Abstract
Background: Rhomboid serine proteases are present in many species with sequenced genomes, and are often encoded in each species by more than one predicted gene. Based on protein sequence comparisons, rhomboids can be differentiated into groups - secretases, presenilin-like associated rhomboid-like (PARL) proteases, iRhoms, and "inactive" rhomboid proteins. Although these rhomboid groups are distinct, the different types can operate simultaneously. Studies in Arabidopsis showed that the number of rhomboid proteins working simultaneously can be further diversified by alternative splicing. This phenomenon was confirmed for the Arabidopsis plastid rhomboid proteins At1g25290 and At1g74130. Although alternative splicing was determined to be a significant mechanism for diversifying these two Arabidopsis plastid rhomboids, there has yet to be an assessment as to whether this mechanism extends to other rhomboids and to other species. Methods: We thus conducted a multi-year analysis of databases to determine if the alternative splicing mechanism observed for the two Arabidopsis plastid rhomboids was utilized in other species to expand the repertoire of rhomboid proteins. To help verify the in silico findings, select splice variants from different groups were tested for activity using transgenic- and additive-based assays. These assays aimed to uncover evidence that the selected splice variants display capacities to influence processes like antimicrobial sensitivity. Results: The multi-year in silico assessment for six model experimental species (human, mouse, Arabidopsis, Drosophila, nematode, and yeast) revealed robust usage of alternative splicing to diversify rhomboid protein structure across the various motifs or regions, especially in human, mouse and Arabidopsis. Subsequent validation studies uncover evidence that the splice variants selected for testing displayed functionality in the different activity assays. Conclusions: The combined results support the hypothesis that alternative splicing is likely used to diversify and expand rhomboid protein functionality, and this potentially occurred across the various motifs or regions of the protein.
Highlights
Rhomboid proteins are found widely in all types of organisms
Using the findings reported for At1g25290 and At1g74130 as guidance, we carried out a periodic analysis of genetic databases of model experimental species to determine the possible extent of alternative splicing in rhomboid genes and, based on coding RNA sequence entries, how splice variants may be reflective of a way to diversify functionality
Rationale and justification for this database study We previously verified in separate studies a mechanism for diversifying rhomboid proteins and their functionality
Summary
Rhomboid proteins are found widely in all types of organisms. In higher-order organisms, rhomboid proteins are often encoded by a large group of genes[1], for example, upwards of twenty-two database entries for Arabidopsis and thirteen for humans (assessed as of May 2017). Based on protein sequence comparisons, rhomboids can be differentiated into groups - secretases, presenilin-like associated rhomboid-like (PARL) proteases, iRhoms, and “inactive” rhomboid proteins. These rhomboid groups are distinct, the different types can operate simultaneously. To help verify the in silico findings, select splice variants from different groups were tested for activity using transgenic- and additive-based assays. These assays aimed to uncover evidence that the selected splice variants display capacities to influence processes like antimicrobial sensitivity. Conclusions: The combined results support the hypothesis that alternative splicing is likely used to diversify and expand rhomboid protein functionality, and this potentially occurred across the various motifs or regions of the protein
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