Expanded genome/proteome databases and effective use of sequence alignment tools make it possible to trace the phylogeny of individual eukaryotic proteins and ultimately to identify the prokaryotes that contributed to the last eukaryotic common ancestor (LECA). I developed an application of reciprocal BLASTp that identifies (1) the prokaryotic lineages that have contributed to the nuclear genome and (2) the specific proteins acquired from prokaryotic ancestors. Eight complete eubacterial proteomes were analyzed: two free-living spirochetes, two clostridia, two actinobacteria, and two proteobacteria (one alpha and one gamma). The data reveal a spirochete genetic contribution to the eukaryotic genome including essential proteins involved in DNA binding and repair, cyclic nucleotide metabolism, acyltransferase, and signal transduction. My results, consistent with the sulfur syntrophy hypothesis that posits LECA evolved from a merger of spirochetes (eubacteria) with sulfidogenic eocytes (archaebacteria), confirm the contribution of mitochondrial genes from alpha-proteobacteria. A contribution from clostridia to eukaryote genomes was also detected whereas none was seen from either actinobacterium or Escherichia coli. The complete spirochete and clostridial genetic contributions to eukaryotes and those of other eu-and archaebacteria can be identified by this method.
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