The genetic basis of interspecies host preference differences in the model parasitoid Nasonia.

The genetic basis of host preference has been investigated in only a few species. It is relevant to important questions in evolutionary biology, including sympatric speciation, generalist versus specialist adaptation, and parasite-host co-evolution. Here we show that a major locus strongly influences host preference in Nasonia. Nasonia are parasitic wasps that utilize fly pupae; Nasonia vitripennis is a generalist that parasitizes a diverse set of hosts, whereas Nasonia giraulti specializes in Protocalliphora (bird blowflies). In laboratory choice experiments using Protocalliphora and Sarcophaga (flesh flies), N. vitripennis shows a preference for Sarcophaga, whereas N. giraulti shows a preference for Protocalliphora. Through a series of interspecies crosses, we have introgressed a major locus affecting host preference from N. giraulti into N. vitripennis. The N. giraulti allele is dominant and greatly increases preference for Protocalliphora pupae in the introgression line relative to the recessive N. vitripennis allele. Through the utilization of a Nasonia genotyping microarray, we have identified the introgressed region as 16 Mb of chromosome 4, although a more complete analysis is necessary to determine the exact genetic architecture of host preference in the genus. To our knowledge, this is the first introgression of the host preference of one parasitoid species into another, as well as one of the few cases of introgression of a behavioral gene between species.

Different rates of nucleotide substitutions in Wolbachia endosymbionts of arthropods and nematodes: arms race or host shifts?

The genus Wolbachia encompasses intracellular bacteria found in arthropods and in filarial nematodes. In arthropods, Wolbachia is primarily a reproductive parasite and shows relatively frequent horizontal transfer between host species, while in nematodes it appears to be a mutualist and is strictly vertically transmitted. We can expect that different selective pressures are acting on their genomes. Here we present an analysis of three Wolbachia genes, wsp, ftsZ and dnaA. In wsp of arthropod Wolbachia, an excess of non-synonymous substitutions was observed, providing evidence for positive selection. In nematode Wolbachia, no evidence for positive selection was found. Pressure for amino acid variation in wsp of arthropod Wolbachia could derive either from an arms race with the host or from the occurrence of more frequent hosts shifts due to horizontal transmission. In nematode Wolbachia, the lack of positively selected sites could result from the absence of an arms race, or from the homogeneity of the biochemical environment they exist in (ensured by strict vertical transmission). In ftsZ minor differences in substitution patterns were observed between arthropod and nematode Wolbachia, only in the 3'-portion of the gene. dnaA showed comparable patterns of variation in both lineages, with evidence for strong conservation.

Intrachromosomal genomic instability in human sporadic colorectal cancer measured by genome-wide allelotyping and inter-(simple sequence repeat) PCR.

We have used genome-wide allelotyping with 348 polymorphic autosomal markers spaced, on average, 10 cM apart to quantitate the extent of intrachromosomal instability in 59 human sporadic colorectal carcinomas. We have compared instability measured by this method with that measured by inter-(simple sequence repeat) PCR and microsatellite instability assays. Instability quantitated by fractional allelic loss rates was found to be independent of that detected by microsatellite instability analyses but was weakly associated with that measured by inter-(simple sequence repeat) PCR. A set of seven loci were identified that were most strongly associated with elevated rates of fractional allelic loss and/or inter-(simple sequence repeat) PCR instability; these seven loci were on chromosomes 3, 8, 11, 13, 14, 18, and 20. A lesser association was seen with two loci flanking p53 on chromosome 17. Coordinate loss patterns for these loci suggest that at least two separate sets of cooperating loci exist for intrachromosomal genomic instability in human colorectal cancer.

Recombination in Wolbachia.

Wolbachia are widely distributed intracellular bacteria that cause a number of reproductive alterations in their eukaryotic hosts. Such alterations include the induction of parthenogenesis, feminization, cytoplasmic incompatibility, and male killing [1-11]. These important bacteria may play a role in rapid speciation in insects [12-14], and there is growing interest in their potential uses as tools for biological control and genetic manipulation of pests and disease vectors [15-16]. Here, we show recombination in the Wolbachia outer surface protein gene (wsp) between strains of Wolbachia. In addition, we find a possible ecological context for this recombination. Evidence indicates either genetic exchange between Wolbachia in a parasitoid wasp and in the fly that it parasitizes or horizontal transfer of Wolbachia between the parasitoid and the fly, followed by a recombination event. Results have important implications for the evolution of these bacteria and the potential use of Wolbachia in biological control.