Chapter 11: Sorghum breeding for abiotic stress tolerance In: achieving sustainable cultivation of sorghm. (W. Rooney,ed.)

Authors: Burke, John

Submitted to: Book Chapter
Publication Type: Book / Chapter
Publication Acceptance Date: 4/20/2017
Publication Date: N/A
Citation: N/A

Interpretive Summary:

Technical Abstract: As a food, feed, and biofuel crop, sorghum is an essential component of global crop production. Worldwide, sorghum is the fifth most important grain crop and occupies 3% of the global cropland (501,000 km2). Recently, sorghum has become the number 2 crop for grain-based ethanol in the United States after maize. Sorghum (Sorghum bicolor (L.) Moench) is believed to have been first domesticated in northeastern Africa (Southern Sudan and Ethiopia) and has spread to tropical and subtropical regions of all continents. This crop has enormous diversity within the National Genetic Resources Program (NGRP), maintaining 43077 accessions of Sorghum bicolor subsp. bicolor that can be found in the Germplasm Resource Information System (GRIN). Because sorghum is rich in genetic diversity it is employed for various purposes. In addition to serving as an important dietary staple for more than 500 million people, sorghum is used for animal forage, shelter, and recently as a feedstock for biofuel production. One of the key characteristics of sorghum is its ability to yield across a range of environments. Primarily grown in arid and semi-arid regions in the U.S., Asia, and sub-Saharan Africa, sorghum has been adapted for these harsh environments, representing perhaps the best cereal model for abiotic stress tolerance studies. Although sorghum exhibits better abiotic stress tolerances than many crops, significant sorghum yield losses are experienced annually in response to unfavorable environments. Globally, domesticated sorghum is often grown on marginal lands and in environments exposing the plant to temperature extremes and water deficits. There are numerous reviews on sorghum abiotic stress tolerance so much of that information will not be repeated here. This chapter will focus on (1) germplasm diversity in responses to low temperatures and water-deficit stress, and (2) methods for identifying diversity among germplasm collections.