The two forms of karyogamy transcription factor Kar4p are regulated by differential initiation of transcription, translation, and protein turnover.

Kar4p is a transcription factor in Saccharomyces cerevisiae that is required for the expression of karyogamy-specific genes during mating, for the efficient transit from G1 during mitosis, and for essential functions during meiosis. Kar4p exists in two forms: a constitutive slower-migrating form, which predominates during vegetative growth, and a faster-migrating form, which is highly induced by mating pheromone. Transcript mapping of KAR4 revealed that the constitutive mRNA was initiated upstream of two in-frame ATG initiation codons, while the major inducible mRNA originated between them. Thus, the two forms of Kar4p are derived from the translation of alternative transcripts, which possess different AUG initiation codons. Site-directed mutations were constructed to inactivate one or the other of the initiation codons, allowing the expression of the two Kar4p forms separately. At normal levels of expression, the constitutive form of Kar4p did not support wild-type levels of mating. However, the two forms of Kar4p could also be expressed separately from the regulatable GAL1 promoter, and no functional difference was detected when they were expressed at equivalent levels. Pulse-chase experiments showed that the induced form of Kar4p was highly expressed and stable during mating but rapidly turned over in vegetative cells. In contrast, the constitutively expressed longer form showed the same rate of turnover regardless of the growth condition. Furthermore, overexpression of either form of Kar4p in vegetative cells was toxic. Thus, the elaborate regulation of the two forms of Kar4p at the levels of transcription, translation, and protein turnover reflects the requirement for high levels of the protein during mating and for low levels during the subsequent phases of the cell cycle.

The kinesin-related proteins, Kip2p and Kip3p, function differently in nuclear migration in yeast.

The roles of two kinesin-related proteins, Kip2p and Kip3p, in microtubule function and nuclear migration were investigated. Deletion of either gene resulted in nuclear migration defects similar to those described for dynein and kar9 mutants. By indirect immunofluorescence, the cytoplasmic microtubules in kip2Delta were consistently short or absent throughout the cell cycle. In contrast, in kip3Delta strains, the cytoplasmic microtubules were significantly longer than wild type at telophase. Furthermore, in the kip3Delta cells with nuclear positioning defects, the cytoplasmic microtubules were misoriented and failed to extend into the bud. Localization studies found Kip2p exclusively on cytoplasmic microtubules throughout the cell cycle, whereas GFP-Kip3p localized to both spindle and cytoplasmic microtubules. Genetic analysis demonstrated that the kip2Delta kar9Delta double mutants were synthetically lethal, whereas kip3Delta kar9Delta double mutants were viable. Conversely, kip3Delta dhc1Delta double mutants were synthetically lethal, whereas kip2Delta dhc1Delta double mutants were viable. We suggest that the kinesin-related proteins, Kip2p and Kip3p, function in nuclear migration and that they do so by different mechanisms. We propose that Kip2p stabilizes microtubules and is required as part of the dynein-mediated pathway in nuclear migration. Furthermore, we propose that Kip3p functions, in part, by depolymerizing microtubules and is required for the Kar9p-dependent orientation of the cytoplasmic microtubules.

Distinct morphological phenotypes of cell fusion mutants.

Cell fusion in yeast is the process by which two haploid cells fuse to form a diploid zygote. To dissect the pathway of cell fusion, we phenotypically and genetically characterized four cell fusion mutants, fus6/spa2, fus7/rvs161, fus1, and fus2. First, we examined the complete array of single and double mutants. In all cases but one, double mutants exhibited stronger cell fusion defects than single mutants. The exception was rvs161Delta fus2Delta, suggesting that Rvs161p and Fus2p act in concert. Dosage suppression analysis showed that Fus1p and Fus2p act downstream or parallel to Rvs161p and Spa2p. Second, electron microscopic analysis was used to define the mutant defects in cell fusion. In wild-type prezygotes vesicles were aligned and clustered across the cell fusion zone. The vesicles were associated with regions of cell wall thinning. Analysis of Fus- zygotes indicated that Fus1p was required for the normal localization of the vesicles to the zone of cell fusion, and Spa2p facilitated their clustering. In contrast, Fus2p and Rvs161p appeared to act after vesicle positioning. These findings lead us to propose that cell fusion is mediated in part by the localized release of vesicles containing components essential for cell fusion.

Rvs161p interacts with Fus2p to promote cell fusion in Saccharomyces cerevisiae.

FUS7 was previously identified by a mutation that causes a defect in cell fusion in a screen for bilateral mating defects. Here we show that FUS7 is allelic to RVS161/END6, a gene implicated in a variety of processes including viability after starvation, endocytosis, and actin cytoskeletal organization. Two lines of evidence indicate that RVS161/END6's endocytic function is not required for cell fusion. First, several other endocytic mutants showed no cell fusion defects. Second, we isolated five function-specific alleles of RVS161/FUS7 that were defective for endocytosis, but not mating, and three alleles that were defective for cell fusion but not endocytosis. The organization of the actin cytoskeleton was normal in the cell fusion mutants, indicating that Rvs161p's function in cell fusion is independent of actin organization. The three to fourfold induction of RVS161 by mating pheromone and the localization of Rvs161p-GFP to the cell fusion zone suggested that Rvs161p plays a direct role in cell fusion. The phenotypes of double mutants, the coprecipitation of Rvs161p and Fus2p, and the fact that the stability of Fus2p was strongly dependent on Rvs161p's mating function lead to the conclusion that Rvs161p is required to interact with Fus2p for efficient cell fusion.

Cell fusion during yeast mating requires high levels of a-factor mating pheromone.

During conjugation, two yeast cells fuse to form a single zygote. Cell fusion requires extensive remodeling of the cell wall, both to form a seal between the two cells and to remove the intervening material. The two plasma membranes then fuse to produce a continuous cytoplasm. We report the characterization of two cell fusion defective (Fus-) mutants, fus5 and fus8, isolated previously in our laboratory. Fluorescence and electron microscopy demonstrated that the fus5 and fus8 mutant zygotes were defective for cell wall remodeling/removal but not plasma membrane fusion. Strikingly, fus5 and fus8 were a specific; both mutations caused the mutant phenotype when present in the MATa parent but not in the MAT alpha parent. Consistent with an a-specific defect, the fus5 and fus8 mutants produced less a-factor than the isogenic wild-type strain. FUS5 and FUS8 were determined to be allelic to AXL1 and RAM1, respectively, two genes known to be required for biogenesis of a-factor. Several experiments demonstrated that the partial defect in a-factor production resulted in the Fus- phenotype. First, overexpression of a-factor in the fus mutants suppressed the Fus- defect. Second, matings to an MAT alpha partner supersensitive to mating pheromone (sst2 delta) suppressed the Fus- defect in trans. Finally, the gene encoding a-factor, MFA1, was placed under the control of a repressible promoter; reduced levels of wild-type a-factor caused an identical cell fusion defect during mating. We conclude that high levels of pheromone are required as one component of the signal for prezygotes to initiate cell fusion.

Kar4p, a karyogamy-specific component of the yeast pheromone response pathway.

Karyogamy is the process whereby two haploid nuclei fuse to form a diploid nucleus during mating in Saccharomyces cerevisiae. Here, we describe the characterization of the KAR4 gene, previously identified in a screen for new nuclear fusion-defective mutants. During mating, kar4 mutants were defective for the microtubule-dependent movement of nuclei, a phenotype identical to that of mutations in KAR3 and CIK1. Consistent with its mutant phenotype, we found that the kar4 mutation resulted in failure to induce KAR3 and CIK1 mRNA during mating. Expression of KAR3 and CIK1 under independent regulatory control suppressed the kar4 defect, indicating that KAR4 is required primarily for the induction of KAR3 and CIK1. KAR4 was also required for meiosis, during which it may regulate KAR3; however, mitotic expression of KAR3 and CIK1 during S/G2 phase was independent of KAR4. A 30-bp region upstream of KAR3 conferred both KAR4- and STE12-dependent induction by mating pheromone. This region contained one moderate and two weak matches to the consensus pheromone response element to which the Ste12p transcriptional activator binds and five repeats of the sequence CAAA(A). Overproduction of Ste12p suppressed the kar4 defect in KAR3 induction and nuclear fusion. In contrast, Ste12p-independent expression of Kar4p did not alleviate the requirement for Ste12p during KAR3 induction. We propose that Kar4p assists Ste12p in the pheromone-dependent expression of KAR3 and CIK1. KAR4 defines a novel level of regulation for the pheromone response pathway, acting at a subset of Stel2p-inducible genes required for karyogamy.

Identification and characterization of CEN12 in the budding yeast Saccharomyces cerevisiae.

In this paper we report the cloning, sequencing and functional characterization of CEN12 and an associated autonomously replicating sequence (ARS) from the budding yeast Saccharomyces cerevisiae. In the course of studying a dynamin-related gene, DNM1, we previously physically mapped the gene to chromosome 12. Genetic mapping showed that the gene was tightly linked (0.35 cM) to the centromere. Subcloning experiments revealed that a centromere-like activity was included in a small segment of DNA immediately downstream from the DNM1 gene. Mitotic centromere activity was discerned by the ability of the region to de-stabilize a centromere-containing plasmid, and to stabilize an ARS-containing plasmid. Meiotic centromere activity was determined by the first-division segregation in crosses of ARS plasmids containing this region. The DNA sequence of this region revealed a sequence with strong homology to the consensus for yeast centromeres.

DNM1, a dynamin-related gene, participates in endosomal trafficking in yeast.

We identified DNM1, a novel dynamin-related gene in Saccharomyces cerevisiae. Molecular and genetic mapping showed that DNM1 is the most proximal gene to the right of centromere 12, and is predicted to encode a protein of 85 kD, designated Dnm1p. The protein exhibits 41% overall identity with full-length dynamin I and 55% identity with the most highly conserved 400-amino acid GTPase region. Our findings show that like mammalian dynamin, Dnm1p participates in endocytosis; however, it is unlikely to be a cognate homologue. Cells with a disruption in the DNM1 gene showed mating response defects consistent with a delay in receptor-mediated endocytosis. The half-life of the Ste3p pheromone receptor was increased two- to threefold in the dnm1 mutant, demonstrating that Dnm1p participates in the constitutive turnover of the receptor. To define the step in the endocytic pathway at which Dnm1p acts, we analyzed mutant strains at both early and late steps of the process. Initial internalization of epitope-tagged pheromone receptor or of labeled pheromone proceeded with wild-type kinetics. However, delivery of the internalized receptor to the vacuole was greatly impeded during ligand-induced endocytosis. These data suggest that during receptor-mediated endocytosis, Dnm1p acts after internalization, but before fusion with the vacuole. The dnm1 mutant was not defective for sorting of vacuolar proteins, indicating that Dnm1p is not required for transport from the late endosome to the vacuole. Therefore, we suggest that Dnm1p participates at a novel step before fusion with the late endosome.

Functional characterization of a replication initiator protein.

Functional domains in the RepI replication initiator protein have been identified by classical and site-directed mutagenesis techniques. Mutations conferring an increase in plasmid copy number contained alterations in a key position of a putative helix-turn-helix DNA binding motif. The mutations did not appear to affect autorepressing functions. Regions of RepI important for autorepression were localized as well. Two classes of mutations resulting in diminished autorepression functions were identified. One class was distinguished by an elevated copy number, while the other class remained at the wild-type copy number level. Analysis of the various mutations leading to changes in copy number or autorepressing functions suggest that in some cases the autorepression and initiating functions of the RepI protein are separable. Finally, analysis with deletion clones suggests that the trans-acting autorepressing functions of RepI might depend on intermolecular coupling control.

Characterization of the recA gene of Vibrio anguillarum.

We have cloned and sequenced the recA gene from two strains, 775 and 531A, of the fish pathogen, Vibrio anguillarum. Although both strains showed different sensitivities to methyl methanesulfonate (MMS), the recA genes were identical. In vitro expression of the V. anguillarum recA gene produced a polypeptide of about 40 kDa, in agreement with the value obtained from the nucleotide sequence. We identified the transcription start point by primer extension. The promoter for the recA gene mapped to an SOS regulatory element. The presence of an SOS box suggests that a LexA-like mediated response system may exist in V. anguillarum. The deduced RecA amino acid sequence is highly homologous with Escherichia coli RecA and other RecA proteins. Domains important in RecA function are conserved. We provide a comparative analysis of the activities and features of RecA analogs from a variety of species. We observed that certain residues that could be important in protein conformation are conserved in RecA proteins across a diverse range of bacterial species.

Co-operative autoregulation of a replication protein gene.

In this work we present the localization and characterization of the repl promoter (Prepl) and show aspects of the regulation. Comparison of Prepl with other autoregulated replication protein gene promoters revealed similarities, but Prepl differs from some of these characterized promoters in not being regulated by the heat-shock RNA polymerase. Primer extension analysis showed that Prepl is contained within five helically aligned 18 base pair repeats, or 18-mers of the previously defined minimal origin. In addition, we find that Prepl is autoregulated by a trans-acting product encoded in the REPI region. Purified Repl protein binds to the 18-mer region of the origin, suggesting that the repl gene is autoregulated by the protein product. The autoregulation appears to be co-operative since decreasing the 18-mer binding site region results in a concomitant non-linear loss of autorepression. The deletion derivatives show a decreased ability to bind the Repl protein when compared with origin DNA containing all of the binding region. The diminished capacity of the various deletion derivatives to bind Repl in vitro correlates with the loss of autorepression seen in vivo.

Roles of DNA adenine methylation in controlling replication of the REPI replicon of plasmid pColV-K30.

DNA adenine methylation controls DNA replication of plasmids containing the prototypic REPI replicon by affecting protein recognition and by altering the helical stability of the origin. Denaturing gradient gel electrophoresis shows that adenine methylated origin DNA is more easily melted than unmethylated. However, because an added DNA adenine methylation (dam) site at the origin, whether in or out of phase with other helically aligned dam sites, actually prevents replication, we conclude that destabilization of the helix is not the exclusive function of adenine methylation in REPI replication. We find that the conformation and degree of methylation at the origin, features which are important for protein recognition, are essential for replication. In fact, RepI, a protein required for replication initiation at REPI replicons, contains a region homologous with a domain in proteins which specifically recognize and bind 5'-GATC-3'. We propose that the dam sites in the origin play a dual role: one is destabilization of the helix, and the other is protein recognition.

Nucleotide sequence analysis and expression of the minimum REPI replication region and incompatibility determinants of pColV-K30.

We sequenced the minimum REPI replication region and the incompatibility determinants of pColV-K30. The minimum replication region contains an open reading frame which corresponds to a 35-kilodalton (kDa) protein. Sodium dodecyl sulfate-polyacrylamide gel electrophoretic analysis with maxicells transformed with a number of deletion derivatives demonstrated that this replication region encodes a 39-kDa protein and also established the direction of transcription of the RepI protein gene. The 39-kDa polypeptide was identified as the trans-acting factor essential for replication of REPI-containing plasmids. A translated region of the nucleotide sequence of the RepI protein gene showed homology with the helix-turn-helix binding domains of a number of DNA-binding proteins and also with other plasmid replication proteins. Further nucleotide analysis of the REPI region revealed the presence of direct and inverted repeat sequences in the incE, incF, and ori regions. The REPI ori also contained a perfect DnaA-binding site in addition to a high frequency of occurrence of the DNA adenine methylation (dam) site 5'GATC3'.

The phylogeny of macrophage function: antigen uptake and degradation by peritoneal exudate cells of two amphibian species and CAF1 mice.

Equal numbers of thioglycollate mobilized peritoneal exudate cells (PEC) of the newt, Notophthalmus viridescens, the South African clawed toad, Xenopus laevis, and CAF1 mice were compared with respect to their capacity to take up and degrade soluble 14C-ovalbumin (OVA). PEC of the newt failed to take up the labeled antigen, while those of the toad incorporated only one-half as much as those of the mice. Moreover, the toad PEC degraded only 42% of the immunogen which was taken up, while PEC of the mice degraded 78% of the immunogen they had ingested during the 60-min period. Paraformaldehyde treatment of the PEC prevented antigen uptake, while chloroquine treatment prevented degradation with both species, and thus, active processes were involved. While newt PEC were unable to ingest soluble OVA, they were able to ingest and degrade OVA conjugated to sepharose during the same time period. The failure of primitive vertebrates to respond immunologically to soluble proteins appears to be due to their failure to ingest soluble immunogen.