Majallah-i ̒Ulum-i Bāghbānī (Feb 2018)

Study of Genetic Diversity of Some Persian walnut Genotypes in Mashhad Commercial Orchards by using ISSR Marker

  • Shadi Attar,
  • Gholamhossein Davarynejad,
  • Leila Samiee,
  • Mohammad Moghadam

DOI
https://doi.org/10.22067/jhorts4.v31i3.60521
Journal volume & issue
Vol. 31, no. 3
pp. 611 – 620

Abstract

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Introduction: Persian walnut (Juglans regia L.), belonging to the Juglandaceae family, has its natural origin in the mountainous regions of central Asia and especially northern forests of Iran. Most walnut genotypes are seedling and sexually reproduced. Conducting studies on the genetic structure of these genotypes to identify, select and maintain their genetic resources is important. Identifying and collecting local varieties of fruit trees is considered as the first step on the path of breeding programs and lack of information regarding plants genetic characteristics causes the breeding work to be done slowly. Various methods have been used for studying genetic diversity and determining the genetic relationship between European and Asian varieties of walnut and identifying commercial walnut varieties, among which we can mention: Morphologic indices, Alozyme, Isozym, RFLP, RAPD, AFLP and ISSR markers. ISSR molecular marker was used in order to investigate genetic diversity of some genotypes of Persian walnut (Juglans regia L.) in Mashhad orchards. . Materials and methods: To begin with, about 56 walnut trees from 4 orchards in Mashhad (Esteghlal (1), Golestan (2), Alandasht (3) and Emam Reza (4)) were selected and tagged from 2014 to 2016. In the spring of 2014 with the beginning of trees growth and opening of leaves, a number of leaves from each genotype were collected. After DNA extraction, the quality of samples by agarose gel (1 percentage) and electrophoresis method and quantity of them via spectrophotometer device at 260 and 280 nm wavelengths were determined. First, 24 primers of ISSR marker were prepared and after initial evaluation on 5 random genotypes, 9 primers with high polymorphism and repeatability were selected for further investigation. For PCR reaction, Amplicon kit (code 180 301, made in Denmark) was used. Gel electrophoresis images of primers that produced polymorphic bands with suitable resolution were analyzed manually. After scoring the bands, in which 0 used for showing the absence of a band and 1 showing the presence of a band in each sample, 1 and 0 numbers were changed to matrix by using NTedit software. Genetic similarities of samples were calculated by using NTSYSpc software, SIMQUAL method and DICE similarity coefficient. Dendrogram by cluster analysis was drawn by using UPGMA method. Principle coordinate analysis (PCO) was performed using the NTSYS software and grouping samples were evaluated in a two-dimensional plot. Results and discussion: Results showed that from 9 primers in total, 118 bands amplified were in 300 to 3000 base pairs, while 29 bands were polymorphic. The number of amplified fragment for each primer was different so that UBC 844 (14 bands) had the highest and UBC 890 (8 bands) had the lowest amplified bands. The average amplified fragments for each primer was 9.83. The percentage of polymorphic in various primers was different. Maximum polymorphism (80%) of the primers was observed in UBC830. In general, according to the percentage of polymorphic bands, low adjustment to any changes in the environment was indicated. This can be used as an indicator to determine the value of diversity and genetic erosion. In genotypes cluster analysis, clustering was performed based on Dice similarity coefficient and UPGMA method, and 10 clusters were formed. ISSR molecular marker somewhat revealed genetic diversity among walnuts genotypes, whereas the genetic diversity was lower than expected. In general, by reviewing the findings in other parts of the world about walnut genetic diversity and comparing them with the results of this study, despite existing high genetic diversity among walnuts in many areas, some reports of low genetic diversity among walnuts populations have been published and unfortunately in recent years these reports has made more attention. Based on the results of several studies reporting low genetic diversity among walnuts, the following factors can be effective in this problem: natural disasters, human impacts such as deforestation and selection and propagation of superior genotypes, and sometimes walnuts self - pollination. In this respect, there is concern that if this trend of decreasing genetic diversity in the walnut population continues, this invaluable crop will be in danger of extinction. So we should think about a remedy. Finally, this investigation can be used as a start for conducting more researches in the region to maintain and manage this valuable crop germplasm and maximize genetic diversity for performing breeding programs in the future.

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