The 2microm-plasmid-encoded Rep1 and Rep2 proteins interact with each other and colocalize to the Saccharomyces cerevisiae nucleus.

The efficient partitioning of the 2microm plasmid of Saccharomyces cerevisiae at cell division requires two plasmid-encoded proteins (Rep1p and Rep2p) and a cis-acting locus, REP3 (STB). By using protein hybrids containing fusions of the Rep proteins to green fluorescent protein (GFP), we show here that fluorescence from GFP-Rep1p or GFP-Rep2p is almost exclusively localized in the nucleus in a cir+ strain. Nuclear localization of GFP-Rep1p and GFP-Rep2p, though discernible, is less efficient in a cir(0) host. GFP-Rep2p or GFP-Rep1p is able to promote the stability of a 2microm circle-derived plasmid harboring REP1 or REP2, respectively, in a cir(0) background. Under these conditions, fluorescence from GFP-Rep2p or GFP-Rep1p is concentrated within the nucleus, as is the case in cir+ cells. This characteristic nuclear accumulation is not dependent on the expression of the FLP or RAF1 gene of the 2microm circle. Nuclear colocalization of Rep1p and Rep2p is consistent with the hypothesis that the two proteins directly or indirectly interact to form a functional bipartite or high-order protein complex. Immunoprecipitation experiments as well as baiting assays using GST-Rep hybrid proteins suggest a direct interaction between Rep1p and Rep2p which, in principle, may be modulated by other yeast proteins. Furthermore, these assays provide evidence for Rep1p-Rep1p and Rep2p-Rep2p associations as well. The sum of these interactions may be important in controlling the effective cellular concentration of the Rep1p-Rep2p complex.

The Saccharomyces SHP1 gene, which encodes a regulator of phosphoprotein phosphatase 1 with differential effects on glycogen metabolism, meiotic differentiation, and mitotic cell cycle progression.

The phosphoprotein phosphatase 1 (PP1) catalytic subunit encoded by the Saccharomyces GLC7 gene is involved in control of glycogen metabolism, meiosis, translation, chromosome segregation, cell polarity, and G2/M cell cycle progression. It is also lethal when overproduced. We have isolated strains which are resistant to Glc7p overproduction lethality as a result of mutations in the SHP1 (suppressor of high-copy PP1) gene, which was previously encountered in a genomic sequencing project as an open reading frame whose interruption totally blocked sporulation and slightly slowed cell proliferation. These phenotypes also characterized our shp1 mutations, as did deficient glycogen accumulation. Lysates from the shp1 mutants were deficient in PP1 catalytic activity but exhibited no obvious abnormalities in the steady-state level or subcellular localization pattern of a catalytically active Glc7p-hemagglutinin fusion polypeptide. The lower level of PP1 activity in shp1 cells permitted substitution of a galactose-induced GAL10-GLC7 fusion for GLC7; depletion of Glc7p from these cells by growth in glucose medium resulted in G2/M arrest as previously observed for a glc7cs allele but with depletion arrest occurring most frequently at a later stage of mitosis. The higher requirement of glycogen accumulation and sporulation for PP1 activity would permit their regulation via Glc7p activity, independent of its requirement for mitosis.

A genetic investigation of the mechanism of adenovirus marker rescue.

We have developed quantitative and segregational methods for investigating the mechanism of genetic exchange in adenovirus marker rescue. Estimates of "marker rescue frequency" (m.r.f.) were used to show that marker rescue increases linearly with increasing dose of fragment up to equimolarity with the full-length genome. The m.r.f. is also affected by the size of the rescuing fragment and the position of the wild-type allele within it, regardless of whether the fragment is terminal or internal. This is compatible with marker rescue being based on homologous exchange between the recombining partners. Examination of individually transfected cells showed that there is very wide variability in the values of the m.r.f.'s. This suggests that marker transfer can occur after replication of the full-length genome has begun, and can occur late into the infectious cycle. Unselected markers on the rescuing fragment were shown to be co-inherited frequently. This suggests that physical linkage is accompanied by genetic linkage. To examine this more closely, a multifactorial marker rescue was performed. The data show unequivocally that markers resident on the same fragment as the selected allele are inherited at high frequency, with a gradient of transfer in which markers closest to the selected marker are transferred most frequently. Markers up to 13 and perhaps as many as 17 kb apart can be inherited together. There are very few examples of the inheritance of distal markers in the absence of proximal ones. These data suggest that large pieces of DNA are transferred in a concerted reaction during marker rescue.

Autoregulation of 2 micron circle gene expression provides a model for maintenance of stable plasmid copy levels.

The yeast plasmid 2 micron circle actively maintains high but stable copy levels in the cell, even though the plasmid confers no selective advantage to its host. To address the mechanism by which stable copy control is achieved, we have examined the level of expression of the genes resident on the yeast plasmid 2 micron circle as a function of the presence of proteins encoded by the plasmid. We find that transcription of the site-specific recombinase gene, FLP, is repressed at least 100-fold by the concerted action of the products of two other plasmid genes, REP1 and REP2. In addition, these products repress transcription of the REP1 gene itself. These results can be formulated into a consistent model for plasmid copy control.

Site-specific recombination promotes plasmid amplification in yeast.

All stable, naturally occurring circular yeast DNA plasmids contain a pair of long, nontandem inverted repeats that undergo frequent reciprocal recombination. This yields two plasmid inversion isomers that exist in the cell in equal numbers. In the 2 mu circle plasmid of S. cerevisiae such inversion is catalyzed by a plasmid-encoded site-specific recombinase, FLP. We show that the site-specific recombination system of 2 mu circle enables the plasmid to increase its mean intracellular copy number in yeast cells growing under nonselective conditions. This apparently occurs by a FLP-induced transient shift in the mode of replication from theta to double rolling circle as initially proposed by Futcher. This capability may ensure stable maintenance of the plasmid by enabling it to correct downward deviations in copy number that result from imprecision of the plasmid-encoded partitioning system.

Survival strategies of the yeast plasmid two-micron circle.

The multicopy yeast plasmid 2-micron circle uses a number of strategies to insure its persistence in its host. The plasmid confers no selective phenotype to the cell in which it is resident. Nonetheless, the plasmid is lost at less than 1 per 10(5) cell divisions during continuous exponential growth. We have determined that the plasmid persists at least in part due to the ability of the plasmid to amplify its mean copy number when its cellular copy level is low and to distribute plasmid molecules equally between mother and daughter cells at mitosis. We have found that amplification of plasmid copy number occurs by a novel mechanism in which site-specific recombination induces a transient shift in the mode of replication from theta to rolling circle. Equitable partitioning of plasmid molecules requires plasmid-encoded proteins and a centromere-like segment on the plasmid. We have accumulated evidence consistent with a model of partitioning in which the partitioning proteins form a transnuclear structure that is responsible for distributing plasmid molecules throughout the nucleus prior to cell division. In this chapter we describe evidence supporting the existence and mode of action of these two plasmid strategies and discuss the extent to which these strategies may be a pervasive facet of the biology of eukaryotic extrachromosomal elements.

A thermolabile mutant of adenovirus 5 resulting from a substitution mutation in the protein VIII gene.

The mutant adenoviruses H5sub304 and H5RIr were isolated sequentially from adenovirus 5 wild type by selection for the loss of EcoRI restriction endonuclease sites by Jones and Shenk (Cell 13:181-188, 1978). sub304 lacks the site at 84.0 map units (m.u.), and RIr lacks both that and the site at 75.9 m.u. A set of derivatives of RIr that lack the site at 75.9 m.u. accumulated virus more slowly at 38.8 or 39.5 degrees C than those with the site present, as measured by low-multiplicity passage or single-step replication cycles, respectively. Since the EcoRI site at 75.9 m.u. is predicted to lie in the gene encoding the precursor to virion polypeptide VIII (pVIII), the failure to accumulate virus rapidly could lie either in some step in processing and assembly of virions or in an increased virion thermolability. The latter possibility was shown to be the case, as all strains mutated at the EcoRI 75.9 m.u. site were extremely thermolabile in vitro, even at 37 degrees C. CsCl equilibrium density centrifugation of heated crude stocks of RIr and sub304 demonstrated that loss of infectivity in RIr was accompanied by physical disruption of virions. Polyacrylamide gel electrophoresis of infected cell extracts or of purified virions showed that pVIII of RIr had an apparent molecular weight that was slightly greater than that of sub304, and mature RIr and sub304 virions displayed polypeptide VIIIs which appeared to be of identical molecular weights. Nucleotide sequence analysis of RIr demonstrated that it contained a 9-base-pair (bp) substitution for 6 bp found in sub304, leading to a loss of the EcoRI site and a predicted insertion of a single amino acid. Comparison of the sequence of sub304 with the published sequence of adenovirus 2 revealed two changes, a single transversion at bp 1,722 and a bp deletion at 1,749, leading to the loss of a TaqI site. The predicted reading frame change would lead to a stop codon at bp 1,885. This raises the question of whether adenovirus 2 and adenovirus 5 use the same reading fame for pVIII.

The genetic analysis of recombination using adenovirus overlapping terminal DNA fragments.

We have studied the consequences of genetic recombination between overlapping terminal fragments of adenovirus genomes with respect to markers in the overlapping sequence. The findings are consistent with general recombination occurring approximately isotonically within the interval. In particular, single markers within the overlap, scored nonselectively, showed frequencies of recovery dependent on the position of their locus in relation to the ends of the overlap. Pairs of ts markers recombined to form ts+ progeny in proportion to their distance apart, provided the markers were oriented so that a single crossover between them would produce a full-length genome bearing both ts+ alleles. In the opposite orientation, where such a single crossover would be expected to produce ts/ts recombinants, the ts+ frequency was much lower, indicating that multiple recombination events are rare in this system. These findings rule out site-specific recombination, recombination occurring exclusively at the cleaved ends of the overlap, and recombination by means of mismatch repair of a heteroduplex the length of the overlap. They also indicate either that any heteroduplex junction region formed in the course of this reaction is quite short or that it is not subject to heteroduplex repair. Finally, our results demonstrate the efficacy of overlap recombination as a genetic and physical mapping tool and as a method of strain construction, and they suggest other applications, such as using overlap recombination to demonstrate that closely spaced pairs of markers (e.g., putative second-site reversions and their accompanying ts lesions) can be segregated.