Selection for Oil Content During Soybean Domestication Revealed by X-Ray Tomography of Ancient Beans

Overview

Journal Sci Rep

Specialty Science

Date 2017 Feb 28

PMID 28240321

Citations 9

Authors

Yunbing Zong

Shengkun Yao

Gary W Crawford

Hui Fang

Jianfeng Lang

Jiadong Fan

Zhibin Sun

Yang Liu

Jianhua Zhang

Xiulan Duan

Guangzhao Zhou

Tiqiao Xiao

Fengshi Luan

Qing Wang

Xuexiang Chen

Huaidong Jiang

Affiliations

Soon will be listed here.

Abstract

When and under what circumstances domestication related traits evolved in soybean (Glycine max) is not well understood. Seed size has been a focus of archaeological attention because increased soybean seed weight/size is a trait that distinguishes most modern soybeans from their ancestors; however, archaeological seed size analysis has had limited success. Modern domesticated soybean has a significantly higher oil content than its wild counterpart so oil content is potentially a source of new insight into soybean domestication. We investigated soybean oil content using X-ray computed tomography (CT; specifically, synchrotron radiation X-ray CT or SRX-CT) of charred, archaeological soybean seeds. CT identified holes in the specimens that are associated with oil content. A high oil content facilitates the development of small holes, whereas a high protein content results in larger holes. The volume of small holes increased slowly from 7,500 to 4,000 cal B.P. We infer that human selection for higher oil content began as early as 7,500 cal B.P. and that high oil content cultivars were well established by 4,000 cal B.P.

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