An electrophoretic karyotype for yeast

The TRANSPARENT TESTA GLABRA1 locus, which regulates trichome differentiation and anthocyanin biosynthesis in Arabidopsis, encodes a WD40 repeat protein

The TRANSPARENT TESTA GLABRA1 (TTG1) locus regulates several developmental and biochemical pathways in Arabidopsis, including the formation of hairs on leaves, stems, and roots, and the production of seed mucilage and anthocyanin pigments. The TTG1 locus has been isolated by positional cloning, and its identity was confirmed by complementation of a ttg1 mutant. The locus encodes a protein of 341 amino acid residues with four WD40 repeats. The protein is similar to AN11, a regulator of anthocyanin biosynthesis in petunia, and more distantly related to those of the beta subunits of heterotrimeric G proteins, which suggests a role for TTG1 in signal transduction to downstream transcription factors. The 1.5-kb TTG1 transcript is present in all major organs of Arabidopsis. Sequence analysis of six mutant alleles has identified base changes producing truncations or single amino acid changes in the TTG1 protein.

The TRANSPARENT TESTA GLABRA1 locus, which regulates trichome differentiation and anthocyanin biosynthesis in Arabidopsis, encodes a WD40 repeat protein

The TRANSPARENT TESTA GLABRA1 (TTG1) locus regulates several developmental and biochemical pathways in Arabidopsis, including the formation of hairs on leaves, stems, and roots, and the production of seed mucilage and anthocyanin pigments. The TTG1 locus has been isolated by positional cloning, and its identity was confirmed by complementation of a ttg1 mutant. The locus encodes a protein of 341 amino acid residues with four WD40 repeats. The protein is similar to AN11, a regulator of anthocyanin biosynthesis in petunia, and more distantly related to those of the beta subunits of heterotrimeric G proteins, which suggests a role for TTG1 in signal transduction to downstream transcription factors. The 1.5-kb TTG1 transcript is present in all major organs of Arabidopsis. Sequence analysis of six mutant alleles has identified base changes producing truncations or single amino acid changes in the TTG1 protein.

Specific chromosome alterations in fluconazole-resistant mutants of Candida albicans

The exposure of Candida albicans to fluconazole resulted in the nondisjunction of two specific chromosomes in 17 drug-resistant mutants, each obtained by an independent mutational event. The chromosomal changes occurred at high frequencies and were related to the duration of the drug exposure. The loss of one homologue of chromosome 4 occurred after incubation on a fluconazole medium for 7 days. A second change, the gain of one copy of chromosome 3, was observed after exposure for 35 or 40 days. We found that the mRNA levels of ERG11, CDR1, CDR2, and MDR1, the candidate fluconazole resistance genes, remained either the same or were diminished. The lack of overexpression of putative drug pumps or the drug target indicated that some other mechanism(s) may be operating. The fluconazole resistance phenotype, electrophoretic karyotypes, and transcript levels of mutants were stable after growth for 112 generations in the absence of fluconazole. This is the first report to demonstrate that resistance to fluconazole can be dependent on chromosomal nondisjunction. Furthermore, we suggest that a low-level resistance to fluconazole arising during the early stages of clinical treatment may occur by this mechanism. These results support our earlier hypothesis that changes in C. albicans chromosome number is a common means to control a resource of potentially beneficial genes that are related to important cellular functions.

Separation of micronuclear DNA of Stylonychia lemnae by pulsed-field electrophoresis and identification of a DNA molecule with a high copy number

DNA from the hypotrichous ciliatae Stylonychia lemnae was separated by PFGE. In addition to the separation of the macronuclear DNA molecules with a size up to approximately 40 kb, we were able to separate the micronuclear DNA with a size between approximately 90 kb and 2 Mb. One very prominent 90-kb DNA band appeared on the pulsed-field gels. We propose that this 90-kb DNA fragment represents a linear plasmid residing in the micronucleus in a very high copy number. About 10% of the micronuclear DNA consists of the 90-kb DNA molecule. It appears in the micronucleus as well as in the macronuclear anlagen during macronuclear development but not in the mature macronucleus. Thus, the multicopy DNA is eliminated during fragmentation of the macronuclear anlagen DNA in the course of macronuclear development. Therefore, this 90-kb DNA molecule might serve as an excellent tool to study the recognition and elimination of DNA during nuclear differentiation of hypotrichous ciliates.

Separation of Micronuclear DNA of Stylonychia lemnae by Pulsed-Field Electrophoresis and Identification of a DNA Molecule with a High Copy Number

DNA from the hypotrichous ciliatae Stylonychia lemnae was separated by PFGE. In addition to the separation of the macronuclear DNA molecules with a size up to ∼40 kb, we were able to separate the micronuclear DNA with a size between ∼90 kb and 2 Mb. One very prominent 90-kb DNA band appeared on the pulsed-field gels. We propose that this 90-kb DNA fragment represents a linear plasmid residing in the micronucleus in a very high copy number. About 10% of the micronuclear DNA consists of the 90-kb DNA molecule. It appears in the micronucleus as well as in the macronuclear anlagen during macronuclear development but not in the mature macronucleus. Thus, the multicopy DNA is eliminated during fragmentation of the macronuclear anlagen DNA in the course of macronuclear development. Therefore, this 90-kb DNA molecule might serve as an excellent tool to study the recognition and elimination of DNA during nuclear differentiation of hypotrichous ciliates.

Isolation and characterization of the ATF2 gene encoding alcohol acetyltransferase II in the bottom fermenting yeast Saccharomyces pastorianus

The ATF2 gene encodes alcohol acetyltransferase II, which catalyses the synthesis of isoamyl acetate from acetyl coenzyme A and isoamyl alcohol. To characterize the ATF2 gene from the bottom fermenting yeast Saccharomyces pastorianus, the S. pastorianus ATF2 gene was cloned by colony hybridization using the S. cerevisiae ATF2 gene as a probe. When an atf1 null mutant strain was transformed with a multi-copy plasmid carrying the S. pastorianus ATF2 gene, the AATase activity of this strain was increased by 2.5-fold compared to the control. The S. pastorianus ATF2 gene has 99% nucleic acid homology in the coding region and 100% amino acid homology with the S. cerevisiae ATF2 gene. Southern blot analysis of chromosomes separated by pulse-field gel electrophoresis indicated that the ATF2 gene probe hybridized to chromosome VII in S. cerevisiae and to the 1100 kb chromosome in S. pastorianus. As S. pastorianus is thought to be a hybrid of S. cerevisiae and S. bayanus, the S. bayanus-type gene, which has a relatively low level of homology with the S. cerevisiae-type gene, is also usually detected. Interestingly, an S. bayanus-type ATF2 gene could not be detected. These results suggested that the cloned ATF2 gene was derived from S. cerevisiae. Analysis using an ATF2-lacZ fusion gene in S. pastorianus showed that expression of the ATF2 gene was relatively lower than that of the ATF1 gene and that it is repressed by aeration but activated by the addition of unsaturated fatty acids. The S. pastorianus ATF1, Lg-ATF1 and ATF2 Accession Numbers in the DDBJ Nucleotide Sequence Database are D63449, D63450 and D86480, respectively.

Inter- and intraspecific chromosome pattern variation in the yeast genus Kluyveromyces

The analysis of the electrophoretic chromosome patterns of the species of the genus Kluyveromyces, reveals a high polymorphism in size, number and intensity of bands. Different sets of electrophoresis running conditions were used to establish species-specific patterns and also to detect intraspecific variation. According to their karyotypes, the species of this genus can be divided into two major groups. The first group includes the species K. africanus, K. bacillisporus, K. delphensis, K. lodderae, K. phaffi, K. polysporus and K. yarrowii, composing the so-called 'Saccharomyces cerevisiae-like' group, because their karyotypes resemble that of the species S. cerevisiae. The second group comprises the species K. aestuarii, K. blattae, K. dobzhanskii, K. lactis, K. marxianus, K. thermotolerans, K. waltii and K. wickerhamii, whose chromosomal patterns exhibit common characteristics very different to those of the species included in the 'S. cerevisiae-like' group. This division is concordant with the position of these species in previous phylogenetic reconstructions. Additionally, the intraspecific analysis of the chromosome patterns show a rich polymorphism in the heterogeneous species K. dobzhanskii, K. lactis, and K. marxianus, which is in concordance with the variability observed with other phenotypic or genetic markers. On the contrary, K. thermotolerans exhibits a homogeneous karyotype indicative of a very low level of chromosomal polymorphism, which is congruent with the reduced variability found in this species with other molecular markers.

Yeast telomeres exert a position effect on recombination between internal tracts of yeast telomeric DNA

In Saccharomyces cerevisiae, proximity to a telomere affects both transcription and replication of adjacent DNA. In this study, we show that telomeres also impose a position effect on mitotic recombination. The rate of recombination between directly repeated tracts of telomeric C1-3A/TG1-3 DNA was reduced severely by proximity to a telomere. In contrast, recombination of two control substrates was not affected by telomere proximity. Thus, unlike position effects on transcription or replication, inhibition of recombination was sequence specific. Moreover, the repression of recombination was not under the same control as transcriptional repression (telomere position effect; TPE), as mutations in genes essential for TPE did not alleviate telomeric repression of recombination. The reduction in recombination between C1-3A/TG1-3 tracts near the telomere was caused by an absence of Rad52p-dependent events as well as a reduction in Rad1p-dependent events. The sequence-specific repression of recombination near the telomere was eliminated in cells that overexpressed the telomere-binding protein Rap1p, a condition that also increased recombination between C1-3A/TG1-3 tracts at internal positions on the chromosome. We propose that the specific inhibition between C1-3A/TG1-3 tracts near the telomere occurs through the action of a telomere-specific end-binding protein that binds to the single-strand TG1-3 tail generated during the processing of recombination intermediates. The recombination inhibitor protein may also block recombination between endogenous telomeres.

Chromosomal DNA patterns and gene stability of Pichia pastoris

We have clearly resolved four chromosomal bands from four Pichia pastoris (Komagataella pastoris) strains by using contour-clamped homogeneous electric field gel electrophoresis. The size of the P. pastoris chromosomal bands ranged from 1.7 Mb to 3.5 Mb and total genome size was estimated to be 9.5 Mb to 9.8 Mb; however, chromosome-length polymorphisms existed among four strains. Thirteen cloned genes isolated from strain GTS115 were assigned to the separated chromosomes, revealing that different hybridization patterns were observed in the AOX2 and URA3 genes among strains. P. pastoris is frequently used as an efficient host for heterologous gene expressions. We analysed chromosomal stability of strain GTS115-derived recombinant cell expressing human serum albumin during serial cultivation under the condition of vegetative and non-selective growth. No chromosomal rearrangements were observed and the expression constructs integrated into the his4 locus on chromosome I were very stable even at 83 generations, suggesting that stable expression would be carried out even in large-scale fermentation.

Co-existence of two types of chromosome in the bottom fermenting yeast, Saccharomyces pastorianus

The bottom fermenting yeasts in our collection were classified as Saccharomyces pastorianus on the basis of their DNA relatedness. The genomic organization of bottom fermenting yeast was analysed by Southern hybridization using eleven genes on chromosome IV, six genes on chromosome II and five genes on chromosome XV of S. cerevisiae as probes. Gene probes constructed from S. cerevisiae chromosomes II and IV hybridized strongly to the 820-kb chromosome and the 1500-kb chromosome of the bottom fermenting yeast, respectively. Five gene probes constructed from segments of chromosome XV hybridized strongly to the 1050-kb and the 1000-kb chromosomes. These chromosomes are thought to be S. cerevisiae-type chromosomes. In addition, these probes also hybridized weakly to the 1100-kb, 1350-kb, 850-kb and 700-kb chromosome. Gene probes constructed from segments including the left arm to TRP1 of chromosome IV and the right arm of chromosome II hybridized to the 1100-kb chromosomes of S. pastorianus. Gene probes constructed using the right arm of chromosome IV and the left arm of chromosome II hybridized to the 1350-kb chromosome of S. pastorianus. These results suggested that the 1100-kb and 1350-kb chromosomes were generated by reciprocal translocation between chromosome II and IV in S. pastorianus. Three gene probes constructed using the right arm of chromosome XV hybridized weakly to the 850-kb chromosome, and two gene probes from the left arm hybridized weakly to the 700-kb chromosome. These results suggested that chromosome XV of S. cerevisiae was rearranged into the 850-kb and 700-kb chromosomes in S. pastorianus. These weak hybridization patterns were identical to those obtained with S. bayanus. Therefore, two types of chromosome co-exist independently in bottom fermenting yeast: one set which originated from S. bayanus and another set from S. cerevisiae. This result supports the hypothesis that S. pastorianus is a hybrid of S. cerevisiae and S. bayanus.

The absence of enhancer competition between Igf2 and H19 following transfer into differentiated cells

H19 and Igf2 are reciprocally imprinted genes that lie 90 kb apart on mouse chromosome 7. The two genes are coexpressed during development, with the H19 gene expressed exclusively from the maternal chromosome and Igf2 from the paternal chromosome. It has been proposed that their reciprocal imprinting is governed by a competition between the genes for a common set of enhancers. The competition on the paternal chromosome is influenced by extensive allele-specific methylation of the H19 gene and its 5' flank, which acts to inhibit H19 transcription and thus indirectly leads to the activation of the Igf2 gene. In contrast, no allele-specific methylation has been detected on the maternal chromosome, and the basis for the preference for H19 transcription on that chromosome is unresolved. In this investigation, the mechanism controlling the silencing of the Igf2 gene on the maternal chromosome was explored by studying the transcriptional activity of a yeast artificial chromosome (YAC) containing Igf2 and H19 following transfer into differentiated tissue culture cells. Contrary to expectations, both H19 and Igf2 were expressed from a single integrated copy of the YAC. Furthermore, Igf2 expression appeared to be independent of the H19 locus, based on deletions of the H19 gene promoter and its enhancers. These results suggest that an active process is responsible for the transcriptional bias toward H19 on the maternal chromosome and that the hypomethylated state of this chromosome cannot be viewed as a "default" state. Moreover, the active process is not reproduced in a differentiated cell and may require passage through the female germ line.

Cloning and localization of the murine Xpct gene: evidence for complex rearrangements during the evolution of the region around the Xist gene

The overall organization of the X-inactivation center (XIC/Xic) candidate region seems poorly conserved between human and mouse. The orientation of a region containing the X-inactive-specific transcript (Xist/ XIST) gene and three genes located 3' of Xist/XIST has been shown to be inverted between the two species, although the actual extent of this rearrangement is unknown. We have cloned and mapped the mouse homolog of the human XPCT (X-linked PEST-containing transporter) gene, which encodes a putative transmembrane transporter. Human XPCT is located about 200 kb outside of the XIC candidate region and 600 kb 5' of or telomeric to the XIST gene. The mouse Xpct gene, which lies approximately 300 kb 5' of and centromeric to Xist, displays 85% identity at the nucleotide level with the human gene, and the overall protein structure is conserved. The transcriptional orientation of mouse Xpct with respect to Xist is the opposite of that in human. Consequently, the evolution of the region between human and mouse appears to be highly complex, with structural rearrangements involving a region of up to 600 kb or more around the Xist gene.

Variation in the electrophoretic karyotype of Brazilian strains of Metarhizium anisopliae

Pulsed-field gel electrophoresis (PFGE) was used to separate chromosome-sized DNA molecules of four strains of Metarhizium anisopliae from Brazil. Metarhizium anisopliae isolates from Japan have been reported as possessing seven chromosomes. Variation was observed among the Brazilian strains and the chromosomal DNA was resolved into eight bands for strain CG46. Densitometric analysis of PFGE gels suggested that the other three Brazilian strains also possess eight chromosomes, with two chromosomes migrating as doublets under the electrophoretic conditions used. The genome size was estimated as varying between 23.39 to 31.88 Mb, not including possible doublet chromosomes.

Specific isolation of human rDNA genes by TAR cloning

Selective cloning of human DNA in YACs from monochromosomal human/rodent hybrid cells lines and radiation hybrids can be accomplished by transformation-associated recombination (TAR) between Alu-containing vector(s) and human DNA in yeast. We have expanded this approach to the specific isolation of repetitive genes from the human genome. Highly selective isolation of human rDNA was accomplished using total human DNA and a pair of differentially marked linear TAR cloning vectors where one contained a small fragment of a human rDNA repeat and the other had an Alu repeat as targeting sequences. About half the transformants that acquired both vectors markers had YACs with human rDNA inserts. These results suggest that TAR can be applied to the general isolation of gene families and amplified region from genomic DNAs.

The characterization of two new clusters of duplicated genes suggests a 'Lego' organization of the yeast Saccharomyces cerevisiae chromosomes

The systematic sequencing of 42,485 bp of yeast chromosome VII (nucleotides 377948 to 420432) has revealed the presence of 27 putative open reading frames (ORFs) coding for proteins of at least 100 amino acids. The degree of redundancy observed is elevated since five of the 27 ORFs are duplications of a previously identified gene. These duplicated copies may be classified in two types of cluster organization. The first type includes genes sharing a significant level of identity in the amino acid sequences of their predicted protein product. They are recovered on two different chromosomes, transcribed in the same orientation and the distance between them is conserved. The second type of cluster is based on one gene unit tandemly repeated. This duplication is itself repeated elsewhere in the genome. The level of nucleic acid identity is high within the coding sequence and the non-coding region between the two repeats. In addition, the basic gene unit is recovered many times in the genome and is a component of a multigene family of unknown function. These organizations in clusters of genes suggest a 'Lego organization' of the yeast chromosomes, as recently proposed for the genome of plants (Moore, 1995). The sequence is deposited in the Yeast Genome Databank under Accession Number from Z72562 to Z72586.

A t(6;12)(q23;p13) results in the fusion of ETV6 to a novel gene, STL, in a B-cell ALL cell line

ETV6 (TEL) is rearranged in various types of hematologic malignancies. The B-cell precursor acute lymphoblastic leukemia (ALL) cell line SUP-B2 has a t(6;12)(q23;p13) involving ETV6 at 12p13 and a submicroscopic deletion of the other ETV6 allele. The reciprocal translocation results in the fusion of ETV6 to a previously unknown gene at 6q23, which we named STL (six-twelve leukemia gene). Both reciprocal fusion transcripts can be detected: On the der(6) chromosome, the ETV6/STL mRNA shows an apparently out of frame fusion of ETV6 at nucleotide 187 to STL, which would result in the addition of 14 amino acids to the first 54 amino acids of ETV6. On the der(12) chromosome three different variants of the STL/ETV6 fusion mRNA could be detected; variable size segments were inserted at the breakpoint between STL and ETV6 exon 3. One of these variants could give rise to a protein in which the first 54 amino acids of ETV6 are replaced by 12 amino acids from one of the STL short open reading frames. Sequence analysis of a 1.4 kb STL cDNA clone from a skeletal muscle library revealed no long open reading frames. This cell line will be very useful in studying the different mechanisms by which alterations of ETV6 contribute to leukemogenesis and in testing the hypothesis that ETV6 might act as a tumor suppressor gene.

Karyotypic Variability in Ribosomal DNA Subchromosome Size among Colpodid Ciliates, a Possible Tool To Differentiate Colpodid Species

Pulsed-field gel electrophoresis has been applied to analyze the karyotypic variability among colpodid ciliates. The 18S ribosomal gene was found at different locations in the electrophoretic pattern, and these size variations in the ribosomal DNA subchromosomal molecule seem to be species specific. This could potentially be a useful new tool with which to differentiate colpodid ciliates.

Determination of the relative ploidy in different Saccharomyces cerevisiae strains used for fermentation and 'flor' film ageing of dry sherry-type wines

The full chromosomal karyotype of six enological Saccharomyces cerevisiae strains used for fermentation and biological ageing of sherry-type wines was studied. A genetic method based on the analysis of segregation frequencies of auxotrophic markers, among random spore progeny of hybrids, constructed between laboratory and industrial wine strains (Bakalinsky and Snow, 1990) was used. This method was combined with the analysis of strains by pulsed-field gel electrophoresis. The results obtained clearly indicate the presence of two, three or four copies of a chromosome in the industrial strains examined, and thus confirm that aneuploidy/polyploidy is not uncommon in these strains. In all strains examined, chromosome XIII polysomy is observed. This chromosome contains the ADH2 and ADH3 loci, that code for the ADHII and ADHIII isoenzymes of alcohol dehydrogenase, which are involved in ethanol oxidative utilization during biological ageing of wines. Tetrad analysis for the 'flor formation' character suggest two possibilities: this character is either regulated by at least a digenic system, or by only one gene present on a chromosome which is, at least, disomic.

Molecular cytogenetic characterization and physical mapping of 12q13-15 amplification in human cancers

Amplification of sequences derived from 12q13-15 is frequent in human sarcomas and brain tumors. Detailed mapping studies of the amplified region are necessary for definition of the impact of these amplification events on the tumor cell phenotype. By using the genes in this region and genomic fragments isolated by chromosome microdissection, we have established a series of ordered probes from 12q13-15 for fluorescence in situ hybridization (FISH) and Southern blot analysis. These probes have been used for physical mapping of two portions of the interval from GLI to D12S8. The centromeric region extends 1.8 Mb from GLI to microclone M79 and contains at least five genes, including the cyclin-dependent kinase gene CDK4. The more telomeric region includes the p53 regulator MDM2 and covers 1.1 Mb. We used the same group of probes to determine the pattern of amplification in three cell lines and three tumor specimens carrying amplified sequences from 12q13-15. In addition, we used a yeast artificial chromosome (YAC) contig of several megabases covering the entire region from SAS to D12S8 for FISH to determine the pattern of amplification in the neuroblastoma cell line NGP-127. The results suggest that the MDM2 and CDK4 regions may be either coamplified or amplified independently, and they illustrate how the map positions of genes and their functions may interact to determine the pattern of DNA amplification in human malignancies.

Genetic and physical mapping of the mouse Ulnaless locus

The mouse Ulnaless locus is a semidominant mutation which displays defects in patterning along the proximal-distal and anterior-posterior axes of all four limbs. The first Ulnaless homozygotes have been generated, and they display a similar, though slightly more severe, limb phenotype than the heterozygotes. To create a refined genetic map of the Ulnaless region using molecular markers, four backcrosses segregating Ulnaless were established. A 0.4-cM interval containing the Ulnaless locus has been defined on mouse chromosome 2, which has identified Ulnaless as a possible allele of a Hoxd cluster gene(s). With this genetic map as a framework, a physical map of the Ulnaless region has been completed. Yeast artificial chromosomes covering this region have been isolated and ordered into a 2 Mb contig. Therefore, the region that must contain the Ulnaless locus has been defined and cloned, which will be invaluable for the identification of the molecular nature of the Ulnaless mutation.

Cloning, mapping and characterization of a genomic copy of the Lipomyces kononenkoae alpha-amylase-encoding gene (LKA1)

The expression in Saccharomyces cerevisiae and Schizosaccharomyces pombe of a cDNA copy of the Lipomyces kononenkoae IGC4052B alpha-amylase gene (LKA1), linked to the phosphoglycerate kinase gene (PGK1) promoter, resulted in the extracellular production of biologically active alpha-amylase (LKA1). However, transformation of S. cerevisiae and Schiz. pombe with a cosmid clone containing the complete genomic copy of LKA1, expressed from its native promoter, did not result in secretion of active alpha-amylase by any of the transformants. When the cDNA copy of LKA1 was expressed in S. cerevisiae under control of the wild-type L, kononenkoae promoter, biologically active alpha-amylase was secreted into the culture medium, indicating the recognition of the LKA1 promoter in S. cerevisiae. Sequence analysis of the GC-rich LKA1 promoter revealed canonical sequences that are homologous to the TATAAA, CAAT and CCAAT boxes and GCN4-binding sites that are present in several promoter sequences of S. cerevisiae. Primer extension analysis of LKA1 transcripts in L. kononenkoae indicated major initiation sites at nucleotides -64 and -65. S. cerevisiae and Schiz. pombe cells transformed with a plasmid containing the open reading frame of the genomic copy of LKA1, linked to the PGK1 promoter, did not produce alpha-amylase. Polymerase chain reaction mapping and sequence analysis revealed the presence of a 61-bp intron in the genomic copy of LKA1 that impaired synthesis of biologically active alpha-amylase in S. cerevisiae and Schiz. pombe. This intron contains donor, acceptor and branch sequences that correlate with the consensus sequences identified in the introns of split genes from Schiz. pombe and mammals. Pulsed-field gradient gel electrophoresis resolved at least eight chromosomal DNAs for L. kononenkoae IGC4052B and chromoblot analysis indicated that LKA1 is located on the second smallest chromosome, designated chromosome II.

Characterization of cwl1+, a gene from Schizosaccharomyces pombe whose overexpression causes cell lysis

From a Schizosaccharomyces pombe genomic library we have isolated the gene cwl1+ that causes cell lysis when it is overexpressed in the absence of an osmotic stabilizer. Southern hybridization showed that cwl1+ exists as a single copy in the S. pombe genome. The cwl1+ gene nucleotide sequence revealed a putative open reading frame of 924 bp encoding a polypeptide of 308 amino acids with a calculated Mt of 27000. The cwl1+ DNA hybridizes to a major RNA transcript of 1.5 kb whose 5' end maps at a position 452 bp upstream from the predicted translation start. Comparison of the amino acid sequence with those included in the current databases, showed no significant similarity to any known sequences. Cells overexpressing the cwl1+ gene under the control of the S. pombe nmt inducible promoter displayed a reduced cell wall content, were unable to separate after division and lysed drastically in the absence of osmotic stabilizer. Disruption of the cwl1+ gene caused no noticeable phenotype.

Multiple determinants controlling activation of yeast replication origins late in S phase

Analysis of a 131-kb segment of the left arm of yeast chromosome XIV beginning 157 kb from the telomere reveals four highly active origins of replication that initiate replication late in S phase. Previous work has shown that telomeres act as determinants for late origin activation. However, at least two of the chromosome XIV origins maintain their late activation time when located on large circular plasmids, indicating that late replication is independent of telomeres. Analysis of the replication time of plasmid derivatives containing varying amounts of chromosome XIV DNA show that a minimum of three chromosomal elements, distinct from each tested origin, contribute to late activation time. These late determinants are functionally equivalent, because duplication of one set of contributing sequences can compensate for the removal of another set. Furthermore, insertion of an origin that is normally early activated into this domain results in a shift to late activation, suggesting that the chromosome XIV origins are not unique in their ability to respond to the late determinants.

Genomic reorganization between two sibling yeast species, Saccharomyces bayanus and Saccharomyces cerevisiae

Genomic comparison of two sibling yeast species, Saccharomyces bayanus and Saccharomyces cerevisiae, was performed by Southern blot analysis with various S. cerevisiae gene probes following electrophoretic karyotyping. Fifteen genes on chromosome IV of S. cerevisiae were examined and classified into two groups. Gene probes of CEN4 and TRP1, as well as six other genes located on the left arm of the chromosome hybridized to a 1100-kb chromosome of S. bayanus that is smaller than chromosome IV of S. cerevisiae. On the other hand, probes of seven genes located on the right arm of chromosome IV hybridized to a 1350-kb chromosome that is homeologous to chromosome IV, judging from its size. Two genes located on the left arm of chromosome II hybridized to the 1350-kb chromosome, while four genes on the right arm hybridized to the 1100-kb chromosome. These pieces of evidence indicate that chromosomes II and IV of S. cerevisiae are rearranged into 1350-kb and 1100-kb chromosomes in S. bayanus. Furthermore, it is suggested that chromosome XV is rearranged into two chromosomes (800 and 850 kb in size) in S. bayanus. The translocation points of chromosomes II and IV were delimited using S. cerevisiae prime clone membranes. The results indicated that the translocation points are located close to the FUR4 locus on chromosome II and close to the RAD57 locus on chromosome IV.

In situ localization of yeast artificial chromosome sequences on tomato and potato metaphase chromosomes

In situ localization of short low- or single-copy sequences is still difficult in plants. One solution to this problem could be the use of large yeast artificial chromosomes (YACs) for fluorescence in situ hybridization. Two YACs specific for a single copy marker on the long arm of the NOR-chromosome 2 of tomato (Lycopersicon esculentum) were selected. Both probes hybridized exclusively to this chromosome, although one produced a slightly dispersed hybridization signal. Hybridization of these YACs onto potato chromosome showed a clear single locus on the homoeologous potato chromosome in both cases.

The complete code for a eukaryotic cell. Genome sequencing

The complete sequencing of the genome of a simple eukaryotic organism - the budding yeast Saccharomyces cerevisiae - is a milestone for biology, and sets the stage for a complete understanding of how a eukaryotic cell functions.

The yeast CDC16 and CDC27 genes restrict DNA replication to once per cell cycle

CDC16 and CDC27 were identified as genes in S. cerevisiae necessary to limit DNA replication to once per cell cycle. A screen for mutants that overreplicated their DNA uncovered new conditional alleles that cause accumulation of up to 8C DNA. DNA overreplication involves all chromosomes and does not require passage through mitosis or another START. It occurs within a single cell cycle and can cause arrest at the MEC1 checkpoint. Remarkably, Clb2-Cdc28 activity remains elevated in the overreplicating cells. These observations distinguish CDC16 and CDC27 from other mutants that accumulate extra DNA after completing an aberrent mitosis, or skipping mitosis altogether, and entering a second, inappropriate G1 and S phase. CDC16 and CDC27 may contribute to replication control by targeted proteolysis of an S phase initiator.

A palindromic structure in the pericentromeric region of various human chromosomes

The primate-specific multisequence family chAB4 is represented with approximately 40 copies within the haploid human genome. Former analyis revealed that unusually long repetition units ( > 35 kb) are distributed to at least eight different chromosomal loci. Remarkably varying copy-numbers within the genomes of closely related primate species as well as the existence of human specific subfamilies, which most probably arose by frequent sequence exchanges, demonstrate that chAB4 is an unstable genomic element, at least in an evolutionary sense. To analyze the chAB4 basic unit in more detail we established a cosmid contig and found it to be organized as inverted duplications of approximately 90 kb flanking a noninverted core sequence of approximately 60 kb. FISH as well as the analysis of chromosome-specific hybrid cell lines revealed a chromosomal localization of chAB4 on chromosomes 1, 3, 4, 9, Y, and the pericentromeric region of all acrocentrics. Furthermore, we can detect chAB4 sequences together with alpha satellites, beta satellites, and satellite III sequences within a single chromosome 22-specific YAC clone, indicating that chAB4 is located in close proximity to the centromere, at least on the acrocentrics. Hence, chAB4 represents an unstable genomic structure that is located just in the chromosomal region that is very often involved in translocation processes.

Saccharomycodes ludwigii has seven chromosomes

Tetrad distributions for 108 different gene pairs in 1346 asci of 113 diploids heterozygous for various combinations of 24 genes in Saccharomycodes ludwigii were investigated. Tetratype tetrads occurred only rarely and the 24 genes tested were classified into seven linkage groups. Electrophoretic karyotypes of three independent strains of S'codes ludwigii showed seven bands of chromosome-sized DNA having molecular sizes of 0 center dot 8 to 2 center dot 3 Mb with strain-specific polymorphic chromosomal DNAs as determined based on their migration distances.

The yeast VRG4 gene is required for normal Golgi functions and defines a new family of related genes

Sodium vanadate is an effective agent for the enrichment of yeast mutants with defects in glycosylation steps that occur in the Golgi complex (Ballou, L., Hitzeman, R. A., Lewis, M. S., and Ballou, C. E. (1991) Proc. Natl. Acad. Sci. U. S. A. 88, 3209-3212). We isolated and screened vanadate-resistant glycosylation mutants in the budding yeast, Saccharomyces cerevisiae, to identify any that may be defective in the secretory pathway, since changes in normal glycosylation may reflect defects within the secretory pathway. We identified one such mutant, allelic to vrg4/van2, that is defective in processes that occur specifically in the Golgi complex. Protein secreted from vrg4 mutants lacks the outer chain glycosylation that is normally extended during passage through the Golgi. This mutant fails to retrieve soluble endoplasmic reticulum proteins from the Golgi and accumulates the Golgi-specific biosynthetic intermediate of the vacuolar protein, carboxypeptidase Y. Analyses of intracellular membranes by staining with the fluorescent lipophilic dye, DiOC6, and by electron microscopy reveals a dramatic alteration in the membrane morphology of vrg4 mutant cells. The VRG4 gene encodes a 36.9-kDa membrane protein that is essential for cell viability. A sequence homology search has identified five related genes, establishing that VRG4 is a founding member of a family of structurally similar genes. Taken together, these results suggest that the VRG4 gene plays an important role in regulating Golgi functions and in maintaining the normal organization of intracellular membranes.

Systematic mapping of autonomously replicating sequences on chromosome V of Saccharomyces cerevisiae using a novel strategy

We have developed a new procedure for easy and rapid identification of autonomously replicating sequences (ARSs) and have applied it to the analysis of chromosome V of Saccharomyces cerevisiae. The procedure makes use of the ordered lambda phage clone bank of this chromosome that we have constructed, and includes transposition of a mini-transposon and selection of transposon-containing derivatives, isolation of their DNA and circularization at their cos-ends, transformation of yeast cells with the circularized DNA, and scoring transformation frequency. The transposon used was derived from Tn5supF, contained the yeast LEU2 gene, and was placed, together with the hyperactive transposase gene, on a mini-F plasmid for stable maintenance in Escherichia coli K-12. Sixteen regions of chromosome V showing ARS activity were identified, of which 12 were newly found in this work. Thus, the procedure will be useful for systematic genomic scale analysis of ARSs in yeast and related organisms in which ordered clone banks have been established. The average distance between adjacent ARS-containing regions was approximately 40 kb. Two-dimensional gel electrophoretic analysis of chromosome replication indicated that one of the newly identified ARSs was functional as an actual in situ replication origin, at least under the conditions employed.

Construction of a YAC contig and an STS map spanning 3.6 megabase pairs in Xp22.1

We have constructed a 3.6 Mb sequence tagged sites (STS)-based yeast artificial chromosome (YAC) contig, consisting of 58 individual YAC clones, spanning the region PDHA1 and DXS451 on Xp22.1. In addition to establishing the order of PDHA1, ISPK-1, DXS2504, DXS1528 and the 13 known polymorphic loci as Xpter-PDHA1-DXS443-DXS3424-ISPK-1-DXS12 29-DXS2504-DXS1528-DXS365-DXS7101- DXS1683-DXS1052-DXS274-DXS92-DXS1226-DX S41-DXS989-DXS451-Xcen, we have also developed 35 novel STSs from YAC end clones. These results provide a high density of STS markers (approximately 1 per 70 kb). Furthermore, a detailed long-range restriction map of the contig has been constructed with rare-cutter enzymes and this has refined and verified the physical distances between markers inferred from YAC sizes and their STS content. The integration of the physical mapping data with previous genetic mapping data and the use of STSs and non-chimeric YAC clones reported here should facilitate the construction of a transcript map of this region and the positional cloning of disease genes in this portion of Xp22.1.

Electrophoretic karyotype of Dipodascus (Endomyces) magnusii: two main intraspecific chromosomal polymorphisms associated with the difference in total genome size

This study describes the karyotype of strain 270 of the yeast-like fungus Endomyces magnusii. It consists of 13 chromosomal DNA molecules, the size of which range between 1.2 and 5.7Mb producing a genome size of approximately 38Mb. By comparing the karyotype of six strains of E. magnusii, we revealed two main chromosome length polymorphisms (CLPs) associated with a pronounced difference in the total genome size (roughly 50%). Karyotype heterogeneity between two main CLPs was demonstrated by Southern analysis with three heterologous probes. The same species affiliation of six E. magnusii strains was confirmed by morphological and cytological studies, protein fingerprint comparisons, as well as restriction analysis of mitochondrial DNA and genomic Southern analysis.

Inactivation of transgenes in Phytophthora infestans is not associated with their deletion, methylation, or mutation

The mitotic and meiotic stabilities of transgenes were evaluated in the oomycete, Phytophthora infestans. Genes encoding beta-glucuronidase (GUS), neomycin phosphotransferase (NPT) and hygromycin phosphotransferase (HPT), fused to one of six promoters from P. infestans or other oomycetes, were usually stably expressed during continued asexual culture and transmitted to progeny. However, the activity of these genes became undetectable in many strains during asexual or sexual propagation. Over 33 months of growth, transgene expression stopped each month in 1-3% of the transformants. Silencing of the genes was not associated with their deletion, mutation, or hypermethylation. The conformation of the integrated sequences was similar in strains destined to continue or terminate expression of the transgenes. Expression of the genes was not associated with a loss of fitness during growth in vitro and in planta, which might otherwise have selected for silencing events.

Single-stranded DNA arising at telomeres in cdc13 mutants may constitute a specific signal for the RAD9 checkpoint

A cdc13 temperature-sensitive mutant of Saccharomyces cerevisiae arrests in the G2 phase of the cell cycle at the restrictive temperature as a result of DNA damage that activates the RAD9 checkpoint. The DNA lesions present after a failure of Cdc13p function appear to be located almost exclusively in telomere-proximal regions, on the basis of the profile of induced mitotic recombination. cdc13 rad9 cells dividing at the restrictive temperature contain single-stranded DNA corresponding to telomeric and telomere-proximal DNA sequences and eventually lose telomere-associated sequences. These results suggest that the CDC13 product functions in telomere metabolism, either in the replication of telomeric DNA or in protecting telomeres from the double-strand break repair system. Moreover, since cdc13 rad9 cells divide at a wild-type rate for several divisions at the restrictive temperature while cdc13 RAD9 cells arrest in G2, these results also suggest that single-stranded DNA may be a specific signal for the RAD9 checkpoint.

Genetic mapping and non-Mendelian segregation of mating type loci in the oomycete, Phytophthora infestans

DNA markers linked to the determinants of mating type in the oomycete, Phytophthora infestans, were identified and used to address the genetic basis of heterothallism in the normally diploid fungus. Thirteen loci linked to the A1 and A2 mating types were initially identified by bulked segregant analysis using random amplified polymorphic DNA markers (RAPDs) and subsequently scored in three crosses polymorphisms (SSCP), cleaved amplified polymorphisms (CAPS), or allele-specific polymerase chain reaction markers (AS-PCR). All DNA markers mapped to a single region, consistent with a single locus determining both mating types. Long-range restriction mapping also demonstrated the linkage of the markers to one region and delimited the mating type locus to a 100-kb region. The interval containing the mating type locus displayed non-Mendelian segregation as only two of the four expected genotypes were detected in progeny. This is consistent with a system of balance lethal loci near the mating type locus. A model for mating type determination is presented in which the balanced lethals exclude form progeny those with potentially conflicting combinations of mating type alleles, such as those simultaneously expressing A1 and A2 functions.

Improvement of chromosomal DNA extraction from different yeast species by analysis of single preparation steps

A modified procedure is proposed for chromosomal DNA extraction based on a cell-wall lytic enzyme never applied before in pulsed field gel electrophoresis. Protoplasting efficiency is retained under very challenging conditions for enzyme activity, such as those required for non-Saccharomyces yeasts often characterized by cell walls highly resistant to lysis.

A mitochondrial molecular marker, ori-rep-tra, for differentiation of yeast species

Yeasts exhibit various mechanisms for the inheritance of their mitochondrial genomes. Differences among these mechanisms are based on variations within nuclear as well as mitochondrial genetic elements. Here we report diagnostic differences in the presence of biologically active mitochondrial intergenic sequences, ori-reptra, among related yeasts in the genera Saccharomyces, Arxiozyma, Debaryomyces, Kluyveromyces, Pachytichospora, Torulaspora, and Zygosaccharomyces. A molecular probe containing ori-rep-tra can be employed specifically for the differentiation and identification of isolates belonging to the species complex Saccharomyces sensu stricto.

RTM1: a member of a new family of telomeric repeated genes in yeast

We have isolated a new yeast gene called RTM1 whose overexpression confers resistance to the toxicity of molasses. The RTM1 gene encodes a hydrophobic 34-kD protein that contains seven potential transmembrane-spanning segments. Analysis of a series of industrial strains shows that the sequence is present in multiple copies and in variable locations in the genome. RTM loci are always physically associated with SUC telomeric loci. The SUC-RTM sequences are located between X and Y' subtelomeric sequences at chromosome ends. Surprisingly RTM sequences are not detected in the laboratory strain X2180. The lack of this sequence is associated with the absence of any SUC telomeric gene previously described. This observation raises the question of the origin of this nonessential gene. The particular subtelomeric position might explain the SUC-RTM sequence amplification observed in the genome of yeasts used in industrial biomass or ethanol production with molasses as substrate. This SUC-RTM sequence dispersion seems to be a good example of genomic rearrangement playing a role in evolution and environmental adaptation in these industrial yeasts.

Sequence of a 9.8 kb segment of yeast chromosome II including the three genes of the MAL3 locus and three unidentified open reading frames

We report the DNA sequence of a segment located on the right arm of chromosome II from Saccharomyces cerevisiae S288C near the subtelomeric sequences. The sequence was determined using a random cloning strategy followed by an oligonucleotide-directed sequencing. The segment contains four non-overlapping open reading frames (ORFs) YBR297w, YBR298c, YBR299w and YBR301c, and two overlapping ones (YBR300c and YBR300w). Three of them--YBR297w, YBR298c and YBR299w--are the MAL3R (transcriptional regulatory protein), MAL3T (maltose permease) and MAL3S (maltase) genes of the MAL3 locus previously localized. The three other ORFs are unidentified. Another MAL locus (MALl) has been localized on chromosome VII. The Mal- phenotype of strain S288c cannot be explained by telomeric silencing.

Zinc- and arsenic-resistant strains of Thiobacillus ferrooxidans have increased copy numbers of chromosomal resistance genes

Pulsed-field gel electrophoresis (PFGE) was used to examine chromosomal DNA from various strains of Thiobacillus ferrooxidans: these were the reference strain VKM-458, strains isolated from different environments and pilot plants for processing gold-bearing concentrates, and strains experimentally adapted to high zinc and arsenic concentrations in growth medium. The restriction endonuclease Xbal digested T. ferrooxidans VKM-458 chromosomal DNA into a number of fragments sufficient for identification of their size and calculation of the size of the entire genome (2855/pm44 kb). Restriction fragment length polymorphism of the chromosomal DNA in various strains suggests the usefulness of this approach for analysis of the diversity of T. ferrooxidans strains and for the study of strain stability under conditions of industrial utilization. A comparison of Xbal-restriction patterns in parent strains and in strains with acquired enhanced resistance to zinc or arsenic revealed amplification of certain fragments in the resistant strains, i.e. a 98 kb fragment in strain TFZ and a 28 kb fragment in strain VKM-458As2. We suggest that the enhanced resistance to toxic metals in T. ferrooxidans is gained through increase of the copy number of resistance genes and enhanced synthesis of proteins involved in resistance.