MORE THAN 2 BILLION PEOPLE WORLDWIDE EXPERIENCE MICRONUTRIENT DEFICIENCIES. FAILURE TO CONSUME ENOUGH VITAMINS AND MINERALS IS A GROWING, GLOBAL PROBLEM (TERMED HIDDEN HUNGER). AN UNLIKELY, LOW-TECH SOLUTION TO IMPROVING CROP QUALITY WITHOUT SACRIFICING YIELD COULD LITERALLY BE LAYING AT OUR FEET. THE SOIL/ROOT MICROBIOME HAS BEEN TOUTED AS A POTENTIAL SOLUTION TO AFFECT AGRONOMICALLY IMPORTANT PLANTS TRAITS AND YIELD, BUT COULD IT ALSO IMPROVE NUTRIENT QUALITY?THE PLANT MICROBIOME MEDIATES MANY ASPECTS OF PLANT PHENOTYPE, INCLUDING YIELD, REPRODUCTIVE PHENOLOGY, AND STRESS TOLERANCE PHENOTYPES. MICROBES ALSO PROFOUNDLY AFFECT NUTRIENT CYCLING AND AVAILABILITY IN THE RHIZOSPHERE WHICH CAN DIRECTLY AFFECT CROP NUTRITIONAL QUALITY. THE MAJOR GOAL OF THIS PROJECT IS TO HARNESS THE PLANT MICROBIOME TO ENHANCE CROP NUTRITIONAL QUALITY, AN EMERGING RESEARCH AREA WITH THE POTENTIAL TO LINK ECOLOGICAL AND PHYSIOLOGICAL PROCESSES TO OPTIMIZE FOOD PRODUCTION.I PROPOSE TO INVESTIGATE HOW THE RHIZOSPHERE MICROBIOME AFFECTS SEED NUTRITIONAL QUALITY OF THE SECOND MOST IMPORTANT PULSE CROP WORLDWIDE, CHICKPEA (CICER ARIETINUM). I WILL MINE THE MICROBIOME OF DOMESTIC AND WILD CHICKPEA RELATIVES, USING AN APPROACH THAT INCORPORATES CUTTING EDGE SEQUENCING TECHNOLOGIES, SEED NUTRITIONAL PHENOTYPING, AND INFORMATICS TO GENERATE HYPOTHESES, AND SYNTHETIC COMMUNITY APPROACHES TO VALIDATE THESE RELATIONSHIPS. THIS WORK WILL RESULT IN ALTERNATIVE TECHNOLOGIES THAT WILL LEAD TO IMPROVED CROP QUALITY, THUS AMELIORATING HIDDEN HUNGER WORLDWIDE. ADDITIONALLY, APPROACHES DEVELOPED HERE CAN BE USED WIDELY BY RESEARCHERS INTERESTED IN LINKING HOST PHENOTYPE TO MICROBIOME STRUCTURE AND FUNCTION.
$165,000FY2021National Institute of Food and AgricultureUSDA
Washington State University, Pullman WA