Molecular cloning and genetic mapping of the DNA topoisomerase II gene of Saccharomyces cerevisiae

The structural gene for DNA topoisomerase II from the yeast Saccharomyces cerevisiae has been cloned. The clones were selected from a YEp13 plasmid bank of yeast DNA by complementing a temperature-sensitive mutation (top2-1) in the topoisomerase II gene, TOP2. Chromosomal integrants of the clone were derived by homologous recombination in strains lacking the 2 mu circle plasmid. Genetic analysis of these integrants indicates that we have cloned the TOP2 gene and not an extragenic suppressor. A YEp13-TOP2 hybrid plasmid integrant was used to localize the TOP2 gene to the left arm of chromosome XIV by the 2 mu circle-directed marker loss method. Results from standard meiotic mapping experiments indicate that TOP2 is about 16 centi-Morgans to the centromere proximal side of MET4. Northern blot analysis of TOP2 RNA isolated from a wild-type strain and from an rna2 mutant shows the RNA to be 4.5 kb long in both cases, thus indicating that the TOP2 gene has no large introns.     

Chromosome walking shows a highly homologous repetitive sequence present in all the centromere regions of fission yeast

By cloning centromere-linked genes followed by partial overlapping hybridization, we constructed a 210-kb map encompassing the centromere in chromosome II and a 60-kp map near the centromere of chromosome I in the fission yeast Schizosaccharomyces pombe which has three chromosomes. Integration of the cloned sequences into the chromosome and subsequent analyses of tetrads and dyads revealed an approximately 50 kb long domain located in the middle of the 210-kb map, tightly linked to the centromere and greatly reduced in meiotic recombination. This domain contained at least two classes of repetitive sequences. One, designated yn1, was specifically present in a particular chromosome and repeated three times in the 210-kb map of chromosome II. The other, designated dg, was located in all the centromere regions of three chromosomes. One (dgI) and two (dgIIa, dgIIb) copies of the dg were found in the maps of chromosomes I and II, respectively. The dgIIa and dgIIb were arranged with a 20-kb interval within the repetitive domain. In the centric region of chromosome II, 3-4 copies of the dg appeared to exist. By determining the nucleotide sequences of dgI and dgIIa, the dg was identified to be 3.8 kb long. The sequence homology was 99% between dgI and dgIIa. These extraordinarily homologous sequences seemed not to be transcribed into RNA nor to be encoding any protein. The larger part of the dg sequence was internally non-repetitious, a 600-bp region existed which consisted of stretches of several short repeating units. The structures in or surrounding the centromeres of S. pombe appear to be much more complex than those of the budding yeast Saccharomyces cerevisiae.     

Copy number control by a yeast centromere

Plasmids containing a cloned yeast (Saccharomyces cerevisiae) centromere (CEN3) in combination with a suitable DNA replication system are maintained in yeast at the low copy number typical of a chromosome. In composite plasmids containing CEN3 plus the yeast 2 mu plasmid, the CEN3 copy number control is dominant over the amplification system that normally drives the 2 mu plasmids to high copy number. The CEN3-2 mu composite plasmids are relatively stably maintained in yeast at a copy number of about one per haploid genome, and segregate through meiosis in a typical Mendelian pattern. Some of the CEN3-2 mu composite plasmids isolated from yeast contain deletions of variable size that remove the functional centromere, resulting in loss of the CEN3 control and reversion to high copy number. Formation of the CEN3 deletions requires the specialized recombination system (inverted repeat sequences and FLP gene) of the yeast 2 mu plasmid.     

Meiotic recombination within the centromere of a yeast chromosome

In order to examine the frequency of nonreciprocal recombination (gene conversion) within the centromere of the yeast chromosome, we constructed strains that contained heterozygous restriction sites in the conserved centromere sequences of chromosome III in addition to heterozygous markers flanking the centromere. One of these markers was the selectable URA3 gene, which was inserted less than one kb from the centromere. We found that meiotic conversion of the URA3 gene occurred at normal frequency (about 2% of unselected tetrads) and that more than one-third of these convertants coconverted the markers within the centromere. In addition, we observed tetrads in which conversion events extended through the centromere to include a marker on the opposite side from URA3. We conclude that meiotic conversion events occur within the centromere at rates similar to other genomic sequences.     

Characterization of recombination in the HLA class II region.

Studies of linkage disequilibrium across the HLA class II region have been useful in predicting where recombination is most likely to occur. The strong associations between genes within the 85-kb region from DQB1 to DRB1 are consistent with low frequency of recombination in this segment of DNA. Conversely, a lack of association between alleles of TAP1 and TAP2 (approximately 15 kb) has been observed, suggesting that recombination occurs here with relatively high frequency. Much of the HLA class II region has now been sequenced, providing the tools to undertake detailed analysis of recombination. Twenty-seven families containing one or two recombinant chromosomes within the 500-kb interval between the DPB1 and DRB1 genes were used to determine patterns of recombination across this region. SSCP analysis and microsatellite typing yielded identification of 127 novel polymorphic markers distributed throughout the class II region, allowing refinement of the site of crossover in 30 class II recombinant chromosomes. The three regions where recombination was observed most frequently are as follows: the 45-kb interval between HLA-DNA and RING3 (11 cases), the 50-kb interval between DQB3 and DQB1 (6 cases), and an 8.8-kb segment of the TAP2 gene (3 cases). Six of the 10 remaining recombinants await further characterization, pending identification of additional informative markers, while four recombinants were localized to other intervals (outliers). Analysis of association between markers flanking HLA-DNA to RING3 (45 kb), as well as TAP1 to TAP2 (15 kb), by use of independent CEPH haplotypes indicated little or no linkage disequilibrium, supporting the familial recombination data. A notable sequence motif located within a region associated with increased rates of recombination consisted of a (TGGA)12 tandem repeat within the TAP2 gene.     

Molecular mapping of a recombination hotspot located in the second intron of the human TAP2 locus.

Recombination across the HLA class II region is not randomly distributed, as indicated by both strong linkage disequilibrium within the 100 kb encompassing the DRB1-DQA1-DQB1 loci and complete equilibrium between TAP1 and TAP2, the closest variant sites of which are < 15 kb. In an attempt to explain these observations, 39 novel polymorphic markers in a region encompassing the TAP, LMP, and DOB genes were used to delineate the site of crossover in 11 class II recombinant chromosomes. SSCP demonstrated that two recombination events occurred within an 850-bp interval in the second intron of TAP2, which separates the variant sites of TAP1 and TAP2. These data indicate the presence of a recombination hotspot, the first to be identified from the analysis of familial transmission in the human major histocompatibility complex. The region of crossover was cloned and sequenced from one of the recombinants, further defining the crossover site to a 138-bp segment nested within the 850-bp region. This represents the most precisely defined region of recombination in the human genome.     

A novel acetylcholinesterase gene in mosquitoes codes for the insecticide target and is non-homologous to the ace gene in Drosophila

Acetylcholinesterase (AChE) is the target of two major insecticide families, organophosphates (OPs) and carbamates. AChE insensitivity is a frequent resistance mechanism in insects and responsible mutations in the ace gene were identified in two Diptera, Drosophila melanogaster and Musca domestica. However, for other insects, the ace gene cloned by homology with Drosophila does not code for the insensitive AChE in resistant individuals, indicating the existence of a second ace locus. We identified two AChE loci in the genome of Anopheles gambiae, one (ace-1) being a new locus and the other (ace-2) being homologous to the gene previously described in Drosophila. The gene ace-1 has no obvious homologue in the Drosophila genome and was found in 15 mosquito species investigated. In An. gambiae, ace-1 and ace-2 display 53% similarity at the amino acid level and an overall phylogeny indicates that they probably diverged before the differentiation of insects. Thus, both genes are likely to be present in the majority of insects and the absence of ace-1 in Drosophila is probably due to a secondary loss. In one mosquito (Culex pipiens), ace-1 was found to be tightly linked with insecticide resistance and probably encodes the AChE OP target. These results have important implications for the design of new insecticides, as the target AChE is thus encoded by distinct genes in different insect groups, even within the Diptera: ace-2 in at least the Drosophilidae and Muscidae and ace-1 in at least the Culicidae. Evolutionary scenarios leading to such a peculiar situation are discussed.     

Application of the Ovarian Teratoma Mapping Method in the Mouse

Murine ovarian teratomas were used to determine recombination percentages for gene-gene and centromere-gene intervals. Data were obtained utilizing a recombinant inbred strain, LTXBJ, and a number of newly developed LT/SvEi congenic strains.--Centromere-gene recombination was measured at 11.3 +/- 1.2% for the centromere of chromosome 7 - Gpi-1 interval and 15.8 +/- 2.4% for the centromere of chromosome 14 - Np-1 interval using the ovarian teratoma method. The centromere - Np-1 interval was measured at 26.5 +/- 3.6% using a standard backcross involving the Rb6Bnr Robertsonian translocation as a centromere marker.--To assess the accuracy of the ovarian teratoma mapping method, we compared the recombination frequency obtained for the Mpi-1-Mod-1 interval on chromosome 9 using the ovarian teratoma method to that obtained using a standard backcross. The recombination percentage was 22.9 +/- 5.4 using the ovarian teratoma method and 18.6 +/- 3.3 using the backcross method, indicating that the two methods produce equivalent estimates of recombination. In addition, for centromere-gene intervals known to be more than 30 cM in length, the ovarian teratoma method was consistent with classical recombination methods, yielding high recombination percentages. We conclude from these results that the ovarian teratoma mapping method is a reliable method for estimating recombination frequencies and the most accurate method available for estimating centromere-gene recombination frequency in the mouse.     

Complete nucleotide sequence of mouse immunoglobulin mu gene and comparison with other immunoglobulin heavy chain genes

We have determined the complete nucleotides sequence (2168 bases) of the immunoglobulin mu gene cloned from newborn mouse DNA. The cloned 13kb fragment contained the entire constant region gene sequence that is interrupted by three intervening sequences at the junction of domains as previously shown in the gamma 1, gamma 2 b and alpha genes. The amino acid sequence predicted by the nucleotide sequence agrees with that of the mu chain secreted by a myeloma MOPC104E except for 8 residues out of 448 residues. The homologous domains of the mu, gamma 1 and gamma 2b genes are more similar to each other than the different domains of the mu genes are. The result implicates that the class of the immunoglobulin heavy chain genes diverged after the heavy chain genes established the multi-domain structure. The short intervening sequences of the mu and gamma genes are more conserved than the coding sequences except for the COOH-terminal domains. The results implicate that the nucleotide sequence of the intervening sequence is under selective pressure, possibly to maintain a secondary structure of the nuclear RNA to be spliced.     

Analysis of recombination in the centromere region of mouse chromosome 7 using ovarian teratoma and backcross methods

Recombination near the centromere of mouse chromosome 7 was studied using data obtained from ovarian teratomas and backcrosses. The recombination percentage for the centromere-Gpi-1 (glucose phosphate isomerase-1) interval was 13.4 +/- 2.6 using the ovarian teratoma mapping method. In a backcross using the Robertsonian translocation Rb(7.18)9Lub (Rb9) as the centromeric marker, the centromere-Gpi-1 recombination percentage was 4.5 +/- 1.3, demonstrating that Rb9 suppresses recombination near the centromere of chromosome 7. The recombination percentage for the Gpi-1-Ldh-1 (lactate dehydrogenase-1) interval was estimated on the LT/Sv mouse genetic background to be 19.0 +/- 2.9 using the ovarian teratoma mapping method, a value comparable to the 15.5 +/- 4.8 reported earlier. On the same genetic background in a backcross segregating for Rb9, the Gpi-1-Ldh-1 recombination percentage was 7.1 +/- 1.6. Another backcross, without the Rb9 translocation but utilizing a different genetic background, produced a recombination percentage for the Gpi-1-Ldh-1 interval of 10.7 +/- 1.5, a value similar to that obtained in the Rb-containing cross. These results suggest that either the recombination suppression in the centromere area caused by Rb9 does not extend to the Gpi-1-Ldh-1 genetic region or, if it does, that the differing genetic backgrounds of these two crosses influence recombination. No recombinants were detected among 410 offspring produced from a backcross mating segregating for Ldh-1 and ru-2 (ruby-eye-2). Thus, the gene order of Ldh-1 and ru-2 on chromosome 7 remains uncertain.     

Variant (6;15) translocations in murine plasmacytomas involve a chromosome 15 locus at least 72 kb from the c-myc oncogene.

The variant (6;15) translocations in murine plasmacytomas join the myc oncogene-bearing band of chromosome 15 and the immunoglobulin kappa band of chromosome 6. We recently cloned a region from chromosome 15 linked to C kappa and have now used probes from that region to define the major locus of plasmacytoma variant translocations, which we denote pvt-1. In five of nine plasmacytomas we analysed, the 6;15 translocation resulted from reciprocal recombination between the C kappa locus and a 4.5-kb region of pvt-1. Moreover, nearby we located the region shown by others to have undergone a complex (15;12;6) translocation in plasmacytoma PC7183. All the chromosome 6 breakpoints fell between 1 and 3 kb 5' to C kappa but only two were near J kappa genes. Thus the J kappa -C kappa region appears to be a recombination 'hot spot' in lymphocytes, but the breaks are unlikely to be mediated via V/J recombination enzymes. Comparison of a cloned 108-kb region across pvt-1 and another of 52 kb across c-myc established that the pvt-1 breakpoints lie at least 72 kb from the c-myc promoters. Since c-myc is expressed at a substantial level, the 6;15 translocation apparently activates c-myc. Activation may occur directly, at a remarkable distance along the chromosome, or indirectly, via a putative pvt-1 gene product.     

Chromosomal localization of opioid peptide and receptor genes in the mouse

Opiate receptors are the primary targets for the drugs of abuse morphine and heroin. In this study, we completed the localization on mouse chromosomes of the genes encoding mu (Oprm) and kappa (Oprk) receptors, as well as the genes for the opioid propeptides proenkephalin (Penk) and prodynorphin (Pdyn). The genetic mapping was performed using a panel of DNA samples from an interspecific cross [C3H/HeJ-gld and (C3H/HeJ-gld x Mus spretus)Fi] that has been characterized for more than 800 markers throughout the genome. The genes are localized on mouse Chr 1 (Oprk, 10 cM from the centromere), Chr 2 (Pdyn, 75 cM from the centromere), Chr 4 (Penk, 1 cM from the centromere) and Chr 10 (Oprm, 10 cM from the centromere). Interestingly, the gene for the mu receptor is located in the same region as a Quantitative Trait Locus for high morphine consumption, thus raising the possibility of its direct role in drug abuse mechanisms.     

Cloning of human immunoglobulin mu gene and comparison with mouse mu gene

We have cloned a 12 kb DNA segment containing human mu gene and its flanking sequence from human fetal liver DNA library using mouse mu gene as a probe. Partial nucleotide sequence determination shows that the cloned DNA contains the sequence encoding human mu chain. This is the first constant region gene of the human heavy chain that is cloned. We have compared human and mouse mu genes by heteroduplex analysis and Southern blot hybridization. The results clearly show that not only the sequence encoding the CH4 domain but also the 5'-flanking (S mu) sequence is conserved between human and mouse mu genes, suggesting that the nucleotide sequence in the S mu region has an important biological function, presumably a recognition signal for the class switch recombinant as proposed previously.     

Acetylcholinesterase genes within the Diptera: takeover and loss in true flies

It has recently been reported that the synaptic acetylcholinesterase (AChE) in mosquitoes is encoded by the ace-1 gene, distinct and divergent from the ace-2 gene, which performs this function in Drosophila. This is an unprecedented situation within the Diptera order because both ace genes derive from an old duplication and are present in most insects and arthropods. Nevertheless, Drosophila possesses only the ace-2 gene. Thus, a secondary loss occurred during the evolution of Diptera, implying a vital function switch from one gene (ace-1) to the other (ace-2). We sampled 78 species, representing 50 families (27% of the Dipteran families) spread over all major subdivisions of the Diptera, and looked for ace-1 and ace-2 by systematic PCR screening to determine which taxonomic groups within the Diptera have this gene change. We show that this loss probably extends to all true flies (or Cyclorrhapha), a large monophyletic group of the Diptera. We also show that ace-2 plays a non-detectable role in the synaptic AChE in a lower Diptera species, suggesting that it has non-synaptic functions. A relative molecular evolution rate test showed that the intensity of purifying selection on ace-2 sequences is constant across the Diptera, irrespective of the presence or absence of ace-1, confirming the evolutionary importance of non-synaptic functions for this gene. We discuss the evolutionary scenarios for the takeover of ace-2 and the loss of ace-1, taking into account our limited knowledge of non-synaptic functions of ace genes and some specific adaptations of true flies.     

Phytophthora sojae avirulence genes Avr4 and Avr6 are located in a 24kb, recombination-rich region of genomic DNA

A cross between two different races (race 7xrace 25) of the soybean root and stem rot pathogen Phytophthora sojae was analyzed to characterize the genomic region flanking two cosegregating avirulence genes, Avr4 and Avr6. Both genes cosegregated in the ratio of 82:17 (avirulent:virulent) in an F(2) population, suggestive of a single locus controlling both phenotypes. A chromosome walk was commenced from RAPD marker OPE7.1C, 2.0cM distant from the Avr4/6 locus. Three overlapping cosmids were isolated which included genetic markers that flank the Avr4/6 locus. The chromosome walk spanned a physical distance of 67kb which represented a genetic map distance of 22.3cM, an average recombination frequency of 3.0kb/cM and 11.7-fold greater than the predicted average recombination frequency of 35.3kb/cM for the entire P. sojae genome. Six genes (cDNA clones) expressed from the Avr4/6 genomic region encompassed by the cosmid contig were identified. Single nucleotide polymorphisms and restriction fragment length polymorphisms showed these six genes were closely linked to the Avr4/6 locus. Physical mapping of the cDNA clones within the cosmid contig made it possible to deduce the precise linkage order of the cDNAs. None of the six cDNA clones appear to be candidates for Avr4/6. We conclude that two of these cDNA clones flank a physical region of approximately 24kb and 4.3cM that appears to include the Avr4/6 locus.     

Human U1 small nuclear RNA genes: extensive conservation of flanking sequences suggests cycles of gene amplification and transposition.

The DNA immediately flanking the 164-base-pair U1 RNA coding region is highly conserved among the approximately 30 human U1 genes. The U1 multigene family also contains many U1 pseudogenes (designated class I) with striking although imperfect flanking homology to the true U1 genes. Using cosmid vectors, we now have cloned, characterized, and partially sequenced three 35-kilobase (kb) regions of the human genome spanning U1 homologies. Two clones contain one true U1 gene each, and the third bears two class I pseudogenes 9 kb apart in the opposite orientation. We show by genomic blotting and by direct DNA sequence determination that the conserved sequences surrounding U1 genes are much more extensive than previously estimated: nearly perfect sequence homology between many true U1 genes extends for at least 24 kb upstream and at least 20 kb downstream from the U1 coding region. In addition, the sequences of the two new pseudogenes provide evidence that class I U1 pseudogenes are more closely related to each other than to true genes. Finally, it is demonstrated elsewhere (Lindgren et al., Mol. Cell. Biol. 5:2190-2196, 1985) that both true U1 genes and class I U1 pseudogenes map to chromosome 1, but in separate clusters located far apart on opposite sides of the centromere. Taken together, these results suggest a model for the evolution of the U1 multigene family. We speculate that the contemporary family of true U1 genes was derived from a more ancient family of U1 genes (now class I U1 pseudogenes) by gene amplification and transposition. Gene amplification provides the simplest explanation for the clustering of both U1 genes and class I pseudogenes and for the conservation of at least 44 kb of DNA flanking the U1 coding region in a large fraction of the 30 true U1 genes.