Browsing by Author "Vetch, Justin Michael"

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Genetics of seed dormancy in wheat and barley
(Montana State University - Bozeman, College of Agriculture, 2020) Vetch, Justin Michael; Chairperson, Graduate Committee: Michael J. Giroux; Robert N. Stougaard, John M. Martin and Michael J. Giroux were co-authors of the article, 'Revealing the genetic mechanisms of preharvest sprouting' in the journal 'Plant science' which is contained within this dissertation.; Robert N. Stougaard, John M. Martin and Michael J. Giroux were co-authors of the article, 'Allelic impacts of TaPHS1, TaMKK3, and Vp1B3 on preharvest sprouting of northern Great Plains winter wheats' in the journal 'Crop science' which is contained within this dissertation.; Jason G. Walling, Jamie D. Sherman, John M. Martin and Michael J. Giroux were co-authors of the article, 'Mutations in the HvMKK3 AND HvAlaAT1 genes affect barley pre-harvest sprouting and after-ripened seed dormancy' in the journal 'Crop science' which is contained within this dissertation.; Philip L. Bruckner, John M. Martin and Michael J. Giroux were co-authors of the article, 'TAMFT homeologs are associated with preharvest sprouting winter wheat' submitted to the journal ''Crop science' which is contained within this dissertation.
Montana producers have many biotic and abiotic stresses to contend with. One of interest to avoid is preharvest sprouting (PHS), which is the precocious germination of grains before harvest. PHS affected grain is discounted at the elevator, resulting in grain being unsuitable for many foods and direct losses to producers. PHS is not widespread every year in Montana but in some years causes large economic loss. Although PHS is a response to environmental cues it is largely controlled by genetics. Genes that control seed dormancy are the most likely candidate genes for PHS resistance and the series of studies presented in this dissertation examine the impact of several genes upon small grain PHS susceptibility. The studies used several methods to assess PHS susceptibility and determine which alleles of individual genes were present. The methods included seed dormancy screening assays, alpha amylase enzyme activity analysis, falling numbers analysis, genotyping by direct sequencing and via use of various markers, RNA-sequencing, and gene expression analysis. The first study served as a PHS susceptibility survey and provides PHS tolerance information on MT grown wheat varieties. This study also found that of the three most reported PHS associated genes (TaMFT 3A, TaMKK3 4A, and TaVp1 3B), only TaMFT 3A was associated with PHS in Montana winter wheats, even though the previously reported variation was observed in all three genes. The second study looked at PHS susceptibility among current and historically grown barley varieties. It was found that malt varieties vary greatly in their susceptibility to PHS with the top grown AMBA recommended varieties among the most susceptible. It was also found that a previously unstudied mutation in the HvMKK3 gene is associated with PHS susceptibility. Interestingly, HvMKK3 and HvAlaAT1 affect dormancy at different time points in grain maturity indicating dormancy may be tailored to a specific timeframe (high dormancy at harvest with rapid decay of dormancy after harvest). The final study revisited winter wheat PHS and found that the TaMFT 3B and 3D homeologs are associated with PHS which has not been shown to date.
TAMFT‐3A and TAMFT‐3B2 homeologs are associated with wheat preharvest sprouting
(Wiley, 2022-08) Vetch, Justin Michael; Tillett, Brandon J.; Bruckner, Phil L.; Martin, John M.; Marlowe, Karol; Hooker, Marcus Alan; See, Deven Robert; Giroux, Michael J.
The phenomenon of preharvest sprouting (PHS), caused by rain after physiological maturity and prior to harvest, negatively affects wheat (Triticum aestivum L.) production and end use. Investigating the genetics that control PHS resistance may result in increased control of seed dormancy. Multiple genes involved in the development of seed dormancy are associated with PHS. In this study, the TaMFT (3A, 3B1, 3B2, 3D), TaMKK3-4A, and TaVP1-3B genes were assessed for association with PHS in a double-haploid line (DHL) hard red winter wheat population derived from a BC1 cross between the cultivars Loma and Warhorse, where Loma was the recurrent and PHS susceptible parent. The 162 BC1 DHL lines were grown over two field seasons and PHS susceptibility was assessed by measuring PHS resistance in physiologically mature heads. The PHS variation was associated with the TaMFT-A and the B2 homeolog with Loma carrying mutant forms of each gene. No sequence variation between Loma and Warhorse was detected in the exons of the TaMFT-B1 and D homeologs. No association between PHS resistance and TaMKK3-4A or TaVp1-3B variation was observed, though Loma and Warhorse vary for TaMKK3-4A and TaVp1-3B mutations reported to be PHS associated. Previous research has shown TaMFT-3A as having a large impact on PHS resistance. In the current study, the TaMFT-3A and TaMFT-3B2 alleles each explained 14% of observed PHS variation. Markers for both TaMFT-3A and TaMFT-3B2 should be used in selecting for increased wheat dormancy and PHS resistance.