In the yeast Saccharomyces cerevisiae there are three copies of the F1F0‐ATPase α‐subunit gene ATP1 on chromosome II (Takeda et al., 1995). However, after genome analysis using S. cerevisiae strain S288C, only one ATP1 gene sequence was observed (Feldman et al., 1994; Obermaier et al., 1995). To check whether the number of copies of ATP1 is strain‐dependent or not, we carried out three different experiments: (a) long‐PCR analyses of total DNAs isolated from several reference strains, carried out by preparing 29‐mer oligonucleotides based on the 5′‐ and 3′‐ up‐ and downstream regions of the ATP1 nucleotide sequence using the data from the genome project to synthesize primers; (b) restriction analyses of chromosome II from the reference strains with SplI; and (c) long‐PCR analyses of prime clones 70113 and 70804, both of which contained two ATP1 gene copies, ATP1a and ATP1b, and ATP1b and ATP1c, respectively, using 30 nucleotides just inside the 3′‐end (sense) and 5′‐end (antisense) of the ATP1‐coding region as primers. In the case of the long‐PCR experiments, the reference strains DC5, SEY2102, W303‐1A, W303‐1B, LL20 and DBY746, as well as strain S288C, generated a DNA fragment of approximately 32 kb, which hybridized with ATP1. During SplI digestion, a DNA fragment of more than 50 kb which hybridized with ATP1, was obtained from all reference strains. In the case of prime clone analyses using the long‐PCR experiments, the distance between ATP1a and ATP1b or ATP1b and ATP1c was approximately 10 kb or 7 kb, respepectively. The S288C strain generated these two DNA fragments, as do the other strains. These results showed that all these strains contained three copies of ATP1 on chromosome II. Copyright © 1999 John Wiley & Sons, Ltd.
In this paper, we present evidence that there are two closely linked copies of the ATP3 gene coding for the γ subunit of the F 1 F 0 -ATPase complex (EC3.6.1.34) in four laboratory strains of Saccharomyces cerevisiae, even though the yeast genome project has reported that ATP3 is a single-copy gene on chromosome II. We previously reported that the gene dosage (three copies) of ATP1 and ATP2 is coincident with the subunit number of F 1 -α and F 1 -β, but that the gene dosage of ATP3 was not consistent with the subunit stoichiometry of F 1 F 0 -ATPase. By applying long PCR and gene walking analyses, we estimated that the two copies of ATP3 were approximately 20 kb apart, and we designated that which is proximal to the centromere ATP3a, while we named that which is distal ATP3b. The nucleotide sequences of the two copies of ATP3 were identical to the reported sequence in the W303-1A, W303-1B and LL20 strains, while only the DC5 strain had a single base substitution in its ATP3a. With the exception of this substitution, the other nucleotide sequences were identical to the upstream 860 bp and the downstream 150 bp. The differences between ATP3 with the single base substitution (Ser 308 to Phe) and ATP3 without the substitution on the complementation of the ATP3 disruptant and on the maintenance of the mitochondrial DNA were observed, suggesting that Atp3ap and Atp3bp in the DC5 strain might have different functions. However, it should not always be necessary for yeast cells to carry different types of ATP3 because the other three strains carry the same type of ATP3. It was also demonstrated that the disruption of the ATP3 genes basically leads to a loss of wild-type mtDNA, but the stability of the mtDNA is not dependent on the ATP3 alone.
We previously reported that there were three copies of ATP1 coding for F1-alpha and two copies of ATP3 coding for F1-gamma on the left and right arm of chromosome II, respectively. In this study, we present evidence that there are three closely linked copies of ATP2 encoding the beta subunit of the F1F0-ATPase complex on the right arm of chromosome X in several laboratory strains, including Saccharomyces cerevisiae strain S288C, although it was reported by the yeast genome project that ATP2 is a single-copy gene. Chromosome X fragmentation, long-PCR, chromosome-walking and ATP2-disruption analysis using haploid wild-type strains and prime clone 70645 showed that the three copies of ATP2 are present on the right arm of chromosome X, like those of ATP1 on chromosome II. Each was estimated to be approximately 4 kb apart. We designated the ATP2 proximal to the centromere as ATP2a, the middle one as ATP2b and the distal one as ATP2c. The region containing the three ATP2s is composed of two repeated units of approximately 7 kb; that is, both ends (ATP2a, ATP2c) accompanying the ATP2-neighboring ORFs are the same. A part of YJR119c, YJR120w, YJR122w (CAF17) and YJR123w (RP55), which were reported by the yeast genome project, are contained in the ATP2 repeated units; and the middle ATP2 of the three ATP2s, ATP2b, is located between the two repeated units. Expression of all three copies of ATP2 (ATP2a, ATP2b, ATP2c) was confirmed because a single or double ATP2-disruptant could grow on glycerol, but a triple ATP2-disruptant could not. In addition, of the three copies of ATP1 and ATP2, even if only one copy of the ATP1 and ATP2 genes remained, the cells grew on glycerol.
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