Examination of protein sequence homologies: III. Ribosomal protein YS25 from Saccharomyces cerevisiae and its counterparts from Schizosaccharomyces pombe, rat liver, and Escherichia coli

Yeast ribosomal proteins: XII. YS11 of Saccharomyces cerevisiae is a homologue to E. coli S4 according to the gene analysis

We isolated and sequenced a gene, YS11A, encoding ribosomal protein YS11 of Saccharomyces cerevisiae. YS11A is one of two functional copies of the YS11 gene, located on chromosome XVI and transcribed in a lower amount than the other copy which is located on chromosome II. The disruption of YS11A has no effect on the growth of yeast. The 5'-flanking region contains a similar sequence to consensus UASrpg and the T-rich region. The open reading frame is interrupted with an intron located near the 5'-end. The predicted amino acid sequence reveals that yeast YS11 is a homologue to E. coli S4, one of the ram proteins, three chloroplast S4s and others out of the ribosomal protein sequences currently available.

Yeast ribosomal proteins: XI. Molecular analysis of two genes encoding YL41, an extremely small and basic ribosomal protein, from Saccharomyces cerevisiae

Two genes encoding ribosomal protein YL41 were cloned from Saccharomyces cerevisiae chromosomal DNA. Both genes contain an uninterrupted region of only 75 nucleotides coding for a protein of 3.3 kD. Within the coding regions the nucleotide sequences are virtually identical, whereas in both the 5'- and 3'-flanking regions the two genes differ significantly from each other. The deduced protein shows an arginine and lysine content of 68 percent, i.e., 17 out of 25 residues, and the basic residues are evenly distributed over the molecule. When compared to the ribosomal protein sequences currently available no counterpart to YL41 could be found in prokaryotes and it seems likely that YL41 is a eukaryote-specific ribosomal protein.

Examination of protein sequence homologies: V. New perspectives on evolution between bacterial and chloroplast-type ferredoxins inferred from sequence evidence

Sequence homologies among 34 chloroplast-type ferredoxins were examined using a computer program that quantitatively evaluates the extent of sequence similarity as a correlation coefficient. The resultant alignment contains six gaps representing insertions or deletions of some residues, all of which are located such that they precisely preserve the domains of structural fragments as determined by crystallographic data on Spirulina platensis ferredoxin. In the search for any total correlation between the chloroplast-type and 27 bacterial ferredoxins, 1891 comparison matrices prepared for possible combinations indicated that the bacterial basal sequence of 55 residues has been conserved evolutionarily in the chloroplast-type sequences corresponding to residue positions 36-90 of Spirulina platensis ferredoxin. In addition, the bacterial "connector sequence" region was found to be conserved. These findings strongly suggest that the bacterial and chloroplast-type ferredoxins descended from a common ancestor, and branched off after the bacterial gene duplication, whereas the chloroplast-type ferredoxins originally were generated by duplicating the already duplicated bacterial gene, i.e., by "double-duplication."

Structural comparison of 26S rRNA-binding ribosomal protein L25 from two different yeast strains and the equivalent proteins from three eubacteria and two chloroplasts

The sequences of Saccharomyces carlsbergensis ribosomal protein (r-protein) SL25* and its equivalents from Candida utilis (CL25), Escherichia coli (EL23), Bacillus stearothermophilus (BL23), Mycoplasma capricolum (ML23), Marchantia polymorpha chloroplasts (McpL23), and Nicotiana tabacum chloroplasts (NcpL23) were examined using a computer program that evaluates the extent of sequence similarity by calculating correlation coefficients for each pair of residues in two proteins from a number of physical properties of individual amino acids. Comparison matrices demonstrate that the prokaryotic sequences (including McpL23 and NcpL23) can be aligned unambiguously by introducing small internal deletions/insertions at three specific positions. A similar comparison brought to light a clear evolutionary relationship between the prokaryotic and the yeast proteins despite the fact that visual inspection of these sequences revealed only limited similarity. The alignment deduced from this comparison shows the two yeast r-proteins to have acquired a long (50-60 amino acids) N-terminal extension as well as a 13-amino acid-long deletion near the C-terminus. The significance of these findings in terms of the evolution of r-proteins in general and the biological function of various parts of the SL25 protein in particular is discussed.

Examination of protein sequence homologies: IV. Twenty-seven bacterial ferredoxins

Sequence homologies of 27 bacterial ferredoxins were examined using a computer program that quantitatively evaluates extent of similarity as a correlation coefficient. The results of a similarity search among the sequences demonstrated that the basal sequence consists of a pair of extremely similar segments of 26 amino acids connected by a three-amino acid group. The segment pairs, which would have arisen from gene duplication, are termed the first and second units. Because of the gene duplication, the connector sequence appears to have been introduced as a structurally important chain reversal. Each of the two units contains four cysteine residues, which are inserted one by one among seven, two, two, three, and eight amino acid alignments, respectively. The bacterial ferredoxins were categorized with regard to basal constitution as follows: group 1, in which both units closely conform to the basal structure; group 2, in which the second unit is modified in a characteristic manner among members; group 3, in which the first unit is modified in a characteristic manner, while the conforming second unit is accompanied by a long accessory sequence; group 4, in which there are modifications before and/or after the units, of which the respective central domains remain nearly intact; and group 5, where only the former of two Fe:S cluster ligation sets of four cysteines is estimated to remain intact, whereas the latter set is extremely modified. It is noteworthy that throughout all bacterial ferredoxins, one of two cysteine sets never fails to be completely intact and, moreover, the connector of three amino acids also exists intact. Based on this grouping and on the correspondences among the groups, average correlation coefficients among all members were computed, and the respective evolutionary relationships were examined. The results supported the proposition that transposition had occurred in the Azotobacter-type ferredoxins of group 3.