This paper reports the biochemical properties of two types of recombinant flap endonuclease-1 (FEN-1) proteins obtained from the thermophilic crenarchaeon, Sulfolobus tokodaii strain 7. One of the two FEN-1 proteins is a product of the gene with AUG as the translational start codon (StoS-FEN-1), which is originally assigned in the database. The other is a product of the gene with a new AUG start codon (StoL-FEN-1), which is inserted at 153 bases upstream of the original AUG codon. Although StoL-FEN-1 showed activity and thermostability, StoS-FEN-1 showed neither activity nor thermostability. The N-terminal region in StoL-FEN-1 was also conserved in all of the FEN-1 homologs deduced from genes from newly isolated Sulfolobus spp. These results strongly suggest that the actual start codon of the fen-1 gene from S. tokodaii is not the originally assigned AUG, but rather is located at about 100 bases upstream of this codon.
Vertebrate genomes are mosaics of isochores. On the assumption that marked differences exist in the isochore structure between warm-blooded and cold-blooded animals, variations among vertebrates were previously attributed to adaptation to homeothermy. However, based on the data of coding regions from representatives of extant vertebrates, including a turtle, a crocodile (Archosauromorpha) and a few kinds of snakes (Lepidosauromorpha), it was recently hypothesized that the common ancestors of mammals, birds and extant reptiles already had the "warm-blooded" isochore structure. To test this hypothesis, the nucleotide sequences of α-globin genes including non-coding regions (introns) from two snakes, N. kaouthia and E. climacophora, were determined (accession number: AB104824, AB104825). The correlation between the GC contents in the introns and exons of α-globin genes from snakes and those from other vertebrates supports the above hypothesis. Similar analysis using data for exons and introns of other genes obtained from the GenBank (Release 131) also support the above hypothesis.
In the previous report, we demonstrated the origin of eukaryotic cell nuclei as the symbiosis of Archaea in Bacteria by the newly developed "Homology-Hit Analysis". In that case, we counted yeast Open Reading Frames (ORFs) showing the highest similarity to a bacterial ORF as orthologous ORFs (Orthologous ORFs were produced by speciation from a common ancestor, and have the highest similarity to each other.) by comparing whole ORFs of yeast with those of individual bacteria. However, we could not count all yeast ORFs showing the highest similarity to a bacterial ORF in functional categories of yeast. Therefore, the origin of ORFs in the functional categories of yeast could not be inferred strictly. Here, we have improved the method for detecting orthologous ORFs. In this method, we count the numbers of ORF with the highest similarity between individual yeast functional categories and individual bacteria as orthologous ORFs. By this method, it was possible to detect the correct orthologous ORFs and to infer the origins of the functional categories in eukaryotic cells. As a result, two categories, assembly of protein complexes and DNA repair were newly judged to be of Archaeal origin, while five categories, lipid (fatty-acid and isoprenoid) metabolism, protein folding and stabilization, signal transduction, organization of the plasma membrane and organization of the cytoplasm, were newly judged to be of Bacterial origin. On the other hand, the origins of two categories (meiosis and cellular import, which were determined in the previous analysis) could not be judged. It is considered that functional categories related to the nucleus have origins common to Archaea, while those related to the cytoplasm have origins common to Bacteria. From these data including the origin of plasma membrane, it was further clarified that cell nucleus originated by the symbiosis of Archaea in Bacteria.
Codon usages are known to vary among vertebrates chiefly due to variations in isochore structure. Under the assumption that marked differences exist in isochore structure between warm-blooded and cold-blooded animals, the variations among vertebrates were previously attributed to an adaptation to homeothermy. However, based on data from a turtle species and a crocodile (Archosauromorpha), it was recently proposed that the common ancestors of mammals, birds and extent reptilies already had the "warm-blooded" isochore structure. We determined the nucleotide sequences of α-globin genes from two species of heterotherms, cuckoo (Cuculus canorus) and bat (Pipistrellus abramus), and three species of snakes (Lepidosauromorpha), Naja kaouthia from a tropical terrestrial habitat, Elaphe climacophora from a temperate terrestrial habitat, and Hydrophis melanocephalus from a tropical marine habitat. Our purposes were to assess the influence of differential body temperature patterns on codon usage and GC content at the third position of a codon (GC3), and to test the hypothesis concerning the phylogenetic position at which GC contents had increased in vertebrates. The results of principal component analysis (PCA) using the present data and data for other taxa from GenBank indicate that the primary difference in codon usage in globin genes among amniotes and other vertebrates lies in GC3. The codon usages (and GC3) in α-globin genes from two heterotherms and three snakes are similar to those in α-globin genes from warm-blooded vertebrates. These results refute the influence of body temperature pattern upon codon usages (and GC3) in α-globin genes, and support the hypothesis that the increase in GC content in the genome occurred in the common ancestor of amniotes.
There is currently no consensus on the evolutionary origin of eukaryotes. In the search of the ancestors of eukaryotes, we analyzed the phylogeny of 46 genomes, including those of 2 eukaryotes, 8 archaea, and 36 eubacteria. To avoid the effects of gene duplications, we used inparalog pairs of genes with orthologous relationships. First, we grouped these inparalogs into the functional categories of the nucleus, cytoplasm, and mitochondria. Next, we counted the sister groups of eukaryotes in prokaryotic phyla and plotted them on a standard phylogenetic tree. Finally, we used Pearson’s chi-square test to estimate the origin of the genomes from specific prokaryotic ancestors. The results suggest the eukaryotic nuclear genome descends from an archaea that was neither euryarchaeota nor crenarchaeota and that the mitochondrial genome descends from α-proteobacteria. In contrast, genes related to the cytoplasm do not appear to originate from a specific group of prokaryotes.
