Divergence of plastid 2-oxoglutarate 'only' transporters away from general transporters by using a cysteine-rich architecture

The common carbon and nitrogen currency, 2-oxoglutarate, could become a valuable resource for nitrogen assimilation and carbon centered biochemical fates. Here in this in silico study, a myriad of factors was used, namely phylogeny, sequence comparisons, and presence and location of clustered cysteines in specific plastid transporters of 2-oxoglutarate, to examine their evolution away from more generalized transporters. This transition would be to adopt the capability of internalizing 2-oxoglutarate alone or with superior specificities at the expense of malate. In phylogeny, the specific 2-oxoglutarate transporters (Cluster 1) are clustered in a separate clade away from 2 clades of general transporters (Cluster 2 and 3). The exclusivity (Cluster 1) and promiscuity of transporters (Cluster 2 and 3) compared to Arabidopsis counterparts characterized prior to this study, were used as a benchmark for my study. Within this mother clade of exclusive transporters, C4 and C3 2-oxoglutarate transporters once again form separate clusters of monophyly. Furthermore, a pattern of Cys –X-X-Cys-X(19)-Cys is conserved within the 2-oxo-glutarate only transporters that is missing in general transporters. Cysteines which are functionally key residues are inferred to be mediating intra- or inter-reactive disulfide bond formation or using a thiol (sulfhydryl) group for transport or to be forming a metal binding site. When a disulfide bond prediction tool was employed, it showed with negligible doubt that the Cys-X-X Cys-X(19) -Cys region was a strong contender for 2 separate disulfide bonds, although the middle cysteine was predicted to be involved in both. In addition, Cluster 2 general Zea mays C4 transporters are shown to be more recalcitrant to mutations of cysteines, compared to Panicum and Oryza counterparts. The study of 2-oxoglutarate and its availability in the chloroplast could play a two-prong role in C4 plants: to be a candidate for synthesis of bundle sheath cell Rubisco enzyme, which makes up ~50% of plant proteins, via ammonia assimilation, and even playing a role in carbon-centered biochemical pathways. This study could greatly facilitate choices in the tinkering of the right transporters for a future C4 rice in a climate change impacted world.