Department of Genetics
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Browsing Department of Genetics by browse.metadata.advisor "Botha, F. C."
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- ItemCarbon turnover and sucrose metabolism in the culm of transgenic sugarcane producing 1-Kestose(Stellenbosch : University of Stellenbosch, 2007-12) Nicholson, Tarryn Louise; Botha, F. C.; Huckett, B. I.; University of Stellenbosch. Faculty of Agrisciences. Dept. of Genetics. Institute for Plant Biotechnology.Carbon partitioning was investigated in sugarcane (Saccharum spp. hybrids) that was genetically modified with sucrose: sucrose 1-fructosyltransferase (1-SST; EC 2.4.1.99) from Cynara scolymus. This enzyme catalyses the transfer of a fructosyl moiety from one sucrose molecule to another to produce the trisaccharide 1-kestose. Molecular characterisation of four sugarcane lines, regenerated after transformation, confirmed that two lines (2153 and 2121) were transgenic, with at least one intact copy of 1-SST present in line 2153, and a minimum of five copies (or portions thereof) present in line 2121. The novel gene was successfully transcribed and translated in both lines, as confirmed by cDNA gel blot hybridisation and HPLC analysis respectively. Kestose production was stable under field resembling conditions and levels of this trisaccharide progressively increased with increasing internodal maturity from 7.94 ± 2.96 nmol.g-1 fresh mass (fm) in internode 6 to 112.01 ± 17.42 nmol.g-1 fm in internode 16 of 2153, and by 1.05 ± 0.93 nmol.g-1 fm from the youngest to the oldest internode in line 2121. Sugarcane line 2153 contained 100 times more 1-kestose than 2121 in the oldest sampled internode hence the lines were referred to as high- and low-1-kestose producers. The production of 1-kestose did not reduce sucrose levels in the transgenics, instead they contained significantly higher levels of sucrose than the control line NCo310 (p<0.01, N=72). The production of this alternative sugar in addition to elevated sucrose levels significantly increased the total sugar content in the transgenic lines (p<0.01, N=72). Moreover, the high-1-kestose producer had statistically more total sugar than the low-1-kestose producer (p<0.01, N=72). Soluble acid invertase (SAI) and neutral invertase (NI, β-fructofuranosidase EC 3.2.1.26) from non-transgenic sugarcane internodal tissues were separated and partially purified. Kinetic analysis of the purified invertases revealed two isoforms of SAI eluting at approximately 100 mM KCl in a linear gradient while NI eluted at approximately 500 mM KCl. The final specific activities of SAI and NI were 88.57 pkat.mg-1 protein and 92.31 pkat.mg-1 protein, respectively. This implied a 16- fold purification of SAI, and 4- fold purification of NI. The pH optimum for NI was 7.0 and that for soluble acid invertase less than 5.0. Due to the broad pH activities of the invertases, activities significantly overlapped between pH 4.5 and 7.0. The affinity of these invertases for 1-kestose hydrolysis was tested. The invertases displayed hyperbolic saturation kinetics for sucrose, and had low affinities for 1-kestose with Km values ranging from 50 - 247 mM. Furthermore, the presence of 200 mM 1-kestose had an inhibitory effect on SAI-mediated sucrose hydrolysis reducing activity to 51 % and 54 % for isoform 1 and 2 respectively. To determine whether carbon allocation had been altered by the expression and activity of 1-SST, 14C whole-plant radiolabelling experiments were conducted. Radiolabelled CO2 was fed to the leaf subtending internode 5 and the allocation of carbon to different parts of the culm was assessed. There was no significant difference in the distribution of total radiolabel down the culm of the three sugarcane lines (p>0.05, N=72). However, the percentage of total radiolabel in the water-soluble fraction per internode in the high-1-kestose producer was significantly higher than the other two lines (p<0.01, N=72). As a result, the percentage radiolabel in the waterinsoluble fraction in this transgenic was concomitantly lower than in the other lines. Carbon was therefore redirected from the water-insoluble fraction to the water-soluble fraction to account for the additive production of 1-kestose. The expression of 1-SST in sugarcane therefore established an additional carbohydrate sink by the flow of carbon from the sucrose pool into 1-kestose. This did not lead to a depletion of the sucrose pool, but rather stimulated carbon channelling into this pathway, thereby increasing the non-structural carbohydrate content of the plant in one of the transgenics. The work described in this study is the first to report on carbon partitioning in 1- kestose-producing sugarcane grown under field resembling conditions. It contributes significantly to an improved understanding of carbon partitioning in the culm, and demonstrates that an alternative sugar can be produced in sugarcane under field resembling conditions.
- ItemCharacterisation of sucrose synthase activity in the sugarcane culm(Stellenbosch : University of Stellenbosch, 2004-04) Schafer, Wolfgang Erich; Botha, F. C.; Rohwer, J. M.; University of Stellenbosch. Faculty of Agrisciences. Dept. of Genetics. Institute for Plant Biotechnology (IPB).ENGLISH ABSTRACT: This study had three main goals: 1. to investigate the occurrence on the protein level of sucrose synthase (SuSy) isoforms in sugarcane sink tissue, 2. to determine the kinetic properties of these isoforms, 3. to establish the tissue localisation of SuSy in the sugarcane culm The results are summarised below: Three SuSy isoforms were obtained from leaf roll tissue. The SuSyA and SuSyB isoforms differed in terms of charge characteristics, with SuSyA not binding to an anion exchange column that bound SuSyB and SuSyC under the same conditions. Both SuSyB and SuSyC isoforms were eluted at 180 mM KCl. The SuSyA and SuSyB isoforms were present during autumn, but during winter only the SuSyC isoform could be isolated. Even though they eluted at the same salt concentration, SuSyB and SuSyC were different isoforms, because they had different kinetic parameters, as well as different immunological properties. SuSyB and SuSyC could not have been mixtures of the same isoforms, since a polyclonal antiserum against SuSyB, which inactivates native SuSyB, did not inactivate SuSyC. All three isoforms had significantly different kinetic parameters, with the SuSyA isoform also having a much lower sucrose breakdown/synthesis ratio than the other two isoforms. Therefore, at least three SuSy isoforms occur in sugarcane leaf roll tissue on the protein level. The SuSyC isoform was subsequently kinetically characterised in detail. Data showed that the enzyme employs an ordered ternary complex mechanism, with UDP binding first and UDP-glucose dissociating last. These experimentally obtained kinetic parameters were then used to extend a kinetic model of sucrose accumulation. Data show that when the experimentally determined SuSy kineticparameters were entered into the model, a 40 % increase in sucrose concentration and 7 times reduction in fructose concentration resulted. These data illustrate the pronounced physiological effects that may result from the presence of different SuSy isoforms. SuSy protein localisation data, obtained by an immunohistochemical approach, indicated that SuSy protein was present in both storage parenchyma and vascular tissue of young, intermediate, and mature internodes. SuSy enzyme activity in different parts of the internodes was similar, except for internode 3, which had much higher activity in the bottom part of the internode, possibly because growth is faster here, hence a higher demand for sucrose cleavage exists here.
- ItemThe characterization of vacuolar pyrophosphatase expression in sugarcane(Stellenbosch : University of Stellenbosch, 2005-03) Swart, Johannes Cornelius; Groenewald, J-H.; Botha, F. C.; University of Stellenbosch. Faculty of Agrisciences. Dept. of Genetics. Institute for Plant Biotechnology (IPB)Vacuolar Pyrophosphatase (V-PPase) has never been studied in sugarcane before and to date nothing is known about V-PPase in sugarcane, except for the sequences of a few expressed sequence tags (ESTs). The aim of this project was to characterize V-PPase expression in several hybrid sugarcane varieties that differ significantly in sucrose content, with the main objective of the study to assess whether V-PPase is correlated in any way to the sucrose storage phenotype. Therefore, the goals of this project were to (i) develop molecular tools for the detection and quantification of V-PPase on a DNA, RNA, protein and enzyme level and (ii) to use these tools to characterize the expression of V-PPase within the culm of the three hybrid varieties. The cDNA sequence of the catalytic subunit of the sugarcane V-PPase gene was cloned, expressed in a bacterial system and the V-PPase peptide was purified. This peptide was used for the immunization of mice and the production of polyclonal anti-VPPase antiserum. Anti-VPPase antiserum reacted specifically with a single polypeptide among vacuolar membrane proteins. Moreover, anti-VPPase antiserum recognized V-PPase from various monocotyledons and dicotyledons. The anti-VPPase antiserum was used for the establishment of an ELISA system to determine V-PPase protein content in vacuolar membrane preparations. This system proved to have several advantages over the protein blotting technique and shared a strong linear relation with V-PPase specific activity, showing that these two tests are compatible and reliable. The optimisation of sugarcane V-PPase zero-order kinetics was fundamental in order to measure V-PPase specific activity accurately. It had a relative broad pH optimum, retaining more than 90% of its maximum activity between pH 6.50 and 7.25. V-PPase required both Mg2+ and K+, in addition to PPi, for maximum activity in vitro. The reported kinetic variables are within range of previous data determined for other species, including mung bean, red beet and sugar beet. V-PPase protein level and specific activity within the sugarcane culm followed a similar trend , withoiofofoenaobserved for sucrose accumulation rates observed in sugarcane. Moreover, V-PPase protein contents and specific activity share the same general trend as total sucrose content in a specific tissue compared among the three varieties. No significant differences were observed in V-ATPase activity among the three varieties. Our findings suggest that V-PPase may play a role in sucrose accumulation in sugarcane.
- ItemDevelopment of a transformation system for sugarcane (Saccharum spp. hybrids) in South Africa using herbicide resistance as a model system(Stellenbosch : Stellenbosch University, 2002-12) Snyman, Sandra Jane; Botha, F. C.; Huckett, B.; Stellenbosch University. Faculty of AgriSciences. Dept. of Genetics and Institute of Plant Biotechnology.ENGLISH ABSTRACT: Please refer to fulltext for abstract
- ItemDevelopment of in situ hybridisation to examine tissue-specific expression patterns of the invertase genes in sugarcane culm(Stellenbosch : University of Stellenbosch, 2005-04) Turner, Gabrielle M.; Cramer, M. D.; Botha, F. C.; University of Stellenbosch. Faculty of Agrisciences. Dept. of Genetics. Institute for Plant Biotechnology (IPB).ENGLISH ABSTRACT: The goals of this project were firstly to develop the tissue preparation and in situ hybridisation protocols for sugarcane culm tissue, and secondly to use the developed techniques to examine the expression patterns of three invertase isoforms in sugarcane internodes of various developmental stages. Sugarcane invertases have been the focus of intense research for many years, yet almost nothing is known of their tissue-specific distribution. It was thought that by characterising their expression patterns using in situ hybridisation, more knowledge of their functions and involvement in sucrose accumulation would be gained. Although in situ hybridisation is now regularly used to study gene expression in plants, there is to date only a single publication describing its use on immature sugarcane tissue. Therefore this technique needed further development, and this was achieved by comparing different tissue preparation methods, as well as by systematically testing the various parameters pertaining to each method. The in situ hybridization technique was also developed by testing and comparing a number of key parameters. It was found that fixing whole mount tissue for 48 h preserved sugarcane tissue adequately. High hybridization temperatures and probe concentrations provided the best signal, and including pre-treatment with HCl and Pronase was essential in sensitizing the tissue to the probe. A less viscous detection buffer reduced both osmotic effects and time required for signal detection. In the second part of this study, the developed method was used to examine the expression patterns of the three invertase isoforms in young, maturing and mature internodes of sugarcane, and the results were complemented with Northern blot analysis. Transcript of all three isoforms was found to be present in the storage parenchyma and in the phloem tissue. Transcript levels of all three isoforms declined in maturing tissue, with soluble acid invertase declining sharply and dropping below detection in maturing and mature tissue. Transcript levels of cell wall invertase and neutral invertase declined only gradually, and appreciable levels of both were still present in mature tissue. Acid invertase is suggested to be mainly involved in internode elongation, while cell wall invertase would appear to play important roles in phloem unloading and turgor control. Neutral invertase is suggested to be involved in either sucrose cycling or maintenance of hexose pools, however the function of this enzyme remains unclear. This study has demonstrated the value of in situ hybridization, yet at the same time has shown its limitations, especially when more traditional biochemical techniques are not employed to complement the results. Although the precise functions of the invertase isoforms in sugarcane remain inconclusive, this study has opened up the way for tissuespecific promoter design and future in situ studies of sugarcane invertases
- ItemDifferential gene expression during berry ripening in Vitis vinifera (cv Chardonnay) : isolation of specific sequences through subtractive cloning(Stellenbosch : Stellenbosch University, 2002-12) Olivier, Abraham Jacobus; Botha, F. C.; Groenewald, S.; Stellenbosch University. Faculty of AgriSciences. Dept. of Genetics. Institute for Plant Biotechnology (IPB).ENGLISH ABSTRACT: Grapevine is worldwide an agronomically important crop. Traditionally selective breeding has been used to improve existing cultivars. In the last ten years, however, the advent of biotechnology has shortened these breeding programmes by producing transgenic grapevine. Because this new technology is aimed at the possible genetic manipulation of the ripening process in grape berries, it is important to elucidate all the mechanisms that may be involved in ripening. The aim of the present study was the identification of genes that play an important role during the ripening process in grape berries. This was achieved by investigation of putative differentially expressed genes in ripening Chardonnay berries isolated through subtractive hybridisation. Two subtraction libraries, representing early and late ripening stages were constructed. Four of the ten genes analysed exhibited expression during berry ripening. One of the four genes was expressed in a tissue and stage specific manner. Further characterisation of eight of the DNA and protein sequences revealed that the putative translation products of these clones had homologues that are involved in amongst others cell wall structure in other species. These included UDP-glucose dehydrogenase, which is involved in the synthesis of hemicellulose precursors. The remaining seven clones encoded putative stress response proteins. These included two heat shock proteins, a vacuolar pyrophosphatase and a protein involved in cell division. It is suggested that specific grape mRNAs accumulate in response to stresses such as the storage of high concentrations of sugars and rapid cell expansion. These processes occur rapidly during the ripening of berries. Accumulation of specific mRNAs can be attributed to part of the normal ripening developmental programme.
- ItemEnzyme profiling of a range of sugarcane tissue types with different levels of sucrose(Stellenbosch : University of Stellenbosch, 2005-12) Orendo-Smith, R.; Botha, F. C.; Groenewald, J-H.The study had two main objectives: 1) to investigate specific enzyme activity profiles at various developmental stages and to determine possible implications for sucrose metabolism, 2) to incorporate enzyme activity data of different internodes to obtain a detailed model of every stage in the tissue maturation process. The most significant findings of the regulation of sucrose accumulation in this study are centred on three main point controls in sucrose metabolism pathway. Firstly, the maturation of sugarcane internodes coincided with an increase of SPS in most genotypes, and this underlines the key role of this enzyme in sucrose accumulation. Secondly, SuSy activity (cleavage reaction) correlated negatively with sucrose concentration and hence with tissue maturation process, in most of the varieties. This finding indicates that SuSy could well be implicated in sucrose metabolism. Thirdly, in vitro PFP activity was found to be negatively correlated to sucrose content in sugarcane varieties differing in amount of sucrose.
- ItemExpression behaviour of primary carbon metabolism genes during sugarcane culm development(Stellenbosch : University of Stellenbosch, 2004-04) McCormick, Alistair James; Watt, D.; Huckett, B. I.; Botha, F. C.; University of Stellenbosch. Faculty of Agrisciences. Dept. of Genetics. Institute for Plant Biotechnology.ENGLISH ABSTRACT: Despite numerous attempts involving a variety of target genes, the successful transgenic manipulation of sucrose accumulation in sugarcane remains elusive. It is becoming increasingly apparent that enhancing sucrose storage in the culm by molecular means may depend on the modification of the activity of a novel gene target. One possible approach to identify target genes playing crucial coarse regulatory roles in sucrose accumulation is to assess gene expression during the developmental transition of the culm from active growth to maturation. This study has resulted in the successful optimisation of a mRNA hybridisation technique to characterise the expression of 90 carbohydrate metabolism-related genes in three developmentally distinct regions of sugarcane culm. A further goal of this work was to extend the limited knowledge of the regulation of sucrose metabolism in sugarcane, as well as to complement existing data from physiological and biochemical studies. Three mRNA populations derived from the different culm regions were assayed and their hybridisation intensities to the immobilised gene sequences statistically evaluated. The relative mRNA transcript abundance of 74 genes from three differing regions of culm maturity was documented. Genes exhibiting high relative expression in the culm included aldolase, hexokinase, cellulase, alcohol dehydrogenase and soluble acid invertase. Several genes (15) were demonstrated to have significantly different expression levels in the culm regions assessed. These included UDP-glucose pyrophosphorylase and UDP-glucose dehydrogenase, which were down-regulated between immature and mature internodes. Conversely, sucrose phosphate synthase, sucrose synthase and neutral invertase exhibited up-regulation in maturing internodal tissue. A variety of sugar transporters were also found to be up-regulated in mature culm, indicating a possible control point of flux into mature stem sink tissues. Combined with knowledge of the levels of key metabolites and metabolic intermediates this gene expression data will contribute to identifying key control points of sucrose accumulation in sugarcane and assist in the identification of gene targets for future manipulation by transgenic approaches.
- ItemGene discovery and expression analysis in sugarcane leaf and culm(Stellenbosch : Stellenbosch University, 2002-12) Carson, Deborah L. (Deborah Lee); Botha, F. C.; Huckett, B.; Stellenbosch University. Faculty of AcriSciences. Dept. of Genetics.ENGLISH ABSTRACT: Sugarcane (Saccharum spp. hybrids) is a commercial crop plant capable of storing up to 20% sucrose on a fresh mass basis in the culm. Knowledge about gene expression during sugarcane growth and maturation is limited. The aim of this study was to assess whether an Expressed Sequence Tag (EST)-based approach towards analysis of sugarcane would reveal new information about gene expression and metabolic processes associated with sugarcane growth and development. The specific objectives were two-fold: firstly, to develop an EST database for sugarcane and secondly, to identify and analyse genes that are expressed in different sugarcane tissue types and developmental stages, with a specific focus on leaf and culm. An EST database for sugarcane was initiated to obtain information on sugarcane gene sequences. A total cDNA library was constructed from sugarcane immature leaf (leaf roll: meristematic region) tissue and 250 clones randomly selected and subjected to single-pass DNA sequence analysis. Sugarcane ESTs were identified by sequence similarity searches against gene sequences in international databases. Of the 250 leaf roll clones, 26% exhibited similarity to known plant genes, 50% to non-plant genes while 24% represented new gene sequences. Analysis of the identified clones indicated sequence similarity to a broad diversity of genes. A significant proportion of genes identified in the leaf roll were involved in processes related to protein synthesis and protein modification, as would be expected in meristematic tissues. Submission of 495 sugarcane gene sequences to the dbEST database represented the first sugarcane ESTs released into the public domain. Two subtracted cDNA libraries were constructed by reciprocal subtractive hybridisation between sugarcane immature and maturing internodal tissue. To explore gene expression during sugarcane culm maturation, partial sequence analysis of random clones from maturing culm total and subtracted cDNA libraries was performed. Database comparisons revealed that of the 337 cDNA sequences analysed, 167 showed sequence homology to gene products in the protein databases while 111 matched uncharacterised plant ESTs only. The remaining cDNAs showed no database match and could represent novel genes. The majority of ESTs corresponded to a variety of genes associated with general cellular metabolism. ESTs homologous to various stress response genes were also well represented. Analysis of ESTs from the subtracted library identified genes that may be preferentially expressed during culm maturation. The expression patterns of sugarcane genes were examined in different tissue sources and developmental stages to identify differentially expressed genes. cDNA arrays containing 1000 random clones from immature leaf and maturing culm cDNA libraries were hybridised with poly (At RNA from immature leaf, mature leaf, immature culm and maturing culm. All cDNAs examined hybridised to all four probes, but differences in signal intensity were observed for individual cDNAs between hybridisation events. No cDNAs displaying tissue- or developmental-stage specific expression were detected. Comparisons between hybridisation patterns identified 61 cDNAs that were more abundantly expressed in immature and mature leaf than the culm. Likewise, 25 cDNAs preferentially expressed in immature and maturing culm were detected. ESTs established for the differentially expressed cDNAs revealed sequence homology to a diverse collection of genes in both the leaf and the culm. These included genes associated with general cellular metabolism, transport, regulation and a variety of stress responses. None of the differentially expressed genes identified in the culm were homologous to genes known to be associated with sucrose accumulation. To examme differences at the level of gene transcription between low sucroseaccumulating and high sucrose-accumulating tissues, subtracted cDNA libraries were utilised. To isolate cDNAs differentially expressed during culm maturation, cDNA arrays containing 400 random clones (200 from each library) were screened with total cDNA probes prepared from immature and maturing culm poly (At RNA. Results indicated that 36% and 30% of the total number of cDNAs analysed were preferentially expressed in the immature and maturing culm, respectively. Northern analysis of selected clones confirmed culm developmental stage-preferential expression for most of the clones tested. ESTs generated for the 132 differentially expressed clones isolated exhibited homology to genes associated with cell wall metabolism, carbohydrate metabolism, stress responses and regulation, where the specific ESTs identified in the immature and maturing culm were distinct from each other. No developmentally regulated ESTs directly associated with sucrose metabolism were detected. These results suggest that growth and maturation of the sugarcane culm is associated with the expression of genes for a wide variety of metabolic processes. In addition, genes encoding enzymes directly involved with sucrose accumulation do not appear to be abundantly expressed in the culm.
- ItemGenetic enhancement of pearl millet(Stellenbosch : Stellenbosch University, 2004-03) O'Kennedy, Martha Margaretha; Botha, F. C.; Burger, Johan T.; Stellenbosch University. Faculty of AgriSciences. Dept. of Genetics. Institute for Plant Biotechnology (IPB).ENGLISH ABSTRACT: The aim of this study was toe stablish a reliable protocol for the production 0 f transgenic pearl millet as this will open new avenues for augmenting the gene pool of this crop. This was achieved by identifying a highly regenerabie genotype and optimisation of a tissue culture system, and biolistic protocol f or stable integration of selected transgenes. Both a negative, herbicide resistance selectable marker gene, bar, and a positive selectable marker gene, manA, were individually introduced in order to identify and establish a reliable transformation protocol. The optimised transformation protocol was then used to introduce an antifungal gene in the genome of pearl millet to enhance resistance to the biotrophic fungus Sclerospora graminicola. S. graminicola, an obligate oomycetous fungal phytopathogen, is the causal agent of downy mildew in pearl millet plants and a major constraint in the production of pearl millet. A single component of antifungal resistance was introduced into the genome of pearl millet, as preliminary work towards determining its role in the total plant defence system. The approach chosen was to introduce a hydrolytic enzyme, 13-1,3- glucanase, from Trichoderma atroviride (formerly T. harzianum), a soil-borne filamentous fungus, capable of parasitizing several plant pathogenic fungi. It was anticipated that introducing this glucanase gene from T. atroviride which degrades glucan in the fungal cell walls, would significantly contribute to the improvement of resistance against downy mildew. Constructs were prepared containing the gene (gluc78) encoding a 78 kDa beta-1,3- glucanase. The constructs were prepared containing the gluc78 gene driven either by a strong constitutive promoter (ubiquitin promoter, exon and intron) or a wound inducible promoter, the potato proteinase inhibitor ilK gene promoter. The wound inducible promoter includes either an AMV leader' sequence or the rice Act1 intron to obtain higher expression levels in the monocotyledonous plant. The transformation efficiency using the particle inflow gun and the herbicide resistance gene, bar, was improved from 0.02% on a MS based medium, to 0.19 or 0.72% with manA as selectable marker gene on MS or L3 based medium, respectively. However, individual experiments, introducing manA as selectable marker gene, resulted in frequencies of 1.2 and 3%. This translated to one transformation event per plate, which contains on average 31-35 pre-cultured immature zygotic embryos. This is the first report of t he successful introduction and expression of a 13-1,3-glucanase encoding gene from a biocontrol fungus not only under constitutive expression but also under wound inducible expression in a plant. Optimisation of genetic engineering of pearl millet, a cereal crop recalcitrant to transformation, and the introduction of an antifungal transgene, was accomplished in this study. Initial results hint that expression of this transgene enhances resistance to S. graminicola.
- ItemGenetic manipulation of sucrose-storing tissue to produce alternative products(Stellenbosch : University of Stellenbosch, 2007-03) Nell, Hanlie; Botha, F. C.; University of Stellenbosch. Faculty of Agrisciences. Dept. of Genetics. Institute for Plant Biotechnology (IPB)The main aim of the work presented in this dissertation was to explore the possibility to genetically manipulate the sucrose storing crops, sugarcane and sweet sorghum, to convert their sucrose reserves into higher-value alternatives. For the purpose of this study we focussed on fructans as alternative sucrose-based high-value carbohydrates, since these fructose polymers are of significant commercial interest. To investigate the technical feasibility of transforming sugarcane and sweet sorghum to produce this novel carbohydrate, we proposed to transfer the fructosyltransferase genes from Cynara scolymus into these plants by means of particle bombardment. In order to apply this technology to sweet sorghum, an in vitro culture system suitable for transformation had to be established. For this purpose an extensive screening process with different combinations of variables were conducted. Though the relationships between these variables proved to be complex, it was concluded that immature zygotic embryos could be used to initiate a genotype-independent totipotent regeneration system with a 65% callus induction rate, provided that initiation takes place during summer. Stable transformation and regeneration of these calli were however not successful and will have to be optimised to allow future applications. By introducing fructosyltransferase genes into sugarcane, we succeeded in transforming sugarcane into a crop that produces a variety of fructans of the inulintype. Low molecular weight (LMW) inulins were found to accumulate in the mature internodes of 42% of the transgenic sugarcane plants expressing the sucrose:sucrose 1-fructosyltransferase (1-SST) gene, and in 77% of the plants that incorporated both 1-SST and fructan:fructan 1-fructosyltransferase (1-FFT), while only 8% of these plants accumulated high molecular weight (HMW) inulins. Our results demonstrated that sugarcane could be manipulated to synthesise and accumulate fructans without the induction of phenotypical irregularities. Inulins with a degree of polymerisation up to 60 were found in sugarcane storage tissue. In these HMW inulin-producing plants, up to 78% of the endogenous sucrose in the mature sugarcane culm was converted to inulin. This enabled inulin accumulation up to 165.3 mg g-1 fresh weight (FW), which is comparable to that found in native plants. These transgenic sugarcane plants, therefore exhibit great potential as a future industrial inulin source. Fructan production was detected in all the sugarcane plant tissue tested, predominantly as 1-kestose. In contrast with the fact that fructan accumulation in leaves did not affect the endogenous sucrose concentrations in these organs, the sucrose content of mature internodes that accumulated high levels of 1-kestose was severely reduced. However, increases in total sugar content, in some instances up to 63% higher than control plants, were observed. This phenomenon was investigated with the use of radio-labelled-isotopes. An increase in the allocation of incoming carbon towards sucrose storage, resulting in higher carbon partitioning into both 1- kestose and sucrose, were detected in the culms of transgenic compared to control lines. This modification therefore established an extra carbohydrate sink in the vacuoles that affected photosynthate partitioning and increased total soluble sugar content. The data suggests that sucrose sensing is the main regulatory mechanism responsible for adapting carbon flow in the cells to maintain sucrose concentration.
- ItemThe influence of genetic manipulation of cytosolic aldolase (ALDc) on respiration in sugarcane(Stellenbosch : University of Stellenbosch, 2005-03) Scheepers, Ilana; Botha, F. C.; Potier, B. A. M.; University of Stellenbosch. Faculty of Agrisciences. Dept. of Genetics. Institute for Plant Biotechnology (IPB)Previous studies indicated that cytosolic aldolase (ALDc) could be a rate limiting step in glycolysis and thus play a role in the regulation of carbon partitioning in sink tissues. In this study the role of ALDc in sugarcane was studied. Expression patterns of both ALDc transcript and protein were examined. In contrast to the leaves where ALDc expression is very low, the enzyme (transcript and protein) levels were high in all internodal tissues at all stages of maturity. In the leaves the plastidic isoform was prevalent as found previously in other C4 plants. The similar pattern of expression in transcript and protein abundance illustrate that there are no activators or inhibitors of ALDc activity present in sugarcane. The control on ALDc activity in sugarcane is therefore regulation of gene expression. To investigate the possibility that ALDc could be regulating carbon partitioning in sugarcane a series of transgenic sugarcane plants in the varieties NCo310 and N19 were produced. The presence and expression of the transgene and resultant effect on ALDc levels were determined for all the transgenic lines. The degree of ALDc reduction varied, with the biggest suppression of aldolase being 90% of that of the control plants. Alteration of ALDc activity caused no obvious phenotype. In both the varieties large decreases in ALDc tended to to lead to higher sucrose levels than that of the the control plants. 14C radiolabelling studies were conducted to investigate the effect of reduced ALDc levels on respiration and carbon partitioning. No differences in carbon metabolism could be found between the transgenic and control plants. Even in the line exhibiting a more than 90% decrease, the residual ALDc was sufficient for plants to grow normally under favourable glasshouse conditions. This would suggest that ALDc does not play a role in the regulation of flux through glycolysis, carbon partitioning and sucrose accumulation.
- ItemInfluence of hexose-phosphates and carbon cycling on sucrose accumulation in sugarcane spp.(Stellenbosch : University of Stellenbosch, 2005-12) Van der Merwe, Margaretha Johanna; Botha, F. C.; Groenewald, J-H.; University of Stellenbosch. Faculty of Agrisciences. Dept. of Genetics.Sucrose accumulation, marked by a continuous cycle of synthesis and degradation, is characterised by a shift of carbon away from the insoluble matter and respiratory intermediates into sucrose. Despite this shift, a significant proportion of carbon is returned to these pools by hexose-phosphate: triose-phosphate cycling and/or sucrose cycling. Little is known about the magnitude and behaviour of these cycles in sugarcane. Contradictory reports on the relationship between these two cycles have led to the evaluation of the link between the hexose-phosphate: triose-phosphate- and sucrose cycle. In addition, it still needs to be tested whether these cycles could significantly influence carbon partitioning within sugarcane internodal tissue. In this work, a comprehensive metabolic profile was constructed for sugarcane internodal tissue by gas chromatography-mass spectrometry (GC-MS) in order to determine the steady state levels of a broad range of primary metabolites that are involved in these cycles. The power of GC-MS was illustrated by the detection of raffinose, maltose, ribose, xylitol, inositol, galactose, arabinose and quinic acid, which was quantified for the first time in sugarcane internodal tissue. Analyses were not solely based on the prevailing metabolite levels, but also on the interactions between these metabolites. Thus, in a complementary approach the metabolic flux between the two substrate cycles was assessed by 13C nuclear magnetic resonance (NMR). Analyses of transgenic sugarcane clones with 45-95% reduced cytosolic pyrophosphate: D-fructose-6-phosphate 1-phosphotransferase (PFP, EC 2.7.1.90) activity displayed no visual phenotypic change, but significant changes were evident in in vivo metabolite levels. Sucrose concentrations increased six and three-fold in young and maturing internodal tissue, respectively. Reduced PFP activity also resulted in an eight-fold increase in the hexose-phosphate: triose-phosphate ratio in the transgenic immature internodes. In addition, the hexose-phosphate: triose-phosphate cycling decreased in the immature internodes of the transgenic lines if compared to the immature control internode. However, there was no significant difference between the hexose-phosphate: triose-phosphate cycling in the mature internodal tissue of the transgenic and the control lines. This illustrated that PFP mediates hexose-phosphate: triose-phosphate cycling in immature sugarcane internodal tissue. Unpredictably, reduced PFP activity led to a ten-fold increase in sucrose cycling in the transgenic immature internodes. The combination of metabolite profiling and flux distribution measurements demonstrated that the fluxes through the sucrose and the hexose-phosphate pools were not co-regulated in sugarcane internodal tissue. From these observations a model was constructed that implicates higher sucrose cycling as a consequence of increased sucrose concentrations.
- ItemIsolation and characterisation of a culm-specific promoter element from sugarcane(Stellenbosch : University of Stellenbosch, 2005-03) Goshu Abraha, Tsion; Botha, F. C.; Groenewald, J-H.; University of Stellenbosch. Faculty of Science. Dept of Botany and Zoology. Institute of Plant Biotechnology.Sugarcane (Saccharum spp) is an important crop worldwide and is cultivated for the high level of sucrose in its mature internodes. Because of the exhaustion of the genetic potential in the commercial sugarcane germplasm conventional breeding has not lately been able to enhance sucrose content. Currently there is a concerted effort to improve culm sucrose content by genetic engineering which will require appropriate transgenes and promoters. One of the major constraints to genetic engineering of sugarcane is the lack of stable promoters required to drive tissue- or organ-specific expression of transgenes. Tissue and developmental stage specific promoters allow targeting of transgene activity and in doing so reduce the impact on non-target tissues. These promoters could also be advantageous to manipulate certain aspects of sucrose metabolism specifically in mature culm tissue. In addition, no promoters are currently freely available to the South African Sugar Industry for use in their transgenic program. The primary goal of this project was therefore to isolate a mature tissue-specific promoter for use in transgenic sugarcane plants. The approach followed was firstly, to identify an endogenous gene expressed in the desired pattern, and then to isolate the corresponding promoter from the sugarcane genome. cDNA macroarrays were initially used to identify differentially expressed sequences. The tissue specificity of potential clones was confirmed using RNA blot analysis. Two clones (c23-a and c22-a) were isolated and confirmed to be mature culm specific. Clone c22-a (putative dirigent-like protein) was selected for promoter isolation based on its culm tissue specific expression pattern and its proximity to the 5’ end of the gene. Furthermore, to confirm the activity of this promoter in the storage parenchyma cells, the exact cellular localisation of the transcript in the mature tissue was determined through in situ hybridisation. In situ hybridisation results confirmed the presence of the transcript in the parenchyma cells of mature culm tissue only. Moreover, the transcript is present in high concentrations in the parenchyma tissues surrounding the vascular bundles and parenchyma cells of the vascular complex. The selected dirigent-like gene was sequenced to allow the design of primers that could be used for the isolation of the corresponding promoter region using a long-range inverse PCR (LR-iPCR) method. Using these we have successfully isolated two highly homologous promoter regions of the dirigent like gene of respectively 1151 and 985 base pairs. In silico analyses confirmed the presence of various transcription motifs, including a TATA-box. However, experimental verification is needed to fully assess the functionality of these promoter regions. Verifying the activity of the isolated promoters through transient expression analysis proved to be problematic because of their highly mature culm specificity. Both constructs are therefore being used to obtain stable transformants in which promoter activity can be evaluated in mature internodal tissues.
- ItemThe isolation and characterisation of a developmentally-regulated gene from Vitis vinifera L. berries(Stellenbosch : University of Stellenbosch, 2004-12) Burger, Anita L.; Botha, F. C.; University of Stellenbosch. Faculty of AgriSciences. Dept. of Genetics. Institute for Plant Biotechnology.ENGLISH ABSTRACT: Despite increased focus on ripening-related gene transcription in grapevine, and the large number of ripening-related cDNAs identified from grapes in recent years, the molecular basis of processes involved in grape berry ripening is still poorly understood. Moreover, little is known about the mechanisms involved in the ripening-related regulation of fruit-specific genes, since the isolation and characterisation of no ripening-related, fruit-specific promoter elements has been reported to date. This study was aimed at the isolation and characterisation of a fruit-specific, ripeningregulated gene from Vitis vinifera L. In the first phase of the work, gene transcription in ripening berries of Cabernet Sauvignon (a good quality wine cultivar) and Clairette blanche (a poor quality wine cultivar) were studied by Amplified Fragment Length Polymorphism analysis of complementary DNA (cDNA-AFLP analysis). Total RNA from immature (14-weeks post flowering, wpf) and mature (18-wpf) berries was used for the analysis. A total of 1 276 cDNA fragments were visualised, of which 175 appeared to be ripening related. Average pairwise difference of the fragments amplified from immature and mature Clairette and Cabernet berries, suggested that ripening-related gene transcription in these two phenotypically different cultivars is remarkably similar. Nevertheless, it was shown that seventy percent of the 175 ripening-related cDNA fragments were cultivar-specific. It was suggested that these differences should be targeted to identify genes related to the phenotypical differences between the two cultivars, but also to identify genes possibly involved berry quality. Moreover, the analysis illustrated the usefulness of cDNA-AFLPs for the analysis of ripening-related gene transcription during grape berry ripening. In the second phase of the work, one of the ripening-related cDNAs identified by the cDNA-AFLP analysis, was selected for further characterisation. This work highlighted the limitation placed on the isolation of a single specific sequence from a cDNA-AFLP gel, indicating the presence of multiple ripening-related genes in a single band excised from a cDNA-AFLP gel. Steps to overcome this limitation of cDNA-AFLP analysis to identify and clone a specific ripening-related gene, were implemented. In short, the band corresponding to the particular ripening-related cDNA was band was excised from the cDNA-AFLP polyacrylamide gel and re-amplified. Northern blot analysis using the re-amplified, uncloned product confirmed the ripening-related transcription demonstrated by cDNA-AFLP analysis. The re-amplified, uncloned product was then cloned. Sequence analysis of two randomly selected candidate clones revealed two distinctly different sequences, of which neither hybridised to messenger RNA from ripening grape berries. Furtheranalysis revealed an additional five cDNAs with terminal sequences corresponding to the selective nucleotides of the primers used for selective amplification, in the re-amplified, uncloned product. Of these, only two were abundantly expressed in ripening grape berries, accounting for the ripeningrelated transcription visualised by cDNA-AFLP analysis. All seven cDNAs identified from the particular excised band were shown to be ripening-regulated during berry development, although most were characterised by low levels of transcription during berry ripening. One of the clones, based on the relative high levels of the transcript and the initiation of gene transcription at the onset of véraison (10- to 12-wpf), was identified for isolation and characterisation of the full length coding sequence. In the third phase of the work, it was shown that this cloned sequence corresponded to a gene encoding a proline-rich protein (PRP) associated with ripening in Merlot and Chardonnay (mrip1, Merlot ripening-induced protein 1). It was shown that the gene is specifically transcribed in the fruit tissue, seed and bunchstems of grapes, from 10-wpf (véraison) to the final stages of berry ripening. The results showed that mrip1 encodes a distinct member of the plant PRP family. Most obvious is the central region of mrip1, which is comprised of eight consecutive repeats of 19 amino acid residues each. In comparison with other grapevine PRPs, mrip1 revealed single amino acid differences and deletion of one of the 19 amino acid residues repeats, all in the central region of mrip1. In situ hybridisation studies showed that accumulation of the mrip1 transcript in the ripening berry is limited to the mesocarp and exocarp cells of the ripening grape berry. No transcript with high sequences similarity to mrip1 could be detected in ripening strawberry or tomato fruit. Based on the properties and proposed function of PRPs, and the results obtained in this study, potential applications for the use of this gene in the control of cell wall architecture in fruits, were proposed. Furthermore, as manipulation of fruit properties in grape berries would be most important in the later stages of ripening, mrip1 was proposed an ideal candidate gene for the isolation of a fruit- and late-ripening-specific promoter to achieve transgene transcription in genetically modified grapevine. The final phase of the work was dedicated to the isolation and characterisation of the mrip1 promoter element. A 5.5 kb sequence corresponding to the mrip1 5’ untranslated (UTR) flanking region was isolated and characterised by sequence analysis. In the 2.8 kb sequence directly upstream of the mrip1 transcription initiation site, several putative cis-acting regulatory elements were identified. These include a spectrum of hormone-, light-, phytochrome-, sugar-and stressresponsive elements, as well as elements implicated in tissue-specific transcription. Analysis of the sequence further upstream (3.6 – 5.5 kb) of the mrip1 transcription initiation site (TIS), revealed the presence of another proline-rich protein directly upstream of mrip1. Sequence identity of this sequence (mprp2) to the mrip1 coding sequence was 88%. This information provided the first insight into the chromosomal organisation of grapevine PRPs. For functional analysis of the mrip1 promoter element, the 2.2 kb sequence directly upstream of the mrip1 TIS, was translationally fused to the sgfpS65T reporter gene. Functionality of the mrip1:sgfpS65T fusion was verified by transient expression in green pepper pericarp tissue, before introduction into tobacco by Agrobacteriummediated transformation. In transgenic tobacco, transcription of the mrip1:sgfpS65T fusion was developmentally-regulated and specific to the ovary and nectary-tissue of the developing flower. Whilst low in immature flowers, the green fluorescent protein (GFP) rapidly accumulated to the high level of expression visualised in the flower in full-bloom, followed by a decrease in the final stages of ovary development. These observations suggested that the 2.2 kb mrip1 promoter is functional and that this promoter region harbours cis-elements necessary for tissue- and developmental-specific regulation of GFP accumulation. It furthermore suggested that the transcriptional activation of mrip1 is mediated by developmental signals present in both grapevine berries and tobacco flowers. Results presented, suggest that the use of tobacco as heterologous system for the analysis of ripening-related promoters, can be more generally applied. Evidently, characterisation of the mrip1 promoter region contributes towards a better understanding of the regulatory mechanisms involved in non-climacteric fruit ripening, and forms a basis for future experiments defining the cis-acting elements necessary for tissue- and cell-specific gene regulation in fruit, more specifically in grapevine. Moreover, the mrip1 promoter is an ideal candidate for the ripening-related, tissue-specific regulation of transgene transcription in genetically modified grapevine.
- ItemIsolation and evaluation of the sugarcane UDP-glucose dehydrogenase gene and promoter(Stellenbosch : University of Stellenbosch, 2006-12) Van der Merwe, Jennie; Botha, F. C.; Groenewald, S.; University of Stellenbosch. Faculty of Agrisciences. Dept. of Genetics. Institute for Plant Biotechnology (IPB)The young internodes of sugarcane are ideal targets for altering metabolism, through genetic manipulation, to potentially control known fungal diseases such as Smut or to increase sucrose yields in these regions that are currently being discarded. At present, no regulatory sequences that specifically drive transgene expression in young developing sugarcane tissues are available. The objective of this study was therefore to isolate and evaluate such a sequence. The promoter targeted for isolation in this study regulates the expression of UDP-glucose dehydrogenase (EC 1.1.1.22), an enzyme which catalyses the oxidation of UDP-glucose to UDP-glucuronic acid, a precursor for structural polysaccharides which are incorporated into the developing cell wall. A strong correlation between the expression of UDP-glucose dehydrogenase and a demand for structural polysaccharides in developing tissues could therefore be expected. The first part of this study addressed the general practicality of promoter isolation from sugarcane, a complex polyploid. A gene encoding UDP-glucose dehydrogenase was isolated from a sugarcane genomic library. The gene contains an open reading frame (ORF) of 1443 bp, encoding 480 amino acids and one large intron (973 bp), located in the 5’-UTR. The derived amino acid sequence showed 88 – 98% identity with UDP-glucose dehydrogenase from other plant species, and contained highly conserved amino acid motifs required for cofactor binding and catalytic activity. Southern blot analysis indicates a low copy number for UDP-glucose dehydrogenase in sugarcane. The possible expression of multiple gene copies or alleles of this gene was investigated through comparison of sequences amplified from cDNA prepared from different tissues. Although five Single Nucleotide Polymorphisms (SNP) and one small-scale insertion/deletion (INDEL) were identified in the aligned sequences, hundred percent identity of the derived amino acid sequences suggested the expression of different alleles of the same gene rather than expression of multiple copies. The finding that multiple alleles are expressed to provide the required level of a specific enzyme, rather than the increased expression of one dominant allele, is encouraging for sugarcane gene and promoter isolation. In the second part of the study the suitability of UDP-glucose dehydrogenase as a target for the isolation of a developmentally regulated promoter was investigated. The contribution of UDP glucose dehydrogenase to pentan synthesis, as well as the expression pattern and subcellular localisation of the enzyme in mature sugarcane plants was studied at the tissue and cellular level. Radiolabelling with positionally labelled glucose was used to investigate the relative contributions of glycolysis, the oxidative pentose phosphate pathway and pentan synthesis to glucose catabolism. Significantly (P=0.05) more radiolabel was released as CO2 from [6-14C]- glucose than [1-14C]-glucose in younger internodes 3, 4 and 5, demonstrating a significant contribution of UDP-glucose dehydrogenase to glucose oxidation in the younger internodes. In addition, there was significantly (P=0.05) more radiolabel in the cell wall (fiber) component when the tissue was labelled with [1-14C]-glucose rather than [6-14C]-glucose. This also demonstrates a selective decarboxylation of glucose in position 6 prior to incorporation into the cell wall and is consistent with a major role for UDP-glucose dehydrogenase in cell wall synthesis in the younger internodes. Expression analysis showed high levels of expression of both the UDP-glucose dehydrogenase transcript and protein in the leafroll, roots and young internodes. In situ hybridisation showed that the UDP-glucose dehydrogenase transcript is present in virtually all cell types in the sugarcane internode, while immunolocalisation showed that the abundance of the protein declined in all cell types as maturity increased. Results obtained confirmed that this enzyme plays an important role in the provision of hemicellulose precursors in most developing tissues of the sugarcane plant, indicating that UDP-glucose dehydrogenase was indeed a suitable target for promoter isolation. Lastly, the promoter region and first intron, located in the 5’-untranslated region (UTR) of this gene, were isolated and subsequently fused to the GUS reporter gene for transient expression analysis and plant transformation. Transient expression analysis showed that the presence of the intron was essential for strong GUS expression. Analysis of stably transformed transgenic sugarcane plants, evaluated in a green house trial, showed that the isolated promoter is able to drive GUS expression in a tissue specific manner under these conditions.
- ItemThe manipulation of fructose 2,6-bisphosphate levels in sugarcane(Stellenbosch : University of Stellenbosch, 2006-03) Hiten, Nicholas Fletcher; Botha, F. C.; University of Stellenbosch. Faculty of Agrisciences. Dept. of Genetics. Institute for Plant Biotechnology (IPB)Fructose 2,6-bisphosphate (Fru 2,6-P2) is an important regulatory molecule in plant carbohydrate metabolism. There were three main objectives in this study. Firstly, to determine whether the recombinant rat 6-phosphofructo 2-kinase (6PF2K, EC 2.7.1.105) and fructose 2,6-bisphosphatase (FBPase2, EC 3.1.3.11) enzymes, which catalyse the synthesis and degradation of Fru 2,6-P2 respectively, showed any catalytic activity as fusion proteins. Secondly, to alter the levels of Fru 2,6-P2 in sugarcane, an important agricultural crop due to its ability to store large quantities of sucrose, by expressing the recombinant genes. Thirdly, to investigate whether sugar metabolism in photosynthetic- (leaves) and non-photosynthetic tissue (internodes) were subsequently influenced. Activity tests performed on the bacterially expressed glutathione-S-transferase (GST) fusion 6PF2K and FBPase2 enzymes showed that they were catalytically active. In addition antibodies were raised against the bacterially expressed proteins. Methods for extracting and measuring Fru 2,6-P2 from sugarcane tissues had to be optimised because it is known that the extraction efficiencies of Fru 2,6-P2 could vary significantly between different plant species and also within tissues from the same species. A chloroform/methanol extraction method was established that provided Fru 2,6-P2 recoveries of 93% and 85% from sugarcane leaves and internodes respectively. Diurnal changes in the levels of Fru 2,6-P2, sucrose and starch were measured and the results suggested a role for Fru 2,6-P2 in photosynthetic sucrose metabolism and in the partitioning of carbon between sucrose and starch in sugarcane leaves. Transgenic sugarcane plants expressing either a recombinant rat FBPase2 (ODe lines) or 6PF2K (OCe lines) were generated. The ODe lines contained decreased leaf Fru 2,6-P2 levels but increased internodal Fru 2,6-P2 levels compared to the control plants. Higher leaf sucrose and reducing sugars (glucose and fructose) were measured in the transgenic plants than the control plants. The transgenic lines contained decreased internodal sucrose and increased reducing sugars compared to the control plants. Opposite trends were observed for Fru 2,6-P2 and sucrose when leaves, internodes 3+4 or internodes 7+8 of the different plant lines were compared. In contrast, no consistent trends between Fru 2,6-P2 and sucrose were evident in the OCe transgenic lines.
- ItemManipulation of pyrophosphate fructose 6-phosphate 1-phosphotransferase activity in sugarcane(Stellenbosch : University of Stellenbosch, 2006-03) Groenewald, Jan-Hendrik; Botha, F. C.; University of Stellenbosch. Faculty of Agrisciences. Dept. of Genetics. Institute for Plant Biotechnology (IPB)The main aim of the work presented in this thesis was to elucidate the apparent role of pyrophosphate fructose 6-phosphate 1-phosphotransferase (PFP) in sucrose accumulation in sugarcane. PFP activity in sugarcane internodal tissue is inversely correlated to the sucrose content and positively to the water-insoluble component across varieties which differ in their capacities to accumulate sucrose. This apparent well defined and important role of PFP seems to stand in contrast to the ambiguity regarding PFP’s role in the general literature as well as the results of various transgenic studies where neither the downregulation nor the over-expression of PFP activity had a major influence on the phenotype of transgenic potato and tobacco plants. Based on this it was therefore thought that either the kinetic properties of sugarcane PFP is significantly different than that of other plant PFPs or that PFP’s role in sucrose accumulating tissues is different from that in starch accumulating tissues. In the first part of the study sugarcane PFP was therefore purified and its molecular and kinetic properties were determined. It consisted of two subunits which aggregated in dimeric, tetrameric and octameric forms depending on the presence of Fru 2,6-P2. Both the glycolytic and gluconeogenic reactions had broad pH optima and the kinetic parameters for all the substrates were comparable to that of other plant PFPs. The conclusion was therefore that sugarcane PFP’s molecular and kinetic characteristics do not differ significantly from that of other plant PFPs. The only direct way to confirm if PFP is involved in sucrose accumulation in sugarcane is to alter its levels in the same genetic background through genetic engineering. This was therefore the second focus of this study. PFP activity was successfully down-regulated in sugarcane. The transgenic plants showed no visible phenotype under greenhouse and field conditions and sucrose concentrations in their immature internodes were significantly increased. PFP activity was inversely correlated with sucrose content in the immature internodes of the transgenic lines. Both the immature and mature internodes of the transgenic plants had significantly higher fibre contents. This study suggests that PFP plays a significant role in glycolytic carbon flux in immature, metabolically active sugarcane internodal tissues. The data presented here confirm that PFP can indeed have an influence on the rate of glycolysis and carbon partitioning in these tissues. It also implies that there are no differences between the functions of PFP in starch and sucrose storing tissues and it supports the hypothesis that PFP provides additional glycolytic capacity to PFK at times of high metabolic flux in biosynthetically active tissue. This work will serve as a basis to refine future genetic manipulation strategies and could make a valuable contribution to the productivity of South African sugarcane varieties.
- ItemMarker assisted breeding in sugarcane : a complex polyploid(Stellenbosch : University of Stellenbosch, 2007-03) Butterfield, Michael Keith; Botha, F. C.; Warnich, L.; University of Stellenbosch. Faculty of Agrisciences. Dept. of Genetics.Association analysis was used to improve the efficiency of breeding sugarcane varieties for the negatively correlated traits of resistance to sugarcane smut and the eldana stalk borer. 275 RFLP and 1056 AFLP markers were scored across a population of 77 genotypes representing the genetic variation present within the SASRI breeding programme. Genetic diversity analysis did not detect significant structure within the population. Regression analysis identified 64 markers significantly associated with smut rating and 115 markers associated with eldana rating at r2 > 6.25%. Individual markers with the largest effects explained 15.9% of the phenotypic variation in smut rating and 20.2% of the variation in eldana. Five markers were significantly associated with both smut and eldana. In each case the marker effect was negatively correlated between the two traits, suggesting that they are genetically as well as phenotypically negatively correlated.
- ItemResponses of sugarcane to aluminium toxicity(Stellenbosch : Stellenbosch University, 2006-03) Rowland, Ronelle; Cramer, M. D.; Botha, F. C.; Watt, D. A.; Stellenbosch University. Faculty of Agriscience. Dept. of Genetics.ENGLISH ABSTRACT: The aims of this study were (1) to determine whether N03- orNH4+ nutrition could influence the effect of Al on N12 and N19 sugarcane plants grown in sand or hydroponic medium and (2) to assess whether the different root environments of sand and hydroponically cultured plants could influence the effect of Al on Nl2 and N19 sugarcane plants supplied with N03- or NH/ nutrition. N12 and N19 sugarcane was grown in sand and hydroponic culture with and without Al and with either N03- or NH4+as N source. Biomass accumulation, tissue N, P and Al and root assimilation of 14C02 supplied to the root system were measured. Both N12 and N19 sugarcane plants were found to be relatively Al tolerant (tolerating up to 1 mM Al). This lack of effect of Al on plant growth might be due to amelioration of Al-toxicity in sugarcane by the adequate supply of carbon skeletons from the C4 photosynthetic pathways of sugarcane. The supply of carbon skeletons may enable both cultivars to exude large amounts of organic acids into the rhizosphere, which confers a dual advantage to these plants. Organic acids can form soluble complexes with Al thus preventing its entry into the roots and can form soluble complexes with nutrients (cations), which makes some nutrients (e.g. P) more available for plant uptake. The availability of carbon in the root system is dependent on the N source. Increased growth of Al treated plants supplied with NH4 +, relative to those grown on N03-, might be due to the capacity of C4 photosynthesis to meet the needs for both the assimilation of NH4 + into amino acids and the synthesis/excretion of organic acids for Al-detoxification. The fact that growth was improved with NNH4 + and Al may indicate that NH4 + and Al cations compete for access to the root tissue resulting in an increase in root activity, organic acid exudation and nutrient uptake. It was postulated that sand-grown plants would be less influenced by Al than hydroponic plants because organic acids can form a protective sheath that shields the root apex from the toxic Al cations in sand due to the relative lack of mobility of the soil solution. However, Al increased the growth of NH4 +-fed hydroponically grown plants more than that of NH4 +-fed sand grown plants. Thus we did not find evidence to support our expectation that the roots of the hydroponically grown plants would be more exposed to Al due to nutrients and organic acids being uniformly distributed in the growth solution compared to sand grown plants.