Simple mathematical model of pathologic microsatellite expansions: when self-reparation does not work

We propose a simple model of pathologic microsatellite expansion, and describe an inherent self-repairing mechanism working against expansion. We prove that if the probabilities of elementary expansions and contractions are equal, microsatellite expansions are always self-repairing. If these probabilities are different, self-reparation does not work. Mosaicism, anticipation and reverse mutation cases are discussed in the framework of the model. We explain these phenomena and provide some theoretical evidence for their properties, for example, the rarity of reverse mutations.     

The relationship between microsatellite polymorphism and recombination hot spots in the human genome

Although previous studies have failed to detect an association between microsatellite polymorphism and broadscale recombination rates in the human genome, there are several possible reasons why such a relationship could exist. For instance, there might be a direct link if recombination is mutagenic to microsatellite sequences or if polymorphic microsatellites act as recombination signals. Alternatively, recombination could exert an indirect effect by uncoupling of natural selection at linked loci, promoting polymorphism. As recombination is concentrated in narrow hotspot regions in the human genome, we investigated the relationship between microsatellite polymorphism and recombination hot spots. By using data from a common allele frequency database, we found several polymorphism estimates to be similar for hot spots and the genomic average. However, this is likely explained by an ascertainment bias because markers with high polymorphism information content are usually selected for genotyping in human populations and pedigrees. In contrast, by using an unbiased set of shotgun sequence data, we found an excess of microsatellite polymorphism in recombination hot spots of 14%. However, when other genomic variables are taken into account in a generalized model and using wavelet analysis, the effect is no longer detectable and the only firm predictor of microsatellite polymorphism is the incidence of SNPs and indels. One possible neutral explanation to these observations is that there is a common denominator affecting the local rate of mutation in unique as well as in repetitive DNA, for example, base composition.     

Massive expansions of Dscam splicing diversity via staggered homologous recombination during arthropod evolution

The arthropod Down syndrome cell adhesion molecule (Dscam) gene can generate tens of thousands of protein isoforms via combinatorial splicing of numerous alternative exons encoding immunoglobulin variable domains organized into three clusters referred to as the exon 4, 6, and 9 clusters. Dscam protein diversity is important for nervous system development and immune functions. We have performed extensive phylogenetic analyses of Dscam from 20 arthropods (each containing between 46 and 96 alternative exons) to reconstruct the detailed history of exon duplication and loss events that built this remarkable system over 450 million years of evolution. Whereas the structure of the exon 4 cluster is ancient, the exon 6 and 9 clusters have undergone massive, independent expansions in each insect lineage. An analysis of nearly 2000 duplicated exons enabled detailed reconstruction of the timing, location, and boundaries of these duplication events. These data clearly show that new Dscam exons have arisen continuously throughout arthropod evolution and that this process is still occurring in the exon 6 and 9 clusters. Recently duplicated regions display boundaries corresponding to a single exon and the adjacent intron. The boundaries, homology, location, clustering, and relative frequencies of these duplication events strongly suggest that staggered homologous recombination is the major mechanism by which new Dscam exons evolve. These data provide a remarkably detailed picture of how complex gene structure evolves and reveal the molecular mechanism behind this process.     

Statistical power analysis of neutrality tests under demographic expansions, contractions and bottlenecks with recombination

Several tests have been proposed to detect departures of nucleotide variability patterns from neutral expectations. However, very different kinds of evolutionary processes, such as selective events or demographic changes, can produce similar deviations from these tests, thus making interpretation difficult when a significant departure of neutrality is detected. Here we study the effects of demography and recombination upon neutrality tests by analyzing their power under sudden population expansions, sudden contractions, and bottlenecks. We evaluate tests based on the frequency spectrum of mutations and the distribution of haplotypes and explore the consequences of using incorrect estimates of the rates of recombination when testing for neutrality. We show that tests that rely on haplotype frequencies-especially Fs and ZnS, which are based, respectively, on the number of different haplotypes and on the r2 values between all pairs of polymorphic sites-are the most powerful for detecting expansions on nonrecombining genomic regions. Nevertheless, they are strongly affected by misestimations of recombination, so they should not be used when recombination levels are unknown. Instead, class I tests, particularly Tajima's D or R2, are recommended.     

Sexual recombination punctuated by outbreaks and clonal expansions predicts Toxoplasma gondii population genetics

The cosmopolitan parasitic pathogen Toxoplasma gondii is capable of infecting essentially any warm-blooded vertebrate worldwide, including most birds and mammals, and establishes chronic infections in one-third of the globe’s human population. The success of this highly prevalent zoonosis is largely the result of its ability to propagate both sexually and clonally. Frequent genetic exchanges via sexual recombination among extant parasite lineages that mix in the definitive felid host produces new lines that emerge to expand the parasite’s host range and cause outbreaks. Highly successful lines spread clonally via carnivorism and in some cases sweep to pandemic levels. The extent to which sexual reproduction versus clonal expansion shapes Toxoplasma’s current, global population genetic structure is the central question this review will attempt to answer.     

Mini- and micro-satellites in the genome of rodent malaria parasites.

Higher eukaryotes contain within their DNA numerous arrays of repetitive DNA, many of which are known as satellite DNAs and display extensive variability. The presence of these repeats has been demonstrated for various species and they have been used for genetic identification and classification. Here, it is demonstrated that Southern hybridisation of DNA from rodent malaria parasites allows detection of micro- and minisatellite sequences in the genome of Plasmodium species. Closely related lines of malaria parasites exhibit a monomorphic hybridisation pattern, which is in contrast to the allelic variation observed in higher eukaryotes. Among different species, however, restriction-fragment length polymorphism was observed. Pulsed-field gel electrophoretic chromosome separation showed that the probes used in this study [33.15, 33.6, (CAC)n and (GT)n] detect several loci spread over different chromosomes.     

Gene conversion (recombination) mediates expansions of CTG[middle dot]CAG repeats

Genetic recombination is a robust mechanism for expanding CTG.CAG triplet repeats involved in the etiology of hereditary neurological diseases (Jakupciak, J. P., and Wells, R. D. (1999) J. Biol. Chem. 274, 23468-23479). This two-plasmid recombination system in Escherichia coli with derivatives of pUC19 and pACYC184 was used to investigate the effect of triplet repeat orientation on recombination and extent of expansions; tracts of 36, 50, 80, and 36, 100, and 175 repeats in length, respectively, in all possible permutations of length and in both orientations (relative to the unidirectional replication origins) revealed little or no effect of orientation of expansions. The extent of expansions was generally severalfold the length of the progenitor tract and frequently exceeded the combined length of the two tracts in the cotransformed plasmids. Expansions were much more frequent than deletions. Repeat tracts bearing two G-to-A interruptions (polymorphisms) within either 171- or 219-base pair tracts substantially reduced the expansions compared with uninterrupted repeat tracts of similar lengths. Gene conversion, rather than crossing over, was the recombination mechanism. Prior studies showed that DNA replication, repair, and tandem duplication also mediated genetic instabilities of the triplet repeat sequence. However, gene conversion (recombinational repair) is by far the most powerful expansion mechanism. Thus, we propose that gene conversion is the likely expansion mechanism for myotonic dystrophy, spinocerebellar ataxia type 8, and fragile X syndrome.     

Hypertension: the sodium connection

It appears from epidemiologic, population, and individual studies that sodium is capable of raising blood pressure and its attendant cardiovascular complications in susceptible individuals. Potassium loss occurs with sodium loading and may modulate the blood pressure responses to sodium. Populations known to be at greater risk for the development of hypertension and its cardiovascular sequelae, such as blacks, older individuals, and those over the age of 40 years are also known to be less efficient in handling sodium. Furthermore, they are more apt to be sodium-sensitive than -resistant. The phenomena of sensitivity and resistance, demonstrable in both normotensive and hypertensive individuals, can be identified by rapid sodium and volume loading and depletion as well as by modest reduction in dietary sodium intake. Finally, preliminary evidence suggests that sodium sensitivity may be predictable by genetic markers as well as by demographic characteristics.     

Cancer: the chromatin connection

The American Association for Cancer Research's 93rd Annual Meeting was held in San Francisco, California, USA, from 6 to 10 April 2002.     

Aging: progeria and the lamin connection

The relationship between progerias--diseases that resemble premature aging--and the normal aging process has been a source of debate in the aging research community. A recent study finds that LMNA, a gene targeted for mutation in Hutchinson Gilford Progeria Syndrome, may control the onset of aging-associated decline in normal fibroblasts.     

Atherosclerosis: the eicosanoid connection

This bird's eye view presents connections between the metabolically short-lived local hormones (collectively known as eicosanoids) and atherosclerotic cardiovascular disease. The discussion will be centered around an overview of coronary atherosclerosis with an emphasis on the sequences involved in the formation of atherosclerotic lesions; structure and historical background of oxygenated fatty acids cyclooxygenase and lipoxygenase products — eicosanoids; the generation of free radicals during the formation of endoperoxides by cyclooxygenase; the involvement of eicosanoids in the atherosclerotic inflammatory process, and finally, the effects of non-steroidal and steroidal anti-inflammatory drugs on the synthesis of eicosanoids and experimental atherosclerosis. Little is known about the exact role of eicosanoids in the genesis of atherosclerosis.     

Cell-matrix adhesion: the Wech connection

Integrins link the extracellular matrix to the cytoskeleton via a complex of proteins: the integrin-cytoskeleton link. A recent study in Drosophila has uncovered a new component of the link, Wech, and shown that it is essential for integrin-mediated adhesion.     

Iron dysregulation and neurodegeneration: the molecular connection

Iron is essential for many biological processes however excess concentrations can be harmful to many tissues. Its amounts must therefore be carefully regulated in all cells of the body including those in the brain. Increased amounts of iron have been reported in many neurodegenerative disorders. Whether this increased iron contributes to neurodegeneration has been considered controversial. In this review, we discuss some recently identified anomalies in proteins linked with iron metabolism which signify a critical role for iron dysregulation in neurodegeneration.     

Chromatin assembly: the kinetochore connection

An unexpected new role for the chromatin assembly factor CAF-1 and the histone-regulating Hir proteins has been discovered in budding yeast. Both protein complexes are required together for building functional kinetochores.