Idiosyncratic evolution of conserved eukaryote proteins that are similar in sequence to archaeal or bacterial proteins

	Sequence comparisons have been made between the proteins of 571 prokaryote species including 46 archaea and 525 bacteria and the set of human proteins. Highly conserved eukaryotic proteins are often strikingly similar in sequence to archaeal and bacterial proteins. Yet in many cases similarity to archaeal proteins is not correlated to the similarity to bacterial proteins. In these comparisons there are hundreds of eukaryote proteins that match well archeal proteins, but do not match recognizably to bacterial proteins, while thousands of proteins match well to bacterial proteins but not recognizably to archeal proteins. Forty percent of the 21,440 human proteins that significantly match prokaryote proteins are in this extreme idiosyncratic category. These relationships have been preserved over billions of years since the last common ancestor or sharing of protein genes between prokaryotes and eukaryotes. For each of the 21,440 members of this set of human proteins (that make significant matches to any of the 1.8 million proteins in this set of prokaryote species protein libraries) it is certain that each protein has important functions both in prokaryotes and eukaryotes and the precursor proteins have been important in the precursor species of both. That is the only explanation for the preservation of amino acid sequence similarity for the billions of years since the last common ancestor or period of sharing of proteins. Comparisons were made between the proteins of Arabidopsis thaliana and Saccharomyces cerevisiae to the proteins of the 571 prokaryote species. The results agreed with the human comparisons indicating that the conclusions apply to eukaryotes generally