Nucleotide sequence of the rat gamma-crystallin gene region and comparison with an orthologous human region

The sequences of a 51-kb region containing the cluster of five rat gamma-crystallin-coding genes (CRYG) and of a 7-kb region surrounding the sixth rat CRYG gene were determined. Approximately 78% of the total sequence represents intergenic DNA. We also sequenced 22 kb of DNA from the human CRYG gene cluster. All CRYG genes are associated with CpG-rich regions. The sequence similarity between the human and rat gene regions drops sharply (to 65%) in intronic and 3'-flanking regions but decreases only gradually in the 5'-flanking region. Highly conserved regions (greater than 80%) are found as far upstream as 1.5 kb. Overall intergenic distances are conserved. The human region contains much more repetitive DNA (24% vs. 10%) but less simple-sequence (sps) DNA (0.7% vs. 4%) than the rat region. Almost all repeats and spsDNA elements are located in the intergenic region. The location of repetitive and spsDNA differs between the orthologous regions and these elements were probably inserted after the evolutionary separation of rat and man. The Alu repeats in man and the B3 repeats in the rat are close copies of their respective consensus sequences and bordered by virtually perfect repeats. In contrast, the B1 and B2 repeats in the rat have diverged considerably from the consensus sequence and the surrounding direct repeats are usually imperfect. Thus the dispersion of the B1 and B2 repeats in the rat probably preceded that of the B3 repeats. Within the rat genomic region the spacing of Z-DNA elements is surprisingly regular, they are located about 12 kb apart. A search for putative matrix-associated regions suggests that the rat CRYG gene cluster is organized into two chromosomal domains.     

Alpha-galactosidase A gene rearrangements causing Fabry disease. Identification of short direct repeats at breakpoints in an Alu-rich gene

Fabry disease, an inborn error of glycosphingolipid catabolism, results from mutations in the X-linked gene encoding the lysosomal enzyme, alpha-galactosidase A (EC 3.2.1.22). Six alpha-galactosidase A gene rearrangements that cause Fabry disease were investigated to assess the role of Alu repetitive elements and short direct and/or inverted repeats in the generation of these germinal mutations. The breakpoints of five partial gene deletions and one partial gene duplication were determined by either cloning and sequencing the mutant gene from an affected hemizygote, or by polymerase chain reaction amplifying and sequencing the genomic region containing the novel junction. Although the alpha-galactosidase A gene contains 12 Alu repetitive elements (representing approximately 30% of the 12-kilobase (kb) gene or approximately 1 Alu/1.0 kb), only one deletion resulted from an Alu-Alu recombination. The remaining five rearrangements involved illegitimate recombinational events between short direct repeats of 2 to 6 base pairs (bp) at the deletion or duplication breakpoints. Of these rearrangements, one had a 3' short direct repeat within an Alu element, while another was unusual having two deletions of 1.7 kb and 14 bp separated by a 151-bp inverted sequence. These findings suggested that slipped mispairing or intrachromosomal exchanges involving short direct repeats were responsible for the generation of most of these gene rearrangements. There were no inverted repeat sequences or alternating purine-pyrimidine regions which may have predisposed the gene to these rearrangements. Intriguingly, the tetranucleotide CCAG and the trinucleotide CAG (or their respective complements, CTGG and CTG) occurred within or adjacent to the direct repeats at the 5' breakpoints in three and four of the five alpha-galactosidase A gene rearrangements, respectively, suggesting a possible functional role in these illegitimate recombinational events. These studies indicate that short direct repeats are important in the formation of gene rearrangements, even in human genes like alpha-galactosidase A that are rich in Alu repetitive elements.     

Three independent insertions of retrovirus-like sequences in the haptoglobin gene cluster of primates

The human haptoglobin two-gene cluster (HP-HPR) contains two retrovirus-like elements. One (RTVL-Ia) is in the first intron of the HPR gene, and the second (RTVL-Ic) is at the 3'-end of the gene cluster. The chimpanzee three-gene cluster (HP-HPR-HPP) contains an additional, third copy (RTVL-Ib) in the intergenic region between HPR and HPP. RTVL-Ia and RTVL-Ib are essentially full size and have the general structure, 5'-LTR-gag-pol-env-3'-LTR, while RTVL-Ic lacks about one-third of its 5'-part. Although none of the elements has retained long open reading frames, we could detect stretches having amino acids identical to various parts of Moloney murine leukemia virus (Mo-MuLV) proteins. We conclude that the RTVL-I elements were derived from a virus very similar in structure to Mo-MuLV. The DNA sequences surrounding the insertion points of the three RTVL-I elements are not alike and allow the inference that they integrated into the haptoglobin gene cluster independently at some time after the initial formation of the triplicated gene cluster in primates. Comparison of the nucleotide sequences of the three elements leads to the hypothesis that foreign DNA introduced into the genome can initially accumulate mutations more rapidly than the genomic sequences surrounding it.     

On the role of repeated sequences 5' to variant surface glycoprotein genes in African trypanosomes

In African trypanosomes, the DNA region situated upstream from all active and some silent variant surface glycoprotein genes (VSG genes) has a repetitive structure. This region is composed of a variable number of tandem repeats of an A + T-rich sequence which lacks the recognition sites for most commonly used restriction endonucleases, and is thus called 'barren region'. The length of the barren regions varies in different trypanosome variants from 0.2 to many kb. We have characterized the barren region upstream from the active VSG gene in two independent Trypanosoma equiperdum variants expressing the same VSG gene in the same expression site. To analyse the junction point between the expression site and the inserted gene, these two barren regions were cloned and sequenced. The longer barren region contains 14 repeats and the other contains two repeats. In both cases the junction point has been shown to lie within a repeat but different repeats were used in each case. These results argue that the repeats are important for the insertion of the duplicated-transposed gene into the expression site and that any repeat can be used.     

A chicken middle-repetitive DNA sequence which shares homology with mammalian ubiquitous repeats.

We have identified and sequenced two members of a chicken middle repetitive DNA sequence family. By reassociation kinetics, members of this family (termed CRl) are estimated to be present in 1500-7000 copies per chicken haploid genome. The first family member sequenced (CRlUla) is located approximately 2 kb upstream from the previously cloned chicken Ul RNA gene. The second CRl sequence (CRl)Va) is located approximately 12 kb downstream from the 3' end of the chicken ovalbumin gene. The region of homology between these two sequences extends over a region of approximately 160 base pairs. In each case, the 160 base pair region is flanked by imperfect, but homologous, short direct repeats 10-15 base pairs in length. When the CRl sequences are compared with mammalian ubiquitous interspersed repetitive DNA sequences (human Alu and Mouse Bl families), several regions of extensive homology are evident. In addition, the short nucleotide sequence CAGCCTGG which is completely conserved in ubiquitous repetitive sequence families from several mammalian species is also conserved at a homologous position in the chicken sequences. These data imply that at least certain aspects of the sequence and structure of these interspersed repeats must predate the avian-mammalian divergence. It seems that the CRl family may possibly represent an avian counterpart of the mammalian ubiquitous repeats.     

Linkage disequilibrium among RFLPs at the insulin-receptor locus despite intervening Alu repeat sequences.

Multiple mutations of the insulin receptor (INSR) gene have been identified in individuals with extreme insulin resistance. These mutations have included recombination events between Alu repeat units in the tyrosine kinase-encoding beta-chain region of the gene. To evaluate the influence of Alu and dinucleotide repetitive sequences on recombination events within the insulin receptor gene, I examined the degree of linkage disequilibrium between RFLP pairs spanning the gene. I established 228 independent haplotypes for seven RFLPs (two each for PstI, RsaI, and SstI and one for MspI and 172 independent haplotypes which included an additional RFLP with BglII) from 19 pedigrees. These RFLPs span > 130 kb of this gene, and my colleagues and I previously demonstrated that multiple Alu sequences separate RFLP pairs. Observed haplotype frequencies deviated significantly from those predicted. Pairwise analysis of RFLP showed high levels of linkage disequilibrium among RFLP in the beta-chain region of the insulin receptor, but not between alpha-chain RFLPs and those of the beta-chain. Disequilibrium was present among beta-chain RFLPs, despite separation by one or more Alu repeat sequences. The very strong linkage disequilibrium which was present in sizable regions of the INSR gene despite the presence of both Alu and microsatellite repeats suggested that these regions do not have a major impact on recombinations at this locus.     

Three transposed elements in the intron of a human VK immunoglobulin gene.

Two gene segments coding for the variable region of human immunoglobulin light chains of the kappa type (VK genes, ref. 2) were found to have unusual structures. The two genes which are called A6 and A22 are located in duplicated gene clusters. Their restriction maps are very similar. About 4 kb of the A22 gene region were sequenced. It turned out that the intron contains an insert with the characteristics of a transposed element. The inserted DNA of 1.2 kb length contains imperfect direct and inverted repeats at its ends; at the insertion site a duplication of five nucleotides was found. Within the inserted DNA one copy each of an Alu element and of the simple sequence motif (T-G)17 were identified. Also these two repetitive sequences are themselves flanked by short direct repeats. The major inserted DNA has no significant homology to published human nucleic acid sequences. The whole structure is interpreted best by assuming a sequential insertion of the three elements. The coding region of the VK gene itself has several mutations which by themselves would render it a pseudogene; we assume that the insertion event(s) occurred prior to the mutations. According to mapping and hybridization data A6 is very similar to A22.     

Human ribosomal RNA gene spacer sequences are found interspersed elsewhere in the genome

A cloned EcoRI fragment containing human 18 S rRNA gene sequences was used to screen a gene library to obtain a set of 8 overlapping cloned DNA segments extending into the non-transcribed spacer region of the human ribosomal RNA gene cluster. 19.4 kb of the approx. 43-kb rDNA repeat was obtained in cloned form and mapped with restriction endonucleases. None of the clones obtained extended into 28 S rRNA sequences. A 7-kb region of non-transcribed spacer DNA shared in common between five independent clones was subjected to comparative restriction digests. It was estimated that sequences among the five different spacer isolated varied by not more than 1.0%, if all the observed differences are assumed due to point mutation. HaeII-restriction fragments from within this same 7-kb region contain sequences carried not only within the tandem repeats of the gene cluster but interspersed elsewhere in the genome. Some of these sequences correspond to the Alu family of highly repeated interspersed sequences.     

Mechanisms of tandem duplication in the Duchenne muscular dystrophy gene include both homologous and nonhomologous intrachromosomal recombination.

Three tandem duplications were previously identified in patients with Duchenne muscular dystrophy and were shown in each case to have a subset of dystrophin gene exons duplicated. The origin of these duplications was traced to the single X chromosome of the maternal grandfathers, suggesting that an intrachromosomal event (unequal sister chromatid exchange) was involved in the formation of these duplications. In the present study, a DNA segment containing the duplication junction and the normal DNA that corresponds to both ends of the duplicated region have been cloned. Subsequent mapping studies confirmed the tandem arrangement (head to tail) of these duplications and revealed their sizes to be 130 kb, approximately 300 kb, and 35-80 kb, respectively. Sequence analysis of the duplication junctions showed that one duplication was due to homologous recombination between two repetitive elements (Alu sequences) and the other two were due to recombination between unrelated nonhomologous sequences. In the latter cases, the preferred cleavage sites of the eukaryotic type I and II DNA topoisomerases were found at the junctions of these duplications, suggesting a possible role of these enzymes in the chromatid exchange events. This study provides the first insight into the molecular basis of gene duplications formed through unequal sister chromatid exchange in humans.     

Nonrandom Distribution of Chloroplast Recombination Events in Chlamydomonas Reinhardtii: Evidence for a Hotspot and an Adjacent Cold Region

Intermolecular recombination of Chlamydomonas chloroplast genes has been analyzed in sexual crosses and following biolistic transformation. The pattern and position of specific exchange events within 15 kb of the 22-kb inverted repeat have been mapped with respect to known restriction fragment length polymorphism markers that distinguish the chloroplast genomes of the interfertile species Chlamydomonas reinhardtii and Chlamydomonas smithii. Recombinant progeny were selected from two- and three-factor crosses involving point mutations conferring herbicide (dr) and antibiotic resistance (er and spr) in the psbA, 23S and 16S ribosomal RNA genes, respectively. Exchange events were not randomly distributed over the 15-kb region, but were found to occur preferentially in a 0.7-kb sequence spanning the 3' end of the psbA gene and were much less common in an adjacent region of ca. 2.0 kb. These findings are corroborated by data showing that the dr mutation is unlinked genetically (3% recombination/kb) to the er and spr rRNA mutations, which are themselves linked and show ca. 1% recombination/kb. This discrepancy is significant since the dr-er and er-spr intervals are about the same length (ca. 7 kb). During chloroplast transformation, the 0.7-kb recombination hotspot also functions as a preferential site for exchange events leading to the integration of donor psbA gene sequences. The 0.7-kb hotspot region contains four classes of 18-37-bp direct repeats also found in other intergenic regions, but no open reading frame. Using deletion constructs in a chloroplast transformation assay, the hotspot was localized to a 500-bp region that lacks most of these repeats, which suggests that the repeats themselves are not responsible for the increased recombination frequency. Within this region, a 400-bp sequence is highly conserved between the chloroplast genomes of C. reinhardtii and C. smithii and includes several structural motifs characteristic of recombination hotspots in other systems.     

Transcription map of the 13q14 region, frequently deleted in B-cell chronic lymphocytic leukemia patients]

Deletions in the region located between the STS markers D13S1168 and D13S25 on chromosome 13 are the most frequent genomic changes in patients with B-cell chronic lymphocytic leukemia (B-CLL). After sequencing of this region, two novel candidate genes were identified: C13orf1 (chromosome 13 open reading frame 1) and PLCC (putative large CLL candidate). Analysis of the repeat distribution revealed two subregions differing in composition of repetitious DNA and gene organization. The interval D13S1168-D13S319 contains 131 Alu repeats accounting for 24.8% of its length, whereas the interval GCT16C05-D13S25, which is no more than 180 kb away from the former one is extremely poor in Alu repeats (4.1% of the total length). Both intervals contain almost the same amount of the LINE-type repeats L1 and L2 (20.3 and 21.24%, respectively). In the chromosomal region studied, 29 Alu repeats were found to belong to the evolutionary young subfamily Y, which is still capable of amplifying. A considerable proportion of repeats of this type with similar nucleotide sequences may contribute to the recombinational activity of the chromosomal region 13q14.3, which is responsible for its rearrangements in some tumors in humans.     

Analysis of the regions flanking the human insulin gene and sequence of an Alu family member.

The regions around the human insulin gene have been studied by heteroduplex, hybridization and sequence analysis. These studies indicated that there is a region of heterogeneous length located approximately 700 bp before the 5' end of the gene; and that the 19 kb of cloned DNA which includes the 1430 bp insulin gene as well as 5650 bp before and 11,500 bp after the gene is single copy sequence except for 500 bp located 6000 bp from the 3' end of the gene. This 500 bp segment contains a member of the Alu family of dispersed middle repetitive sequences as well as another less highly repeated homopolymeric segment. The sequence of this region was determined. This Alu repeat is bordered by 19 bp direct repeats and also contains an 83 bp sequence which is present twice. The regions flanking the human and rat I insulin genes were compared by heteroduplex analysis to localize homologous sequences in the flanking regions which could be involved in the regulation of insulin biosynthesis. The homology between the two genes is restricted to the region encoding preproinsulin and a short region of approximately 60 bp flanking the 5' side of the genes.     

Invasion of the human albumin-alpha-fetoprotein gene family by Alu, Kpn, and two novel repetitive DNA elements

The human albumin-alpha-fetoprotein genomic domain contains 13 repetitive DNA elements randomly distributed throughout the symmetrical structures of these genes. These repeated sequences are located at different sites within the two genes. The human albumin gene contains five Alu elements within four of its 14 intervening sequences. Two of these repeats are located in intron 2, and the remaining three are located in introns 7, 8, and 11. The human alpha-fetoprotein gene contains three of these Alu elements, one in intron 4 and the remaining two in the 3'-untranslated region. In addition, the human alpha-fetoprotein gene contains a Kpn repeat and two classes of novel repeats that are absent from the human albumin gene. Six of the Alu elements within the two genes are bound by short direct repeats that harbor five base substitutions in 120 possible positions (60 bp times 2 termini). The absence of Alu repeats from analogous positions in rodents indicates that these repeats invaded the albumin-alpha-fetoprotein domain less than 85 Myr ago (the time of mammalian radiation). Furthermore, considering the conservation of terminal repeats flanking the Alu sequences of the albumin-alpha-fetoprotein domain (0.042 changes per site), we submit that the average time of Alu insertion into this gene family could have been as recently as 15-30 Myr ago.     

The Transcription Map of the 13q14 Region Frequently Deleted in B-cell Chronic Lymphocytic Leukemia

Deletions in the region located between the STS markers D13S1168 and D13S25 on chromosome 13 are the most frequent genomic changes in patients with B-cell chronic lymphocytic leukemia (B-CLL). After sequencing of this region, two novel candidate genes were identified: C13orf1(chromosome 13 open reading frame 1) and PLCC (putative large CLL candidate). Analysis of the repeat distribution revealed two subregions differing in composition of repetitious DNA and gene organization. The interval D13S1168–D13S319 contains 131 Alu repeats accounting for 24.8% of its length, whereas the interval GCT16C05–D13S25, which is no more than 180 kb away from the former one is extremely poor in Alu repeats (4.1% of the total length). Both intervals contain almost the same amount of the LINE-type repeats L1 and L2 (20.3 and 21.24%, respectively). In the chromosomal region studied, 29 Alu repeats were found to belong to the evolutionary young subfamily Y, which is still capable of amplifying. A considerable proportion of repeats of this type with similar nucleotide sequences may contribute to the recombinational activity of the chromosomal region 13q14.3, which is responsible for its rearrangements in some tumors in humans.     

Recombinational biases in the rearranged C1-inhibitor genes of hereditary angioedema patients

DNA structural changes responsible for hereditary angioedema were sought in the C1-inhibitor gene, which contains unusually dense clusters of Alu repeats in various orientations. Among patients belonging to 45 unrelated families, eight partial C1-inhibitor gene deletions and a partial duplication were found. Four deletions had one of the boundaries within the gene and the other in extragenic regions--in three cases 5' of the gene and in one case 3' of the gene. The boundaries of the partial duplication and of the remaining four deletions mapped instead within a few kilobases of exon 4. The same element--Alu 1--the first of three tandem Alu repeats preceding exon 4, contained one of the breakpoints of each of these five rearrangements. Moreover, these recombination breakpoints spread over the entire length of Alu 1, in contrast with the tight clustering observed near the 5' end of Alu sequences rearranged in other human genes. Thus, two uncommon recombinational biases are observed in the Alu rearrangements of hereditary angioedema patients; one promotes the occurrence of intragenic breakpoints in a single Alu repeat, and the other allows the breaks to be distributed over the entire Alu structure rather than within the hot spot of the left Alu monomer. A region of potential Z-DNA structure, located 1.7 kb upstream of Alu 1, may contribute to both peculiarities.     

Increased gene coverage and Alu frequency in large linkage disequilibrium blocks of the human genome

The human genome has linkage disequilibrium (LD) blocks, within which single-nucleotide polymorphisms show strong association with each other. We examined data from the International HapMap Project to define LD blocks and to detect DNA sequence features inside of them. We used permutation tests to determine the empirical significance of the association of LD blocks with genes and Alu repeats. Very large LD blocks (>200 kb) have significantly higher gene coverage and Alu frequency than the outcome obtained from permutation-based simulation, whereas there was no significant positive correlation between gene density and block size. We also observed a reduced frequency of Alu repeats at the gaps between large LD blocks, indicating that their enrichment in large LD blocks does not introduce recombination hotspots that would cause these gaps.