Does biased gene conversion influence polymorphism in the circumsporozoite protein-encoding gene of Plasmodium vivax?

Variation between North Korean and Latin American isolates in the circumsporozoite (CS) protein encoding gene of the human malaria parasite Plasmodium vivax was studied. Polymorphic positions are confined to the central tandemly repeated sequences. Nucleotide substitutions in the tandem repeats produce variants; these substituted positions within the repeat array tend to be conserved between genes. The North Korean CS gene has a short insertion after the repeats encoding a 4-amino acid repeat (Ala-Gly-Gly-Asn) not found in the New World P. vivax genes. This sequence is found both flanking and within the tandem repeats of the CS genes of several strains of the Southeast Asian simian malaria parasite, Plasmodium cynomolgi. The intraspecific conservation of positions of variants within tandem repeat arrays and the interspecific conservation of probably ancestral repeat motifs at the end of these arrays are consistent with the occurrence of nonreciprocal genetic exchanges between the tandem repeats of these genes. However, a striking asymmetry in strand nucleotide composition within the tandem repeats of all CS genes leads us to suggest that biased correction of heteroduplexes formed during recombination plays a role in the evolution of these genes.     

Stabilization of diverged tandem repeats by mismatch repair: evidence for deletion formation via a misaligned replication intermediate.

A functional methyl-directed mismatch repair pathway in Escherichia coli prevents the formation of deletions between 101-bp tandem repeats with 4% sequence divergence. Deletions between perfectly homologous repeats are unaffected. Deletion in both cases occurs independently of the homologous recombination gene, recA. Because the methyl-directed mismatch repair pathway detects and excises one strand of a mispaired duplex, an intermediate for RecA-independent deletion of tandem repeats must therefore be a heteroduplex formed between strands of each repeat. We find that MutH endonuclease, which in vivo incises specifically the newly replicated strand of DNA, and the Dam methylase, the source of this strand-discrimination, are required absolutely for the exclusion of "homeologous" (imperfectly homologous) tandem deletion. This supports the idea that the heteroduplex intermediate for deletion occurs during or shortly after DNA replication in the context of hemi-methylation. Our findings confirm a "replication slippage" model for deletion formation whereby the displacement and misalignment of the nascent strand relative to the repeated sequence in the template strand accomplishes the deletion.     

Local and long-range stability in tandemly arrayed tetratricopeptide repeats

The tetratricopeptide repeat (TPR) is a 34-aa alpha-helical motif that occurs in tandem arrays in a variety of different proteins. In natural proteins, the number of TPR motifs ranges from 3 to 16 or more. These arrays function as molecular scaffolds and frequently mediate protein-protein interactions. We have shown that correctly folded TPR domain proteins, exhibiting the typical helix-turn-helix fold, can be designed by arraying tandem repeats of an idealized TPR consensus motif. To date, three designed proteins, CTPR1, CTPR2, and CTPR3 (consensus TPR number of repeats) have been characterized. Their high-resolution crystal structures show that the designed proteins indeed adopt the typical TPR fold, which is specified by the correct positioning of key residues. Here, we present a study of the thermodynamic properties and folding kinetics of this set of designed proteins. Chemical denaturation, monitored by CD and fluorescence, was used to assess the folding and global stability of each protein. NMR-detected amide proton exchange was used to investigate the stability of each construct at a residue-specific level. The results of these studies reveal a stable core, which defines the intrinsic stability of an individual TPR motif. The results also show the relationship between the number of tandem repeats and the overall stability and folding of the protein.     

Simple tandem DNA repeats and human genetic disease.

The human genome contains many repeated DNA sequences that vary in complexity of repeating unit from a single nucleotide to a whole gene. The repeat sequences can be widely dispersed or in simple tandem arrays. Arrays of up to 5 or 6 nt are known as simple tandem repeats, and these are widely dispersed and highly polymorphic. Members of one group of the simple tandem repeats, the trinucleotide repeats, can undergo an increase in copy number by a process of dynamic mutation. Dynamic mutations of the CCG trinucleotide give rise to one group of fragile sites on human chromosomes, the rare folate-sensitive group. One member of this group, the fragile X (FRAXA) is responsible for the most common familial form of mental retardation. Another member of the group FRAXE is responsible for a rarer mild form of mental retardation. Similar mutations of AGC repeats give rise to a number of neurological disorders. The expanded repeats are unstable between generations and somatically. The intergenerational instability gives rise to unusual patterns of inheritance--particularly anticipation, the increasing severity and/or earlier age of onset of the disorder in successive generations. Dynamic mutations have been found only in the human species, and possible reasons for this are considered. The mechanism of dynamic mutation is discussed, and a number of observations of simple tandem repeat mutation that could assist in understanding this phenomenon are commented on.     

Characteristic enrichment of DNA repeats in different genomes

Using computer programs developed for this purpose, we searched for various repeated sequences including inverted, direct tandem, and homopurine–homopyrimidine mirror repeats in various prokaryotes, eukaryotes, and an archaebacterium. Comparison of observed frequencies with expectations revealed that in bacterial genomes and organelles the frequency of different repeats is either random or enriched for inverted and/or direct tandem repeats. By contrast, in all eukaryotic genomes studied, we observed an overrepresentation of all repeats, especially homopurine–homopyrimidine mirror repeats. Analysis of the genomic distribution of all abundant repeats showed that they are virtually excluded from coding sequences. Unexpectedly, the frequencies of abundant repeats normalized for their expectations were almost perfect exponential functions of their size, and for a given repeat this function was indistinguishable between different genomes.     

A single G-to-C change causes human centromere TGGAA repeats to fold back into hairpins.

Recently, we established that satellite III (TGGAA)n tandem repeats, which occur at the centromeres of human chromosomes, pair with themselves to form an unusual "self-complementary" antiparallel duplex containing (GGA)2 motifs in which two unpaired guanines from opposite strands intercalate between sheared G.A base pairs. In separate studies, we have also established that the GCA triplet does not form bimolecular (GCA)2 motifs but instead promotes the formation of hairpins containing a GCA-turn motif in which the loop contains a single cytidine closed by a sheared G.A pair. Since TGCAA is the most frequent variant of TGGAA found in satellite III repeats, we reasoned that the potential of this variant to form GCA-turn miniloop fold-back structures might be an important factor in modulating the local structure in natural (TGGAA)n repeats. We report here the NMR-derived solution structure of the heptadecadeoxynucleotide (G)TGGAATGCAATGGAA(C) in which a central TGCAA pentamer is flanked by two TGGAA pentamers. This 17-mer forms a rather unusual and very stable hairpin structure containing eight base pairs in the stem, only four of which are Watson-Crick pairs, and a loop consisting of a single cytidine residue. The stem contains a (GGA)2 motif with intercalative 14G/4G stacking between two sheared G.A base pairs; the loop end of the stem consists of a sheared 8G.10A closing pair with the cytosine base of the 9C loop stacked on 8G. The remarkable stability of this unusual hairpin structure (Tm = 63 degrees C) suggests that it probably plays an important role in modulating the folding of satellite III (TGGAA)n repeats at the centromere.     

A family of short, interspersed repeats is associated with tandemly repetitive DNA in the human genome.

A family of short, interspersed repeats in the human genome, designated the Mst II family, is described. The canonical structure of the repeat consists of a 220-base-pair (bp) left arm joined to a 160-bp right arm by a 39-bp junction sequence. The right arm is absent in some isolates. Some homology with the "O" and "THE" (transposon-like element) families of repeats was observed, suggesting that the Mst II elements could be a subgroup of a SINE superfamily. The 39-bp junction sequence is tandemly repeated in one of our clones. The association of tandemly repetitive sequences with Mst II elements or the putative superfamily is probably nonrandom; a search of DNA sequence data bases revealed that approximately 80 bp of the Mst II left arm occurs immediately adjacent to the tandem repeat that comprises the human homologue to the BK virus enhancer. The fortuitous occurrence of a gene duplication event involving an Mst II repeat has allowed us to estimate a mutation rate for human DNA.     

普通人群急性心肌梗死患者MEF2A第11外显子的基因变异研究

目的研究MEF2A基因第11外显子在普通急性心肌梗死(简称心梗)患者中的变异情况。方法应用聚合酶链反应-单链构象多态性(PCR-SSCP)和DNA测序技术检测263例散发急性心梗和207例非冠心病个体MEF2A基因第11外显子的基因序列,并比较其异同。结果按SSCP电泳条带的多少和泳动距离将标本分类后,随机选取200例病例组和101例对照组进行DNA直接测序,共发现4个多态位点:A位点,8290-8319CAG重复序列,呈长度多态,导致翻译产物421-430之间谷氨酰胺q个数呈4～15个不等;B位点:8320-8334呈ccgccgccaccaccg和ccgccaccaccg两种多态,导致翻译产物431-435脯氨酸p个数为4～5个不等;C位点,同义变异8334G→A;D位点,同义变异8382G→T。4个多态位点在病例组和对照组之间无差异。本实验未发现MEF2A基因第11外显子上的突变。结论普通急性心梗人群MEF2A基因第11外显子存在4个多态位点,但这些多态位点似乎与心梗的发病无关。     

Stabilization of perfect and imperfect tandem repeats by single-strand DNA exonucleases

Rearrangements between tandemly repeated DNA sequences are a common source of genetic instability. Such rearrangements underlie several human genetic diseases. In many organisms, the mismatch-repair (MMR) system functions to stabilize repeats when the repeat unit is short or when sequence imperfections are present between the repeats. We show here that the action of single-stranded DNA (ssDNA) exonucleases plays an additional, important role in stabilizing tandem repeats, independent of their role in MMR. For perfect repeats of approximately 100 bp in Escherichia coli that are not susceptible to MMR, exonuclease (Exo)-I, ExoX, and RecJ exonuclease redundantly inhibit deletion. Our data suggest that >90% of potential deletion events are avoided by the combined action of these three exonucleases. Imperfect tandem repeats, less prone to rearrangements, are stabilized by both the MMR-pathway and ssDNA-specific exonucleases. For 100-bp repeats containing four mispairs, ExoI alone aborts most deletion events, even in the presence of a functional MMR system. By genetic analysis, we show that the inhibitory effect of ssDNA exonucleases on deletion formation is independent of the MutS and UvrD proteins. Exonuclease degradation of DNA displaced during the deletion process may abort slipped misalignment. Exonuclease action is therefore a significant force in genetic stabilization of many forms of repetitive DNA.     

Autoantigenic proteins that bind recombinogenic sequences in Epstein-Barr virus and cellular DNA.

We have identified conserved autoantigenic cellular proteins that bind to G-rich sequence motifs in recombinogenic regions of Epstein-Barr virus (EBV) DNA. This binding activity, called TRBP, recognizes the EBV terminal repeats, a locus responsible for interconversion of linear and circular EBV DNA. We found that TRBP also binds to EBV DNA sequences involved in deletion of EBNA2, a gene product required for immortalization. We show that TRBP binds sequences present in repetitive cellular DNA, such as variable-number tandem repeats (VNTR) and immunoglobulin heavy-chain class switch regions. We propose that EBV utilizes cellular DNA recombination systems to mediate several types of viral genome alterations. These findings may lead to an understanding of the mechanism of rearrangements of EBV DNA that are a central feature of the biology of the virus.     

HeT DNA: a family of mosaic repeated sequences specific for heterochromatin in Drosophila melanogaster.

HeT DNA is a complex family of repeated DNA found only in pericentric and telomeric heterochromatin. In contrast to other DNA families that have been specifically associated with heterochromatin, HeT DNA is not principally a family of tandemly repeated elements. Much of the HeT DNA family appears to be a mosaic of several different classes of large sequence elements arranged in a scrambled array; however, some elements of the family can be found in tandem repeats. In spite of the variable order of the different elements in HeT DNA, the sequence homology between different members of each class of element is extremely high, suggesting that the members are evolving in a concerted fashion. Sequence analysis suggests that some elements in the HeT family may make up a novel family of heterochromatin-specific transposable elements and that the mosaic organization of the elements may be produced by retroposition and other mechanisms involved in the transposition of mobile elements. We suggest that such mechanisms may be a general feature for the maintenance of chromosome structure.     

Analysis of the phiX DNA replication cycle by electron microscopy.

We have monitored the development of intracellular phiX DNA forms during the course of a virus life cycle that duplicates as closely as possible the normal infection of individual cells by single virions. The viral DNA was isolated in a one-step purification procedure, and quantitative electron microscopy was performed on the samples, resulting in the following conclusions: (i) Early in the life cycle, when the cells accumulate duplex rings, two types of DNA replication intermediates are observed: a rolling circle with a single-stranded tail; and a novel form, a single-stranded circle that is partially duplex. Thus, duplex ring synthesis appears to occur in two asymmetric steps, with positive strand DNA first being processed from the tail of the rolling circle and circularized, before it acts as a template for negative strand synthesis. (ii) Late in the life cycle, as single-stranded circles are synthesized and virus particles are assembled, only one replicating intermediate is observed--the rolling circle with a single-stranded tail. At this stage, the number of rolling circles reaches a level of about 35 per cell. (iii) The net rate of polymerization in the rolling circle intermediates is about 200 nucleotides per sec.     

Recognition of tandem PxxP motifs as a unique Src homology 3-binding mode triggers pathogen-driven actin assembly

Src homology 3 (SH3) domains are globular protein interaction modules that regulate cell behavior. The classic SH3 ligand-binding site accommodates a hydrophobic PxxP motif and a positively charged specificity-determining residue. We have determined the NMR structure of insulin receptor tyrosine kinase substrate (IRTKS) SH3 domain in complex with a repeat from Escherichia coli-secreted protein F-like protein encoded on prophage U (EspF(U)), a translocated effector of enterohemorrhagic E. coli that commandeers the mammalian actin assembly machinery. EspF(U)-IRTKS interaction is among the highest affinity natural SH3 ligands. Our complex structure reveals a unique type of SH3 interaction based on recognition of tandem PxxP motifs in the ligand. Strikingly, the specificity pocket of IRTKS SH3 has evolved to accommodate a polyproline type II helical peptide analogously to docking of the canonical PxxP by the conserved IRTKS SH3 proline-binding pockets. This cooperative binding explains the high-affinity SH3 interaction and is required for EspF(U)-IRTKS interaction in mammalian cells as well as the formation of localized actin "pedestals" beneath bound bacteria. Importantly, tandem PxxP motifs are also found in mammalian ligands and have been shown to contribute to IRTKS SH3 recognition similarly.     

Amplification of integrated viral DNA sequences in polyoma virus-transformed cells.

Polyoma virus (Py) transformation of rat cells requires integration of viral genomes into the host DNA, which generally occurs in a partial or full head-to-tail tandem arrangement. The instability of this structure was previously demonstrated by the high rate of loss of integrated Py genomes in the presence of viral large tumor (T) antigen. We now show that integrated Py DNA sequences can also undergo amplification. We studied two rat cell lines transformed by the ts-a Py mutant, which codes for a thermolabile large T antigen. In a derivative of the ts-a H6A cell line, we have observed loss of full-length Py DNA molecules from the integrated tandem ("curing"), accompanied by the creation of new tandem repeats of two segments of viral DNA corresponding to 38% and 10% of the viral genome, each containing the origin of DNA replication. In the ts-a H3A cell line, which contains an integrated partial tandem of about 1.3 viral genomes with three distinct deletions, propagation at 33 degrees C resulted in the generation of full tandem repeats of a 94% Py DNA "unit" (including two 3% deletions), an 85% "unit" (including a 3% and the 12% deletion), or both. Amplification of integrated viral DNA was not observed in cells propagated at 39.5 degrees C, the nonpermissive temperature for large T antigen function. Amplification of integrated Py DNA sequences thus requires an active large T antigen and can generate a full tandem of integrated viral DNA molecules long after the initial integration event.     

Cloning, sequence, and expression of the lysostaphin gene from Staphylococcus simulans.

A 1.5-kilobase-pair fragment of DNA that contains the lysostaphin gene from Staphylococcus simulans and its flanking sequences has been cloned and completely sequenced. The gene encodes a preproenzyme of Mr 42,000. The NH2-terminal sequence of the preproenzyme is composed of a signal peptide followed by seven tandem repeats of a 13-amino acid sequence. Conversion of prolysostaphin to the mature enzyme occurs extracellularly in cultures of S. simulans and involves removal of the NH2-terminal portion of the proenzyme that contains the tandem repeats. The high degree of homology of the repeats suggests that they have arisen by duplication of a 39-base-pair sequence of DNA. In S. simulans, the lysostaphin gene is present on a large beta-lactamase plasmid.