Skip to main content
ARS Home » Research » Publications at this Location » Publication #178091

Title: DEVELOPING RICE VARIETIES WITH IMPROVED FISSURE RESISTANCE: STEP 1. IDENTIFYING EFFECTIVE BREEDER SELECTION TECHNIQUES.

Author
item Pinson, Shannon

Submitted to: Experiment Station Bulletins
Publication Type: Experiment Station
Publication Acceptance Date: 6/15/2004
Publication Date: 7/8/2004
Citation: Pinson, S.R., 2004. Developing rice varieties with improved fissure resistance: Step 1. identifying effective breeder selection techniques. Texas Rice. p. 7-8.

Interpretive Summary:

Technical Abstract: Kernel cracking due to field fissuring is one of the leading causes of reduced milling quality in rice. Any reduction in fissuring will result in direct increases in whole-kernel yield and profit for both the producer and the miller. The rice industry experienced this increased profitability first hand when producers grew the fissure resistant variety ‘Cypress’ after its release in 1993. Breeders want to develop new, improved varieties with fissure resistance equal to Cypress’, but progress is severely limited by the fact that present methods for evaluating fissure resistance all require large amounts of seed and/or labor. The presently available evaluation techniques may be used to prevent the release of a highly susceptible variety, but they cannot be used to proactively select for high fissure resistance among segregating breeding progeny. Drs. Shannon Pinson (USDA, Beaumont, TX) and Scott Osborn (U. of AR) have joined together their Genetics and Ag. Engineering expertise to study genetic, physical, and chemical grain attributes (Fig. 1) with the aim of identifying key factors that could then be used by breeders to identify fissure resistance among segregating progeny. This research has received support from TRRF and the Rice Foundation. Engineers studying post-harvest fissuring during drying and storage have identified a multitude of kernel components, such as hull chemistry and tightness, bran chemistry and thickness, and endosperm chemistry and shape, as affecting fissure rates (Fig. 1). Before Drs. Pinson and Osborn could identify which of these factors were key determinants of pre-harvest fissuring, they first had to develop a “measuring stick” capable of distinguishing both large and small differences in fissure response. At the initiation of this project, it was known that Cypress was more fissure resistant than ‘Lemont’, and it was suspected but not proven that ‘LaGrue’ and ‘TeQing’ were less fissure resistant than Lemont. Pinson’s and Osborn’s replicated multi-year milling stability data now document that the order of fissure resistance among the following varieties is ‘Saber’, ‘Cypress’, ‘Jodon’, ‘Cocodrie’, ‘Lemont’, ‘LaGrue’, ‘TeQing’, ‘Jefferson’. ‘Saber’ consistently exhibited fissure resistance equal to or better than that of Cypress. Field studies focussed on fissuring should be planted after May 5. Fissure-causing environments are more prevalent later in the growing season, making plots planted early in the season less informative than plots planted later in the season. Cypress’ fissure resistance is predominantly due to the hull barrier. When the hull keeps moisture out of the kernel, less swelling and pressure occurs within the kernel. If the underlying causes of Cypress’ low moisture transfer through the hull (i.e., hull tightness versus permeability) are identified, they may then be exploited as rapid, small-sample methods for identifying fissure resistance among breeding progeny. Saber’s fissure resistance appears to be predominantly due to endosperm characteristics. High endosperm diffusivity allows re-adsorbed moisture to disperse throughout the endosperm rather than becoming concentrated in outer layers to cause swelling and pressure. It may be possible to create varieties with even higher levels of fissure resistance by combining key attributes from Saber with those of Cypress.