Roles for ORC in M phase and S phase.

The origin recognition complex (ORC), a six-subunit protein, functions as the replication initiator in the yeast Saccharomyces cerevisiae. Initiation depends on the assembly of the prereplication complex in late M phase and activation in S phase. One subunit of ORC, Orc5p, was required at G1/S and in early M phase. Asynchronous cells with a temperature-sensitive orc5-1 allele arrested in early M phase. In contrast, cells that were first synchronized in M phase, shifted to the restrictive temperature, and then released from the block arrested at the G1/S boundary. The G1/S arrest phenotype could not be suppressed by introducing wild-type Orc5p during G1. Although all orc2 and orc5 mutations were recessive in the conventional sense, this dominant phenotype was shared with other orc5 alleles and an orc2 allele. The dominant inhibition to cell-cycle progression exhibited by the orc mutants was restricted to the nucleus, suggesting that chromosomes with mutant ORC complexes were capable of sending a signal that blocked initiation on chromosomes containing functional origins.

Separable functions of ORC5 in replication initiation and silencing in Saccharomyces cerevisiae.

Origin recognition complex (ORC) is a six subunit complex that functions as the replication initiator and is required for silencing the HML and HMR loci in the yeast Saccharomyces cerevisiae. The roles of ORC5 in replication initiation and silencing were investigated to determine whether the two roles were mechanistically coincident or separable. Some spontaneous revertants of orc5-1 were functional for replication initiation, but not silencing. Other alleles of ORC5 were obtained that were nonfunctional for replication initiation, but fully competent for silencing. The two types of alleles, when put in the same cell, complemented, establishing two separable functions for ORC5. These data implied that replication initiation at HMR-E was not required for silencing. The data were consistent with a model in which different ORC species functioned at different origins within the genome and that only one Orc5p subunit functioned at any given origin.

Yeast mutants deficient in ER-associated degradation of the Z variant of alpha-1-protease inhibitor.

Saccharomyces cerevisiae mutants deficient in degradation of alpha-1-proteinase inhibitor Z (A1PiZ) have been isolated and genetically characterized. Wild-type yeast expressing A1PiZ synthesize an ER form of this protein that is rapidly degraded by an intracellular proteolytic process known as ER-associated protein degradation (ERAD). The mutant strains were identified after treatment with EMS using a colony blot immunoassay to detect colonies that accumulated high levels of A1PiZ. A total of 120,000 colonies were screened and 30 putative mutants were identified. The level of A1PiZ accumulation in these mutants, measured by ELISA, ranged from two to 11 times that of A1PiZ in the parent strain. Further studies demonstrated that the increased levels of A1PiZ in most of the mutant strains was not the result of defective secretion or elevated A1PiZ mRNA. Pulse chase experiments indicated that A1PiZ was stabilized in several strains, evidence that these mutants are defective in ER-associated protein degradation. Genetic analyses revealed that most of the mutations were recessive, approximately 30% of the mutants characterized conformed to simple Mendelian inheritance, and at least seven complementation groups were identified.

Roles of ABF1, NPL3, and YCL54 in silencing in Saccharomyces cerevisiae.

A sensitized genetic screen was carried out to identify essential genes involved in silencing in Saccharomyces cerevisiae. This screen identified temperature-sensitive alleles of ORC2 and ORC5, as described elsewhere, and ABF1, NPL3, and YCL54, as described here. Alleles of ABF1 that caused silencing defects provided the genetic proof of Abflp's role in silencing. The roles of Npl3p and Ycl54p are less clear. These proteins did not act exclusively through any one of the three protein binding sites of the HMR-E silencer. Unlike the orc2, orc5, and abf1 mutations that were isolated in the same (or a similar) screen for silencing mutants, neither temperature-sensitive mutation in NPL3 or YCL54 caused overt replication defects.

On the origin of a silencer.

Although there are several compelling pieces of evidence suggesting that transcription can promote DNA replication, there are few studies that indicate a role for DNA replication in controlling transcription. Here, we discuss the role of the HMR-E silencer, an origin of replication that plays a crucial role in the regulation of expression of mating-type genes in the yeast Saccharomyces cerevisiae.

The origin recognition complex has essential functions in transcriptional silencing and chromosomal replication.

The role of the origin recognition complex (ORC) was investigated in replication initiation and in silencing. Temperature-sensitive mutations in ORC genes caused defects in replication initiation at chromosomal origins of replication, as measured by two-dimensional (2-D) origin-mapping gels, fork migration analysis, and plasmid replication studies. These data were consistent with ORC functioning as a eukaryotic replication initiator. Some origins displayed greater replication initiation deficiencies in orc mutants than did others, revealing functional differences between origins. Alleles of ORC5 were isolated that were defective for silencing but not replication, indicating that ORC's role in silencing could be separated from its role in replication. In temperature-sensitive orc mutants arrested in mitosis, temperature-shift experiments caused a loss of silencing, indicating both that ORC had functions outside of the S phase of the cell cycle and that ORC was required for the maintenance of the silenced state.