VARIABILIDAD GENÉTICA DE PARENTALES Y POBLACIONES F1 INTER E INTRAESPECÍFICAS DE Physalis peruviana L. Y P. floridana Rydb.

Berdugo-Cely, Jhon A.; Rodríguez, Felix Enciso; Almario, Carolina González; Meneses, Luz Stella Barrero

doi:10.1590/0100-2945-002/14

Cited by 12 publications

(9 citation statements)

References 14 publications

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“…Las tres poblaciones mostraron baja diversidad genética, incluso San Pablo presentó nula. Los valores bajos de diversidad genética se generan por la presencia de una población estructurada, que puede ser generada en poblaciones cultivadas por dos razones principales: (1) el tipo de reproducción vegetal, principalmente en autógamas, lo cual no es el caso pues aguaymanto es principalmente alógama (Cely et al 2015) y (2) la presencia de un programa de mejora genetica; esto último fue mencionado por los representantes de las empresas que cultivan los denominados ecotipos Agroandino y Celendino, quienes aplican el método de selección de masal. Por lo tanto, esta sería la razón de la baja diversidad genética encontrada.…”

Section: Discussionunclassified

Diversidad genética de tres poblaciones de Physalis peruviana a partir del fraccionamiento y patrón electroforético de proteínas de reserva seminal

et al. 2019

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En el presente trabajo, es estudiada la diversidad genética de tres poblaciones atribuidas a ecotipos de aguaymanto, Physalis peruaviana. Las tres poblaciones eran atribuidas a los ecotipos Agroandino (provincia de San Pablo), Celendino (provincia de Celendín) y Cajabamba (provincia de Cajabamba) del departamento de Cajamarca. Se realizó la cuantificación proteica y evaluó el polimorfismo de las proteínas de reserva seminal (SSPs) mediante electroforesis en gel de poliacrilamida denaturante (SDS-PAGE). Además, se identificaron características bioquímicas de las proteínas seminales en esta especie. No se hallaron diferencias entre las tres poblaciones basados en la cuantificación proteica. Las globulinas (82.4%) fueron la fracción mayoritaria seguida por las albuminas (13.9%), glutelinas (3.7%) y prolaminas (0.7%). Sólo las albuminas mostraron polimorfismo, hallándose 21 proteínas entre ~ 6.5 a ~45 kDa y tres perfiles electroforéticos diferentes, los cuales fueron compartidos entre las poblaciones. Se identificaron las leguminas y vicilinas en la fracción globulina. Las glutelinas mostraron proteínas de mismo peso molecular (PM) a las leguminas; y las prolaminas sólo una banda de bajo PM. La población de San Pablo fue completamente homogénea a diferencia de la población de Cajabamba que mostró la mayor diversidad genética seguida de Celendín. No fue posible diferenciar las poblaciones designadas como ecotipos Agroandino, Cajabamba y Celendino basados en el análisis de proteínas seminales.

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Section: Discussionunclassified

Diversidad genética de tres poblaciones de Physalis peruviana a partir del fraccionamiento y patrón electroforético de proteínas de reserva seminal

et al. 2019

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“…Consequently, we could carry out intraspecific crosses among genotypes with the same chromosomal numbers, expecting to obtain viable and stable progeny. A precedent example of the success of crossing between genotypes with the same ploidy is the work of Berdugo et al, (2015). In their study the authors made intraspecific crosses among accessions of P. peruviana with the same chromosome number, finding 100% viability in the progeny.…”

Section: Crossability Strategiesmentioning

confidence: 99%

“…Liberato et al, (2014) determined chromosome numbers of 2n = 4x = 48 and 2n = 2x = 24 that correlated with the nuclear DNA content estimated by flow cytometry. In addition, Berdugo et al, (2015) carried out crosses between some genotypes analyzed by Liberato et al, (2014) and found distortion in the segregation, possibly related to differences in the chromosome size or chromosome number of these materials. The cytogenetic variability, found in the collection of the germplasm bank maintained at Agrosavia and in the working collections, highlights the importance of knowing the cytogenetic identity of each genotype before its inclusion in hybridization-based breeding programs.…”

Section: Introductionmentioning

confidence: 99%

Cytogenetic and cytological analysis of advanced genetic material of cape gooseberry Physalis peruviana for use in plant breeding

et al. 2021

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The cape gooseberry, Physalis peruviana L., is a crop that is transitioning from a semi-wild rural food source to becoming an international export commodity fruit deserving of greater attention from the scientific community, producers, policy makers and opinion makers. Despite its importance, the crop has serious technological development challenges, mainly associated with the limited supply of genetically improved materials for producers and consumers. In the present study, the level of ploidy of 100 genotypes of gooseberry from a working collection was determined by counting the number of chromosomes and chloroplasts, to include them in the breeding program. The number of chromosomes in dividing cells of root-tip meristems, as well as the number of chloroplasts per guard cell, from plants grown in vitro and ex vitro conditions were determined. Haploid with 24 chromosomes, doubled haploid-tetraploid with 48 chromosomes, aneuploid (44 and 49 chromosomes) and mixoploid genotypes with 36 to 86 chromosomes were found. The number of chloroplasts / cell guard ranged from 4-8, 6-16, 7-16 and 9-21 for the haploid, aneuploid, doubled haploid-tetraploid and mixoploid genotypes, respectively. Evidence of a high cytogenetic diversity in the evaluated genotypes.

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“…They detected a low differentiation and high heterozygosity levels among the majority of the accessions [20,21]. Other studies used more informative markers, such as simple sequences repeats (SSRs), conserved ortholog sequences II (COSII), immunity related genes (IRGs) and single nucleotide polymorphisms (SNPs) to analyze the diversity levels and population structure in natural and breeding P. peruviana populations [22][23][24][25][26]. However, these low-throughput platforms provide a limited ability to estimate the extent of cape gooseberry genetic variability, since they focus on limited genomic regions.…”

Section: Introductionmentioning

confidence: 99%

Optimization of the genotyping‐by‐sequencing SNP calling for diversity analysis in cape gooseberry (Physalis peruviana L.) and related taxa

et al. 2020

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A robust Genotyping-By-Sequencing (GBS) pipeline platform was examined to provide accurate discovery of Single Nucleotide Polymorphisms (SNPs) in a cape gooseberry (Physalis peruviana L.) and related taxa germplasm collection. A total of 176 accessions representing, wild, weedy, and commercial cultivars as well as related taxa from the Colombian germplasm bank and other world repositories were screened using GBS. The pipeline parameters mnLCov of 0.5 and a mnScov of 0.7, tomato and potato genomes, and cape gooseberry transcriptome for read alignments, were selected to better assess diversity and population structure in cape gooseberry and related taxa. A total of 7,425 SNPs, derived from P. peruviana common tags (unique 64 bp sequences shared between selected species), were used. Within P. peruviana, five subpopulations with a high genetic diversity and allele fixation (H E : 0.35 to 0.36 and F IS :-0.11 to-0.01, respectively) were detected. Conversely, low genetic differentiation (F ST : 0.01 to 0.05) was also observed, indicating a high gene flow among subpopulations. These results contribute to the establishment of adequate conservation and breeding strategies for Cape gooseberry and closely related Physalis species.

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VARIABILIDAD GENÉTICA DE PARENTALES Y POBLACIONES F1 INTER E INTRAESPECÍFICAS DE Physalis peruviana L. Y P. floridana Rydb.

Cited by 12 publications

References 14 publications

Diversidad genética de tres poblaciones de Physalis peruviana a partir del fraccionamiento y patrón electroforético de proteínas de reserva seminal

Diversidad genética de tres poblaciones de Physalis peruviana a partir del fraccionamiento y patrón electroforético de proteínas de reserva seminal

Cytogenetic and cytological analysis of advanced genetic material of cape gooseberry Physalis peruviana for use in plant breeding

Optimization of the genotyping‐by‐sequencing SNP calling for diversity analysis in cape gooseberry (Physalis peruviana L.) and related taxa

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