Positive selection pressure introduces secondary mutations at Gag cleavage sites in human immunodeficiency virus type 1 harboring major protease resistance mutations.

Human immunodeficiency virus type 1 (HIV-1) protease inhibitors (PIs) specifically target the HIV-1 protease enzyme. Mutations in the enzyme can result in PI resistance (termed PI mutations); however, mutations in the HIV-1 gag region, the substrate for the protease enzyme, might also lead to PI resistance. We analyzed gag and pol sequence data from the following 313 HIV-1-infected patients: 160 treatment-naïve patients, 93 patients failing antiretroviral treatment that included a PI (with no major PI mutations), and 60 patients failing antiretroviral treatment that included a PI (with major PI mutations). Additional sequences from 13 patients were included for longitudinal analysis. We assessed positive selection pressure on the gag/protease region using a test for the overall influence of positive selection and a total of five tests to identify positively selected single codons. We found that positive selection pressure was the driving evolutionary force for the gag region in all three patient groups. An increase in positive selection was observed in gag cleavage site regions p7/p1/p6 only after the acquisition of major PI mutations, suggesting that amino acids in gag cleavage sites under positive selection pressure could function as compensatory mutations for major PI mutations in the protease region. Isolated gag mutations did not appear to confer PI resistance, but mutations in the gag cleavage sites could substitute for minor PI resistance mutations in the protease region.

Origin and domestication of the fungal wheat pathogen Mycosphaerella graminicola via sympatric speciation.

The Fertile Crescent represents the center of origin and earliest known place of domestication for many cereal crops. During the transition from wild grasses to domesticated cereals, many host-specialized pathogen species are thought to have emerged. A sister population of the wheat-adapted pathogen Mycosphaerella graminicola was identified on wild grasses collected in northwest Iran. Isolates of this wild grass pathogen from 5 locations in Iran were compared with 123 M. graminicola isolates from the Middle East, Europe, and North America. DNA sequencing revealed a close phylogenetic relationship between the pathogen populations. To reconstruct the evolutionary history of M. graminicola, we sequenced 6 nuclear loci encompassing 464 polymorphic sites. Coalescence analyses indicated a relatively recent origin of M. graminicola, coinciding with the known domestication of wheat in the Fertile Crescent around 8,000-9,000 BC. The sympatric divergence of populations was accompanied by strong genetic differentiation. At the present time, no genetic exchange occurs between pathogen populations on wheat and wild grasses although we found evidence that gene flow may have occurred since genetic differentiation of the populations.

Global migration patterns in the fungal wheat pathogen Phaeosphaeria nodorum.

The global migration patterns of the fungal wheat pathogen Phaeosphaeria nodorum were analysed using 12 microsatellite loci. Analysis of 693 isolates from nine populations indicated that the population structure of P. nodorum is characterized by high levels of genetic diversity and a low degree of subdivision between continents. To determine whether genetic similarity of populations was a result of recent divergence or extensive gene flow, the microsatellite data were analysed using an isolation-with-migration model. We found that the continental P. nodorum populations diverged recently, but that enough migration occurred to reduce population differentiation. The migration patterns of the pathogen indicate that immigrants originated mainly from populations in Europe, China and North America.