The mitotic stability of deletion derivatives of chromosome III in yeast

We have constructed a series of deletion derivatives of chromosome III in yeast. Two telocentric chromosomes, one with a deletion of about 100 kilobases (kb) from the left arm and another with a deletion of about 240 kb from the right arm, are mitotically stable, showing only a 2- to 3-fold decrease in stability compared to a normal chromosome III. Chromosomes as small as 100 kb with deletions on both the left and right arms show only slight decreases in mitotic stability. Slight decreases in size in chromosomes smaller than 100 kb produce dramatic decreases in mitotic stability. In general, deletion chromosomes of similar size but different structure display similar stabilities. We find no evidence for the existence of any new cis-acting elements [besides the centromere, autonomously replicating sequences (ARS elements) and telomeres] essential for the stabilization of chromosome III.

Resolution of dicentric chromosomes by Ty-mediated recombination in yeast

We have integrated a plasmid containing a yeast centromere, CEN5, into the HIS4 region of chromosome III by transformation. Of the three transformant colonies examined, none contained a dicentric chromosome, but all contained a rearranged chromosome III. In one transformant, rearrangement occurred by homologous recombination between two Ty elements; one on the left arm and the other on the right arm of chromosome III. This event produced a ring chromosome (ring chromosome III) of about 60 kb consisting of CEN3 and all other sequences between the two Ty elements. In addition, a linear chromosome (chromosome IIIA) consisting of sequences distal to the two Ty elements including CEN5, but lacking 60 kb of sequences from the centromeric region, was produced. Two other transformants also contain a similarly altered linear chromosome III as well as an apparently normal copy of chromosome III. These results suggest that dicentric chromosomes cannot be maintained in yeast and that dicentric structures must be resolved for the cell to survive.--The meiotic segregation properties of ring chromosome III and linear chromosome IIIA were examined in diploid cells which also contained a normal chromosome III. Chromosome IIIA and normal chromosome III disjoined normally, indicating that homology or parallel location of the centromeric regions of these chromosomes are not essential for proper meiotic segregation. In contrast, the 60-kb ring chromosome III, which is homologous to the centromeric region of the normal chromosome III, did not appear to pair with fidelity with chromosome III.

Construction of telocentric chromosomes in Saccharomyces cerevisiae

We describe a simple method for the construction of large chromosomal deletions in yeast. Diploid yeast cells were transformed with DNA fragments that replace large regions of the chromosomes by homologous recombination. Using this method, we have constructed a telocentric chromosome III in which approximately equal to 100 kilobases (kb) of DNA has been removed from the left arm of the chromosome, so that the centromere is 12 kb from the left telomere. This telocentric chromosome is mitotically stable. Its rate of loss in a diploid strain is 2.5-7.4 X 10(-4) per cell division compared to a rate of loss of 0.36-1.8 X 10(-4) per cell division for a normal chromosome III. It also segregates 2+:2- with fidelity during meiosis. The construction of systematic deletions in a chromosome should be useful in determining the essential features for proper chromosomal segregation and replication.

Unusual DNA sequences associated with the ends of yeast chromosomes

The genome of the yeast Saccharomyces cerevisiae, like those of other eukaryotes, contains multiple sequences that hybridize with a poly(GT) probe. We have shown previously that some of the sequences that hybridize with the poly(GT) probe are located near the tips of the yeast chromosomes. We report here that many of the remaining poly(GT)-hybridizing sequences are associated with a family of putative replication origins localized near the chromosome ends. These sequences have the general form poly(C1-3A), similar to sequences reported to occur at the tips of chromosomes in the accompanying paper. In addition to poly(C1-3A) tracts, yeast cells contain tracts of alternating C and A bases, similar to those seen in mammalian genomes. These results are used as the basis for a new model of telomere replication.

Mutants of S. cerevisiae defective in the maintenance of minichromosomes

We have isolated yeast mutants that are defective in the maintenance of circular minichromosomes. The minichromosomes are mitotically stable plasmids, each of which contains a different ARS (autonomously replicating sequence), a centrometeric sequence, CEN5, and two yeast genes, LEU2 and URA3. Forty minichromosome maintenance-defective (Mcm-) mutants were characterized. They constitute 16 complementation groups. These mutants can be divided into two classes, specific and nonspecific, by their differential ability to maintain minichromosomes with different ARSs. The specific class of mutants is defective only in the maintenance of minichromosomes that carry a particular group of ARSs irrespective of the centromeric sequence present. The nonspecific class of mutants is defective in the maintenance of all minichromosomes tested irrespective of the ARS or centromeric sequence present. The specific class may include mutants that do not initiate DNA replication effectively at specific ARSs present on the minichromosomes; the nonspecific class may include mutants that are affected in the segregation and/or replication of circular plasmids in general.

Isolation and characterization of the centromere from chromosome V (CEN5) of Saccharomyces cerevisiae

We have cloned a functional centromeric DNA sequence from Saccharomyces cerevisiae. Using the 2 mu chromosome-loss mapping technique and meiotic tetrad analysis, we have identified this DNA sequence as the centromere of chromosome V (CEN5). The CEN5 sequence has been localized on an 1,100-base-pair BamHI-BglII restriction fragment. Plasmids containing CEN5 and an autonomously replicating sequence are mitotically stable in S. cerevisiae and segregate in a Mendelian fashion during meiosis.

A family of Saccharomyces cerevisiae repetitive autonomously replicating sequences that have very similar genomic environments

We have characterized a family of moderately repetitive autonomously replicating sequences (ARSs) in Saccharomyces cerevisiae. Restriction mapping, deletion studies and hybridization studies suggest that these ARSs, which are probably less than 350 base-pairs in size, share one common feature: each is located close to, but not within, a repetitive sequence (131) of approximately 10(3) to approximately 1.5 X 10(3) base-pairs in length. These ARSs can be divided into two classes (X and Y) by their sequence homology and genomic environments. Each of the class X ARSs is embedded within a repetitive sequence (X) of variable length (approximately 0.3 X 10(3) to approximately 3.75 X 10(3) base-pairs); each of the class Y ARSs is embedded within a highly conserved repetitive sequence (Y) of approximately 5.2 X 10(3) base-pairs in length. Both of these sequences are located directly adjacent to the 131 sequence.

Organization of DNA sequences and replication origins at yeast telomeres

We have shown that the DNA sequences adjacent to the telomeres of Saccharomyces cerevisiae chromosomes are highly conserved and contain a high density of replication origins. The salient features of these telomeres can be summarized as follows. There are three moderately repetitive elements present at the telomeres: the 131 sequence (1 to 1.5 kb), the highly conserved Y sequence (5.2 kb), and the less conserved X sequence (0.3 to 3.75 kb). There is a high density of replication origins spaced about 6.7 kb apart at the telomeres. These replication origins are part of the X or the Y sequences. Some of the 131-Y repetitive units are tandemly arranged. The terminal sequence T (about 0.33 to 0.6 kb) is different from the 131, X, or Y sequences and is heterogeneous in length. The order of these sequences from the telomeric end towards the centromere is T-(Y-131)n-X-, where n ranges from 1 to no more than 4. Although these telomeric sequences are conserved among S. cerevisiae strains, they show striking divergence in certain closely related yeast species.

Autonomously replicating sequences in Saccharomyces cerevisiae

A method is presented for isolating DNA segments capable of autonomous replication from Saccharomyces cerevisiae chromosomal DNA based on the differential transforming ability of autonomously replicating plasmids and nonreplicating plasmids. DNA plasmids that are capable of self-replication in yeast transform yeast spheroplasts at about 1000-fold higher frequency than nonreplicating plasmids. We have cloned from total yeast DNA a number of DNA segments that permit the pBR322 plasmid carrying the yeast LEU2 gene to replicate autonomously. These plasmid clones are characterized by their ability to transform Leu- spheroplasts to Leu+ at a high frequency and their ability to replicate autonomously. Analysis of the insert DNAs carried in some of these self-replicating plasmids divides them into two categories: those that are unique in the yeast genome and those that are repetitive.

Uracil incorporation: a source of pulse-labeled DNA fragments in the replication of the Escherichia coli chromosome

Uracil is incorporated into newly synthesized DNA by mutants of Escherichia coli with reduced levels of dUTPase (dUTP nucleotidohydrolase; EC 3.6.1.23). Excision-repair of the incorporated uracil results in the generation of labeled DNA fragments that appear after brief pulses with [(3)H]thymidine [Tye, B-K., Nyman, P.-D., Lehman, I. R., Hochhauser, S. & Weiss, B. (1977) Proc. Natl. Acad. Sci. USA 74, 154-157]. Uracil is also incorporated into the newly synthesized DNA of strains of E. coli that contain normal levels of dUTPase. DNA fragments generated by the postreplication excision-repair of uracil may therefore contribute to the pool of nascent DNA (Okazaki) fragments that normally appear in wild-type strains. Discontinuous DNA replication has been examined in the absence of uracil excision by comparing Okazaki fragments in strains that are defective in DNA polymerase I (polA(-)) and polA(-) strains that are also defective in uracil N-glycosidase, an enzyme required for the excision-repair of uracil in DNA (polA(-)ung(-)). Little or no difference was detected in the level of Okazaki fragments in the polA(-) strain as compared with the polA(-)ung(-) strain. Thus, the uracil-induced cleavage of DNA cannot be the sole mechanism for the generation of Okazaki fragments. Mutants that are defective both in dUTPase and in uracil N-glycosidase incorporate uracil into their DNA with a high frequency (up to 1 per 100 nucleotides). These uracil residues, once incorporated, persist in the DNA without an adverse affect on the growth of the cells.

Transient accumulation of Okazaki fragments as a result of uracil incorporation into nascent DNA

Strains of Escherichia coli with a mutation in the sof (dnaS) locus show a higher than normal frequency of recombination (are hyper rec) and incorporate label into short (4-5S) DNA fragments following brief [3H]thymidine pulses [Konrad and Lehman, Proc. Natl. Acad. Sci. USA 72, 2150 (1975)]. These mutant strains have now been found to be defective in deoxyuridinetriphosphate diphosphohydrolase (dUTPase; deoxyuridinetriphosphatase, EC 3.6.1.23), the enzyme that catalyzes the hydrolysis of dUTP to dUMP and PPi. Reversion of one sof- mutation to sof+ restores dUTPase activity and abolishes the accumulation of labeled 4-5S DNA fragments. Mutants initially isolated as defective in dUTPase (dut-) are also hyper rec and show transient accumulation of short DNA fragments. Both the sof and dut mutations are located at 81 min on the E. coli map, closely linked to the pyrE locus. The sof and dut loci thus appear to be identical. A decrease in dUTPase as a consequence of a sof or dut mutation may result in the increased incorporation of uracil into DNA. Rapid removal of the uracil by an excision-repair process could then lead to the transient accumulation of short DNA fragments. It is possible that at least a portion of the Okazaki fragments seen in wild-type cells may originate in this way.