Phytophthora infestans (Mont.) de Bary caused the 19th century Irish Potato Famine. We assessed the genealogical history of P. infestans using sequences from portions of two nuclear genes (-tubulin and Ras) and several mitochondrial loci P3, (rpl14, rpl5, tRNA) and P4 (Cox1) from 94 isolates from South, Central, and North America, as well as Ireland. Summary statistics, migration analyses and the genealogy of current populations of P. infestans for both nuclear and mitochondrial loci are consistent with an ''out of South America'' origin for P. infestans. Mexican populations of P. infestans from the putative center of origin in Toluca Mexico harbored less nucleotide and haplotype diversity than Andean populations. Coalescent-based genealogies of all loci were congruent and demonstrate the existence of two lineages leading to present day haplotypes of P. infestans on potatoes. The oldest lineage associated with isolates from the section Anarrhichomenun including Solanum tetrapetalum from Ecuador was identified as Phytophthora andina and evolved from a common ancestor of P. infestans. Nuclear and mitochondrial haplotypes found in Toluca Mexico were derived from only one of the two lineages, whereas haplotypes from Andean populations in Peru and Ecuador were derived from both lineages. Haplotypes found in populations from the U.S. and Ireland was derived from both ancestral lineages that occur in South America suggesting a common ancestry among these populations. The geographic distribution of mutations on the rooted gene genealogies demonstrate that the oldest mutations in P. infestans originated in South America and are consistent with a South American origin.late blight ͉ oomycetes ͉ phylogeography ͉ Solanum tuberosum ͉ stamenopiles
The mitochondrial genomes of haplotypes of the Irish potato famine pathogen, Phytophthora infestans, were sequenced. The genome sizes were 37,922, 39,870 and 39,840 bp for the type Ia, IIa and IIb mitochondrial DNA (mtDNA) haplotypes, respectively. The mitochondrial genome size for the type Ib haplotype, previously sequenced by others, was 37,957 bp. More than 90% of the genome contained coding regions. The GC content was 22.3%. A total of 18 genes involved in electron transport, 2 RNA-encoding genes, 16 ribosomal protein genes and 25 transfer RNA genes were coded on both strands with a conserved arrangement among the haplotypes. The type I haplotypes contained six unique open reading frames (ORFs) of unknown function while the type II haplotypes contained 13 ORFs of unknown function. Polymorphisms were observed in both coding and non-coding regions although the highest variation was in non-coding regions. The type I haplotypes (Ia and Ib) differed by only 14 polymorphic sites, whereas the type II haplotypes (IIa and IIb) differed by 50 polymorphic sites. The largest number (152) of polymorphic sites was found between the type IIb and Ia haplotypes. A large spacer flanked by the genes coding for tRNA-Tyr (trnY) and the small subunit RNA (rns) contained the largest number of polymorphic sites and corresponds to the region where a large indel that differentiates type II from type I haplotypes is located. The size of this region was 785, 2,666 and 2,670 bp in type Ia, IIa and IIb haplotypes, respectively. Among the four haplotypes, 81 mutations were identified. Phylogenetic and coalescent analysis revealed that although the type I and II haplotypes shared a common ancestor, they clearly formed two independent lineages that evolved independently. The type II haplotypes diverged earlier than the type I haplotypes. Thus our data do not support the previous hypothesis that the type II lineages evolved from the type I lineages. The type I haplotypes diverged more recently and the mutations associated with the evolution of the Ia and Ib types were identified.
Phylogenetic relationships of Phytophthora infestans sensu lato in the Andean highlands of South America were examined. Three clonal lineages (US-1, EC-1, EC-3) and one heterogeneous lineage (EC-2) were found in association with different host species in genus Solanum. The EC-2 lineage includes two mitochondrial (mtDNA) haplotypes, Ia and Ic. Isolates of P. infestans sensu lato EC-2 fit the morphological description of P. infestans but are different from any genotypes of P. infestans described to date. All isolates of P. infestans sensu lato from Ecuador were amplified by a P. infestans specific primer (PINF), and restriction fragment length patterns were identical in isolates amplified with ITS primers 4 and 5. The EC-1 clonal lineage of P. infestans sensu lato from S. andreanum, S. columbianum, S. paucijugum, S. phureja, S. regularifolium, S. tuberosum and S. tuquerense was confirmed to be P. infestans based on sequences of the cytochrome oxidase I (cox I) gene and intron 1 of ras gene. The EC-2 isolates with the Ic haplotype formed a distinct branch in the same clade with P. infestans and P. mirabilis, P. phaseoli and P. ipomoeae for both cox I and ras intron 1 phylogenies and were identified as the newly described species P. andina. Ras intron 1 sequence data suggests that P. andina might have arisen via hybridization between P. infestans and P. mirabilis.
Coffee (Coffea arabica L. cv. Catuai) seedlings with abundant small root galls caused by an unknown root-knot nematode were found in southern Costa Rica. Morphology, esterase and malate dehydrogenase isozyme phenotypes and DNA markers differentiated this nematode from known Meloidogyne spp. A new species, M. lopezi n. sp., with common name Costa Rican root-knot nematode, is suggested. Meloidogyne lopezi n. sp. is distinguished from other coffee-associated Meloidogyne spp. by size of female lips and stylet, male body length and stylet and second-stage juvenile body and tail morphology. The region of the mitochondrial genome between COII and 16S rRNA showed a unique amplicon size of 1370 bp, and digestions with restriction enzymes HinfI, AluI, DraI and DraIII revealed characteristic PCR-RFLP patterns that differed from the tropical root-knot nematode species M. arabicida, M. incognita, M. izalcoensis, M. javanica and M. paranaensis. Characterisation of the protein-coding map-1 gene and phylogenetic analyses suggested that M. lopezi n. sp. might reproduce by mitotic parthenogenesis. Phylogenies estimated using Bayesian analyses based on the region between the COII and 16S rRNA mitochondrial genes, as well as the 18S and 28S ribosomal nuclear genes, indicated that M. lopezi n. sp. is closely related to other tropical Meloidogyne spp. that infect coffee, especially M. arabicida, M. izalcoensis and M. paranaensis from Central and South America. Isozyme analyses and PCR-RFLP of the COII-16S rRNA mitochondrial gene region enable a clear diagnostic differentiation between these species.
La antracnosis, causada por Colletotrichum spp., es una de la enfermedades poscosecha más importantes en papaya. En este estudio, frutas de papaya, híbrido Pococí, recolectados en plantaciones ubicadas en el cantón de Guácimo, provincia de Limón, presentaron 7 síntomas de antracnosis, luego de un período de almacenamiento. De cada síntoma se obtuvieron aislados de Colletotrichum en medio de cultivo PDA (papa-dextrosa-agar). Los aislamientos se clasificaron en 3 grupos según la similitud de los síntomas y la morfología de la colonia. El análisis de la secuencia de la región espaciadora interna transcrita (ITS) del ADN ribosomal reveló que los aislamientos pertenecieron a 3 especies del género Colletotrichum: C. gloeosporioides sensu lato, C. magnum y C. capsici (C. truncatum). La identificación de las especies fue confirmada con imprimadores taxón específico para C. gloeosporioides e imprimadores especie-específicos para C. magnum. Las 3 especies identificadas mostraron ser patogénicas sobre frutas de papaya. Las especies C. magnum y C. capsici (C. truncatum) se registran por primera vez en Costa Rica, como agentes causales de la antracnosis en papaya.
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