Genetic characterization of Trypanosoma cruzi DTUs in wild Triatoma infestans from Bolivia: predominance of TcI

Background

The current persistence of Triatoma infestans (one of the main vectors of Chagas disease) in some domestic areas could be related to re-colonization by wild populations which are increasingly reported. However, the infection rate and the genetic characterization of the Trypanosoma cruzi strains infecting these populations are very limited.

Methodology/Principal Findings

Of 333 wild Triatoma infestans specimens collected from north to south of a Chagas disease endemic area in Bolivia, we characterized 234 stocks of Trypanosoma cruzi using mini-exon multiplex PCR (MMPCR) and sequencing the glucose phosphate isomerase (Gpi) gene. Of the six genetic lineages (“discrete typing units”; DTU) (TcI-VI) presently recognized in T. cruzi, TcI (99.1%) was overdominant on TcIII (0.9%) in wild Andean T. infestans, which presented a 71.7% infection rate as evaluated by microscopy. In the lowlands (Bolivian Chaco), 17 “dark morph” T. infestans were analyzed. None of them were positive for parasites after microscopic examination, although one TcI stock and one TcII stock were identified using MMPCR and sequencing.

Conclusions/Significance

By exploring large-scale DTUs that infect the wild populations of T. infestans, this study opens the discussion on the origin of TcI and TcV DTUs that are predominant in domestic Bolivian cycles.     

Mitochondrial DNA polymorphisms in Phytophthora infestans: New haplotypes are identified and re-defined by PCR

Polymorphisms of mitochondrial DNA (mt-DNA) are particularly useful for monitoring specific pathogen populations like Phytophthora infestans. Basically type I and II of P. infestans mt-DNA were categorized by means of polymorphism lengths caused by an ~ 2 kb insertion, which can be detected via restriction enzyme digestion. In addition genome sequencing of haplotype Ib has been used as a simple Polymerase Chain Reaction–Restriction Fragment Length Polymorphism (PCR–RFLP) method to indirectly identify type I and II alterations through EcoR I restriction enzyme DNA fragment patterns of the genomic P4 area. However, with the common method, wrong mt-DNA typing occurs due to an EcoR I recognition site mutation in the P4 genomic area. Genome sequencing of the four haplotypes (Ia, Ib, IIa, and IIb) allowed us to thoroughly examine mt-DNA polymorphisms and we indentified two hypervariable regions (HVRs) named HVRi and HVRii. The HVRi length polymorphism caused by a 2 kb insertion/deletion was utilized to identify mt-DNA types I and II, while another length polymorphism in the HVRii region is caused by a variable number of tandem repeats (n = 1, 2, or 3) of a 36 bp sized DNA stretch and was further used to determine mt-DNA sub-types, which were described as R_{n=1, 2, or 3}. Finally, the P. infestans mt-DNA haplotypes were re-defined as IR₁ or IIR₂ according to PCR derived HVRi and HVRii length polymorphisms. Twenty-three isolates were chosen to verify the feasibility of our new approach for identifying mt-DNA haplotypes and a total of five haplotypes (IR₁, IR₂, IR₃, IIR₂ and IIR₃) were identified. Additionally, we found that six isolates determined as type I by our method were mistakenly identified as type II by the PCR–RFLP technique. In conclusion, we propose a simple and rapid PCR method for identification of mt-DNA haplotypes based on sequence analyses of the mitochondrial P. infestans genome.     

Microsatellite variability and heterozygote excess in Elymus trachycaulus populations from British Columbia in Canada

Microsatellite markers were used to assess the genetic diversity and population structure in four populations of Elymus trachycaulus from British Columbia and one population of Elymus alaskanus from Northwest Territories. Fourteen microsatellite loci were used in this study. Our results indicated that E. trachycaulus is highly polymorphic, with an average percentage of polymorphic loci of 96.5% over the four populations. Average expected heterozygosity values (H_E or gene diversity) varied from 0.418 to 0.585 with a mean of 0.497. Most of the genetic variation was found within populations (85%) and the differentiation among populations was found to be 15% (F_st = 0.15). Interpopulation genetic distances corresponded well with the geographic distance between the population sites of origin, as well as morphological characteristics. Tests for Hardy–Weinberg equilibrium (HWE) for all loci and all populations revealed that all loci significantly differ from HWE. Subsequent analysis indicated that departure from HWE at some loci was due to an excess of heterozygotes. Possible explanations for heterozygote excess are discussed. The most likely reason for observed heterozygote excess could be due to the polyploidy nature of the species.     

Niche invasion,competition and coexistence amongst wild and domestic Bolivian populations of Chagas vector Triatoma infestans (Hemiptera,Reduviidae, Triatominae)

The model developed for human parasites by Bottomley et al. (2007) [52] has been adapted to the dynamics of triatomines to better understand the processes of niche invasion, competition among species and coexistence. In Bolivia, both wild and domestic populations of Triatoma infestans exist. Their ecological niches are normally separated and the two populations do not interbreed, behaving as two distinct species. However, it has been suggested that the two populations may compete, highlighting therefore the potential risk of wild populations invading human dwellings. The model revealed the importance of the basic reproduction rates R₀ of triatomine colonies for the risk of invasion. This depends not only on life traits such as survival and fecundity, but also on (1) the density-dependence phenomenon that limits triatomine establishment, (2) on house exposure to infection and (3) on the correlation between house susceptibility to domestic T. infestans and house susceptibility to wild T. infestans. Competition and coexistence amongst the two groups of T. infestans may occur under particular conditions, but are very unlikely.     

Characterization of microsatellite loci developed for <Emphasis Type="Italic">Amaranthus hypochondriacus</Emphasis> and their cross-amplifications in wild species

The present study reports isolation and characterization of 12 polymorphic microsatellite markers for Amaranthus hypochondriacus. A total of 92 alleles were detected across the 20 accessions, with an average of 7.7 alleles per locus. The observed (H _O ) and expected (H _E ) heterozygosity values ranged from 0 to 0.95 and from 0.49 to 0.92, respectively. At significance threshold (P < 0.05), nine loci deviated from Hardy-Weinberg equilibrium (HWE), whereas significant linkage disequilibria (LD) were observed between five pairs of loci. The 12 loci were successfully amplified in 18 other amaranth species representing cultivated grain and vegetable species, their putative progenitors and wild species. These results demonstrate wide potential applicability of these markers for the study of intra- and inter-specific genetic diversity as well as evolutionary relationships among cultivated and wild amaranths.     

Distribution of Pyrethroid Resistant Populations of Triatoma infestans in the Southern Cone of South America

BackgroundA number of studies published during the last 15 years showed the occurrence of insecticide resistance in Triatoma infestans populations. The different toxicological profiles and mechanisms of resistance to insecticides is due to a genetic base and environmental factors, being the insecticide selective pressure the best studied among the last factors. The studies on insecticide resistance on T. infestans did not consider the effect of environmental factors that may influence the distribution of resistance to pyrethroid insecticides. To fill this knowledge gap, the present study aims at studying the association between the spatial distribution of pyrethroid resistant populations of T. infestans and environmental variables.Conclusions/SignificanceThe occurrence of these two groups concentrated over a particular region that coincides with the area where populations of the intermediate cytogenetic group were found might reflect the spatial heterogeneity of the genetic variability of T. infestans, that seems to be the cause of the insecticide resistance in the area, even on sylvatic populations of T. infestans, never before exposed to pyrethroid insecticides, representing natural and wild toxicological phenotypes. The strong linear relationship found between LD₅₀ and RR₅₀ suggest RR₅₀ might not be the best indicator of insecticide resistance in triatomines.     

Clines with partial panmixia in an unbounded unidimensional habitat

In geographically structured populations, global panmixia can be regarded as the limiting case of long-distance migration. The effect of incorporating partial panmixia into diallelic single-locus clines maintained by migration and selection in an unbounded unidimensional habitat is investigated. Migration and selection are both weak. The former is homogenous and isotropic; the latter has no dominance. The population density is uniform. A simple, explicit formula is derived for the maximum value β₀ of the scaled panmictic rate β for which a cline exists. The former depends only on the asymptotic values of the scaled selection coefficient. If the two alleles have the same average selection coefficient, there exists a unique, globally asymptotically stable cline for every β≥0. Otherwise, if β≥β₀, the allele with the greater average selection coefficient is ultimately fixed. If β<β₀, there exists a unique, globally asymptotically stable cline, and some polymorphism is retained even infinitely far from its center. The gene frequencies at infinity are determined by a continuous-time, two-deme migration-selection model. An explicit expression is deduced for the monotone cline in a step-environment. These results differ fundamentally from those for the classical cline without panmixia.     

Clines with partial panmixia

In spatially distributed populations, global panmixia can be regarded as the limiting case of long-distance migration. The effect of incorporating partial panmixia into single-locus clines maintained by migration and selection is investigated. In a diallelic, two-deme model without dominance, partial panmixia can increase or decrease both the polymorphic area in the plane of the migration rates and the equilibrium gene-frequency difference between the two demes. For multiple alleles, under the assumptions that the number of demes is large and both migration and selection are arbitrary but weak, a system of integro-partial differential equations is derived. For two alleles with conservative migration, (i) a Lyapunov functional is found, suggesting generic global convergence of the gene frequency; (ii) conditions for the stability or instability of the fixation states, and hence for a protected polymorphism, are obtained; and (iii) a variational representation of the minimal selection-migration ratio λ₀ (the principal eigenvalue of the linearized system) for protection from loss is used to prove that λ₀ is an increasing function of the panmictic rate and to deduce the effect on λ₀ of changes in selection and migration. The unidimensional step-environment with uniform population density, homogeneous, isotropic migration, and no dominance is examined in detail: An explicit characteristic equation is derived for λ₀; bounds on λ₀ are established; and λ₀ is approximated in four limiting cases. An explicit formula is also deduced for the globally asymptotically stable cline in an unbounded habitat with a symmetric environment; partial panmixia maintains some polymorphism even as the distance from the center of the cline tends to infinity.     

Wild Populations of Triatoma infestans Are Highly Connected to Intra-Peridomestic Conspecific Populations in the Bolivian Andes

Triatoma infestans, the major vector of Chagas disease south of the Amazon in South America, has a large distribution of wild populations, contrary to what has previously been stated. These populations have been suspected of being the source of reinfestation of human habitats and could impede the full success of vector control campaigns. This study examined gene flow between intra-peridomestic populations and wild populations collected in the surround areas in three Andean localities in Bolivia. The populations were defined according to temporal, ecological, and spatial criteria. After DNA extraction from the legs of each insect, the samples were analyzed using seven microsatellite markers. First, the analysis of molecular variance (AMOVA) detected an absence of differentiation between wild and intra-peridomestic populations, although strong structuring was observed between the populations within each environment. Then for some populations, the Bayesian method of assignment to inferred populations showed very similar assignment patterns of the members of wild or intra-peridomestic populations in each locality. Finally, the detection of the first-generation migrants within the different populations provided evidence of insect displacement from the wild to the intra-peridomestic environment. This result indicates that, after control campaigns in the Andes, controlling this new paradigm of vector transmission risk stemming from the invasion of human habitats by wild populations of T. infestans requires long-term maintenance of public monitoring to keep the risk at a minimal level. Since wild populations of T. infestans have also been detected elsewhere in Argentina, Paraguay, and Chile, there is an urgent need to take these populations into account in future monitoring of Chagas disease transmission.     

Evolution under domestication: ongoing artificial selection and divergence of wild and managed Stenocereus pruinosus (Cactaceae) populations in the Tehuac��n Valley, Mexico

Background and Aims

The Tehuacán Valley in Mexico is a principal area of plant domestication in Mesoamerica. There, artificial selection is currently practised on nearly 120 native plant species with coexisting wild, silvicultural and cultivated populations, providing an excellent setting for studying ongoing mechanisms of evolution under domestication. One of these species is the columnar cactus Stenocereus pruinosus, in which we studied how artificial selection is operating through traditional management and whether it has determined morphological and genetic divergence between wild and managed populations.

Methods

Semi-structured interviews were conducted with 83 households of three villages to investigate motives and mechanisms of artificial selection. Management effects were studied by comparing variation patterns of 14 morphological characters and population genetics (four microsatellite loci) of 264 plants from nine wild, silvicultural and cultivated populations.

Key Results

Variation in fruit characters was recognized by most people, and was the principal target of artificial selection directed to favour larger and sweeter fruits with thinner or thicker peel, fewer spines and pulp colours others than red. Artificial selection operates in agroforestry systems favouring abundance (through not felling plants and planting branches) of the preferred phenotypes, and acts more intensely in household gardens. Significant morphological divergence between wild and managed populations was observed in fruit characters and plant vigour. On average, genetic diversity in silvicultural populations (H_E = 0·743) was higher than in wild (H_E = 0·726) and cultivated (H_E = 0·700) populations. Most of the genetic variation (90·58 %) occurred within populations. High gene flow (Nm_FST > 2) was identified among almost all populations studied, but was slightly limited by mountains among wild populations, and by artificial selection among wild and managed populations.

Conclusions

Traditional management of S. pruinosus involves artificial selection, which, despite the high levels of gene flow, has promoted morphological divergence and moderate genetic structure between wild and managed populations, while conserving genetic diversity.     

Genetic Variation within Native Populations of Endemic Silkmoth Antheraea assamensis (Helfer) from Northeast India Indicates Need for In Situ Conservation

A. assamensis is a phytophagous Lepidoptera from Northeast India reared on host trees of Lauraceae family for its characteristic cocoon silk. Source of these cocoons are domesticated farm stocks that crash frequently and/or wild insect populations that provide new cultures. The need to reduce dependence on wild populations for cocoons necessitates assessment of genetic diversity in cultivated and wild populations. Molecular markers based on PCR of Inter-simple sequence repeats (ISSR) and simple sequence repeats (SSR) were used with four populations of wild insects and eleven populations of cultivated insects. Wild populations had high genetic diversity estimates (H_i = 0.25; H_S = 0.28; H_E = 0.42) and at least one population contained private alleles. Both marker systems indicated that genetic variability within populations examined was significantly high. Among cultivated populations, insects of the Upper Assam region (H_i = 0.19; H_S = 0.18; H_E = 0) were genetically distinct (F _ST = 0.38 with both marker systems) from insects of Lower Assam (H_i = 0.24; H_S = 0.25; H_E = 0.3). Sequencing of polymorphic amplicons suggested transposition as a mechanism for maintaining genomic diversity. Implications for conservation of native populations in the wild and preserving in-farm diversity are discussed.     

Genetic structure and association mapping of adaptive and selective traits in the east Texas loblolly pine (Pinus taeda L.) breeding populations

First-generation selection (FGS) and second-generation selection (SGS) breeding populations of loblolly pine from east Texas were studied to estimate the genetic diversity, population structure, linkage disequilibrium (LD), signatures of selection and association of breeding traits with a genome-wide panel of 4,264 single nucleotide polymorphisms (SNPs). Relatively high levels of observed (H _o?=?0.178–0.198) and expected (H _e?=?0.180–0.198) heterozygosities were observed in all populations. The amount of inbreeding was very low with many populations exhibiting a slight excess of heterozygotes. The population structure was weak, but F _ST indicated more pronounced differentiation in the SGS populations. As expected for outcrossing natural populations, the genome-wide LD was low, but marker density was insufficient to deduce the decay rate. Numerous associations were found between various phenotypic traits and SNPs, but only a few remained significant after false positive correction. Signatures of diversifying and balancing selection were found in markers representing important biological functions. These results present the first step in the application of marker-assisted selection (MAS) to the Western Gulf Forest Tree Improvement Program (WGFTIP) for loblolly pine and will contribute to the knowledgebase necessary for genomic selection technology.     

The dihydrolipoyl acyltransferase gene BCE2 participates in basal resistance against Phytophthora infestans in potato and Nicotiana benthamiana

Dihydrolipoyl acyltransferase (EC 2.3.1.12), a branched-chain α-ketoacid dehydrogenase E2 subunit (BCE2), catalyzes the transfer of the acyl group from the lipoyl moiety to coenzyme A. However, the role of BCE2 responding to biotic stress in plant is not clear. In this study, we cloned and characterized a BCE2 gene from potato, namely StBCE2, which was previously suggested to be involved in Phytophthora infestans–potato interaction. We found that the expression of StBCE2 was strongly induced by both P. infestans isolate HB09-14-2 and salicylic acid. Besides, when the homolog of StBCE2 in Nicotiana benthamiana named NbBCE2 was silenced, plants showed increased susceptibility to P. infestans and reduced accumulation of hydrogen peroxide (H₂O₂). Furthermore, we found that a marker gene NbrbohB involved in the production of reactive oxygen species, was also suppressed in NbBCE2-silenced plants. However, silencing of NbBCE2 had no significant effect on the hypersensitive responses trigged by INF1, R3a-AVR3a^KI pair or Rpi-vnt1.1-AVR-vnt1.1 pair. Our results suggest that BCE2 is associated with the basal resistance to P. infestans by regulating H₂O₂ production.     

Genetic diversity and relationships among wild and cultivated Stenocereus queretaroensis populations in western Mexico

Stenocereus queretaroensis is an endemic, chiropterophilous, columnar cactus of economic importance in Mexico. To investigate the effect of artificial selection on genetic diversity, inter-simple sequence repeat (ISSR) markers were used to estimate the genetic variation of wild, orchard, and backyard populations of S. queretaroensis from two regions in western Mexico. Six primers were used to generate 62 bands, of which 39 were polymorphic (62.9%). The total genetic diversity was similar in the wild (H_T = 0.296) and orchard (H_T = 0.291) groups, and slightly lower in the backyard group (H_T = 0.281). Wild populations (F_ST = 0.13) were less differentiated than backyard (F_ST = 0.17) and orchard (F_ST = 0.21) populations. The wild and backyard groups were genetically closer (0.015) than the wild and orchard (0.018) groups. A Mantel test revealed a positive correlation between genetic and geographic distances (r = 0.433, p = 0.002). In conclusion, gene flow and the prevailing management system have efficiently maintained genetic diversity and facilitated inter-population differentiation in S. queretaroensis.     

Isolation and characterization of 11 microsatellite loci from Camellia sinensis in Taiwan using PCR-based isolation of microsatellite arrays (PIMA)

We report 11 novel microsatellite primer pairs for the wild tea, Camellia sinensis (L.) O. Kuntze forma formosensis Kitamura. These simple sequence repeat markers were tested in 24 samples collected from wild tea populations, and in cultivars and C. japonica. The number of alleles ranged from 4 to18. The expected (H _E) and observed (H _O) heterozygosity were 0.687–0.946 and 0.042–0.792, respectively. All loci were significantly deviated from Hardy-Weinberg expectations due to the heterozygote deficiency, indicating a dramatic loss of genetic polymorphisms in the rare species. Significant LD was discovered in most loci. These primers may provide a tool for understanding demography and population structure in wild tea.     

Development of thirty-five novel polymorphic microsatellite markers in Pseudosciaena polyactis (Perciformes:Sciaenidae) and cross-species amplification in closely related species,Pseudosciaena crocea

Small yellow croaker, Pseudosciaena polyactis, is an economically important marine fishery species. In this study, we isolated 35 novel polymorphic microsatellite primers in P. polyactis by using the combined biotin capture method. The polymorphism of each locus was assessed in 30 individuals from Donggang, Northern Yellow Sea, China. A total of 519 alleles were detected and the number of alleles per locus ranged from 3 to 23. The PIC values of these 35 microsatellite loci ranged from 0.367 to 0.940. The observed (H_o) and expected heterozygosity (H_e) per locus ranged from 0.233 to 1.000 and from 0.438 to 0.943, respectively. Seven loci significantly deviated from Hardy–Weinberg equilibrium (HWE) after Bonferroni correction and no significant linkage disequilibrium (LD) was found between pairs of loci. In addition, cross-species amplification was performed in Pseudosciaena crocea, a closely related species of P. polyactis, to assess the applicability of these markers. These polymorphic microsatellites will provide useful tools for the study of genetic diversity and population structure of P. polyactis and P. crocea.