Tandemly duplicated Rubisco activase genes of cereals show differential evolution and response to heat stress.

Heat stress affects various components of photosynthetic machinery of which Rubisco activation inhibition due to heat sensitive Rubisco activase (RCA) is the most prominent. Detailed comparison of RCA coding genes identified a tandem duplication event in the grass family lineage where the duplicated genes showed very different evolutionary pattern. One of the two genes showed high level of sequence conservation whereas the second copy, although present only 1.5 kb away, was highly variable among various plant species because of loss of introns, alternative splicing and loss of the last exon coding redox regulated C-terminal extension domain. Gene specific expression analysis, both at the transcription as well as the protein level, showed very different expression pattern of the two RCA copies. Expression of the highly conserved copy was higher under normal plant growing conditions that decreased many folds under heat stress with substantial genotypic variation, but the variable copy showed much higher expression under heat stress conditions across all grass species. The cultivated rice has only one functional gene as the second copy became nonfunctional due to multiple deletions but Oryza brachyantha and Oryza australiensis still have two functional Rca genes. Detailed analysis of the promoter region of the two copies among various plant species showed insertion of several transposable elements harboring heat responsive elements in the heat inducible copy of the gene. The conserved RCA copy of wheat didn't have any transposable insertions whereas in that of maize has one heat shock element and sorghum had two. It would be interesting to study if the higher level of heat stress tolerance observed in sorghum and maize is associated with the differences observed for RCA. Key message This manuscript is reporting a grass family-specific tandem duplication event in RCA genes of cereals. The duplicated copies underwent neo-functionalization to evolve novel function to deal with heat stress. One copy of the tandem duplication maintained a high level of conservation whereas the second copy showed tremendous divergence to evolve species specific function of the gene. Specific function to respond to heat stress likely evolved via the insertion of various heat responsive elements carried by transposable elements.