Varieties, plant breeding and release

Permanent URI for this collectionhttp://elibrary2.sugarresearch.com.au/handle/11079/13841

Research outcomes: Comprehensive and efficient variety breeding, selection and release programs responding to yield expectations, environmental constraints, resource scarcity and regional preferences. Faster varietal adoption using advanced methods for bulking, distribution and planting.

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Subject: search.filters.subject.Sucrose accumulation

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Now showing 1 - 6 of 6
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    The transfer of high CCS traits from wild relatives to sugarcane using biochemical markers
    (2003) Grof, C; Manners, J
    Over the last 40 years of sugarcane breeding in Australia there have been significant improvements in cane yield but little to no improvement in commercial cane sugar (CCS). It has been hypothesised that this lack of gain is due to the narrow genetic base of current breeding programs and has provided the impetus to examine new sources of germplasm that may provide desirable traits. Broadening the genetic base through the introgression of new Saccharum germplasm could allow the incorporation of 'new' genes for CCS into commercial sugarcane and result in increased CCS. However carefully targeted approaches are required to identify favourable genetic components of value from available new germplasm for introgression.
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    Functional genomics for enhanced sugar accumulation in sugarcane : final report CPI002
    (2003) Manners, J; Casu, R
    Improvement in CCS of sugarcane would provide considerable benefits to the whole sugar industry by improving profitability via enhanced efficiencies in both sugarcane and raw sugar production. Improvements in CCS bring benefits by increasing sugar input to mills with no new costs in cane growing, harvesting and transport and enhanced sugar output with only moderate changes in the sugar milling process. Despite the economic attractions of the CCS plant trait for plant improvement there has been little progress made in improving CCS in released varieties in the past forty years and new approaches are needed. One new approach to breeding high CCS sugarcane varieties is to use DNA markers to select for diverse attributes that contribute to CCS and combine these attributes to produce improved varieties. The CCS trait is complex and involves many genes and a range of plant functions. A key contributor to high CCS is sucrose accumulation and the aim of this project was to identify sugarcane genes that are associated with high levels of sucrose accumulation. These genes provide an input to further research where the CCS trait is being mapped on the sugarcane genome and genes identified in CPI002 are tested as markers. Ultimately, benefits to growers will accrue through the use of these markers in the breeding program to select improved varieties.
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    Knowledge of sugarcane physiology and climate-crop-soil interactions : SRDC final report
    (2003) Inman-Bamber, NG
    Compared to other crops, knowledge of growth mechanisms in sugarcane is inadequate. The question arises as to how much longer can we continue to prosper from sugarcane if knowledge of the growth processes on which our industry depends, remains outdated? Sucrose accumulation and efficient use of resources are primary concerns for this industry. To date we have only limited understanding of climate and management links to sucrose content or CCS and this undermines our ability to manage water, nutrients, varieties and the harvest schedule for maximum CCS and optimum cane yield. Cane and sucrose yields are often below potential for reasons about which we can only speculate (Leslie and Byth, 2000). In the past, research funds have been directed at opportunities for raising limitations to yield and efficiency of resource use at the gene and enzyme level as well as at the crop and paddock level. There has been no attempt to integrate research or information across these disciplines or to assess where progress toward sustainable production is most likely to be achieved. SRDC recognized that it was now time for each discipline interested in the same processes to get together to find out how their different approaches could be complementary. SRDC also recognised the need to review past data relating to crop growth in the later stages of crop development to see if something could be done about under performing crops during this stage.
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    Pathways to exploiting enhanced photosynthetic efficiency for higher sucrose and biomass yield
    (2011) Inman-Bamber, NG
    Australia has one of the highest commercial cane sugar (CCS) levels in the world but unfortunately CCS appears to have plateaud at about 14% of fresh cane weight over the past 20 years. Up to now in breeding programs, increased fibre has been considered to have negative economic impacts because of adverse effects on sugar extraction and milling rate. It is possible that high fibre genotypes can produce higher biomass yields than high sucrose types because high sucrose content in the stalk may feedback negatively on photosynthesis either through end-product suppression or through sugar signalling compounds. This is now an assumption which is gaining acceptance through recent publications. Prior to this project this assumption had not been tested using high fibre and high sucrose clones. Feedback inhibition is also suspected to be the cause of the ‘reduced growth phenomenon’, a term applied to lower than expected biomass accumulation after a certain stage in crop development. This project aimed to establish the role of cane stalk sucrose in feedback inhibition of photosynthesis in order to reveal existing limitations to increasing sucrose content and biomass yield.
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    SRDC Research Project final report Increased CCS, cane yield and water use efficiency by exploiting interactions between genetics and management
    (2009) Inman-Bamber, NG
    In October 2003 delegates at an international workshop on sugarcane physiology funded by SRDC concluded that priority should be directed at a better understanding of traits responsible for high yield and high sucrose content, in order to better design future genotypes. While pathways of sucrose accumulation were and are being investigated at the molecular and cellular levels, there was no concurrent work at the crop level. Consequently it is difficult to answer the questions- To what extent will genetic improvements be modified by management and the environment? and conversely, To what extent does management and environment influence the selection of varieties? These and other questions about the genotype x environment (GxE) interaction on sucrose accumulation and lodging were the major concerns of this project with sucrose accumulation as the predominant issue. This project forms part of a large effort now underway worldwide to find alternative methods to develop cultivars with improved sugar content. The main objective was to better understand the interactions between sugarcane genetics and the environment (including management) with respect to sugar accumulation. After four years of intensive work the project has delivered extensive new knowledge on the physiology of interactions between sugarcane genetics and the environment with respect to sugar accumulation and lodging and as such has met the main objective of the research.
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    Biomass accumulation in sugarcane : final report 79/9028
    (1984) Kingston, G; Ham, GJ; Ridge, DR; Leverington, KC
    Growth analysis experiments were conducted at Ayr and Bundaberg from 1979 to 1982 to study biomass accumulation in plant and ratoon crops of sugarcane. Crops were planted and ratooned in March, June, September and December, and harvested at 6, 9, 12 and 15 months of age. Data were acquired for yields of total fresh and dry matter, in addition to yields of the following vegetative components: dry leaf, green leaf, tops and stalks. Fibre analyses were determined on all components, while glucose, fructose and sucrose % were also determined in the latter three components. It was shown that yield of total dry matter increased with age at harvest for all months of crop initiation. Potential for dry matter accumulation was closely associated with intercepted solar radiation. Growth for three months was ranked December-March > March-June > September-December > June-September. These rankings represented the interaction of crop growth stage with solar radition. The proportion of total dry matter allocated to soluble and structural carbohydrate was shown to be dependent on variety as well as an interaction between age at harvest and month of harvest. Canes older than nine months of age, harvested between June and December, had established a plateau type equilibrium between the proportion of total dry matter in soluble and structural carbohydrate. Good prospects existed for forward extension of the crushing season to March for ethanol production based on 15 month old cane. Models were developed to describe the growth of yield components of the biomass in relation to intercepted solar radition, month of crop initiation, age at harvest and crop class.