Texture development during grain growth

Grant, E. M.

January 1986

No description available.

669

Grain growth in copper rods

Small Grain Varieties for Northern Arizona

Bartel, A. T., Briggs, Ian A.

05 1900

No description available.

Agriculture -- Arizona

Grain -- Varieties -- Arizona

Amylose-lipid relationships in starch of maturing wheat grain

Gadan, H. M.

January 1984

No description available.

572

Amylose-lipid in grain starch

Surface segregation and its influence on the oxidation of polycrystalline nickel

Ritherdon, Justin

January 1996

No description available.

669

Sulphur segregation; Grain boundaries

Modelling the effects of polyphagous predators on the population dynamics of the grain aphid Sitobion avenae (F.)

Winder, Linton

January 1990

No description available.

577

Grain aphid population control

Comparative ecophysiology of two cultivars of wheat (Triticum aestivum L.) under drought

Nabipour, Majid

January 2001

No description available.

630

Additives and control of grain growth in barium titanate ceramics

Xue, L. A.

January 1987

No description available.

666

Ceramics grain growth control

Studies of segregation at interfaces

Moon, D. P.

January 1987

No description available.

669

Metal grain boundary diffusion

Sediment sorting in the gravel-sand transition along rivers : a field and modelling investigation

Bloomer, Daniel John

January 2000

No description available.

551

Bed; GST; Grain size

In vitro and field based evaluation for grain mold resistance and its impact on quality traits in sorghum [Sorghum bicolor (L.) Moench]

Tomar, Sandeep Singh

January 1900

Master of Science / Department of Agronomy / Ramasamy Perumal / Tesfaye Tesso / Grain mold (GM) is an important biotic constraint limiting yield and market value of sorghum grains. It results in kernel discoloration and deterioration. Such kernels have reduced seed viability, low food and feed quality. Breeding for grain mold resistance is challenging because of the complex nature of host-pathogen-environment interactions. This complex task could be made simpler by utilizing molecular markers. Utilization of marker resources may help to find genomic regions associated with grain mold resistance. In this study, three sets of field and laboratory based experiments were performed which will help in finding potential grain mold pathogens responsible for kernel deterioration in the studied environment and search for genotypes with better kernel quality and grain mold resistance. In the first part of the study, in vitro screening of 44 grain mold resistant sorghum genotypes developed and released by Texas A & M AgriLife Research. This study was aimed at identifying sources resistance to grain mold infection through laboratory screening. The result revealed that genotypes Tx3371, Tx3373, Tx3374, Tx3376, Tx3407, Tx3400, and Tx3402 were have high level of resistance and were identified as potential sources of grain mold resistance as each showed minimal fungal infection and higher grain quality traits. The second experiment was performed to optimize surface sterilization protocol for the extraction of fungal pathogens from the kernel surface (pericarp) and to study the effect of bleach percentage and time period on pathogen extraction. Seven treatments using sterilized double distilled water (0 % bleach (v/v)) and different bleach (NaOCl) concentrations (2.5, 5, 7.5, 10, 12.5 and 15 %) were used with a time interval of 2.5, 5, 7.5 and 10 min. Optimized surface sterilization in the range of 7.5 to 15 % bleach (v/v) for 7.5 to 10 min resulted least contamination and fungal genera isolation from the surface of the kernel. The third study was aimed at characterizing genotypes (sorghum association panel) for grain mold pathogen F. thapsinum and by using genome wide association (GWA) tool in order to find genomic regions associated with grain mold resistance. We studied the effect of different agronomic and panicle architecture traits on grain mold incidence and severity. Effects of grain mold on kernel quality traits were also studied. We reported two loci associated with grain mold resistance. Based on first year field screening results, 46 genotypes having grain mold ratings 1-5 (1 = < 1% panicle kernel molded; 5 = > 50% panicle kernel molded) were selected for a detailed study aimed at understanding grain mold x fungal pathogen interactions to physical and chemical kernel traits. Seed germination test, vigor index, and tetrazolium viability test were performed to study effect of grain mold infection on kernel viability and vigor. Alternaria, Fusarium thapsinum, F. verticillioides and F. proliferatum were the main fungal genera isolated from bisected kernels. Based on two year screening, SC623, SC67, SC621, SC947 and SC1494 were most resistant based on both PGMR and TGMR rating while SC370, SC833, SC1484, and SC1077 showed the most susceptible reaction and this was consistent for individual location analysis. SC309, SC213, SC833, SC971 and SC1047 are genotypes having identified loci for grain mold resistance.

Sorghum

Grain mold

Fusarium

GWAS