Flora diversity survey and establishment of a plant DNA barcode database of Lomas ecosystems in Peru.

Lomas formations or "fog oases" are islands of vegetation in the desert belt of the west coast of South America, with a unique vegetation composition among the world's deserts. However, plant diversity and conservation studies have long been neglected, and there exists a severe gap in plant DNA sequence information. To address the lack of DNA information, we conducted field collections and laboratory DNA sequencing to establish a DNA barcode reference library of Lomas plants from Peru. This database provides 1,207 plant specimens and 3,129 DNA barcodes data corresponding with collections from 16 Lomas locations in Peru, during 2017 and 2018. This database will facilitate both rapid species identification and basic studies on plant diversity, thereby enhancing our understanding of Lomas flora's composition and temporal variation, and providing valuable resources for conserving plant diversity and maintaining the stability of the fragile Lomas ecosystems.

Genetic diversity and genetic structure of Puya raimondii (Bromeliaceae) for its conservation in the Peruvian Andes

Resumen Puya raimondii es una especie endémica de los altos Andes de Perú y Bolivia. En el Perú se distribuye desde 8.068501°S, 16.170280°W hasta 16.180580° S, 70.658873° W, entre los 3600 y 4800 m de altitud, viviendo en condiciones climáticas extremas propias de la Puna, donde juega un papel ecológico importante. Pese a la amplia distribución de las poblaciones de P. raimondii en el Perú, aparentemente son bastante uniformes morfológicamente; por lo que surgen las siguientes preguntas: ¿Podrán las actuales herramientas moleculares mostrar diferencias entre las numerosas poblaciones? ¿Son suficientes las áreas de conservación establecidas para P. raimondii ya que albergan la variabilidad existente? Para responder a estas interrogantes, este trabajo tuvo como objetivo evaluar la diversidad genética y estructura genética en una población del norte del país, Pachapaqui (departamento de Ancash), una población del centro, Yanacancha (Junín), y una población del sur, Lampa - sector Choconchaca (Puno), utilizando marcadores microsatélites (SSR) específicos para la especie. Los parámetros de diversidad genética utilizados incluyeron número de alelos (A), alelos exclusivos (RA), heterocigosidad observada (Ho), heterocigosidad esperada (He) e índice de contenido polimórfico (PIC). Los resultados mostraron que el número total de A varió de 2 ‒ 13, los valores de He fueron 0 ‒ 0.723 y Ho 0 ‒ 0.929, con un He promedio de 0.217, indicando una diversidad genética moderada a alta, siendo la población de Lampa-sector Choconchaca, la que presentó mayor diversidad alélica y mayor diversidad genética. La prueba de Hardy-Weinberg mostró que las poblaciones se encuentran en desequilibrio HW, el análisis estadístico indica un 65% de variación genética a nivel poblacional y valores de FST (0.426) y RST (0.650) que indican alta diferenciación genética entre poblaciones, con dos grupos genéticos (K=2) que corresponden a las poblaciones del centro-norte y sur del Perú. Los resultados brindan información útil para establecer estrategias de conservación para P. raimondii, que conduzcan a la creación de una área de conservación adicional para proteger a las poblaciones del sur del Perú.

Abstract Puya raimondii is an endemic species from the high Andes of Peru and Bolivia. In Peru it is distributed from 8.068501°S, 16.170280°W to 16.180580°S, 70.658873°W, between 3600 and 4800 m, living in extreme climatic conditions typical of the Puna, where it plays an important ecological role. Despite the wide distribution of P. raimondii populations in Peru, they appear to be fairly uniform morphologically. The following questions arise: Will the current molecular tools be able to show differences between the numerous populations? Are the conservation areas established for P. raimondii sufficient since they harbor the existing variability? To answer these questions, this work aimed to evaluate the genetic diversity and genetic structure in a northern population, Pachapaqui (Ancash department), a central population, Yanacancha (Junin), and a southern population, Lampa - Choconchaca sector (Puno), using microsatellite markers (SSR) specific for the species. The genetic diversity parameters used included number of alleles (A), exclusive alleles (RA), observed heterozygosity (Ho), expected heterozygosity (He), and polymorphic content index (PIC). The results showed that the total number of A varied from 2 - 13, the He values were 0 ‒ 0.723 and Ho 0 ‒ 0.929, with an average He of 0.217, indicating a moderate to high genetic diversity, being the population of Lampa-Choconchaca sector, the one that presented the greatest allelic diversity and the greatest genetic diversity. The Hardy-Weinberg test showed that the populations are in HW disequilibrium, the statistical analysis indicates 65% of the genetic variation at the population level and values of FST (0.426) and RST (0.650) that indicate high genetic differentiation among populations, with two genetic groups (K=2) that correspond to the populations of northern-central and southern Peru. The results provide useful information to establish conservation strategies for P. raimondii, which lead to the creation of an additional conservation area to protect the populations in southern Peru.

Microsatellite markers for the endangered Puya raimondii in Peru.

PREMISE: Microsatellite primers were developed for Puya raimondii (Bromeliaceae), an endangered species distributed in the Andean Mountains of Bolivia and Peru. METHODS AND RESULTS: Genome skimming of P. raimondii, P. macrura, and P. hutchisonii resulted in the selection of 46 pairs of cross-species microsatellite markers. Of these, 12 microsatellite primer pairs produced clear and polymorphic bands in P. raimondii. These primer sets were then used for the detection of potential polymorphisms in 84 P. raimondii individuals collected from four populations in Peru. The number of alleles per locus ranged from one to six, and the observed and expected levels of heterozygosity ranged from 0.000 to 0.8929 and from 0.000 to 0.7662, respectively. CONCLUSIONS: The microsatellite markers developed in this study will be useful for future population genetic analyses and breeding system studies in P. raimondii.

The emergence of the hyperinvasive vine, Mikania micrantha (Asteraceae), via admixture and founder events inferred from population transcriptomics.

Biological invasions that involve well-documented rapid adaptations to new environments provide unequalled opportunities for testing evolutionary hypotheses. Mikania micrantha Kunth (Asteraceae), a perennial herbaceous vine native to tropical Central and South America, successfully invaded tropical Asia in the early 20th century. It is regarded as one of the most aggressive weeds in the world. To elucidate the molecular and evolutionary processes underlying this invasion, we extensively sampled this weed throughout its invaded range in South-East and South Asia and surveyed its genetic structure using variants detected from population transcriptomics. Clustering results suggest that more than one source population contributed to this invasion. Computer simulations using genomewide genetic variation support a scenario of admixture and founder events during invasion. The genes differentially expressed between native and invasive populations were found to be involved in oxidative and high light intensity stress responses, pointing to a possible ecological mechanism of adaptation. Our results provide a foundation for further detailed mechanistic and population studies of this ecologically and economically important invasion. This line of research promises to provide new mitigation strategies for invasive species as well as insights into mechanisms of adaptation.