Involvement of facultative apomixis in inheritance of EPSPS gene amplification in glyphosate-resistant Amaranthus palmeri

The inheritance of glyphosate resistance in two Amaranthus palmeri populations (R1 and R2) was examined in reciprocal crosses (RC) and second reciprocal crosses (2RC) between glyphosate-resistant (R) and -susceptible (S) parents of this dioecious species. R populations and Female-R × Male-S crosses contain higher 5-enolpyruvylshikimate-3-phosphate synthase (EPSPS) gene copy numbers than the S population. EPSPS expression, EPSPS enzyme activity, EPSPS protein quantity, and level of resistance to glyphosate correlated positively with genomic EPSPS relative copy number. Transfer of resistance was more influenced by the female than the male parent in spite of the fact that the multiple copies of EPSPS are amplified in the nuclear genome. This led us to hypothesize that this perplexing pattern of inheritance may result from apomictic seed production in A. palmeri. We confirmed that reproductively isolated R and S female plants produced seeds, indicating that A. palmeri can produce seeds both sexually and apomictically (facultative apomixis). This apomictic trait accounts for the low copy number inheritance in the Female-S × Male-R offsprings. Apomixis may also enhance the stability of the glyphosate resistance trait in the R populations in the absence of reproductive partners.     

No fitness cost of glyphosate resistance endowed by massive <Emphasis Type="Italic">EPSPS</Emphasis> gene amplification in <Emphasis Type="Italic">Amaranthus palmeri</Emphasis>

Amplification of the EPSPS gene has been previously identified as the glyphosate resistance mechanism in many populations of Amaranthus palmeri, a major weed pest in US agriculture. Here, we evaluate the effects of EPSPS gene amplification on both the level of glyphosate resistance and fitness cost of resistance. A. palmeri individuals resistant to glyphosate by expressing a wide range of EPSPS gene copy numbers were evaluated under competitive conditions in the presence or absence of glyphosate. Survival rates to glyphosate and fitness traits of plants under intra-specific competition were assessed. Plants with higher amplification of the EPSPS gene (53-fold) showed high levels of glyphosate resistance, whereas less amplification of the EPSPS gene (21-fold) endowed a lower level of glyphosate resistance. Without glyphosate but under competitive conditions, plants exhibiting up to 76-fold EPSPS gene amplification exhibited similar height, and biomass allocation to vegetative and reproductive organs, compared to glyphosate susceptible A. palmeri plants with no amplification of the EPSPS gene. Both the additive effects of EPSPS gene amplification on the level of glyphosate resistance and the lack of associated fitness costs are key factors contributing to EPSPS gene amplification as a widespread and important glyphosate resistance mechanism likely to become much more evident in weed plant species.     

Focus on Weed Control: Tandem Amplification of a Chromosomal Segment Harboring 5-Enolpyruvylshikimate-3-Phosphate Synthase Locus Confers Glyphosate Resistance in Kochia scoparia

Recent rapid evolution and spread of resistance to the most extensively used herbicide, glyphosate, is a major threat to global crop production. Genetic mechanisms by which weeds evolve resistance to herbicides largely determine the level of resistance and the rate of evolution of resistance. In a previous study, we determined that glyphosate resistance in Kochia scoparia is due to the amplification of the 5-Enolpyruvylshikimate-3-Phosphate Synthase (EPSPS) gene, the enzyme target of glyphosate. Here, we investigated the genomic organization of the amplified EPSPS copies using fluorescence in situ hybridization (FISH) and extended DNA fiber (Fiber FISH) on K. scoparia chromosomes. In both glyphosate-resistant K. scoparia populations tested (GR1 and GR2), FISH results displayed a single and prominent hybridization site of the EPSPS gene localized on the distal end of one pair of homologous metaphase chromosomes compared with a faint hybridization site in glyphosate-susceptible samples (GS1 and GS2). Fiber FISH displayed 10 copies of the EPSPS gene (approximately 5 kb) arranged in tandem configuration approximately 40 to 70 kb apart, with one copy in an inverted orientation in GR2. In agreement with FISH results, segregation of EPSPS copies followed single-locus inheritance in GR1 population. This is the first report of tandem target gene amplification conferring field-evolved herbicide resistance in weed populations.Glyphosate [N-(phosphonomethyl) Gly] is the most widely used agricultural pesticide globally (Duke and Powles, 2008). Originally, being a nonselective herbicide, its use was limited to vegetation management in noncrop areas; however, introduction of glyphosate-resistant (GR) crops in the late 1990s, coupled with their exceptional adoption, led to accelerated use totaling approximately 128 million ha worldwide in 2012 (James, 2012). GR crop technology has made a significant contribution to global agriculture and the environment, as it not only increased farm income by $32.2 billion (Brookes and Barfoot, 2013), but also moderated the negative environmental impacts of mechanical weed management practices (Gardner and Nelson, 2008; Bonny, 2011). Glyphosate offers a simple, effective, and economic weed management option in GR crops. In addition, it provides immense value in no-till crop production systems by enabling soil and moisture conservation. However, due to intensive glyphosate selection pressure, several weed populations globally have evolved resistance through a variety of mechanisms. Globally, herbicide resistance, in particular the recent proliferation of glyphosate resistance in weed species, is a major crop protection threat; nearly two dozen GR weed species have been reported in the last 15 years (Heap, 2014).Glyphosate, an aminophosphonic analog of the natural amino acid Gly, nonselectively inhibits 5-Enolpyruvylshikimate-3-Phosphate synthase (EPSPS) in plants, preventing the biosynthesis of the aromatic amino acids Phe, Tyr, and Trp (Steinrücken and Amrhein, 1980), resulting in the death of glyphosate-sensitive individuals. In plants, EPSPS is one of the key enzymes in the shikimate pathway (Herrmann and Weaver, 1999), and glyphosate inhibits EPSPS by binding to EPSPS-shikimate-3-P binary complex forming an EPSPS-shikimate-3-P-glyphosate complex (Alibhai and Stallings, 2001). Bradshaw et al. (1997) hypothesized against the likelihood of weeds evolving resistance to glyphosate, primarily because of its complex biochemical interactions in the shikimate pathway and also due to the absence of known glyphosate metabolism in plants. Nonetheless, several cases of glyphosate resistance, as a result of difference in glyphosate translocation (Preston and Wakelin, 2008) or mutations in the EPSPS, were confirmed (Baerson et al., 2002). More importantly, duplication/amplification of the EPSPS appears to be the basis for glyphosate resistance in several weeds (Sammons and Gaines, 2014). Here, we use duplication to refer to the formation of first repetition of a chromosomal segment and amplification to refer to increase in number of the repetitions (more than two repetitions of a chromosomal segment) under positive selection. The first case of EPSPS amplification as a basis for glyphosate resistance was reported in an Amaranthus palmeri population from GA (Gaines et al., 2010). In this A. palmeri population, there is a massive increase (>100-fold relative to glyphosate-susceptible [GS] plants) in EPSPS copies, and these copies are dispersed throughout the genome (Gaines et al., 2010).Field-evolved GR Kochia scoparia populations were first reported in western Kansas in 2007 (Heap, 2014). We previously determined that evolution of GR populations of K. scoparia in the U.S. Great Plains is also due to amplification of the EPSPS (A. Wiersma and P. Westra, unpublished data). Unlike in GR A. palmeri, we found relative EPSPS:acetolactate synthase (ALS) copies ranging from three to nine in GR K. scoparia populations. While it quickly became widespread in the region, its presence was reported in another five Great Plains states by 2013 (Heap, 2014). GR K. scoparia populations we tested were 3- to 11-times resistant (population level) to glyphosate compared with a GS population (Godar, 2014), and EPSPS expression positively correlated with genomic EPSPS copy number (A. Wiersma and P. Westra, unpublished data). Here, we reveal the genomic organization of the amplified EPSPS copies in two GR K. scoparia populations, an alternative mechanism of gene amplification to that reported in GR A. palmeri.     

Growth and Reproduction of Glyphosate-Resistant and Susceptible Populations of Kochia scoparia

Evolution of glyphosate-resistant kochia is a threat to no-till wheat-fallow and glyphosate-resistant (GR) cropping systems of the US Great Plains. The EPSPS (5-enol-pyruvylshikimate-3-phosphate synthase) gene amplification confers glyphosate resistance in the tested Kochia scoparia (L.) Schrad populations from Montana. Experiments were conducted in spring to fall 2014 (run 1) and summer 2014 to spring 2015 (run 2) to investigate the growth and reproductive traits of the GR vs. glyphosate-susceptible (SUS) populations of K. scoparia and to determine the relationship of EPSPS gene amplification with the level of glyphosate resistance. GR K. scoparia inbred lines (CHES01 and JOP01) exhibited 2 to 14 relative copies of the EPSPS gene compared with the SUS inbred line with only one copy. In the absence of glyphosate, no differences in growth and reproductive parameters were evident between the tested GR and SUS inbred lines, across an intraspecific competition gradient (1 to 170 plants m^-2). GR K. scoparia plants with 2 to 4 copies of the EPSPS gene survived the field-use rate (870 g ha^-1) of glyphosate, but failed to survive the 4,350 g ha^-1 rate of glyphosate (five-times the field-use rate). In contrast, GR plants with 5 to 14 EPSPS gene copies survived the 4,350 g ha^-1 of glyphosate. The results from this research indicate that GR K. scoparia with 5 or more EPSPS gene copies will most likely persist in field populations, irrespective of glyphosate selection pressure.     

Isolation and structural analysis of ribosomal protein genes in Xenopus laevis. Homology between sequences present in the gene and in several different messenger RNAs

The ribosomal protein genes are present in two to four copies per haploid genome of Xenopus laevis. Using cloned complementary DNA probes, we have isolated, from a genomic library of X. laevis, several clones containing genes for two different ribosomal proteins (L1 and L14). These genes contain intervening sequences. In the case of the L1 gene, the exons are 100 to 200 base-pairs long and the introns, on average, 400 base-pairs. Along the genomic fragments, two different classes of repetitive DNA are present: highly and middle repetitive DNA. Both are evolutionarily unstable as shown by hybridization to Xenopus tropicalis DNA. Several introns of the gene coding for protein L1 contain middle repetitive sequences. Hybridization and hybrid-released translation experiments have shown that sequences inside the two genes hybridize to several poly(A) messenger RNAs. Some of the products encoded by these mRNA have electrophoretic properties of ribosomal proteins.     

Investigations on Gene Copy Number, Introns and Chromosomal Arrangement of Genes Encoding the Fucoxanthin Chlorophyll a/c-Binding Proteins of the Centric Diatom Cyclotella cryptica

The gene arrangement, existence of introns and the number of gene copies of genes (fcps) encoding fucoxanthin chlorophyll a/c-binding proteins (Fcps) of the centric diatom Cyclotella cryptica were investigated by polymerase chain reaction (PCR), Southern blotting and denaturing gradient gel electrophoresis (DGGE) experiments. PCR-mediated amplification of the fcp genes using chromosomal DNA as template demonstrated the absence of introns within the amplified regions. Clustering of genes could not be demonstrated in these experiments. Digestion of chromosomal DNA of Cy. cryptica followed by Southern blotting and hybridization with specific fcp probes revealed minimum and maximum values of 12 and 20, respectively, for the gene copies. In addition, the DGGE technique confirmed and strengthened the results obtained from Southern blotting experiments as amplification of gene fragments from genomic DNA with different sets of specific primers revealed values of 21 and 23, for the minimum and maximum gene copy number, respectively.     

How a Replication Origin and Matrix Attachment Region Accelerate Gene Amplification under Replication Stress in Mammalian Cells

The gene amplification plays a critical role in the malignant transformation of mammalian cells. The most widespread method for amplifying a target gene in cell culture is the use of methotrexate (Mtx) treatment to amplify dihydrofolate reductase (Dhfr). Whereas, we found that a plasmid bearing both a mammalian origin of replication (initiation region; IR) and a matrix attachment region (MAR) was spontaneously amplified in mammalian cells. In this study, we attempted to uncover the underlying mechanism by which the IR/MAR sequence might accelerate Mtx induced Dhfr amplification. The plasmid containing the IR/MAR was extrachromosomally amplified, and then integrated at multiple chromosomal locations within individual cells, increasing the likelihood that the plasmid might be inserted into a chromosomal environment that permits high expression and further amplification. Efficient amplification of this plasmid alleviated the genotoxicity of Mtx. Clone-based cytogenetic and sequence analysis revealed that the plasmid was amplified in a chromosomal context by breakage-fusion-bridge cycles operating either at the plasmid repeat or at the flanking fragile site activated by Mtx. This mechanism explains how a circular molecule bearing IR/MAR sequences of chromosomal origin might be amplified under replication stress, and also provides insight into gene amplification in human cancer.     

Carbonic Anhydrase-Related Protein XI: Structure of the Gene in the Greater False Vampire Bat (Megaderma lyra) Compared with Human and Domestic Pig

Carbonic anhydrase-related protein XI (CA-RP XI) is a member of the α-carbonic anhydrase family (encoded by the gene CA-11), which has lost features of the active site required for enzymatic activity. Using PCR, we amplified CA-11 from genomic DNA of the bat Megaderma lyra. To elucidate the gene structure, we sequenced PCR products and compared their sequences with genomic and mRNA sequences known from human and domestic pig. We identified and sequenced eight introns in the bat CA-11. Five introns (introns 3–7) are located in identical or similar positions in other members of the vertebrate α-carbonic anhydrase gene family. Two 5′ introns and one 3′ intron are located in the regions of little or no sequence similarity with other members of the gene family. The low sequence similarity and additional introns suggest a separate evolutionary origin for the 5′ and 3′ portions of the CA-RP XI gene.     

Human U1 RNA pseudogenes may be generated by both DNA- and RNA-mediated mechanisms.

Analysis of cloned human genomic loci homologous to the small nuclear RNA U1 established that such sequences are abundant and dispersed in the human genome and that only a fraction represent bona fide genes. The majority of genomic loci bear defective gene copies, or pseudogenes, which contain scattered base mismatches and in some cases lack the sequence corresponding to the 3' end of U1 RNA. Although all of the U1 genes examined to date are flanked by essentially identical sequences and therefore appear to comprise a single multigene family, we present evidence for the existence of at least three structurally distinct classes of U1 pseudogenes. Class I pseudogenes had considerable flanking sequence homology with the U1 gene family and were probably derived from it by a DNA-mediated event such as gene duplication. In contrast, the U1 sequence in class II and III U1 pseudogenes was flanked by single-copy genomic sequences completely unrelated to those flanking the U1 gene family; in addition, short direct repeats flanked the class III but not the class II pseudogenes. We therefore propose that both class II and III U1 pseudogenes were generated by an RNA-mediated mechanism involving the insertion of U1 sequence information into a new chromosomal locus. We also noted that two other types of repetitive DNA sequences in eucaryotes, the Alu family in vertebrates and the ribosomal DNA insertions in Drosophila, bore a striking structural resemblance to the classes of U1 pseudogenes described here and may have been created by an RNA-mediated insertion event.     

Amplification of CFTR Exon 9 Sequences to Multiple Locations in the Human Genome

Cloning and characterization of the cystic fibrosis transmembrane conductance regulator (CFTR) gene led to the identification and isolation of cDNA and genomic sequences that cross-hybridized to the first nucleotide binding fold of CFTR. DNA sequence analysis of these clones showed that the cross-hybridizing sequences corresponded to CFTR exon 9 and its flanking introns, juxtapositioned with two segments of LINE1 sequences. The CFTR sequence appeared to have been transcribed from the opposite direction of the gene, reversely transcribed, and co-integrated with the L1 sequences into a chromosome location distinct from that of the CFTR locus. Based on hybridization intensity and complexity of the restriction fragments, it was estimated that there were at least 10 copies of the “amplified” CFTR exon 9 sequences in the human genome. Furthermore, when DNA segments adjacent to the insertion site were used in genomic DNA blot hybridization analysis, multiple copies were also detected. The overall similarity between these CFTR exon 9-related sequences suggested that they were derived from a single retrotransposition event and subsequent sequence amplification. The amplification unit appeared to be greater than 30 kb. Physical mapping studies includingin situhybridization to human metaphase chromosomes showed that multiple copies of these amplified sequences (with and without the CFTR exon 9 insertion) were dispersed throughout the genome. These findings provide insight into the structure and evolution of the human genome.     

Structure of the human gene encoding the invariant gamma-chain of class II histocompatibility antigens

The primary structures of a cDNA and the genomic DNA of a gene selectively expressed in chronic lymphocytic leukemia were determined. A computer search of the nucleotide sequence data bank identified this gene as the invariant gamma-chain associated with class II histocompatibility antigens. The invariant gamma-chain genomic sequence spans about 11 kilobases, with eight exons and seven introns. Three of the introns contain members of the Alu repeat family. A putative cap site and promoter sequence were identified at the 5' end of the gene. One or two copies of the gene is present in each haploid genome, and no evidence for amplification or polymorphism was obtained.     

Integration,amplification and expression of the Bacillus licheniformis α-amylase gene in Bacillus subtilis chromosome

We have introduced the α-amylase gene from Bacillus licheniformis (amy gene) in a non-replicative plasmid which can be conveniently integrated and amplified at a specific site of the B. subtilis chromosome. Although we were able to select spontaneous and stable gene amplification of about 20 integrated copies, the amylase secretion remained very low. A DNA fragment presenting a high promoter activity in B. subtilis was therefore inserted upstream from the amy gene coding sequence, leading to a significant increase of amylase production. However, the amplified structures obtained with this construction were found to contain no more than 12 copies of the amy gene and to be rather unstable when cells were grown under non-selective conditions.     

Heterogeneity of the glutathione transferase genes encoding enzymes responsible for insecticide degradation in the housefly

One of the four glutathione-S-transferases (GST) that is overproduced in the insecticide-resistant Cornell-R strain of the housefly (Musca domestica) produces an activity that degrades the insecticide dimethyl parathion and conjugates glutathione to lindane. In earlier work, it was shown that the resistant Cornell-R carries an amplification, probably a duplication, of one or more of its GST loci and that this amplification is directly related to resistance. Using polymerase chain reaction (PCR) amplification with genomic DNA, multiple copies of the gene encoding the parathion-degrading activity (called MdGst-3) were subcloned from both the ancestral, insecticide-susceptible strain BPM and from the insecticide-resistant Cornell-R. In BPM, three different MdGst-3 genes were identified while in Cornell-R, 12 different MdGst-3 sequences were found that, though closely related to ancestral genes, had diverged by a few nucleotides. This diversity in MdGst-3 genomic sequences in Cornell-R is reflected in the expressed sequences, as sampled through a cDNA bank. Population heterozygosity cannot account for these multiple GST genes. We suggest that selection for resistance to insecticides has resulted in not only amplification of the MdGst-3 genes but also in the divergence of sequence between the amplified copies. Received: 22 November 1995 / Accepted: 23 February 1996     

Rtt109 Prevents Hyper-Amplification of Ribosomal RNA Genes through Histone Modification in Budding Yeast

The genes encoding ribosomal RNA are the most abundant in the eukaryotic genome. They reside in tandem repetitive clusters, in some cases totaling hundreds of copies. Due to their repetitive structure, ribosomal RNA genes (rDNA) are easily lost by recombination events within the repeated cluster. We previously identified a unique gene amplification system driven by unequal sister-chromatid recombination during DNA replication. The system compensates for such copy number losses, thus maintaining proper copy number. Here, through a genome-wide screen for genes regulating rDNA copy number, we found that the rtt109 mutant exhibited a hyper-amplification phenotype (∼3 times greater than the wild-type level). RTT109 encodes an acetyl transferase that acetylates lysine 56 of histone H3 and which functions in replication-coupled nucleosome assembly. Relative to unequal sister-chromatid recombination-based amplification (∼1 copy/cell division), the rate of the hyper-amplification in the rtt109 mutant was extremely high (>100 copies/cell division). Cohesin dissociation that promotes unequal sister-chromatid recombination was not observed in this mutant. During hyper-amplification, production level of extra-chromosomal rDNA circles (ERC) by intra-chromosomal recombination in the rDNA was reduced. Interestingly, during amplification, a plasmid containing an rDNA unit integrated into the rDNA as a tandem array. These results support the idea that tandem DNA arrays are produced and incorporated through rolling-circle-type replication. We propose that, in the rtt109 mutant, rDNA hyper-amplification is caused by uncontrolled rolling-circle-type replication.     

Characterisation of the beta-tubulin gene of Cylicocyclus nassatus

mRNA and genomic DNA were isolated from adult Cylicocyclus nassatus, and the mRNA was reverse transcribed. The cDNA was PCR amplified using degenerate primers designed according to the alignment of the β-tubulin amino acid sequences of other species. To complete the coding sequence, the 3′ end was amplified with the 3′-RACE, and for amplification of the 5′ end the SL1-primer was used. The cDNA of the β-tubulin gene of C. nassatus spans 1429 bp and encodes a protein of 448 amino acids. Specific primers were developed from the cDNA sequence to amplify the genomic DNA sequence and to analyse the genomic organisation of the β-tubulin gene. The complete sequence of the genomic DNA of the β-tubulin gene of C. nassatus has a size of 2652 bp and is organised into nine exons and eight introns. The identities with the exons of the gru-1 β-tubulin gene of Haemonchus contortus range between 79% and 97%.     

Rapid Evolution of Recombinant Saccharomyces cerevisiae for Xylose Fermentation through Formation of Extra-chromosomal Circular DNA

Circular DNA elements are involved in genome plasticity, particularly of tandem repeats. However, amplifications of DNA segments in Saccharomyces cerevisiae reported so far involve pre-existing repetitive sequences such as ribosomal DNA, Ty elements and Long Terminal Repeats (LTRs). Here, we report the generation of an eccDNA, (extrachromosomal circular DNA element) in a region without any repetitive sequences during an adaptive evolution experiment. We performed whole genome sequence comparison between an efficient D-xylose fermenting yeast strain developed by metabolic and evolutionary engineering, and its parent industrial strain. We found that the heterologous gene XylA that had been inserted close to an ARS sequence in the parent strain has been amplified about 9 fold in both alleles of the chromosomal locus of the evolved strain compared to its parent. Analysis of the amplification process during the adaptive evolution revealed formation of a XylA-carrying eccDNA, pXI2-6, followed by chromosomal integration in tandem arrays over the course of the evolutionary adaptation. Formation of the eccDNA occurred in the absence of any repetitive DNA elements, probably using a micro-homology sequence of 8 nucleotides flanking the amplified sequence. We isolated the pXI2-6 eccDNA from an intermediate strain of the evolutionary adaptation process, sequenced it completely and showed that it confers high xylose fermentation capacity when it is transferred to a new strain. In this way, we have provided clear evidence that gene amplification can occur through generation of eccDNA without the presence of flanking repetitive sequences and can serve as a rapid means of adaptation to selection pressure.     

Abundant and species-specific DINE-1 transposable elements in 12 Drosophila genomes

Background

Miniature inverted-repeat transposable elements (MITEs) are non-autonomous DNA-mediated transposable elements (TEs) derived from autonomous TEs. Unlike in many plants or animals, MITEs and other types of DNA-mediated TEs were previously thought to be either rare or absent in Drosophila. Most other TE families in Drosophila exist at low or intermediate copy number (around < 100 per genome).

Results

We present evidence here that the dispersed repeat Drosophila interspersed element 1 (DINE-1; also named INE-1 and DNAREP1) is a highly abundant DNA-mediated TE containing inverted repeats found in all 12 sequenced Drosophila genomes. All DINE-1s share a similar sequence structure, but are more homogeneous within species than they are among species. The inferred phylogenetic relationship of the DINE-1 consensus sequence from each species is generally consistent with the known species phylogeny, suggesting vertical transmission as the major mechanism for DINE-1 propagation. Exceptions observed in D. willistoni and D. ananassae could be due to either horizontal transfer or reactivation of ancestral copies. Our analysis of pairwise percentage identity of DINE-1 copies within species suggests that the transpositional activity of DINE-1 is extremely dynamic, with some lineages showing evidence for recent transpositional bursts and other lineages appearing to have silenced their DINE-1s for long periods of time. We also find that all species have many DINE-1 insertions in introns and adjacent to protein-coding genes. Finally, we discuss our results in light of a recent proposal that DINE-1s belong to the Helitron family of TEs.

Conclusion

We find that all 12 Drosophila species with whole-genome sequence contain the high copy element DINE-1. Although all DINE-1s share a similar structure, species-specific variation in the distribution of average pairwise divergence suggests that DINE-1 has gone through multiple independent cycles of activation and suppression. DINE-1 also has had a significant impact on gene structure evolution.     

Investigations on gene copy number, introns and chromosomal arrangement of genes encoding the fucoxanthin chlorophyll a/c-binding proteins of the centric diatom Cyclotella cryptica

The gene arrangement, existence of introns and the number of gene copies of genes (fcps) encoding fucoxanthin chlorophyll a/c-binding proteins (Fcps) of the centric diatom Cyclotella cryptica were investigated by polymerase chain reaction (PCR), Southern blotting and denaturing gradient gel electrophoresis (DGGE) experiments. PCR-mediated amplification of the fcp genes using chromosomal DNA as template demonstrated the absence of introns within the amplified regions. Clustering of genes could not be demonstrated in these experiments. Digestion of chromosomal DNA of Cy. cryptica followed by Southern blotting and hybridization with specific fcp probes revealed minimum and maximum values of 12 and 20, respectively, for the gene copies. In addition, the DGGE technique confirmed and strengthened the results obtained from Southern blotting experiments as amplification of gene fragments from genomic DNA with different sets of specific primers revealed values of 21 and 23, for the minimum and maximum gene copy number, respectively.     

Disruption of the Hypoxanthine‐Guanine Phosphoribosyl‐Transferase Gene Caused by a Translocation in a Patient with Lesch‐Nyhan Syndrome

In this study, we have identified a novel mechanism of mutation involving translocation between the HPRT1 loci and other loci on the X chromosome. In HRT‐25's cDNA obtained from a patient with Lesch‐Nyhan syndrome, the upstream region of exon 3 was amplified, but the full‐length region was not amplified. The use of 3′ rapid amplification of cDNA ends polymerase chain reaction (3′RACE‐PCR) for HRT‐25 revealed part of intron 3 and an unknown sequence which have not identified the HPRT1 gene starting at the 3′ end of exon 3. We analyzed HPRT1 genomic DNA in order to confirm the mutation with the unknown sequence in the genomic DNA. Unknown sequence compared through BLAST analysis of human genome (NCBI; http://www.ncbi.nlm.nih.gov/BLAST/) showed that at least 0.5 to 0.6‐Mb telomeric to HPRT1 on chromosome Xq where located near LOC340581. This study provides the molecular basis for the involvement of genomic instability in germ cells.