Construction of an Anchoring SSR Marker Genetic Linkage Map and Detection of a Sex-linked Region in Two Dioecious Populations of Red Bayberry

Overview

Journal Hortic Res

Publisher Oxford University Press

Date 2020 Apr 8

PMID 32257239

Citations 10

Authors

Yan Wang

Hui-Min Jia

Yu-Tong Shen

Hai-Bo Zhao

Qin-Song Yang

Chang-Qing Zhu

De-Li Sun

Guo-Yun Wang

Chao-Chao Zhou

Yun Jiao

Chun-Yan Chai

Li-Ju Yan

Xiong-Wei Li

Hui-Juan Jia

Zhong-Shan Gao

Affiliations

Soon will be listed here.

Abstract

Red bayberry () is an evergreen fruit tree found in southern China whose whole-genome sequence has recently been published. We updated the linkage map of the species by adding 118 SSR markers and the female-specific marker MrFT2_BD-SEX. The integrated map included eight linkage groups and spanned 491 cM. Eleven sex-associated markers were identified, six of which were located in linkage group 8, in agreement with the previously reported location of the sex-determining region. The MrFT2_BD-SEX marker was genotyped in 203 cultivated accessions. Among the females of the accessions, we found two female-specific alleles, designated W-b (151 bp) and W-d (129 bp). We previously found that Dongkui, a female cultivar, could produce viable pollen (we refer to such plants Dongkui-male) and serve as the paternal parent in crosses. The genotypes of the MrFT2_BD-SEX marker were W-b/Z in Biqi and W-d/Z in Dongkui-male. The progeny of a cross between these parents produced a 3:1 female (W-) to male (ZZ) ratio and the expected 1:1:1:1 ratio of W-b/W-d: W-b/Z: W-d/Z: Z/Z. In addition, the flowering and fruiting phenotypes of all the F1 progeny fit their genotypes. Our results confirm the existence of ZW sex determination and show that the female phenotype is controlled by a single dominant locus (W) in a small genomic region (59 kb and less than 3.3 cM). Furthermore, we have produced a homozygous "super female" (WW) that should produce all-female offspring in the F2 generation, providing a foundation for commercial use and presenting great potential for use in modern breeding programs.

Citing Articles

T2T reference genome assembly and genome-wide association study reveal the genetic basis of Chinese bayberry fruit quality.

Zhang S, Yu Z, Sun L, Liang S, Xu F, Li S Hortic Res. 2024; 11(3):uhae033.

PMID: 38495030 PMC: 10940123. DOI: 10.1093/hr/uhae033.

SSR Marker Acquisition and Application from Transcriptome of Captive Chinese Forest Musk Deer (Moschus berezovskii).

Yang J, Luo W, Geng Y, Wei H, Wang J, Gao M Biochem Genet. 2023; 62(4):3215-3230.

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An overview of the nutritional value, health properties, and future challenges of Chinese bayberry.

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MrTPS3 and MrTPS20 Are Responsible for β-Caryophyllene and α-Pinene Production, Respectively, in Red Bayberry ().

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Gene as a New Sex-Identification Marker in Fig ( L.) Is More Efficient Than .

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