Characterization of the patterns of polymorphism in a "cryptic repeat" reveals a novel type of hypervariable sequence.

Alternating purine and pyrimidine repeats (RY(i)) are an abundant source of polymorphism. The subset with long tandem repeats of GT or AC (GT(i)) have been studied extensively, but cryptic RY(i) (i.e., no single tandem repeat predominates) have received little attention. The factor IX gene has a polymorphic cryptic RY(i) of 142-216 bp. Previously, there were four known polymorphic alleles, of the form AB, A2B, A2B2, and A3B2, where A = (GT)(AC)3(AT)3(GT)(AT)4 and B = A with an additional 3'' AT dinucleotide. To further characterize this locus, we examined more than 1,700 additional human chromosomes and determined the sequences of the homologous sites in orangutans and chimpanzees. The novel alleles found in humans expand the repertoire of A/B alleles to A0-4B1 and A1-3B2. The AnB2 series are abundant in Caucasians but are absent in blacks and Asians. Conversely, the A0B1 allele is common in blacks but is not found in more than 1,700 Caucasian chromosomes. The data are compatible with a model in which recombination is more frequent than polymerase slippage at this locus. In orangutans, the RY(i) is present, but the sequence is markedly different. An A/B-type of pattern was discerned in which B differs from A by an additional six (AT) dinucleotides at the 3'' end. In chimpanzees, the size of the RY(i) locus was greatly expanded, and the sequence showed a novel pattern of hypervariability in which there are many tandem repeats of the form (GT)n(AC)o(AT)p(GT)q(AT)s, where n, o, p, q, and s are different integers. The sequences of the factor IX intron 1 cryptic RY(i) in three primates provide perspective on the range of possible patterns of polymorphism. Analysis of the patterns suggests how the RY(i) can be conserved during evolution, while the precise sequence varies.     

Characterization of a highly polymorphic region near the first exon of the human MAOA gene containing a GT dinucleotide and a novel VNTR motif.

The genes encoding the A and B forms of the human monoamine oxidase enzymes (MAOA and MAOB) are localized at Xp11.23-Xp11.4. We report the characterization of a highly informative polymorphic region within a 2.9-kb cloned fragment containing the first exon of the MAOA gene. The polymorphic region consists of a GT microsatellite directly adjacent to an imperfectly duplicated novel 23-bp VNTR motif. DNA sequencing within and flanking the repeated segment allowed the design of specific amplification primers. In 56 unrelated females, 15 different alleles were identified with sizes ranging from 285 to 388 bp. The alleles differed in both the number of dinucleotide and the number of VNTR repeats, yielding a highly informative polymorphic marker locus with a calculated heterozygosity value of 75%.     

“Cryptic” dinucleotide polymorphism in the 3′ region of the factor IX gene shows substantial variation among different populations

Long tandem dinucleotide repeats composed of alternating purines and pyrimidines [RY(i)] are abundant and highly polymorphic. Simple RY(i) are predominately composed of one tandem repeat of a dinucleotide sequence. In contrast, cryptic RY(i [cRY(i)] are composed of multiple short dinucleotide repeats. Herein, we describe the racial distribution of alleles for a polymorphic cRY(i) in the factor IX gene. Allele I is absent in Asians, whereas allele III is rare or absent in Caucasians or blacks. A polymorphic cRY(i) analyzed previously shows even more dramatic variation among racial groups, hinting that a battery of cRY(i) might have utility in assessing the racial origin of a DNA sample.     

Eukaryotic topoisomerase II preferentially cleaves alternating purine-pyrimidine repeats.

Alternating purine-pyrimidine sequences (RY repeats) demonstrate considerable homology to the consensus sequence for vertebrate topoisomerase II (Spitzner and Muller (1988) Nucleic Acids Res. 16: 1533-1556). This is shown below and positions that can match are underscored. RYRYRYRYRYRYRYRYRY = alternating purine-pyrimidine 18 bp RNYNNCNNGYNGKTNYNY = topoisomerase II consensus sequence (R is purine, Y is pyrimidine, K is G or T.) Topoisomerase II cleavage reactions were performed (in the absence of inhibitors) on a plasmid containing a 54 base RY repeat and the single strong cleavage site mapped to the RY repeat. Analysis of this DNA on sequencing gels showed that the enzyme cleaved a number of sites, all within the 54 base pair RY repeat. Topoisomerase II also made clustered cleavages within other RY repeats that were examined. Quantitative analysis of homology to the consensus sequence, as measured by the match of a site to a matrix of base proportions from the consensus data base (the matrix mean), showed that both the locations and the frequencies of cleavage sites within RY repeats were proportional to homology scores. However, topoisomerase II cleaved RY repeats preferentially in comparison to non-RY sites with similar homology scores. The activity of the enzyme at RY repeats appears to be proportional to the length of the repeat; additionally, GT, AC and AT repeats were better substrates for cleavage than GC repeats.     

Polymorphic microsatellite DNA amplification customized for chimpanzee paternity testing

DNA segments containing GT/AC dinucleotide repeats in the chimpanzee (Pan troglodytes) genome were screened. Thirteen transformedE. coli colonies were identified with the (GT)₁₀ probe to have chimpanzee DNA fragments containing (GT)_n repeats. These potentially polymorphic (variable n) DNA segments were sequenced. Primers for the polymerase chain reaction (PCR) amplifying these DNA segments were designed. Six pairs of primers yielded polymorphic PCR products. Three of them revealed considerable length polymorphisms and heterozygosities in a group of captive chimpanzees. For studies on chimpanzees in the wild and in captivity, these primers should be useful for paternity testing, for investigating genetic variations, and for improving the genetic maintenance of breeding colonies. The strategy adopted in the present study to obtain PCR primers amplifying polymorphic microsatellite DNA segments may well be applicable to almost all eukaryotic organisms.     

Analysis of two different tandem repetitive elements within the human apolipoprotein B gene.

A large number of copies of the sequence (dTG-dAC)n, where n is between 10 and 60, exist in the human genome, and many are useful as polymorphic markers. One of these sequences occurs about 3 kilobases 5' of the human apolipoprotein (apo) B gene as seven distinguishable alleles containing from (TG)12 to (TG)18. This repeat is also present in the DNA of other primates. A second alternating purine-pyrimidine sequence with nine dinucleotide repeats and located in intron 4 is not polymorphic. Together with the apoB hypervariable repeat immediately 3' of the gene, the (TG)n sequence will provide a useful haplotype marker capable of distinguishing a large number of human apoB alleles, some of which may be associated with disease states.     

Isolation and Characterization of Microsatellites in Snap Bean

The objectives of this study were to isolate and characterize microsatellites from a heat tolerant variety of snap bean (Phaseolus vulgaris L.) in order to generate polymorphic genetic markers linked to quantitative trait loci for heat tolerance. A genomic library contained 400-800 bp inserts was constructed and screened for the presence of (GA/CT)n and (CA/GT)n repeats. The proportion of positive clones yielded estimated of 3.72×10 4 such dinucleotide repeats per genome, roughly comparable to the abundance reported in other eukaryotic genomes. Twenty-six positive clones were sequenced. In contrast to mammalian genomes, the (GA/CT)n motif was much more abundant than the (CA/GT)n motif in these clones. The (GA/CT)n repeats also showed longer average repeat length (mean n=10.4 versus 6.5), suggesting that they are better candidates for yielding polymorphic genetic markers in the snap bean genome.     

A cluster of highly polymorphic dinucleotide repeats in intron 17b of the cystic fibrosis transmembrane conductance regulator (CFTR) gene.

A cluster of highly polymorphic dinucleotide repeats has been detected in intron 17b of the CFTR gene, 200 bp downstream from the preceding exon. At least 24 alleles, with sizes ranging from 7 to 56 units of a TA repeat, have been identified in a panel of 92 unrelated carriers of cystic fibrosis (CF). The common ones are those with 7, 30, and 31 dinucleotide units, with frequencies of .22, .19, and .12, respectively, among the non-CF chromosomes. Mendelian, codominant segregation of the alleles has been demonstrated in family studies, as expected. A less polymorphic dinucleotide (CA repeat) cluster has also been detected in a region 167 bp downstream from the TA repeat. The length of the CA repeat cluster varies from 11 to 17 dinucleotide units, and it appears to have an inverse relationship to that of the TA repeats. These dinucleotide repeats should be useful in genetic linkage studies, in counseling for CF families with unknown mutations, and in tracing the origins of the various mutant CF alleles.     

A microsatellite polymorphism in intron 2 of human Toll-like receptor 2 gene: functional implications and racial differences

The human Toll-like receptor 2 (TLR2) mediates responses of both innate and adaptive immunity to Gram-positive bacteria, including mycobacteria. We sought functional polymorphisms in the 5'-untranslated region (UTR) of TLR2. We found a highly polymorphic (GT)n dinucleotide repeat 100 bp upstream of the TLR2 translational start site in intron 2. The numbers of GT repeats varied from 12 to 28. There were significant differences in allele distribution between African Americans and Caucasians (P=0.008) and between African Americans and Koreans (P=0.0003). The promoter activities of recombinant promoter-intron2/reporter constructs including the shortest [GT)n=12] or longest [(GT)n=28] alleles were significantly more stimulated when exposed to 200 IU ml(-1) of interferon-gamma than when exposed to 100 IU ml(-1) of GM-CSF (P<==0.03). Since TLR2 plays a critical role in the human innate immune response, this functional microsatellite polymorphism may be important in the pathogenesis of infectious and inflammatory diseases.     

Identification of abundant and informative microsatellites from shrimp (Penaeus monodon) genome

Microsatellites were isolated from P. monodon genomic libraries by direct sequencing of recombinant clones without probe screening. Forty-nine out of 83 clones sequenced contained 99 microsatellite arrays of three or more repeats. When five or more and ten or more repeats were considered, 28 and 14 microsatellites were detected, respectively. The 99 microsatellites were classified as perfect (75%), imperfect (6%), compound perfect (3%) and compound imperfect (16%). The abundance of di-, tri-, tetra- and hexanucleotide repeats were 67%, 20%, 9% and 3%, respectively. The dinucleotide repeats included 36 (CT)n, 31 (GT)n, 17(AT)n and 3 (CG)n. One octanucleotide repeat (ATTTATTC)5 was found within a large repeat sequence. Optimal annealing temperatures were determined for PCR using 11 primer sets encompassing 15 microsatellites. Ten primer sets provided successful amplifications with allele sizes generally ranging from 139 to 410 bp. All these primers amplified polymorphic loci with PIC values ranging from 0.63 to 0.96. Two primer sets amplified additional bands which can easily be distinguished from the bands of the main locus. Three out of 10 P. monodon microsatellites also amplified alleles in P. vannamei. The abundance and informative nature of P. monodon microsatellites and their potential for cross-species amplification make them useful for genetic studies.     

Characterization of a highly polymorphic region 5′ to JH in the human immunoglobulin heavy chain

A cloned DNA segment 1.25 kilobases (kb) upstream from the joining segments of the human heavy chain immunoglobulin gene revealed extensive polymorphic variation at this locus, and the polymorphic pattern was stably transmitted to the next generation. Genomic restriction analysis showed that the polymorphism was caused by insertions/deletions within an MspI/BamHI fragment. Sequencing of one allele, 848 base pairs (bp) long, revealed eleven 50-base-pair tandem repeats. A second allele, 648 bp long, was cloned from a human genomic cosmid library, sequenced, and found to contain four fewer repeats than the first allele. A survey of 186 chromosomes from unrelated individuals of primarily northern European descent revealed at least six alleles.     

Informativeness of dinucleotide repeat-based primers in fungal pathogen of rice Magnaporthe grisea

Microsatellites or simple sequence repeats (SSRs) occur ubiquitously and show complex patterns in length, motif size and sequence. Among SSRs, dinucleotide repeats occur in high abundance in fungi with shorter length as compared to other organisms. In this study, multilocus profiles obtained in Magnaporthe grisea, a model plant pathogen were evaluated. The results showed lower rate of polymorphism by (GT)(n)/(TG)(n) repeat-based primers and suggested occurrence of (GA)(n)/(AG)(n) repeats as integral repeats and (TC)(n)/(CT)(n) and (AC)(n)/(CA)(n) as non-integral repeats. Low repeat length variation was found to be correlated with less number of repeat motifs. The study provides an insight into the possibility of molecular coevolution of mobile elements and dinucleotide repeats in fungi. The study could be applied to other species for wider applications including evolutionary and population genetics.     

The bovine genome contains polymorphic microsatellites

Dinucleotide repeats constitute so-called microsatellites of the human and other eukaryotic genomes. Microsatellite polymorphisms can be identified through the amplification of the microsatellite DNA using the polymerase chain reaction (PCR), followed by resolution of the amplified DNA fragments on a polyacrylamide sequencing gel. We performed a preliminary sequence database search to identify bovine sequences containing (CA)n, (AC)n, (GT)n, or (TG)n blocks, with n greater than or equal to 6. This search yielded 10 sequences containing one or two of the specified repeat blocks and often additional dinucleotide repeat blocks. One of the microsatellite-containing regions has been sequenced twice from independent clones and the reported sequences showed variation in the number of repeats. PCR-amplified fragments of another sequence, the gene for steroid 21-hydroxylase, ranged from 186 to 216 nucleotides in 43 unrelated animals. The database search, as well as the hypervariable microsatellite in the bovine steroid 21-hydroxylase gene, indicates that dinucleotide blocks may be an abundant source of DNA polymorphism in cattle.     

The structure of interrupted human AC microsatellites

Microsatellite lengths change over evolutionary time through a process of replication slippage. A recently proposed model of this process holds that the expansionary tendencies of slippage mutation are balanced by point mutations breaking longer microsatellites into smaller units and that this process gives rise to the observed frequency distributions of uninterrupted microsatellite lengths. We refer to this as the slippage/point-mutation theory. Here we derive the theory's predictions for interrupted microsatellites comprising regions of perfect repeats, labeled segments, separated by dinucleotide interruptions containing point mutations. These predictions are tested by reference to the frequency distributions of segments of AC microsatellite in the human genome, and several predictions are shown not to be supported by the data, as follows. The estimated slippage rates are relatively low for the first four repeats, and then rise initially linearly with length, in accordance with previous work. However, contrary to expectation and the experimental evidence, the inferred slippage rates decline in segments above 10 repeats. Point mutation rates are also found to be higher within microsatellites than elsewhere. The theory provides an excellent fit to the frequency distribution of peripheral segment lengths but fails to explain why internal segments are shorter. Furthermore, there are fewer microsatellites with many segments than predicted. The frequencies of interrupted microsatellites decline geometrically with microsatellite size measured in number of segments, so that for each additional segment, the number of microsatellites is 33.6% less. Overall we conclude that the detailed structure of interrupted microsatellites cannot be reconciled with the existing slippage/point-mutation theory of microsatellite evolution, and we suggest that microsatellites are stabilized by processes acting on interior rather than on peripheral segments.     

Dinucleotide (CA/GT) repeat polymorphism in intron 17B of the cystic fibrosis transmembrane conductance regulator (CFTR) gene

Summary We describe a polymorphic microsatellite (IVS17BCA) in intron 17B of the cystic fibrosis transmembrane conductance regulator (CFTR) gene. It consists of an 11 to 20 CA/GT dinucleotide repeat, located 424 bp from exon 17B.     

Use of short sequence repeat DNA polymorphisms after PCR amplification to detect the parental origin of the additional chromosome 21 in Down syndrome.

The origin of nondisjunction in trisomy 21 has so far been studied using cytogenetic heteromorphisms and DNA polymorphisms using Southern blot analysis. Short sequence repeats have recently been described as an abundant class of DNA polymorphisms in the human genome, which can be typed using the polymerase chain reaction (PCR) amplification. We describe the usage of such markers on chromosome 21 in the study of parental origin of the additional chromosome 21 in 87 cases of Down syndrome. The polymorphisms studied were (a) two (GT)n repeats and a poly(A) tract of an Alu sequence within the HMG14 gene and (b) a (GT)n repeat of locus D21S156. The parental origin was determined in 68 cases by studying the segregation of polymorphic alleles in the nuclear families (either by scoring three different alleles in the proband or by dosage comparison of two different alleles in the proband). Our results demonstrate the usefulness of highly informative PCR markers for the study of nondisjunction in Down syndrome.     

Characterization of an unusual DNA length polymorphism 5'' to the human antithrombin III gene

Nucleotide sequence analysis revealed that a DNA length polymorphism 5' to the human antithrombin III gene is due to the presence of 32bp or 108bp nonhomologous nucleotide sequences (variable segments) 345bp upstream from the translation initiation codon. Sequences at the 3' borders of both variable segments can form intrastrand inverted repeat structures with sequences further downstream. An inverted repeat is also found immediately 5' to the site where the variable segments are located. Thus, cruciform structures may form flanking the variable segments of both alleles of this DNA length polymorphism. DNA secondary structure may be detected with single strand specific nucleases. S1 nuclease sensitive sites were mapped in recombinant plasmids containing the cloned alleles of the ATIII length polymorphism. The site most sensitive to S1 is located upstream from the variable segments in an AT-rich segment flanked by 6bp direct repeats. A region of lesser nuclease sensitivity was also observed in the AT-rich loops formed between the inverted repeats 5' to the variable segments.     

Polymorphism and phylogeny of dinucleotide repeats in human T-cell receptor Vb6 genes

The Vb6 subfamily is the largest reported subfamily of human T-cell receptor (Tcr) genes with as many as 14 possible members based on variation in reported DNA sequences. A study of the genomic organization of four distinct Vb6 genes indicated that they contained within their introns theuniterrupted dinucleotide repeat (GT)_n, with n>8. DNA amplification primers and conditions were determined which amplified the intron of these four different Vb6 gene segments. All four Vb6 genes tested showed length polymorphism when examined in a group of unrelated individuals. Careful sizing and DNA sequencing showed that the alleles of each gene differed in size by multiples of two base pairs (bp), due to different repeat numbers of the dinucleotide (GT)_n. These four microsatellite polymorphisms had from three to ten alleles, and individual heterozygosities of 26% to 83%. The large number of alleles and the high heterozygosity make these polymerase chain reaction (PCR)-based polymorphisms very attractive genetic markers for segregation studies which postulate the presence of autoimmune susceptibility genes within the Tcrb region. Vb6 hybridization to genomic DNA confirmed the relatively large size of the Vb6 subfamily in several hominoid species. Nucleotide sequencing of an intron of the Vb6 genes from other primates revealed the presence of dinucleotide repeats similar to those found in human Vb6 genes. Thus, the (GT)_n microsatellite was not only present in the Vb6 intron before Vb6 gene duplication, but was present before speciation of the hominoids.The nucleotide sequence data reported in this paper have been submitted to the GenBank nucleotide sequence database and have been assigned the accession numbers L07638, L07640, and X07641.     

Two CA/GT repeat polymorphisms in intron 27 of the human neurofibromatosis type 1 (NF1) gene

We describe two polymorphic microsatellites in intron 27 of the neurofibromatosis type l (NF1) gene. The microsatellites consist of TG/AC and AC/TG dinucleotide repeats detecting five and seven alleles and with heterozygosities of 0.46 and 0.72, respectively. These microsatellites are useful tools both for direct and indirect genetic analysis of NF1.