Page Banner

United States Department of Agriculture

Agricultural Research Service

Related Topics

Research Project: IMPROVED FOOD QUALITY IN DRY BEANS USING GENETIC AND MOLECULAR APPROACHES

Location: Sugarbeet and Bean Research

2012 Annual Report


1a. Objectives (from AD-416):
Objective 1: Identify genetic factors controlling bean seed processing quality and consumer acceptance attributes and identify QTL(s) for related traits including seed coat color and appearance, hardness, and digestibility. Objective 2: Characterize genetic diversity for seed traits that influence human nutritional value of bean including antioxidant, mineral, and antinutrient levels that contribute to digestibility, and identify QTL(s) and gene(s) responsible for seed zinc accumulation.


1b. Approach (from AD-416):
Develop a linkage map for a black bean recombinant inbred line population using SSR and SNP markers. Use this resource identify QTL involved in canning quality and color retention in thermally processed beans, and to identify the Asp gene responsible for seed coat shine. Develop rapid phenotypic screens to for canning quality with near infrared spectroscopy. Measure variability for nutrient composition, cooking time, and sensory characteristics of modern and historically important dry bean varieties in the Mesoamerican gene pool. Develop populations of EMS mutagenized beans. Screen mutant populations for lines with reduced levels of seed raffinose and stachyose oligosaccharides. Screen diverse germplasm for natural variability in seed oligosaccharide content. Identify genes involved in seed zinc accumulation and tolerance to low zinc soils via transcriptome profiling, gene expression analysis, and molecular mapping.


3. Progress Report:
Processing quality was evaluated on 108 black bean recombinant inbred lines that were grown in a replicated field experiment in 2011. The materials were canned and evaluated for color retention, texture, appearance and water uptake. A linkage map of 1500 single nucleotide polymorphism markers (SNP) and diversity array markers was developed for the black bean population. This map was anchored to the bean consensus map and the Phaseouls vulgaris genome sequence (v_0.9)(www.phytozome.net). The phenotypic data was used to conduct Quantitative Trait Loci (QTL) analysis of processing quality traits for which the data was collected over a 2 year field experiment (2010 and 2011). The QTL analysis revealed that the genomic region responsible for water uptake during soaking and processing of black beans is linked to the Asp gene for the shiny seed coat. QTL for color retention after canning, appearance, and anthocyanins content were also identified on chromosomes 5 and 11. Near-infrared analysis was conducted with seed from the 2010 and 2011 field seasons and evaluated as potential predictors of canning quality traits. The 2010 results have been analyzed, and it was found that NIR is able to predict water uptake whereas the prediction of other quality traits was not strong enough to warrant NIR as a method of selection. The analysis of 2011 materials is underway. The evaluation of nutrient composition, including protein, fiber, folate, and minerals has been conducted on processed seed of 13 genotypes from 3 market classes grown over 2 years in Michigan. In addition, processing quality, including canned bean appearance, color, texture, and amylose/amylopectin content has been measured. Sensory panels have been used to evaluate how consumers rate the flavor, appearance, color, and texture of each of the cultivars. The data has been analyzed and the results of these studies are being written up for publication. Mutagenized bean lines have been screened for seed oligosaccharide levels. In the first screening of 1000 lines, candidate lines were identified that were potentially low raffinose and/or low stachyose mutants. Based on second and third screening rounds, it appears that none of the lines with low oligosaccharide levels were heritable. Scientists will continue screening for natural variation for this trait in diverse bean germplasm.


4. Accomplishments


Review Publications
Gelaeano, C.H., Fernandez, A.C., Franco-Herrera, N., Cichy, K.A., McClean, P.E., Vanderleyden, J., Beebe, S.E. 2011. Saturation of an intra-gene pool linkage map: toward unified consensus linkage map in common bean. PLoS One. 6(12):e28135.

Last Modified: 10/16/2017
Footer Content Back to Top of Page