This core collection encompassed 70.8% of the allelic variation present in the overall resistance collection. However, the sample size would increase dramatically if each of the individual specific traits were assigned to a specific core collection. But such a step would be inconvenient for researchers and would contravene the principle of core collection. For this reason, the soybean IACC developed in this study was assembled from accessions with different desirable
agronomic and nutritional traits. These accessions showed a high level of diversity with respect to target ON-01910 molecular weight traits, non-target traits, and molecular markers. Comparative analysis revealed that the diversity of phenotype and genetic background did not differ significantly between this newly formed IACC and the established MCC. However, the number of accessions with specific desirable traits is substantially greater in the IACC. Thus the concept of the IACC resolves the conflict between reducing sample size and concentrating genetic diversity. Furthermore, the strategy of integrating various
desirable traits in the IACC of soybean is consistent with the goal of soybean breeding. Some accessions with more than one specific trait can be used directly for breeding elite varieties. However, our study also showed that the diversity of small numbers of accessions with specific desirable traits (such as cold tolerance) differed from that of MCC. The number of such accessions should be increased in future studies. This work was supported by the State Key Basic Research and Development selleckchem Plan of China (973) (2010CB125900, 2009CB118400), the Fundamental Research Funds for Excellent Young Scientists of ICS-CAAS (Grant to Y. G.), the State High-tech Research and Development Program (863 Program) (No. 2012AA101106), and the Crop Germplasm Conservation Program (NB2010-2130135-25-05). The authors thank Dr. Chengguo Yao at the University of California, Irvine, USA for critical reading of the manuscript and the Methane monooxygenase reviewers for constructive comments on earlier
versions of this manuscript. “
“Among the cereals, wheat is the most widely grown in the world. Wheat starch is one of the primary food sources for humans, and the accumulation of starch in endosperm is a fundamental component of grain yield [1] and [2]. Starch is stored in the wheat endosperm as discrete semicrystalline aggregates called starch granules (SGs) [3]. Wheat SGs in mature grains are known to have a bimodal size distribution composed of larger A-type and smaller B-type SGs [4] and [5], which have been characterized structurally and evaluated for their functional properties [6]. In addition, a trimodal size distribution of A-, B- and C-type SGs has been observed by some researchers [7], [8] and [9]. The distribution of SGs influences the starch-to-protein ratio in the endosperm, thereby affecting flour composition and quality [10]. Many studies have reported on SG development in wheat endosperm.