Extensive chromosome translocation in a clinical isolate showing the distinctive carbohydrate assimilation profile from a candidiasis patient

Variation of the electrophoretic karyotype is common among clinical strains of Candida albicans and chromosome translocation is considered one of the causes of karyotypic variation. Such chromosome translocations may be a mechanism to confer phenotypic diversity on the imperfect fungus C. albicans. A clinical strain, TCH23, from a vaginal candidiasis patient shows distinct carbohydrate assimilation profile, serotype B, no chlamydospore formation and an atypical karyotype (Asakura et al., 1991). To examine the taxonomic relationship among C. albicans, Candida dubliniensis and this strain, we sequenced the internal transcribed spacer 1 (ITS1) of nuclear ribosomal DNA. The ITS1 sequence of TCH23 was identical with that of C. albicans but not of C. dubliniensis. Thus, strain TCH23 was classified as a variant of C. albicans with an atypical phenotype. The chromosomal DNAs of this strain were resolved into 13 bands on pulse-field gel electrophoresis (PFGE). Using DNA probes located at or near both ends of each chromosome of C. albicans, we investigated the chromosome organization of this strain. Referring to the SfiI map of C. albicans 1006 (Chu et al., 1993), we found that seven chromosomal DNA bands in strain TCH23 were reciprocal chromosome translocations. One homologue from chromosomes 1, 2 and 6 and both homologues from chromosomes 4 and 7 participated in these events. One translocation product was composed of three SfiI fragments, one each from chromosomes 2, 4 and 7. We deduced the breakpoints of chromosome translocation from the physical map of this strain; between 1J and 1J1, between 2A and 2U, both ends of 4F2, between 6C and 6O and both ends of 7F.     

The ALS6 and ALS7 genes of Candida albicans

ALS genes of Candida albicans encode a family of cell-surface glycoproteins that are composed of an N-terminal domain, a central domain of a tandemly repeated motif, and a relatively variable C-terminal domain. Although several ALS genes have been characterized, more ALS-like sequences are present in the C. albicans genome. Two short DNA sequences with similarity to the 5' domains of known ALS genes were detected among data from the C. albicans genome sequencing project. Probes developed from unique regions of these sequences were used to screen a genomic library from which two full-length genes, designated ALS6 and ALS7, were cloned. ALS6 and ALS7 encode features similar to other genes in the ALS family and map to chromosome 3, a chromosome previously not known to encode ALS sequences. ALS6 and ALS7 are present in all C. albicans strains examined. Additional analysis suggested that some C. albicans strains have another ALS gene with a 5' domain similar to that of ALS6. Characterization of ALS7 revealed a novel tandemly repeated sequence within the C-terminal domain. Unlike other ALS family tandem repeats, the newly characterized ALS7 repeat does not appear to define additional genes in the ALS family. However, our data and information from the C. albicans genome sequencing project suggest that there are additional ALS genes remaining to be characterized.     

Sequence analysis of the right end of chromosome XV in Saccharomyces cerevisiae: An insight into the structural and functional significance of sub-telomeric repeat sequences

Approximately 3·9 kb of DNA, centromere proximal to the previously sequenced Y′ element at the right end of chromosome XV in Saccharomyces cerevisiae strain YP1, has been sequenced. A number of the known sub-telomeric repeat sequences were identified, including Y′, core X and STRs A, B. C and D. Several of these repeat elements contain potentially functional sequences. In addition, two other members of repeated gene families were identified. The first of these shows 61% and 60% DNA sequence identity to Enolases 1 and 2 respectively. The Enolase-like sequence appears to be species specific, with three copies being found in all strains of S. cerevisiae studied. The location of the three copies is the same for all strains. The second repeated sequence has homology with known open reading frames on chromosomes III, V and XI. There are five or six copies of this sequence in all S. cerevisiae and S. paradoxus strains studied and three in S. bayanus strains. The analysis of this region and comparison to sub-telomeric regions on other chromosomes gives some indication as to the potential functional and structural significance of sub-telomeric repeat sequences. In addition, these findings are consistent with the idea that sub-telomeric regions may be targets for unusual recombination events. The updated sequence has been deposited in the EMBL and GenBank databases under Accession Number M58718.     

High-frequency occurrence of chromosome translocation in a mutant strain of Candida albicans by a suppressor mutation of ploidy shift

Significant occurrence of high-ploidy cells is commonly observed among many Candida albicans strains. We isolated two isogenic strains, STN21 and STN22, each from a half sector of a colony obtained after mild UV-irradiation of a Arg(-) derivative of CBS5736. The two strains were different from each other in ploidy states and chromosome organization. Although cells of STN22 were homogeneous in size and had a single nucleus, high-ploidy cells, with either a single large nucleus or several nuclei, were present together with apparently normal cells with a single nucleus in the cell population of STN21. Flow cytometry showed that STN22 was a stable diploid; however, STN21 seemed to be the mixture of different ploidy states, including diploid and tetraploid. The phenotype of STN21 containing high-ploidy cells is referred to here as the Sps(-) phenotype (suppressor of ploidy shift). STN22 showed a typical electrophoretic karyotype similar to strain 1006 in C. albicans. However, an extra chromosomal band appeared in some clones of STN21 at high frequency. By assignment of several DNA probes, this extra chromosome was shown to be a translocation of the 7F-7G portion of chromosome 7 with the 470 kb DNA segment containing H SfiI fragment from chromosome 4. Thus, this extra chromosome is a hybrid of 4H and 7F-7G. Since the isogenic Sps(+) strain STN22 exhibited no extra chromosome bands, a correlation is suggested between the Sps(-) phenotype and the occurrence of chromosome translocations.     

Structural characterization of chromosome I size variants from a natural yeast strain

Many yeast strains isolated from the wild show karyotype instability during vegetative growth, with rearrangement rates of up to 10(-2) chromosomal changes per generation. Physical isolation and analysis of several chromosome I size variants of one of these strains revealed that they differed only in their subtelomeric regions, leaving the central 150 Kb unaltered. Fine mapping of these subtelomeric variable regions revealed gross alterations of two very similar loci, FLO1 and FLO9. These loci are located on the right and left arms, respectively, of chromosome I and encompass internal repetitive DNA sequences. Furthermore, some chromosome I variants lacking the FLO1 locus showed evidence of recombination at a DNA region on their right arm that is enriched in repeated sequences, including Ty LTRs. We propose that repetitive sequences in many subtelomeric regions in S. cerevisiae play a key role in karyotype hypervariability. As these regions encode several membrane-associated proteins, subtelomeric plasticity may allow rapid adaptive changes of the yeast strain to specific substrates. This pattern of semi-conservative chromosomal rearrangement may have profound implications, both in terms of evolution of wild strains and for biotechnological processes.     

A family of laboratory strains of Saccharomyces cerevisiae carry rearrangements involving chromosomes I and III

In order to study meiotic segregation of chromosome length polymorphism in yeast, we analysed the progeny of a cross involving two laboratory strains FL100trp and YNN295. Analysis of the parental strains led us to detect an important length polymorphism of chromosomes I and III in FL100trp. A reciprocal translocation involving 80 kb of the left arm of chromosome III and 45 kb of the right arm of chromosome I was shown to be the cause for the observed polymorphism in this strain. The characterization of the translocation breakpoints revealed the existence of a transposition hot-spot on chromosome I: the sequence of the translocation joints on chromosomes I and III suggests that the mechanism very likely involved homologous recombination between Ty2 transposable elements on each chromosome. Analysis of FL100, FL200 and FL100trp ura, which are related to FL100trp, shows that this reciprocal translocation is present in some of the strains of the FL series, whereas the parental strain FL100 does not carry the same rearrangement. We evidenced instead the duplication of 80 kb of chromosome III on chromosome I and a deletion of 45 kb of the right arm of chromosome I in this strain, indicating that secondary events might have taken place and that the strain currently named FL100 is not the common ancestor of the FL series. © 1998 John Wiley & Sons, Ltd.     

Genetic homology between Saccharomyces cerevisiae and its sibling species S. paradoxus and S. bayanus: electrophoretic karyotypes.

Chromosomal DNAs of many monosporic strains of the biological species Saccharomyces cerevisiae, S. paradoxus and S. bayanus were analysed using contour-clamped homogeneous electric field electrophoresis. Southern blot hybridization with eight cloned S. cerevisiae genes (ADC1, CUP1, GAL4, LEU2, rDNA, SUC2, TRP1 and URA3) assigned to different chromosomes was used to study homology and chromosomal location of the genes in the three sibling species. A comparative study of Ty1, Ty2 and telomere-associated Y' sequences having multiple chromosomal location was also done. Chromosome length polymorphism was found in cultured strains of S. cerevisiae. Wild S. cerevisiae and S. paradoxus strains yielded chromosome banding patterns very similar to each other. The karyotype pattern of S. bayanus was readily distinguishable from that of S. cerevisiae and S. paradoxus. Southern blot analysis revealed a low degree of homology between the S. cerevisiae genes studied and the corresponding S. paradoxus and S. bayanus genes. The number of chromosomes appears to be 16 in all three species.     

Common industrial sake yeast strains have three copies of the AQY1-ARR3 region of chromosome XVI in their genomes

Genomic analysis of industrial yeast strains is important for exploitation of their potential. We analysed the genomic structure of the most widely used sake yeast strain, Kyokai no. 7 (K7), by DNA microarray. Since the analysis suggested that the copy number of the AQY1-ARR3 region in the right arm of chromosome XVI was amplified, we performed Southern blot analysis using the AQY1 gene as a probe. The probe hybridized to three bands in the widely used sake strains derived from K7, but only to one band of 1.4 kb in the laboratory strains. Since the extra two bands were not observed in old sake strains, or in other industrial strains, the amplification of this region appeared to be specific for the widely used sake strains. The copy number of the AQY1-ARR3 region appeared to have increased by chromosomal translocation, since chromosomal Southern blot analysis revealed that the AQY1 probe hybridized to chromosomes IV and XIII, in addition to chromosome XVI, in which AQY1 of the laboratory strain is encoded. The chromosomal translocation was also confirmed by PCR analysis using primers that amplify the region containing the breakpoint. Cloning and sequencing of cosmids that encode the AQY1-ARR3 region revealed that this region is flanked by TG(1-3) repeats on the centromere-proximal side in chromosomes IV and XIII, suggesting that amplification of this region occurred by homologous recombination through TG(1-3) repeats. These results demonstrate the genomic characteristics of the modern widely used sake strains that discriminate them from other strains.     

Creating a Saccharomyces cerevisiae haploid strain having 21 chromosomes

Chromosome engineering techniques that can manipulate a large segment of chromosomal DNA are useful not only for studying the organization of eukaryotic genomes but also for the improvement of industrially important strains. Toward the development of techniques that can efficiently manipulate a large segment of chromosome, we have previously reported a one-step chromosome splitting technique in a haploid Saccharomyces cerevisiae cell, with which we could successfully split yeast chromosome 11, XIII, or XI into two halves to create a haploid strain having 17 chromosomes. We have now constructed chromosome splitting vectors bearing ADE2, HIS3, LEU2, or TRP1 marker, and by using these vectors, we could successively split yeast chromosomes to create a novel yeast haploid strain having up to 21 chromosomes. The specific growth rates of yeast strains carrying more than 16 chromosomes up to 21 did not differ significantly, suggesting that yeast cells can harbor more chromosomes than they do in their natural state, that is, 16 chromosomes, without serious effects on their growth.     

Karyotype of Penicillium nalgiovense and assignment of the penicillin biosynthetic genes to chromosome IV

The karyotype of Penicillium nalgiovense was determined by pulsed-field gel electrophoresis and compared to the karyotype of P. chrysogenum. Both species have four chromosomes, but they differ in the size of the chromosomes and in the overall size of the genome. The sizes of the P. nalgiovense chromosomes as determined by pulsed-field gel electrophoresis are: 9.1 Mb, 7.9 Mb, 5.4 Mb and 4.1 Mb which gives in summary a genome size of 26.5 Mb. This compares to 34.1 Mb for P. chrysogenum. The penicillin gene cluster was located by Southern hybridization on chromosome IV, the smallest chromosome of P. nalgiovense compared to chromosome 1, the largest chromosome of P. chrysogenum.     

具翼烟草(Nicotiana alata)核型、C带与rDNA染色体定位研究

采用去壁低渗法、BSG法和双色荧光原位杂交技术,分别开展了具翼烟草（Nicotiana alata）的核型分析、C显带与45S和5S rDNA染色体定位研究。4个具翼烟草收集系根尖细胞有丝分裂中期染色体平均核型为2n=2x=12m+6st,染色体臂比的变异幅度为1.14~4.22,平均臂比值为2.17,最长与最短染色体之比为2.16,属2B型。C带研究结果显示,具翼烟草中期染色体C带丰富,多态性良好,共显带25条,包括7条着丝粒带、15条端带和3条中间带。45S和5S rDNA染色体定位研究结果显示,具翼烟草根尖细胞有丝分裂中期染色体细胞相分别显示了3对45S rDNA和2对5S rDNA基因位点信号,45S rDNA基因位点分别位于I S、III S、V L上,2对5S rDNA基因位点分别位于I L、IV S上（字母L和S分别代表染色体长臂和短臂,罗马数字代表同源染色体序号）。在I号同源染色体上同时存在45S和5S rDNA基因位点。研究结果对烟草属系统起源、遗传进化以及遗传育种等领域的进一步研究具有重要的参考价值。      

Multiple aneuploidies in the oocytes of balanced translocation carriers: a preimplantation genetic diagnosis study using first polar body

Preimplantation genetic diagnosis (PGD) of first polar bodies (1PBs) has been used in carriers of balanced chromosomal reorganizations and also for aneuploidy screening. Although an acceptable number of normal or balanced embryos is usually obtained using PGD in translocation carriers, the pregnancy rate is disappointingly low. To determine whether aneuploidy of chromosomes not involved in the chromosome rearrangements could be the cause of the low pregnancy rates achieved, the present authors analysed the segregation products of three translocation carriers, t(8;13)(q24.1;q22) and two Robertsonian (Rob)(13;14), using 1PBs, and afterwards another eight chromosomes in the same 1PBs, for a total of 10 chromosomes in each 1PB, that is chromosomes 1, 8, 13, 14, 15, 16, 17, 18, 21, 22 and X. In the reciprocal translocation, chromosomes with different chromatids due to meiotic recombination were found. Only one out of nine 1PBs was normal for the reorganization products but no aneuploidies were found after PGD in this case. In the two balanced Rob(13;14), six out of 12 and four out of 11 1PBs were normal or balanced for the reorganization but only one oocyte was euploid for all the chromosomes analysed in each case; a single embryo transfer was made in both but no pregnancy was achieved. The incidence of aneuploidy for the chromosomes not involved in the Robertsonian translocations was extremely high (91.7% and 81.8%). Extra chromosomes were present in most of the aneuploid oocytes (81.8% and 90%). The reason for this increase could be the tendency to non-disjunction related to advanced maternal age combined with an interchromosomal effect resulting in the presence of synaptic errors in other chromosome pairs.     

X. Yeast sequencing reports. Sequence analysis of a 40·2 kb DNA fragment located near the left telomere of yeast chromosome X

We have sequenced on both strands a 40,257 bp fragment located near the left telomere of chromosome X of Saccharomyces cerevisiae. The sequenced segment contains 21 open reading frames (ORFs) at least 100 amino acids long. Five of the ORFs correspond to known amino acid sequences: two hypothetical proteins in the subtelomeric Y′ repeat region of 65·4 and 12·8 KDa, the cytochrome B pre-mRNA processing CBP1 protein, the mitochondrial nuclease NUC1 and the CRT1 protein. Of the 16 remaining ORFs, eight show highest homologies with the S. cerevisiae hexose transporters family (two ORFs), the yeast α-glucosidase (two ORFs), the yeast PEP1 precursor, the Escherichia coli galactoside O-acetyltransferase, the S. cerevisiae 137·7 KDa protein located in the Y′ region and a protein of unknown function of Schizosaccharomyces pombe. Finally, eight of the ORFs exhibit no significant similarity with any amino acid sequences described in data banks. DNA sequence comparison has revealed the presence of different repeated elements characteristic of yeast chromosome ends. Disruption studies have been performed on two ORFs encoding putative proteins of unknown function. The sequence has been entered in the EMBL Data Library under Accession Number Z34098.     

利用杀配子染色体2C诱导中国春-长穗偃麦草1E二体附加系染色体畸变的研究

偃麦草属具有许多优良的遗传性状,利用杀配子染色体诱导小麦-偃麦草的染色体易位,是创建小麦异源易位系、丰富小麦遗传资源的一个有效途径。杀配子染色体2C在单体附加时,可高效率地诱导染色体畸变,得到易位、缺失等畸变类型。本研究利用含有杀配子染色体的中国春-柱穗山羊草2C(Ae.Cylindrical2n=28CCDD)二体附加系与中国春-长穗偃麦草(E.elongate2n=14EE)1E二体附加系杂交。观察F1花粉母细胞减数分裂情况,发现存在到量的染色体异常行为。单价体数超过理论值,棒状二价体数明显增加,并出现一定频率的三价体和四价体,及大量的染色体断片、染色体桥和落后染色体、微核,并伴随发生多极分裂现象。经C-分带与荧光原位分子杂交鉴定83株杂交F2,共检测到5株易位、6株缺失。易位频率为6.02%,缺失率为7.22%,染色体畸变的总频率为13.24%。并对杀配子染色体的诱变机制及引起杂交后代结实率降低的原因进行了讨论。     

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.     

Cloning and chromosomal mapping of URA3 genes of Pichia farinosa and P. sorbitophila encoding orotidine-5'-phosphate decarboxylase

The PfURA3 gene, which encodes orotidine-5'-phosphate decarboxylase, of osmotolerant yeast Pichia farinosa NFRI 3,621, was cloned by complementation of the ura3 mutation of Saccharomyces cerevisiae. The nucleotide sequence of the PfURA3 gene and its deduced amino acid sequence indicated that the gene encodes a protein (PfUra3p) of 267 amino acids. Pulsed-field gel electrophoresis and subsequent Southern blot analysis showed that the genome of P. farinosa NFRI 3621 consisted of seven chromosomes, each approximately 1.1-2.2 Mb in size (11.8 Mb in total) and that PfURA3 was located on chromosome V. Pichia sorbitophila is considered as a synonym of P. farinosa. The genome of P. sorbitophila IFO10021 may consist of 12 chromosomes, each approximately 1.2-2.2 Mb in size. P. sorbitophila has two copies of URA3 genes, termed PsURA3 and PsURA30, which were located on chromosome VIII and III, respectively. The difference between PfURA3 and PsURA3 was only two amino acid substitutions, whereas that between PsURA3 and PsURA30 was six amino acid substitutions and the deletion of the C-terminal amino acid by a stop codon insertion. The sequences of PfURA3, PsURA3 and PsURA30 have been deposited in the DDBJ data library under Accession Nos AB071417, AB109042 and AB109043, respectively.     

Recovery of gene function by gene duplication in Saccharomyces cerevisiae

A prototroph revertant (Rev9) selected from an ATCase^? mutant of the URA2 gene containing three nonsense mutations was shown to contain two ATCase coding sequences. We cloned both ATCase coding areas to show that the duplicated locus (dl9) was the only functional one. Its size corresponded roughly to the second half of the URA2 wild-type gene. Sequence analysis of the 5′ end of dl9 indicated that this duplicated sequence was inserted within the intergenic region close to the MRS3 gene and was transcribed from an unknown promoter divergently from the MRS3 gene. The event leading to the revertant strain Rev9 included a rearrangement that increased the size of chromosome X by about 60 kb. In agreement with such a rearrangement, recombination was undetectable in the vicinity of the locus dl9. Genetic mapping confirms that the MRS3 gene is 2 cM distal to the URA2 gene on the right arm of chromosome X.     

Meiotic crossing-over in the regions of homology between homologous chromosomes V

Homologous chromosomes V of Saccharomyces cerevisiae and S. carlsbergensis virtually do not recombine in meiosis. Artificially created short regions of homology were found to induce meiotic crossing-over if they contained sequences located upstream of the S. carlsbergensis ILVI gene. Heterozygous restriction site markers were introduced within the 1.1 kb region of homology to monitor conversion events associated with the crossovers. In the presence of five heterozygosities, 85% of crossovers showed associated conversion. Crossovers with no detected conversion were found in the two largest (0.34 and 0.29 kb) intervals, into which the 1.1 kb region was divided by the introduction of the five markers, whereas the shortest conversion tracts observed did not exceed 0.26 kb. Several lines of evidence suggest that each crossover required a formation of heteroduplex DNA with the considerable minimal length of approximately 200-260 bp.     

Quantitative trait loci affecting calving traits in Danish Holstein cattle

The objectives of this study were 1) to detect quantitative trait loci (QTL) affecting direct and maternal calving traits at first calving in the Danish Holstein population, 2) to distinguish between pleiotropic and linked QTL for chromosome regions affecting more than one trait, and 3) to detect QTL affecting stillbirth and calving difficulties but not calf size that could be used in selection to improve calving performance. Progeny-tested sons (2,297) were genotyped for 356 microsatellites in 34 grandsire families on all 29 autosomes. A total of 27 significant QTL on 17 chromosomes were detected using a between-families linear regression model. For the direct calving traits, 4 QTL significantly affected calving difficulty, 5 QTL affected stillbirth, and 7 QTL affected calf size subjectively assessed by the farmer as a categorical trait. When the maternal components of the same traits were tested, there were significant effects of 3 QTL on calving difficulty, 6 QTL on stillbirth, and 2 QTL on calf size. The variance component mapping approach was used to estimate the relative posterior probability of linkage and pleiotropic models. The most probable model indicated a pleiotropic QTL on chromosome 12 and 25 and a linked QTL on chromosome 7 and 26. Chromosome 18 seemed to harbor a QTL with a pleiotropic effect on the direct calving traits and linked to maternal stillbirth. Markers on chromosomes 3, 4, 7, 10, 12, 18, 21, 24, 26, and 28 can be used to select new breeding candidates to produce daughters with more efficient calving performance.