As nitrogen (N) is a critical nutrient for plant growth, the development of synthetic N fertilisers dramatically changed agricultural production in the twentieth century. Improvement in N use efficiency (NUE) has been a focus of breeding for grain crop species, since protein is an important component of the harvested product. The study of NUE in sugarcane has lagged behind grain crops, mainly because N is not a component of sucrose, the primary product of the traditional sugarcane industry. Recently, improvement in NUE has become a focus of sugarcane breeding, due largely to environmental concerns regarding pollution from high N fertilisation, and the increasing cost of N fertilisers. This thesis aimed to gain an initial understanding of the genetic basis for variability in NUE in sugarcane. This was achieved through: (i) the screening of 168 sugarcane genotypes under limiting and non-limiting N supply in two glasshouse experiments; (ii) the mapping of marker-trait associations (MTA) for biomass and physiological traits under limiting and non-limiting N supply in a sugarcane mapping population; (iii) the analysis of expression of candidate genes encoding enzymes involved in the central processes of N assimilation and remobilisation in plants; and (iv) the mapping of candidate genes in a sugarcane genetic map. Genetic variation was identified for growth traits as well as physiological traits including %N, internal NUE (iNUE, g dry weight g-1 N) and leaf glutamine synthetase (GS) activity in a sugarcane mapping population. These traits were also analysed for linkage with genetic markers. Genetic variation in the screened genotypes was higher under limiting N supply, a finding that was reflected by the fact that marker-trait associations (MTA) for increases in iNUE were not identified under non-limiting N supply in the commercial parent of the mapping population. Contrary to findings in grain crop species, there was no link between GS activity and other traits, either through phenotypic correlations or co-location of MTA. The expression of candidate genes encoding GS, nitrate reductase (NR) and alanine amintotransferase (AlaAT) was quantified with Sequenomâ„¢ MassARRAY technology. Plants were grown under growth-limiting N supply, non-limiting N supply, or a N-pulse treatment, which consisted of growth-limiting N supply followed by non-limiting N supply 24 hours prior to sampling. Two genes, scAlaAT.d and scGS1.a, encoding AlaAT and GS respectively, were identified as non-responsive to changes in N supply, whereas scAlaAT.a, scGS1.b and scGS1.c had significantly (p<0.05) increased expression under a N-pulse, indicating an important role for these genes in the response of sugarcane to a sudden increase in N availability. The location of candidate genes associated with variation in NUE in a sugarcane genetic map were sought through restriction fragment length polymorphism (RFLP) markers. Twenty-two probes were screened, of which two generated single-dose markers, allowing the mapping of a single allele of scAspAT, encoding aspartate aminotransferase, and two alleles of scGS2, encoding plastidic GS. Because of the economic and environmental consequences of inefficient N fertiliser application, the development of sugarcane cultivars with improved NUE is essential. Since variation for NUE exists, especially in unimproved sugarcane varieties, this may be achieved through traditional breeding methods by screening existing breeding populations under limiting N supply. Additionally, an improved understanding of the genetic basis of variation for NUE in sugarcane should be pursued by further analysis of candidate gene response to changing N availability by screening widely varying cane species for differences in gene expression, enzyme activity and metabolite profiles. The further addition of candidate gene locations to sugarcane genetic maps will aid both future marker-assisted selection in breeding, and a fundamental understanding of genetic control of NUE variation. Through the development of sugarcane cultivars with improved NUE and an enhanced knowledge of the genetic control underpinning sugarcane N physiology, concerns regarding high N fertiliser applications may be mitigated and sustainability ensured.
Identifer | oai:union.ndltd.org:ADTP/279179 |
Creators | Alexander Whan |
Source Sets | Australiasian Digital Theses Program |
Detected Language | English |
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