Identification of Self Incompatibility (S) Alleles in Turkish Apple Gene Sources using Allele-specific PCR-Reference-Cited by-同舟云学术

Identification of Self Incompatibility (S) Alleles in Turkish Apple Gene Sources using Allele-specific PCR

Published:2023-01-31 Issue: Volume: Page:287-296
ISSN:1300-7580
Container-title:Tarım Bilimleri Dergisi
language:en
Short-container-title:J Agr Sci-Tarim Bili

Author:

KARATAŞ Merve Dilek¹^ORCID,HAZRATİ Nahid²,YÜKSEL ÖZMEN Canan²,HASANZADEH Mohammad³,ALTINTAŞ Serdar⁴,AKÇAY Mehmet Emin⁵,ERGÜL Ali⁶

Affiliation:

1. VAN YUZUNCU YIL UNIVERSITY, FACULTY OF AGRICULTURE, AGRICULTURAL BIOTECHNOLOGY PR.

2. ANKARA UNIVERSITY, INSTITUTE OF BIOTECHNOLOGY

3. Mohaghegh Ardabili University, Faculty of Agriculture and Natural Resources-Moghan, Department of Plant Production

4. SIIRT UNIVERSITY, FACULTY OF AGRICULTURE, DEPARTMENT OF AGRICULTURAL BIOTECHNOLOGY

5. Republic of Turkey Ministry of Agriculture and Forestry, Atatürk Horticultural Central Research Institute

6. ANKARA UNIVERSITY BIOTECHNOLOGY INSTITUTE

Abstract

Self-incompatibility (SI) is a genetic mechanism in many flowering plants by which generative reproduction is prevented. The self-incompatibility caused by the genetic functions of the cell is controlled by genes called S genes or self-incompatibility genes. Self-incompatibility results in decreased pollination and ultimately yield loss. In apple (Malus domestica L.), self-incompatibility is controlled by multi-allelic S-locus. Approaches in the S-glycoprotein profiles and allele-specific PCR methods using the gene profiles and S-glycoprotein profiles for determination of the incompatibility levels are of great importance. In current study, the self-incompatibility status of 192 apple genotypes (such as, Amasya, Hüryemez, Şah elması, Tokat, Demir elması etc.) obtained from the National Collection of Atatürk Horticultural Central Research Institute, Yalova, Turkey, has been determined. For this purpose, genotype-specific allele status and compatibility levels were screened via PCR (Polymerase Chain Reaction) using 4 different S-alleles (Sd, Sf, S26 and S9). 181 genotypes containing at least 1 S-allele were identified as ‘Partially Incompatible’ and 12 genotypes involving 4 S-alleles were assigned ‘Totally Incompatible’. No S-alleles were observed in 2 genotypes (Pancarlık and Hüryemez) which exhibited ‘Compatibility’ status.

Publisher

Ankara University Faculty of Agriculture

Subject

Plant Science,Agronomy and Crop Science,Animal Science and Zoology

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