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Query: UNIPROT:P06889 (Mol)
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The structural gene for alpha-aminoadipate reductase (LYS2) was isolated from a Saccharomyces cerevisiae genomic DNA library by complementation of a lys2 mutant. Both genetic and biochemical criteria confirmed that the DNA obtained corresponds to the LYS2 locus on chromosome II. Subcloning and deletion analysis showed that a functional LYS2 gene is contained within a 4.6-kilobase (kb) EcoRI-HindIII fragment of the original insert, and the slightly larger EcoRI-ClaI segment (4.8 kb) was used to construct a series of cloning vehicles, including integrating, episomal, replicative, and centromeric vectors. The cloned DNA was also used to generate a genomic deletion that lacks all LYS2 coding sequences on chromosome II. The level of the LYS2 transcript (4.2 kb) was 10-fold higher in cells grown on minimal medium than in cells grown on complete medium and was not repressed by the presence of lysine alone. Gene disruption, gene replacement, and promoter analysis of the major alpha-factor structural gene (MF alpha 1) were performed to illustrate the utility of the LYS2 gene for the genetic manipulation of yeasts. Because all fungi synthesize lysine via the alpha-aminoadipate pathway, the techniques developed here for using the S. cerevisiae LYS2 gene should be directly applicable to other fungal systems.
Mol Cell Biol 1986 Aug
PMID:Genetic manipulation of Saccharomyces cerevisiae by use of the LYS2 gene. 302 49

The telomeric sequence cloned from Plasmodium berghei (see M. Ponzi et al. (1985) EMBO J. 4, 2991-2995) was tested for species specificity. A telomeric and a subtelomeric fragment of the cloned insert served as separate, labelled probes on pulsed field gradient electrophoretical patterns and on genomic digests from the rodent malarias Plasmodium yoelii, Plasmodium chabaudi and from the human malaria Plasmodium falciparum. Results indicate that the subtelomeric fragment, abundantly represented in two chromosomes of P. berghei, is not present in the other DNA tested, while the telomeric fragment is present in every chromosome-sized molecule in all the species tested. The telomeric location in the other genomes of the sequences homologous to the P. berghei telomeric probe is confirmed by experiments with Bal 31 exonuclease. In all cases, the TaqI site appears to delimit the common telomeric portion.
Mol Biochem Parasitol 1986 Nov
PMID:Homologous telomeric sequences are present in different species of the genus Plasmodium. 302

To continue the systematic examination of the physical and genetic organization of an entire Saccharomyces cerevisiae chromosome, the DNA from the CEN1-ADE1-CDC15 region from chromosome I was isolated and characterized. Starting with the previously cloned ADE1 gene (J. C. Crowley and D. B. Kaback, J. Bacteriol. 159:413-417, 1984), a series of recombinant lambda bacteriophages containing 82 kilobases of contiguous DNA from chromosome I were obtained by overlap hybridization. The cloned sequences were mapped with restriction endonucleases and oriented with respect to the genetic map by determining the physical positions of the CDC15 gene and the centromeric DNA (CEN1). The CDC15 gene was located by isolating plasmids from a YCp50 S. cerevisiae genomic library that complemented the cdc15-1 mutation. S. cerevisiae sequences from these plasmids were found to be represented among those already obtained by overlap hybridization. The cdc15-1-complementing plasmids all shared only one intact transcribed region that was shown to contain the bona fide CDC15 gene by in vitro gene disruption and one-step replacement to delete the chromosomal copy of this gene. This deletion produced a recessive lethal phenotype that was also recessive to cdc15-1. CEN1 was located by finding a sequence from the appropriate part of the cloned region that stabilized the inheritance of autonomously replicating S. cerevisiae plasmid vectors. Finally, RNA blot hybridization and electron microscopy of R-loop-containing DNA were used to map transcribed regions in the 23 kilobases of DNA that went from CEN1 to CDC15. In addition to the transcribed regions corresponding to the ADE1 and ADC15 genes, this DNA contained five regions that gave rise to polyadenylated RNA, at least two regions complementary to 4S RNA species, and a Ty1 transposable element. Notably, a higher than average proportion of the DNA examined was transcribed into RNA.
Mol Cell Biol 1987 Jan
PMID:Molecular cloning of chromosome I DNA from Saccharomyces cerevisiae: isolation and analysis of the CEN1-ADE1-CDC15 region. 303 71

The mechanism controlling transcription at several telomeric expression sites for variable surface glycoprotein (VSG) genes in Trypanosoma brucei is unknown. Most VSG genes in expression sites have a region 5' of the gene lacking restriction enzyme sites. This 'barren region' is involved in recombination events which replace the VSG gene with a copy of a different, non-telomeric, VSG gene leading to a switch in VSG expression. Alterations in the barren region have been considered as possible modulators of expression of the adjacent VSG gene in other switching events where no gene replacement occurs. The expressed copy of the ILTat 1.3 VSG gene remains in its expression site, on a 160 kilobase (kb) chromosome, in trypanosomes not expressing the ILTat 1.3 VSG. Here we report the complete sequence of the barren region adjacent to this gene, determined both from trypanosomes expressing the gene and from those that are not. The sequence is identical whether or not the ILTat 1.3 VSG gene is expressed. This confirms that alterations in the barren region are not involved in modulation of expression of the gene, as suggested by restriction enzyme mapping. Sequence data from the 5' flanking region of a second telomeric gene copy on an 80 kb minichromosome, and from the ILTat 1.3 expression site after replacement of the ILTat 1.3 gene by another gene from a minichromosome, provide evidence that telomeric VSG genes on minichromosomes are also flanked by long repeat arrays, and that these arrays are involved in inter-telomeric gene replacements as well as replacements by non-telomeric genes.
Mol Biochem Parasitol 1987 Jun
PMID:The 5' flanking sequence of a Trypanosoma brucei variable surface glycoprotein gene. 304 Dec 10

Using as probes the subfragments of the telomeric sequence previously cloned by us from Plasmodium berghei DNA, we identified and cloned a 2.3 kb repeat, largely overlapping the original telomeric insert. Restriction mapping indicated that cloned inserts (2.3 kb in length) represented circularly permutated versions of a rather well conserved repeated element, at least in part organized in tandem. The 2.3 kb repeat family with a copy number of about 300 occupies about 4% of the whole genome. The copies are unevenly distributed among the chromosome-sized molecules revealed by pulsed field gradient electrophoresis. Complete sequence determination of the 2.3 kb element revealed that telomere-related motifs are present with a characteristic pattern in a set of tandem repeats, 27 bp long. The perfect conservation of these motifs as well as the pattern of chromosomal distribution suggest that we are dealing with a specialised structure subject to selective mechanisms of amplification and maintenance.
Mol Biochem Parasitol 1987 Jun
PMID:Telomeric motifs are present in a highly repetitive element in the Plasmodium berghei genome. 304 Dec 11

Another laboratory previously reported that the vast majority of mitotic recombinants in chromosome I disomics of Aspergillus nidulans arise from double exchange events involving the centromeric region and a far distal, possibly telomeric, region. This conclusion was based on the assumption that the camC gene is located in a position far distal to the centromere on the left arm of chromosome I. As a left arm location for camC distal to the centromere was possibly in conflict with mapping data obtained in the context of an unrelated project, camC was partially mapped along with three other previously unlocated chromosome I genes, davA, ornD and uapA. The data presented here indicate that camC is located in a position far distal to the centromere but on the right arm of chromosome I, a conclusion also supported by the previous data. The positioning of uapA and camC in far distal locations on the right arm of chromosome I indicates the existence of a vast, otherwise nearly unmapped region on this chromosome arm.
Mol Gen Genet 1988 Aug
PMID:Localisation of several chromosome I genes of Aspergillus nidulans: implications for mitotic recombination. 305 88

In mutants chl2, chl3, chl5, and chl6, which control mitotic chromosome transmission, the behaviour of the centromeric plasmids with various genes was analyzed. The main cause of chromosome instability in chl2, chl5, and chl6 is chromosome loss during cell division (1:0 segregation). The main cause of chromosome instability in chl3. is nondisjunction (2:0 segregation). According to this, the chl3 mutant, but not other chl's, cannot maintain the mini-chromosome with SUP11 gene. This gene causes cell death in high copy number. Chromosome nondisjunction in chl3 is also confirmed by the data on the mini-chromosome carrying CUP1 gene responsible for copper-resistance in yeast. The copper resistancy level in chl3 transformants is much higher than in chl5 or wild type transformants. Elevated copper resistance of chl3 transformants is caused by the transit accumulation of CUP1-carrying mini-chromosome in part of the cell population as a result of segregation mistakes upon cell divisions. Thus, the CHL3 gene is a new gene that controls the process of mitotic chromosome disjunction in yeast.
Mol Biol (Mosk)
PMID:[The causes of instability of artificial mini-chromosomes in yeasts mutant for chl genes]. 305 2

We have investigated two reactions that occur on telomeric sequences introduced into Saccharomyces cerevisiae cells by transformation. The elongation reaction added repeats of the yeast telomeric sequence C1-3A to telomeric sequences at the end of linear DNA molecules. The reaction worked on the Tetrahymena telomeric sequence C4A2 and also on the simple repeat CA. The reaction was orientation specific: it occurred only when the GT-rich strand ran 5' to 3' towards the end of the molecule. Telomere elongation occurred by non-template-directed DNA synthesis rather than any type of recombination with chromosomal telomeres, because C1-3A repeats could be added to unrelated DNA sequences between the CA-rich repeats and the terminus of the transforming DNA. The elongation reaction was very efficient, and we believe that it was responsible for maintaining an average telomere length despite incomplete replication by template-directed DNA polymerase. The resolution reaction processed a head-to-head inverted repeat of telomeric sequences into two new telomeres at a frequency of 10(-2) per cell division.
Mol Cell Biol 1988 Nov
PMID:Characterization of two telomeric DNA processing reactions in Saccharomyces cerevisiae. 306 64

We sequenced and compared the telomeric regions of linear rDNAs from vegetative macronuclei of several ciliates in the suborder Tetrahymenina. All telomeres consisted of tandemly repeated C4A2 sequences, including the 5' telomere of the 11 kb rDNA from developing macronuclei of Tetrahymena thermophila. Our sequence of the 11 kb 5' telomeric region shows that each one of a previously described pair of inverted repeats flanking the micronuclear rDNA (Yao et al., Mol. Cell. Biol. 5: 1260-1267, 1985) is 29 bp away from the positions to which telomeric C4A2 repeats are joined to the ends of excised 11 kb rDNA. In general we found that the macronuclear rDNA sequences adjacent to C4A2 repeats are not highly conserved. However, in the non-palindromic rDNA of Glaucoma, we identified a single copy of a conserved sequence, repeated in inverted orientation in Tetrahymena spp., which all form palindromic rDNAs. We propose that this sequence is required for a step in rDNA excision common to both Tetrahymena and Glaucoma.
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PMID:Conservation of sequences adjacent to the telomeric C4A2 repeats of ciliate macronuclear ribosomal RNA gene molecules. 309 84

The linear mitochondrial DNA (mtDNA) of Tetrahymena malaccensis has tandem 52-base-pair repeats at its telomeres. The mtDNA has a multimodal distribution of telomeres. Different groups in the distribution have different numbers of telomeric repeats. The standard deviation of the size of each end group is independent of the mean size of the end group. The two sides of the mtDNA have different multimodal distributions of repeats. Cloned cell lines have multimodal distributions of mtDNA telomeres distinct from that of the original cell line. The number of telomere end groups and the average size of the end groups change in an erratic fashion as the cells are passaged and do not reach a stable equilibrium distribution in 185 generations. We propose that the mean size of a telomere end group and the size distribution of an end group are independently regulated. The system controlling the average size of end groups may be defective in T. malaccensis, since a closely related species (T. thermophila) does not have a multimodal distribution of mtDNA telomeres. T. hyperangularis, which has different telomeric repeats on each side of its mtDNA, has a multimodal distribution of mtDNA telomeres on only one side, suggesting that the mechanism controlling the average number of repeats in an end group can be sequence specific. These mitochondrial telomeres provide a new example of the more general phenomenon of expansion and contraction of arrays of repeated sequences seen, for example, with simple-sequence "satellite" DNAs; however, the mitochondrial telomeres change on a very short time scale.
Mol Cell Biol 1988 Oct
PMID:Telomeric repeats of Tetrahymena malaccensis mitochondrial DNA: a multimodal distribution that fluctuates erratically during growth. 318 56


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