Abstract
Iron–sulfur (Fe–S) clusters play important roles in electron transfer, metabolic and biosynthetic reactions, and the regulation of gene expression. Understanding the biogenesis of Fe–S clusters is therefore relevant to many fields. In the complex process of Fe–S protein formation, the A-type assembly protein (ATAP) family, which consists of several subfamilies, plays an essential role in Fe–S cluster formation and transfer and is highly conserved across the tree of life. However, the taxonomic distribution, motif compositions, and the evolutionary history of the ATAP subfamilies are not well understood. To address these problems, our study investigated the taxonomic distribution of 321 species from a broad cross-section of taxa. Then, we identified common and specific motifs in multiple ATAP subfamilies to explain the functional conservation and nonredundancy of the ATAPs, and a novel, essential motif was found in Eumetazoa IscA1, which has a newly found magnetic function. Finally, we used phylogenetic analytical methods to reconstruct the evolution history of this family. Our results show that two types of ErpA proteins (nonproteobacteria-type ErpA1 and proteobacteria-type ErpA2) exist in bacteria. The ATAP family, consisting of seven subfamilies, can be further classified into two types of ATAPs. Type-I ATAPs include IscA, SufA, HesB, ErpA1, and IscA1, with an ErpA1-like gene as their last common ancestor, whereas type-II ATAPs consist of ErpA2 and IscA2, duplicated from an ErpA2-like gene. During the mitochondrial endosymbiosis, IscA became IscA1 in eukaryotes and ErpA2 became IscA2 in eukaryotes, respectively.
Highlights
Iron–sulfur (Fe–S) clusters are ancient and versatile cofactors composed of iron and inorganic sulfur; they play important roles in electron transfer, metabolic and biosynthetic reactions, and the regulation of gene expression (Beinert 2000; Pain and Dancis 2016; Vernis et al 2017)
We classified two families of A-type assembly protein (ATAP), the type-I ATAP family consisting of IscA, IscA1, HesB, SufA, cpIsca, and ErpA1, which are connected with Fe–S cluster assembly scaffolds, and the type-II ATAP family consisting of ErpA2 and IscA2, which interact with apoprotein targets, and we suggested that the archaea-type ErpA3 did not belong to these two ATAP families
We used HMMER software to detect the distribution of ATAP family members among all 9,608 UniProt reference species, and we chose 321 representative species/genera to better present our results
Summary
Iron–sulfur (Fe–S) clusters are ancient and versatile cofactors composed of iron and inorganic sulfur; they play important roles in electron transfer, metabolic and biosynthetic reactions, and the regulation of gene expression (Beinert 2000; Pain and Dancis 2016; Vernis et al 2017). Three types of FeS assembly machinery, ISC, SUF, and NIF, have been identified in bacteria (Zheng and Santos 2018). Previous studies in bacteria have shown that NIF is involved in the maturation of nitrogenase in Azotobacter vinelandii (Kennedy and Dean 1992; Zheng and Dean 1994), ISC plays a housekeeping function in Fe–S cluster assembly, and SUF plays an important role under oxidative stress and iron starvation (Johnson et al 2005; Ayala-Castro et al 2008; Bandyopadhyay et al 2008; Fontecave and Ollagnier-deChoudens 2008).
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