) and their temperature-responsive expression patterns with functional characterization of TaBAG5 interaction with Hsp40/J-domain proteins.

Wheat productivity is severely impacted by temperature extremes, highlighting the need to understand stress tolerance mechanisms. The Bcl-2-associated athanogene (BAG) protein family is known to regulate stress responses, yet its functional roles in wheat under heat and cold stress are not well understood. This study identified ten TaBAG genes in wheat, primarily located on chromosomes 2, 4, 5, and 7. Bioinformatics analysis revealed conserved domains, diverse gene structures, and stress-responsive promoter elements, with notable duplication events on chromosomes 7 A and 7D. Subcellular localization predictions indicated that most TaBAG proteins localize to the nucleus, which was experimentally confirmed for TaBAG5. TaBAG5 also showed interaction with a J domain-containing protein/ heat shock protein 40 (Hsp40) (W5CWD3), suggesting involvement in chaperone-mediated pathways. Gene expression profiling under heat (40 °C) and cold (4 °C) stress demonstrated differential regulation: TaBAG2, TaBAG3, TaBAG6, TaBAG9, and TaBAG10 were upregulated by heat, while TaBAG2, TaBAG3, TaBAG5, TaBAG8, and TaBAG9 were induced by cold. Conversely, TaBAG1 was downregulated under both conditions. These results indicate that TaBAG genes contribute significantly to abiotic stress responses in wheat, potentially via interactions with heat shock proteins, and offer valuable insights for the development of stress-resilient wheat cultivars.