The Genomic Structure of an Insertional Mutation in the Dystonia Musculorum Locus

We have previously identified a line of transgenic mice, Tg4, in which an hsp68-lacZ hybrid gene has inserted into the dystonia musculorum (dt) locus on chromosome 1. We have confirmed the localization of the Tg4 integration site to the proximal region of mouse chromosome 1 by interspecific backcross analysis. One end of the integration complex has been cloned and we have used single-copy probes from the flanking region to screen a mouse genomic library. Several overlapping lambda phage clones have been isolated and arranged into a contig spanning 75 kb of genomic DNA. Probes from the genomic contig have enabled us to characterize the wildtype and Tg4 loci. We report that the integration of the transgene was accompanied by a deletion of 45 kb of host genomic sequences with no other detectable rearrangement in the Tg4 genome.     

A Mutation Leading to Constitutive Expression of High Sexual Activities in the Yeast Saccharomyces cerevisiae

An a mating type mutant of the yeast Saccharomyces cerevisiaewhich expressed high sexual activities during vegetative growthwas isolated and characterized. Its constitutive sexual agglutinabilitywas higher than the sexual agglutinability of its parental straininduced by pheromone. It produced a pheromone and -pheromone-inactivatingsubstances in larger amounts than its parental strain. It alsoproduced large pear-shaped cells (shmooed cells) without pheromone,was more sensitive to pheromone, and grew vegetatively moreslowly than its parental strain. When the mutant was crossedto a wild type strain isogenic with the parental strain, amating type segregants with high constitutive sexual agglutinabilityshowed self-shmooing. However, in a mating type segregants self-shmooingwas not observed regardless of the degree of their sexual agglutinability.The cross between a and segregants, both of which carried themutation, had higher frequency of zygote formation than thecrosses between a and cells one of which or both of which wereof wild type. (Received September 9, 1985; Accepted February 8, 1986)     

The Yeast Gene, MDM20, Is Necessary for Mitochondrial Inheritance and Organization of the Actin Cytoskeleton

In Saccharomyces cerevisiae, the growing bud inherits a portion of the mitochondrial network from the mother cell soon after it emerges. Although this polarized transport of mitochondria is thought to require functions of the cytoskeleton, there are conflicting reports concerning the nature of the cytoskeletal element involved. Here we report the isolation of a yeast mutant, mdm20, in which both mitochondrial inheritance and actin cables (bundles of actin filaments) are disrupted. The MDM20 gene encodes a 93-kD polypeptide with no homology to other characterized proteins. Extra copies of TPM1, a gene encoding the actin filament–binding protein tropomyosin, suppress mitochondrial inheritance defects and partially restore actin cables in mdm20Δ cells. Synthetic lethality is also observed between mdm20 and tpm1 mutant strains. Overexpression of a second yeast tropomyosin, Tpm2p, rescues mutant phenotypes in the mdm20 strain to a lesser extent. Together, these results provide compelling evidence that mitochondrial inheritance in yeast is an actin-mediated process. MDM20 and TPM1 also exhibit the same pattern of genetic interactions; mutations in MDM20 are synthetically lethal with mutations in BEM2 and MYO2 but not SAC6. Although MDM20 and TPM1 are both required for the formation and/or stabilization of actin cables, mutations in these genes disrupt mitochondrial inheritance and nuclear segregation to different extents. Thus, Mdm20p and Tpm1p may act in vivo to establish molecular and functional heterogeneity of the actin cytoskeleton.     

Effects of the Mitotic Cell-Cycle Mutation cdc4 on Yeast Meiosis

The mitotic cell-cycle mutation cdc4 has been reported to block the initiation of nuclear DNA replication and the separation of spindle plaques after their replication. Meiosis in cdc4/cdc4 diploids is normal at the permissive temperature (25 degrees) and is arrested at the first division (one-nucleus stage) at the restrictive temperature (34 degrees or 36 degrees). Arrested cells at 34 degrees show a high degree of commitment to recombination (at least 50% of the controls) but no haploidization, while cells arrested at 36 degrees are not committed to recombination. Meiotic cells arrested at 34 degrees show a delayed and reduced synthesis of DNA (at most 40% of the control), at least half of which is probably mitochondrial. It is suggested that recombination commitment does not depend on the completion of nuclear premeiotic DNA replication in sporulation medium.--Transfer of cdc4/cdc4 cells to the restrictive temperature at the onset of sporulation produces a uniform phenotype of arrest at a 1-nucleus morphology. On the other hand, shifts of the meiotic cells to the restrictive temperature at later times produce two additional phenotypes of arrest, thus suggesting that the function of cdc4 is required at several points in meiosis (at least at three different times).     

Decreasing Gradients of Gene Conversion on Both Sides of the Initiation Site for Meiotic Recombination at the Arg4 Locus in Yeast

We have constructed eight restriction site polymorphisms in the DED81-ARG4 region and examined their behavior during meiotic recombination. Tetrad analysis reveals decreasing gradients of gene conversion on both sides of the initiation site for meiotic recombination at the ARG4 locus, extending on one side into the ARG4 gene, and on the other side into the adjacent DED81 gene. Gene conversion events can extend in both directions from the initiation site as the result of a single meiotic event. There is a second gradient of gene conversion in DED81, with high levels near the 5' end of the gene and low levels near the middle of the gene. The peaks of gene conversion activity for the DED81 and ARG4 gradients map to regions where double-strand breaks are found during meiosis. The implications of these results for models of meiotic gene conversion are discussed.     

The Effects of Three Different MAL Loci on the Regulation of Maltase Synthesis in Yeast

Inbred haploid strains of Saccharomyces cerevisiae carrying MAL1, MAL2 or MAL6 in a common background have been crossed to each other and to strains carrying no active MAL loci. The kinetics of maltase induction and the induced maltase levels have been examined in the inbred strains and in haploid segregants of the crosses. Differences have been found in the kinetics of induction and induced maltase levels that segregate with the different MAL loci. In the strains tested, the relative rates of maltase induction were MAL2>MAL6>>MAL1; the relative induced maltase levels were MAL2>MAL6~MAL1. These results indicate that MAL1, MAL2 and MAL6 are (or include) regulatory genes that control the accumulation of the enzymes of maltose fermentation.     

Reversion at the HIS1 Locus of Yeast

The his1 gene (chromosome V) of Saccharomyces cerevisiae specifies phosphoribosyl transferase (E.C.2.4.2.17), the first enzyme of histidine biosynthesis. This hexameric enzyme has both catalytic and regulatory functions. The spontaneous reversion rates of seven his1 mutations were studied. The reversion rates of the alleles at the proximal end of the locus (relative to the centromere) were about 50-fold higher than distal alleles. Spontaneous reversion to prototrophy was studied in diploids homoallelic for each of the seven his1 mutations. Based on tetrad analysis, the prototrophy revertants could be assigned to three classes: (1) revertant tetrads that carried a prototrophic allele indistinguishable from wild type; (2) revertant tetrads that carried a prototrophic allele characterized by histidine excretion and feedback resistance; and (3) revertant tetrads that did not contain a prototrophic spore, but rather a newly derived allele that complemented the original allele intragenically. Four of the seven his1 mutations produced the excretor revertant class, and two mutations produced the complementer revertant class. The significance of these findings to our understanding of gene organization and the catalytic and regulatory functions of gene products are discussed.     

The Hyper-Gene Conversion Hpr5-1 Mutation of Saccharomyces Cerevisiae Is an Allele of the Srs2/Radh Gene

The HPR5 gene has been defined by the mutation hpr5-1 that results in an increased rate of gene conversion. This mutation suppresses the UV sensitive phenotype of rad18 mutations in hpr5-1 rad18 double mutants by channeling the aborted repair events into a recombination repair pathway. The HPR5 gene has been cloned and is shown to be allelic to the SRS2/RADH gene, a putative DNA helicase. The HPR5 gene, which is nonessential, is tightly linked to the ARG3 locus chromosome X. The hpr5-1 allele contains missense mutation in the putative ATP binding domain. A comparison of the recombination properties of the hpr5-1 allele and the null allele suggests that recombination events in hpr5 defective strains can be generated by several mechanisms. We propose that the HPR5 gene functions in the RAD6 repair pathway.     

Constitutive Activation of an Anthocyanin Regulatory Gene PcMYB10.6 Is Related to Red Coloration in Purple-Foliage Plum

Cherry plum is a popular ornamental tree worldwide and most cultivars are selected for purple foliage. Here, we report the investigation of molecular mechanism underlying red pigmentation in purple-leaf plum ‘Ziyeli’ (Prunus cerasifera Ehrhar f. atropurpurea (Jacq.) Rehd.), which shows red color pigmentation in fruit (flesh and skin) and foliage. Six anthocyanin-activating MYB genes, designated PcMYB10.1 to PcMYB10.6, were isolated based on RNA-Seq data from leaves of cv. Ziyeli. Of these PcMYB10 genes, five (PcMYB10.1 through PcMYB10.5) show distinct spatial and temporal expression patterns, while the PcMYB10.6 gene is highly expressed in all the purple-coloured organs of cv. Ziyeli. Constitutive activation of PcMYB10.6 is closely related to red pigmentation in the leaf, fruit (flesh and skin), and sepal. However, the PcMYB10.6 activation cannot induce red pigmentation in the petal of cv. Ziyeli during late stages of flower development due to due to a lack of expression of PcUFGT. The inhibition of red pigmentation in the petal of cherry plum could be attributed to the high-level expression of PcANR that directs anthocyanidin flux to proanthocyanidin biosynthesis. In addition, PcMYB10.2 is highly expressed in fruit and sepal, but its expression cannot induce red pigmentation. This suggests the PcMYB10 gene family in cherry plum may have diverged in function and PcMYB10.2 plays little role in the regulation of red pigmentation. Our study provides for the first time an example of constitutive activation of an anthocyanin-activating MYB gene in Prunus although its underlying mechanism remains unclear.     

Autosomal-Recessive Hypophosphatemic Rickets Is Associated with an Inactivation Mutation in the ENPP1 Gene

Human disorders of phosphate (Pi) handling and hypophosphatemic rickets have been shown to result from mutations in PHEX, FGF23, and DMP1, presenting as X-linked recessive, autosomal-dominant, and autosomal-recessive patterns, respectively. We present the identification of an inactivating mutation in the ecto-nucleotide pyrophosphatase/phosphodiesterase 1 (ENPP1) gene causing autosomal-recessive hypophosphatemic rickets (ARHR) with phosphaturia by positional cloning. ENPP1 generates inorganic pyrophosphate (PPi), an essential physiologic inhibitor of calcification, and previously described inactivating mutations in this gene were shown to cause aberrant ectopic calcification disorders, whereas no aberrant calcifications were present in our patients. Our surprising result suggests a different pathway involved in the generation of ARHR and possible additional functions for ENPP1.     

The Yeast Mer2 Gene Is Required for Chromosome Synapsis and the Initiation of Meiotic Recombination

Mutation of the MER2 gene of Saccharomyces cerevisiae confers meiotic lethality. To gain insight into the function of the Mer2 protein, we have carried out a detailed characterization of the mer2 null mutant. Genetic analysis indicates that mer2 completely eliminates meiotic interchromosomal gene conversion and crossing over. In addition, mer2 abolishes intrachromosomal meiotic recombination, both in the ribosomal DNA array and in an artificial duplication. The results of a physical assay demonstrate that the mer2 mutation prevents the formation of meiosis-specific, double-strand breaks, indicating that the Mer2 protein acts at or before the initiation of meiotic recombination. Electron microscopic analysis reveals that the mer2 mutant makes axial elements, which are precursors to the synaptonemal complex, but homologous chromosomes fail to synapse. Fluorescence in situ hybridization of chromosome-specific DNA probes to spread meiotic chromosomes demonstrates that homolog alignment is also significantly reduced in the mer2 mutant. Although the MER2 gene is transcribed during vegetative growth, deletion or overexpression of the MER2 gene has no apparent effect on mitotic recombination or DNA damage repair. We suggest that the primary defect in the mer2 mutant is in the initiation of meiotic genetic exchange.     

MAL, an Integral Element of the Apical Sorting Machinery, Is an Itinerant Protein That Cycles between the Trans-Golgi Network and the Plasma Membrane

The MAL proteolipid is a nonglycosylated integral membrane protein found in glycolipid-enriched membrane microdomains. In polarized epithelial Madin-Darby canine kidney cells, MAL is necessary for normal apical transport and accurate sorting of the influenza virus hemagglutinin. MAL is thus part of the integral machinery for glycolipid-enriched membrane-mediated apical transport. At steady state, MAL is predominantly located in perinuclear vesicles that probably arise from the trans-Golgi network (TGN). To act on membrane traffic and to prevent their accumulation in the target compartment, integral membrane elements of the protein-sorting machinery should be itinerant proteins that cycle between the donor and target compartments. To establish whether MAL is an itinerant protein, we engineered the last extracellular loop of MAL by insertion of sequences containing the FLAG epitope or with sequences containing residues that became O-glycosylated within the cells or that displayed biotinylatable groups. The ectopic expression of these modified MAL proteins allowed us to investigate the surface expression of MAL and its movement through different compartments after internalization with the use of a combination of assays, including surface biotinylation, surface binding of anti-FLAG antibodies, neuraminidase sensitivity, and drug treatments. Immunofluorescence and flow cytometric analyses indicated that, in addition to its Golgi localization, MAL was also expressed on the cell surface, from which it was rapidly internalized. This retrieval implies transport through the endosomal pathway and requires endosomal acidification, because it can be inhibited by drugs such as chloroquine, monensin, and NH(4)Cl. Resialylation experiments of surface MAL treated with neuraminidase indicated that approximately 30% of the internalized MAL molecules were delivered to the TGN, probably to start a new cycle of cargo transport. Together, these observations suggest that, as predicted for integral membrane members of the late protein transport machinery, MAL is an itinerant protein cycling between the TGN and the plasma membrane.     

Regulatory Mutants at the his1 Locus of Yeast

The his1 gene in Saccharomyces cerevisiae codes for phosphoribosyl transferase, an allosteric enzyme that catalyzes the initial step in histidine biosynthesis. Mutants that specifically alter the feedback regulatory function were isolated by selecting his1 prototrophic revertants that overproduce and excrete histidine. The prototrophs were obtained from diploids homoallelic for his1--7 and heterozygous for the flanking markers thr3 and arg6. Among six independently derived mutant isolates, three distinct levels of histidine excretion were detected. The mutants were shown to be second-site alterations mapping at the his1 locus by recovery of the original auxotrophic parental alleles. The double mutants, HIS1--7e, are dominant with respect to catalytic function but recessive in regulatory function. When removed from this his1--7 background, the mutant regulatory site (HIS1-e) still confers prototrophy but not histidine excretion. To yield the excretion phenotype, the primary and altered secondary sites are required in cis array. Differences in histidine excretion levels correlate with resistance to the histidine analogue, triazoalanine.