S. cerevisiae STO1 (YMR125W) and its A. gossypii syntenic homolog show two possible amino termini. The STO1 mRNA was proposed to be spliced in S. cerevisiae. However, both the spliced and non-spliced versions show homology to the A. gossypii genome, suggesting two alternative variants.

Classes of overlapping annotated ORFs in S. cerevisiae derived from comparison with the A. gossypii genome. Class A, homologs for both overlapping S. cerevisiae ORFs are found at syntenic positions in A. gossypii and also overlap. Class B, homologs for both overlapping S. cerevisiae ORFs are found in A. gossypii but do not overlap (see comments at end of legend). Class C, gene X but not gene Y has a syntenic homolog in A. gossypii. Class D, both overlapping S. cerevisiae ORFs lack a homolog in A. gossypii. Numbers refer to the frequency of the four types of overlapping pairs. Although all three possible directions of overlaps were observed, for convenience only 3'/3'-end overlaps are depicted here. YPL166W/YPL165C and YLR360W/YLR361C are the only two cases for which overlap was observed both in S. cerevisiae and A. gossypii (class A). The two overlaps are short (24 and 35 nucleotides, respectively, in S. cerevisiae and 24 and 14 nucleotides in A. gossypii, and involve only terminator-ORF sequence overlap. Class B overlaps comprise three syntenic ORF pairs (YJR012C/YJR013W, YML095C/YML096W, and YGR074W/YGR075C) and two non-syntenic (YPL018W/YPL017C and YBR262C/YBR263W). The lack of synteny reflects chromosomal rearrangements in one or the other species which resulted in either the separation of the two ORFs in A. gossypii or in their joining in S. cerevisiae. Two of the five class B ORF pairs refer to YML096W/YML095C and YGR074W/YGR075C, both with 6-nucleotide 3-end overlaps. The syntenic A. gossypii homologs are separated at their 3' ends by 2 and 51 nucleotides respectively, implying some overlap of terminator and ORF sequences very similar to their syntenic S. cerevisiae homologs. For two pairs of ORFs overlapping at their 5' ends in S. cerevisiae (YBR262C/YBR263W and YJR012C/YJR013W) both ORFs have a homolog in A. gossypii. The alignments of YBR263W and YJR012C with their respective A. gossypii homologs strongly suggest an error in selection of their start codons. Both S. cerevisiae ORFs are very likely to be 75 codons shorter, thus eliminating the presumptive promoter-ORF overlaps. Directions are provided for classes C and D in the additional data files.

Genome reinvestigation using comparative genomics. Translated DNA comparison allows the detection of homology outside annotated features of a query genome. This can lead to the detection of (a) novel ORFs, (b) novel introns/exons, (c) ORF extensions, and (d) ORF fusions (fusion of adjacent ORFs or merging of overlapping ORFs with same transcription direction). Gray areas illustrate regions of homology at the protein level and dashed lines depict suggested modifications in the query genome. Cases of changed splice sites may also be detected but are not drawn here.

Proposed changes in the hypothetical protein YMR269W. (a) Multiple alignment of the translated +2 and +3 frames of the S. cerevisiae YMR269W region and the syntenic A. gossypii protein. The boxed sequence indicates the region of the potential shift from frame +3 to +2 as suggested by the multiple alignment. (b) S. cerevisiae YMR269W region. Light gray depicts the current annotation as available at SGD. Dark gray shows the proposed elongation of the frame +2 translation on the 5' end of the yeast YMR269W gene. (c) Domain organization of YMR269W proteins in S. cerevisiae and A. gossypii. While the current YMR269W protein sequence of S. cerevisiae carries only a nuclear localization signal, both the A. gossypii homolog and the proposed extended YMR269W protein have an additional G-patch domain, which has been described as a putative RNA-binding domain.