Browsing by Author "Ndimba, Bongani K."
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Item Analysis of the early events in the interaction between Venturia inaequalis and the susceptible Golden Delicious apple (Malus x domestica Borkh.)(University of the Western Cape, 2014) Hüsselmann, Lizex Hollenbach Hermanus; Ndimba, Bongani K.Apple (Malus x domestica) production in the Western Cape, South Africa, is one of the major contributors to the gross domestic product (GDP) of the region. The production of apples is affected by a number of diseases. One of the economically important diseases is apple scab that is caused by the pathogenic fungus, Venturia inaequalis. Research to introduce disease resistance ranges from traditional plant breeding through to genetic manipulation. Parallel disease management regimes are also implemented to combat the disease, however, such strategies are increasingly becoming more ineffective since some fungal strains have become resistant to fungicides. The recently sequenced apple genome has opened the door to study the plant pathogen interaction at a molecular level. This study reports on proteomic and transcriptomic analyses of apple seedlings infected with Venturia inaequalis. In the proteomic analysis, two-dimensional gel electrophoresis (2-DE) in combination with mass spectrometry (MS) was used to separate, visualise and identify apple leaf proteins extracted from infected and uninfected apple seedlings. Using MelanieTM 2-DE Gel Analysis Software version 7.0 (Genebio, Geneva, Switzerland), a comparative analysis of leaf proteome expression patterns between the uninfected and infected apple leaves were conducted. The results indicated proteins with similar expression profiles as well as qualitative and quantitative differences between the two leaf proteomes. Thirty proteins from the apple leaf proteome were identified as differentially expressed. These were selected for analysis using a combination of MALDI-TOF and MALDI-TOF-TOF MS, followed by database searching. Of these spots, 28 were positively identified with known functions in photosynthesis and carbon metabolism (61%), protein destination and storage (11%), as well as those involved in redox/response to stress, followed by proteins involved in protein synthesis and disease/defence (7%), nucleotide and transport (3%). RNA-Seq was used to identify differentially expressed genes in response to the fungal infection over five time points namely Day 0, 2, 4, 8 and 12. cDNA libraries were constructed, sequenced using Illumina HiScan SQTM and MiSeqTM instruments. Nucleotide reads were analysed by aligning it to the apple genome using TopHat spliceaware aligner software, followed by analysis with limma/voom and edgeR, R statistical packages for finding differentially expressed genes. These results showed that 398 genes were differentially expressed in response to fungal infection over the five time points. These mapped to 1164 transcripts in the apple transcripts database, which were submitted to BLAST2GO. Eighty-six percent of the genes obtained a BLAST hit to which 77% of the BLAST hits were assigned GO terms. These were classed into three ontology categories i.e. biological processes, molecular function and cellular components. By focussing on the host responsive genes, modulation of genes involved in signal perception, transcription, stress/detoxification, defence related proteins, transport and secondary metabolites have been observed. A comparative analysis was performed between the Day 4 proteomic and Day 4 transcriptomic data. In the infected and uninfected apple leaf proteome of Day 4, we found 9 proteins responsive to fungal infection were up-regulated. From the transcriptome data of Day 4, 162 genes were extracted, which mapped to 395 transcripts in the apple transcripts. These were submitted to BLAST2GO for functional annotation. Proteins encoded by the up-regulated transcripts were functionally categorised. Pathways affected by the up-regulated genes are carbon metabolism, protein synthesis, defence, redox/response to stress. Up-regulated genes were involved in signal perception, transcription factors, stress/detoxification, defence related proteins, disease resistance proteins, transport and secondary metabolites. We found that the same pathways including energy, disease/defence and redox/response to stress were affected for the comparative analysis. The results of this study can be used as a starting point for targeting host responsive genes in genetic manipulation of apple cultivars.Item A biochemical and proteomic analysis of sugargraze sorghum under hyperosmotic stress(University of the Western Cape, 2015) Nxele, Xolisa; Ndimba, Bongani K.; Klein, AshwilSugargraze is a moderately drought tolerant sweet sorghum hybrid which is ideal for grazing, winter stand over and pit silage. A major advantage that Sugargraze has over other forages is its very high sugar content which improves feed quality thus increasing palatability and results in significantly reduced feed wastage. This study explored the influence of hyperosmotic stress on plant development, ROS accumulation, antioxidant capacity and the extent of cell death. Heat shock protein (Hsp70) expression immunoblotting assays were used to demonstrate whether the various treatment conditions induced stress within natural physiological parameters for the experimental material. This was coupled with the separation, visualization and identification of abundant proteins in Sugargraze leaves in response to hyperosmotic stress using two-dimensional gel electrophoresis (2-DE) in combination with mass spectrometry (MS). The results showed that hyperosmotic stress significantly influences plant development by reducing plant biomass and increasing the levels of ROS accumulation, proline content and subsequently reducing total chlorophyll content. An over accumulation of ROS in the form of hydrogen peroxide and lipid peroxidation was observed in the stressed plants which was supported by the extent of cell death. Although an increase in antioxidant enzyme activity (in the form of total enzymatic activity or individual isoform activity) in response to hyperosmotic stress was observed, this increase was not sufficient to counter the deleterious effects caused by the stress conditions hence the decrease in plant biomass and increase in cell death. Western blotting analysis of Sugargraze leaf tissues using Hsp70 antibodies showed that hyperosmotic stress induced Hsp70 expression to levels significantly higher than observed for the control plants. A total of thirteen CBB stained spots were selected for mass spectrometric identification, owing to their good resolution and abundance levels, and of these, nine were positively identified. Identified proteins were divided into functional categories including both known and novel/putative stress responsive proteins. Molecular and physiological functions of some of the proteins of interest identified will be subjected to further investigation via bioinformatic and molecular biology approaches.Item Brown rot-type fungal decomposition of sorghum bagasse: variable success and mechanistic implications(Hindawi Publishing Corporation, 2018) Presley, Gerald N.; Ndimba, Bongani K.; Schilling, Jonathan S.Sweet sorghum is a promising crop for a warming, drying African climate, and basic information is lacking on conversion pathways for its lignocellulosic residues (bagasse). Brown rot wood-decomposer fungi use carbohydrate-selective pathways that, when assessed on sorghum, a grass substrate, can yield information relevant to both plant biomass conversion and fungal biology. In testing sorghum decomposition by brown rot fungi (Gloeophyllum trabeum, Serpula lacrymans), we found that G. trabeum readily degraded sorghum, removing xylan prior to removing glucan. Serpula lacrymans, conversely, caused little decomposition. Ergosterol (fungal biomarker) and protein levels were similar for both fungi, but S. lacrymans produced nearly 4x lower polysaccharide-degrading enzyme specific activity on sorghum than G. trabeum, perhaps a symptom of starvation. Linking this information to genome comparisons including other brown rot fungi known to have a similar issue regarding decomposing grasses (Postia placenta, Fomitopsis pinicola) suggested that a lack of CE 1 feruloyl esterases as well as low xylanase activity in S. lacrymans (3x lower than in G. trabeum) may hinder S. lacrymans, P. placenta, and F. pinicola when degrading grass substrates. These results indicate variability in brown rot mechanisms, which may stem from a differing ability to degrade certain lignincarbohydrate complexes.Item Cross-species multiple environmental stress responses: An integrated approach to identify candidate genes for multiple stress tolerance in sorghum (Sorghum bicolor (L.) Moench) and related model species(Public Library of Science, 2018) Woldesemayat, Adugna Abdi; Modise, David M.; Gemeildien, Junaid; Ndimba, Bongani K.; Christoffels, AlanBACKGROUND Crop response to the changing climate and unpredictable effects of global warming with adverse conditions such as drought stress has brought concerns about food security to the fore; crop yield loss is a major cause of concern in this regard. Identification of genes with multiple responses across environmental stresses is the genetic foundation that leads to crop adaptation to environmental perturbations. METHODS In this paper, we introduce an integrated approach to assess candidate genes for multiple stress responses across-species. The approach combines ontology based semantic data integration with expression profiling, comparative genomics, phylogenomics, functional gene enrichment and gene enrichment network analysis to identify genes associated with plant stress phenotypes. Five different ontologies, viz., Gene Ontology (GO), Trait Ontology (TO), Plant Ontology (PO), Growth Ontology (GRO) and Environment Ontology (EO) were used to semantically integrate drought related information. RESULTS Target genes linked to Quantitative Trait Loci (QTLs) controlling yield and stress tolerance in sorghum (Sorghum bicolor (L.) Moench) and closely related species were identified. Based on the enriched GO terms of the biological processes, 1116 sorghum genes with potential responses to 5 different stresses, such as drought (18%), salt (32%), cold (20%), heat (8%) and oxidative stress (25%) were identified to be over-expressed. Out of 169 sorghum drought responsive QTLs associated genes that were identified based on expression datasets, 56% were shown to have multiple stress responses. On the other hand, out of 168 additional genes that have been evaluated for orthologous pairs, 90% were conserved across species for drought tolerance. Over 50% of identified maize and rice genes were responsive to drought and salt stresses and were co-located within multifunctional QTLs. Among the total identified multi-stress responsive genes, 272 targets were shown to be colocalized within QTLs associated with different traits that are responsive to multiple stresses. Ontology mapping was used to validate the identified genes, while reconstruction of the phylogenetic tree was instrumental to infer the evolutionary relationship of the sorghum orthologs. The results also show specific genes responsible for various interrelated components of drought response mechanism such as drought tolerance, drought avoidance and drought escape. CONCLUSIONS We submit that this approach is novel and to our knowledge, has not been used previously in any other research; it enables us to perform cross-species queries for genes that are likely to be associated with multiple stress tolerance, as a means to identify novel targets for engineering stress resistance in sorghum and possibly, in other crop species.Item A decade of plant proteomics and mass spectrometry: Translation of technical advancements to food security and safety issues(Wiley, 2013) Agrawal, Ganesh Kumar; Sarkar, Abhijit; Righetti, Pier Giorgio; Ndimba, Bongani K.Tremendous progress in plant proteomics driven by mass spectrometry (MS) techniques has been made since 2000 when few proteomics reports were published and plant proteomics was in its infancy. These achievements include the refinement of existing techniques and the search for new techniques to address food security, safety, and health issues. It is projected that in 2050, the world’s population will reach 9–12 billion people demanding a food production increase of 34–70% (FAO, 2009) from today’s food production. Provision of food in a sustainable and environmentally committed manner for such a demand without threatening natural resources, requires that agricultural production increases significantly and that postharvest handling and food manufacturing systems become more efficient requiring lower energy expenditure, a decrease in postharvest losses, less waste generation and food with longer shelf life. There is also a need to look for alternative protein sources to animal based (i.e., plant based) to be able to fulfill the increase in protein demands by 2050. Thus, plant biology has a critical role to play as a science capable of addressing such challenges. In this review, we discuss proteomics especially MS, as a platform, being utilized in plant biology research for the past 10 years having the potential to expedite the process of understanding plant biology for human benefits. The increasing application of proteomics technologies in food security, analysis, and safety is emphasized in this review. But, we are aware that no unique approach/technology is capable to address the global food issues. Proteomics-generated information/resources must be integrated and correlated with other omics-based approaches, information, and conventional programs to ensure sufficient food and resources for human development now and in the futureItem Development of a reporter system for the analysis of xylophilus ampelinus type III secreted effectors(University of the Western Cape, 2014) Nyembe, Nompumelelo Philile Praiseworth; Ndimba, Bongani K.; Petersen, YolandaXylophilus ampelinus, the causal agent of bacterial blight and canker of grapevines, has long been a threat to the table grape industry in the Western Cape, leading to severe economic losses due to the reduced productivity and shortened lifespan of infected grapevines. Very little is known about the genetic makeup of the organism, especially with regard to the factors that contribute to its pathogenicity. Generally, bacterial pathogens directly inject the effector proteins into host cells via Type III secretion system (T3SS). In the attempts to identify and characterize the T3 secreted effectors, different reporter plasmid systems have been used to study the secretion and translocation mechanisms the effectors employ during pathogenicity. The aim of the study was to generate a T3 reporter plasmid system for X. ampelinus that will allow the identification and classification of potential pathogenicity factors as members of the Type III secretion class of effectors. First, the avrBs1 family genes avrBs1 and avrA were identified and characterized. The two avirulence genes induced HR on Nicotiana tabacum leaves. Due to the relatedness of the X. ampelinus avr sequences to those of xanthomonads, and the fact that Xanthomonas avrBs1 has been successfully used in a number T3 effector studies, it was decided to construct an X. ampelinus T3 effector reporter vector based on the avrBs1 gene. The minimal segment of the X. ampelinus AvrBs1 protein C-terminus, sufficient for recognition inside host cells and also responsible for HR-induction was identified and characterized using Agrobacterium-mediated transient expression. The AvrBs157-413 HR-inducing domain was cloned in-frame with the 3x FLAG epitope, into a broad-host range vector. To test the reporter vector, the full length avrBs1 sequences of X. ampelinus and Xanthomonas campestris pv. campestris were cloned ahead of the 3x FLAG epitope and the constructs were transferred into XaΔavrBs1 knockout mutant to test for protein secretion. Furthermore, the reporter construct was tested for Type III protein translocation on Bs1 resistant pepper cultivar STAR 6657. Optimization of protein secretion and translocation assays is however required for the improved results. This might include the application of an alternative protein tag to identify candidate X. ampelinus T3SS effectors.Item ¹Genetic analysis of red pigmentation in ‘bon rouge’ pears (Pyrus communis L.)(University of Western Cape, 2014) Booi, Sonwabo; Ndimba, Bongani K.; Tobutt, Kenneth RichardEuropean pear (Pyrus communis L.) is the third most important fruit in South Africa after citrus and apple. The Agricultural Research Council (ARC) breeding programme seeks to obtain a fully red coloured pear. Sports (mutants) with red skin and reddish leaves of various cultivars occur and some have been used in breeding programmes, where they transmit red colour as a single gene. The red trait in ‘Max Red Bartlett’, a mutant of ‘Bartlett’ (Synonym – ‘Williams Bon Chretien’), was mapped in Italy to linkage group 4 (LG4). At ARC Infruitec-Nietvoorbij, Stellenbosch, South Africa, ‘Bon Rouge’ pear, another red mutant of ‘Williams Bon Chretien’, was crossed with ‘Packham’s Triumph’ generating an F1 population with a segregation of (54:71) red:green, approximating to a 1:1 ratio; indicating a simple Mendelian inheritance of the red trait. The aim of the study was to determine if the ‘Bon Rouge’ red colour trait maps to approximately the same position as the ‘Max Red Bartlett’ red colour trait on LG4, and if so, to identify SSR markers that are mapped closer to the red colour trait than were previously reported. The seven published pear and apple SSR markers mapped in the appropriate region of LG4 in pear and in apple maps were identified and screened in the parents and, where informative, were scored in 125 seedlings for co-segregation analysis. Single locus segregations were checked with JoinMap 4.1 and this program was also used to generate a genetic map for LG4 of the ‘Bon Rouge’ x ‘Packham’s Triumph’ progeny using the SSR markers and the red locus. Two linkage maps were constructed at a LOD threshold of 3 using the Kosambi mapping function, one each with the maximum likelihood and regression mapping algorithms. The genetic linkage map of LG4 of ‘Bon Rouge’ x ‘Packham’s Triumph’ consisted of seven SSR markers (2 from apple and 5 from pear). Markers CH01d03 and CH02c02b were mapped on the same position as the red trait in ‘Max Red Bartlett’ reported by Dondini et al. (2008) and four more markers were added. One of the newly mapped markers, NH011a has been found to be closely linked to the red trait, with an approximate distance of 4 cM. This marker can be used to indirectly select for the red gene in pear, for example to distinguish heterozygotes from homozygotes. This work sets the scene for further genetic studies on the red trait in pear breeding programmes.Item Identification and profiling of salinity stress-responsive proteins in Sorghum bicolor seedlings(Elsevier, 2012) Ngara, Rudo; Ndimba, Roya; Borch-Jensen, Jonas; Jensen, Ole Nørregaard; Ndimba, Bongani K.Sorghum bicolor, a drought tolerant cereal crop, is not only an important food source in the semi arid/arid regions but also a potential model for studying and gaining a better understanding of the molecular mechanisms of drought and salt stress tolerance in cereals. In this study, seeds of a sweet sorghumvariety, MN1618, were planted and grown on solid MS growth medium with or without 100mM NaCl. Heat shock protein expression immunoblotting assays demonstrated that this salt treatment induced stress within natural physiological parameters for our experimental material. 2D PAGE in combination with MS/MS proteomics techniques were used to separate, visualise and identify salinity stress responsive proteins in young sorghum leaves. Out of 281 Coomassie stainable spots, 118 showed statistically significant responses (p<0.05) to salt stress treatments. Of the 118 spots, 79 were selected for tandem mass spectrometric identification, owing to their good resolution and abundance levels, and of these, 55 were positively identified. Identified proteins were divided into six functional categories including both known and novel/putative stress responsive proteins. Molecular and physiological functions of some of our proteins of interest are currently under investigation via bioinformatic and molecular biology approaches.Item Identification of differentially expressed proteins in obese rats fed different high fat diets using proteomics and bioinformatics approaches(2013) Gabuza, Kwazikwakhe; Ndimba, Bongani K.; Madiehe, Abram M.Obesity is a medical condition in which an energy imbalance leads to excessive accumulation of body fat. Obesity leads to a reduction in life expectancy through its association with chronic diseases of lifestyle. The prevalence of obesity is rapidly increasing throughout the world. It is now accepted that most cases of obesity result from an interaction between genetic and environmental factors. This rapid increase in obesity generally leads to an increase in morbidity and mortality from chronic diseases such as cardiovascular disease, type 2 diabetes, osteoarthritis and cancer of which obesity is a risk factor. There is a lack of information in molecular research to explain how obesity predisposes individuals to these diseases. Proteomics is a molecular tool and a set of techniques used to identify changes at protein level from a diseased state. This study aims to identify differentially expressed proteins in serum of obese rats fed different isocaloric diets using proteomics.Item INPPO actions and recognition as a driving force for progress in plant proteomics: Change of guard, INPPO update, and upcoming activities(Wiley, 2013) Agrawal, Ganesh Kumar; Job, Dominique; Kieselbach, Thomas; Ndimba, Bongani K.The International Plant Proteomics Organization (INPPO) is a non-profit organization whose members are scientists involved or interested in plant proteomics. Since the publication of the first INPPO highlights in 2012, continued progress on many of the organization’s mandates/goals has been achieved. Two major events are emphasized in this second INPPO highlights. First, the change of guard at the top, passing of the baton from Dominique Job, INPPO founding President to Ganesh Kumar Agrawal as the incoming President. Ganesh K. Agrawal, along with Dominique Job and Randeep Rakwal initiated the INPPO. Second, the most recent INPPO achievements and future targets, mainly the organization of first the INPPO World Congress in 2014, tentatively planned for Hamburg (Germany), are mentioned.Item An integrated and comparative approach towards identification, characterization and functional annotation of candidate genes for drought tolerance in sorghum (Sorghum bicolor (L.) Moench)(BioMed Central, 2017) Woldesemayat, Adugna Abdi; Van Heusden, Peter; Ndimba, Bongani K.; Christoffels, AlanBACKGROUND: Drought is the most disastrous abiotic stress that severely affects agricultural productivity worldwide. Understanding the biological basis of drought-regulated traits, requires identification and an in-depth characterization of genetic determinants using model organisms and high-throughput technologies. However, studies on drought tolerance have generally been limited to traditional candidate gene approach that targets only a single gene in a pathway that is related to a trait. In this study, we used sorghum, one of the model crops that is well adapted to arid regions, to mine genes and define determinants for drought tolerance using drought expression libraries and RNA-seq data. RESULTS: We provide an integrated and comparative in silico candidate gene identification, characterization and annotation approach, with an emphasis on genes playing a prominent role in conferring drought tolerance in sorghum. A total of 470 non-redundant functionally annotated drought responsive genes (DRGs) were identified using experimental data from drought responses by employing pairwise sequence similarity searches, pathway and interprodomain analysis, expression profiling and orthology relation. Comparison of the genomic locations between these genes and sorghum quantitative trait loci (QTLs) showed that 40% of these genes were co-localized with QTLs known for drought tolerance. The genome reannotation conducted using the Program to Assemble Spliced Alignment (PASA), resulted in 9.6% of existing single gene models being updated. In addition, 210 putative novel genes were identified using AUGUSTUS and PASA based analysis on expression dataset. Among these, 50% were single exonic, 69.5% represented drought responsive and 5.7% were complete gene structure models. Analysis of biochemical metabolism revealed 14 metabolic pathways that are related to drought tolerance and also had a strong biological network, among categories of genes involved. Identification of these pathways, signifies the interplay of biochemical reactions that make up the metabolic network, constituting fundamental interface for sorghum defence mechanism against drought stress. CONCLUSIONS: This study suggests untapped natural variability in sorghum that could be used for developing drought tolerance. The data presented here, may be regarded as an initial reference point in functional and comparative genomics in the Gramineae family.Item Mapping and characterisation of the sorghum cell suspension culture secretome(Academic Journals, 2011) Ngara, Rudo; Ndimba, Bongani K.Here we reported the first secretomic study of sorghum (Sorghum bicolor), a naturally drought tolerant cereal crop. In this study, we used a gel-based proteomic approach in combination with mass spectrometry to separate and identify proteins secreted into the culture medium of sorghum cell suspensions, a first step towards understanding their functions during plant growth and development. Proteins secreted into the culture medium of 10-day old sorghum cell suspension cultures termed culture filtrate (CF) proteins were separated by two-dimensional gel electrophoresis (2DE) and visualised using Coomassie brilliant blue (CBB) R-250 staining. Of the 25 visualised CBB stainable spots, 15 abundant, well-resolved and reproducible spots amongst the three biological replicates used were selected for identification using matrix assisted laser desorption/ionisation-time of flight/time of flight tandem mass spectrometry (MALDI-TOF-TOF MS). Of these spots, 14 were positively identified, representing four different protein classes: Peroxidases, germin proteins, oxalate oxidases and ?-galactosidases. All the identified proteins are known secretory proteins, with predicted signal peptides, which target proteins for the secretory pathway. The identified proteins have known functions in signalling processes, defence mechanisms and cell wall metabolism which is consistent with their location outside the cell. Western blotting analysis of the CF protein extracts using an antibody against ?-tubulin, a cytoplasmic protein, indicated that our CF protein preparations are free from any detectable amounts of this marker protein. Therefore, our sorghum cell culture system is ideal for use in the proteomic analysis of secreted proteins. The findings of this study are a step in the process of bridging the gap that currently exists in sorghum proteomics and also provides a foundation for future studies on understanding the roles played by secreted proteins during plant growth and development of the same crop.Item Molecular adaptation mechanisms employed by ethanologenic bacteria in response to lignocellulose-derived inhibitory compounds(Ivyspring, 2013) Ndimba, Bongani K.; Ibraheem, OmodeleCurrent international interest in finding alternative sources of energy to the diminishing supplies of fossil fuels has encouraged research efforts in improving biofuel production technologies. In countries which lack sufficient food, the use of sustainable lignocellulosic feedstocks, for the production of bioethanol, is an attractive option. In the pre-treatment of lignocellulosic feedstocks for ethanol production, various chemicals and/or enzymatic processes are employed. These methods generally result in a range of fermentable sugars, which are subjected to microbial fermentation and distillation to produce bioethanol. However, these methods also produce compounds that are inhibitory to the microbial fermentation process. These compounds include products of sugar dehydration and lignin depolymerisation, such as organic acids, derivatised furaldehydes and phenolic acids. These compounds are known to have a severe negative impact on the ethanologenic microorganisms involved in the fermentation process by compromising the integrity of their cell membranes, inhibiting essential enzymes and negatively interact with their DNA/RNA. It is therefore important to understand the molecular mechanisms of these inhibitions, and the mechanisms by which these microorganisms show increased adaptation to such inhibitors. Presented here is a concise overview of the molecular adaptation mechanisms of ethanologenic bacteria in response to lignocellulose-derived inhibitory compounds. These include general stress response and tolerance mechanisms, which are typically those that maintain intracellular pH homeostasis and cell membrane integrity, activation/regulation of global stress responses and inhibitor substrate-specific degradation pathways. We anticipate that understanding these adaptation responses will be essential in the design of ‘intelligent’ metabolic engineering strategies for the generation of hyper-tolerant fermentation bacteria strains.Item New genetic tools to engineer starch production in crops(University of the Western Cape, 2014) Muteveri, Morleen; Ndimba, Bongani K.Starch is a major carbohydrate reserve in many plants, providing energy during heterotrophic growth and it is contained in large amounts in staple foods such as potatoes, wheat, maize, rice, sorghum and cassava. Apart from being a major product for use in the food industry, starch is also attracting interest from the biofuels industry as a source of bioethanol. This study reports on the development of genetic tools aimed at increasing starch production in sorghum (Sorghum bicolor L Moench), a crop of key agronomic importance worldwide by exploiting a new discovery of a transcription factor gene that regulates starch accumulation in Arabidopsis thaliana namely LEAFY COTYLEDON I (LECl). Ectopic over expression of this gene in arabidopsis has previously been shown to induce a massive hyper accumulation of starch in vegetative tissues. Therefore, we set out to investigate the function of its orthologous gene counterpart in sorghum with the aim of manipulating starch yield directly. Deduced protein sequence analyses showed that the putative sorghum LEAFY COTYLEDON I gene (SbLEC1) cloned in this study shares an overall high amino acid sequence identity (70 %) with the arabidopsis LEC 1, while the functional central B domain shows an even higher percentage sequence identity (91 %) with the same region of arabidopsis LEC 1. The putative SbLEC1 protein shares 14 out of the 16, signature ammo acids characteristic of the Central B Domain with arabidopsis. Furthermore, the putative SbLEC1 protein was also shown to share a significantly high sequence identity (> 80 %) with other well-characterized LEC1 protein sequences from organisms such as maize, rice, rapeseed as well as other organisms documented in the NCB I database. Similarly, much of the sequence similarity lies within the functional central B domain compared to any other region. Gene expression profiling using semi-quantitative PCR showed that SbLEC1 transcripts accumulated in developing seeds as well as in embryogenic calli tissue and no SbLEC 1 transcripts were detectable in leaf, root or sheath tissue. In order to confirm that the identified transcription factor is a functional ortholog, the full cDNA encoding putative SbLEC 1 transcription factor was identified, isolated and cloned from the sweet sorghum MN 1812 genotype. Plant transformation gene constructs based on the pCAMBIA1305.2 binary vector harbouring the transcription factor gene under the control of different promoter sequences were then assembled and immobilized into Agrobacterium tumefaciens strain LBA4404 in preparation for sorghum and arabidopsis transformation. Transient GUS expression studies showed that the five SbLEC1 gene constructs developed in this study were successfully transformed into arabidopsis (Ws ecotype) and sorghum (variety MN1812) callus and cell suspension cultures. The transformed tissues thus represent essential tools that are useful to evaluate the effect of over expressing the putative SbLEC1 protein. Transient GUS expression assays also further revealed differences in efficiency among promoters in driving transgene expression. Transient GUS activity was highest for the maize ubiquitin promoter (MUbi1), followed by the sorghum LEC1 promoter (SLECP), the arabidopsis LEC1 promoter (ALECP) and lastly the maize alcohol dehydrogenase promoter (MAdh1). The ability of the putative SbLEC 1 gene to complement the arabidopsis lecI mutation was also investigated and our findings were not conclusive as they only revealed partial complementation. A detailed comparison of SbLECI full cDNA sequences isolated and cloned from twenty-eight different F2 population plants from different sorghum varieties revealed the existence of sequence variation within the SbLEC 1 gene, which appeared to be allelic. The allelic variation was further shown to affect the amino acid composition of the putative SbLEC 1 protein. Heterologous protein expression studies of the SbLECI gene using an E. coli system showed that the predicted 29.16 kDa putative SbLEC 1 protein could be expressed in vitro both as an development of an efficient tissue culture protocol is a prerequisite for plant genetic engineering, this study also reports on the evaluation of thirteen sorghum genotypes from different genetic backgrounds for their in vitro culture response. A tissue culture protocol for three previously unexplored sorghum genotypes namely Agricol white, AS4 and MNI812 was established. The effect of plant genotype, explant and medium composition on in vitro culture response was highly significant (95 % Cl) in this study. Taken together, the findings in our study demonstrate efforts to draw a baseline foundation for the development of molecular technologies that can be used to increase starch production in sweet sorghum as a water efficient and sustainable feedstock for biofuel production.Item A proteomic analysis of drought and salt stress responsive proteins of different sorghum varieties(University of the Western Cape, 2009) Ngara, Rudo; Ndimba, Bongani K.Sorghum (Sorghum bicolorï, a drought tolerant cereal crop, is not only an important food source in the semi arid/arid regions but also a potential model for studying and gaining a better understanding of the molecular mechanisms of drought and salt stress tolerance in cereals. This study reports on a proteomic analysis of sorghum proteomes in response to salt and hyperosmotie stresses. Two-dimensional gel electrophoresis (2DE) in combination with mass spectrometry (MS) was used to separate, visualise and identify sorghum proteins using both sorghum cell suspension cultures and whole plants. The sorghum cell suspension culture system was used as a source of culture filtrate (CF) proteins. Of the 25 visualised CBB stained CF spots, 15 abundant and well-resolved spots were selected for identification using a combination of MALDI- TOF and MALDI- TOFTOF MS, and database searching. Of these spots, 14 were positively identified as peroxidases, germ in proteins, oxalate oxidases and alpha-galactosidases with known functions in signalling processes, defense mechanisms and cell wall metabolism. Following 200 mM NaCl and 400 mM sorbitol stress treatments, the expression/abundance of a protein spot similar to a rice wall-associated protein kinase was upregulated in the sorghum secretome in response to both stresses. Amino acid sequence alignment of the matching peptides between these two proteins showed that the sorghum CF spot possesses a protein kinase domain. Therefore, this protein could possibly participate in cell signalling functions, which link the external environment with the cell's cytoplasm. Using whole plant systems, a comparative study of leaf protein expression between two sorghum varieties, AS6 (salt sensitive) and MN1618 (salt tolerant) was conducted. Forty well resolved spots of varying abundances were picked for MS analysis. Of these, 28 were positively identified, representing proteins with functions in carbohydrate metabolism (60.7%), proton transport (17.9%), protein synthesis (7.1%), hydrolytic functions (7.1%), nucleotide metabolism (3.6%) and detoxification (3.6%). Using PDQuest™ Advanced 2D Analysis Software version 8.0.1 (BIO-RAD), a comparative analysis of leaf proteome expression patterns between the two sorghum varieties was conducted. The results indicated proteins with similar expression patterns as well as qualitative and quantitative differences between the two leaf proteomes. The effect of 100 mM NaCI on leaf proteome expression between the two sorghum varieties was also studied. Western blotting analysis of leaf, sheath and root tissues using Hsp70 antibodies showed that this treatment induced Hsp70 expression, a known stress protein, in both varieties. Thereafter, the partially annotated leaf proteome map was used to landmark other salt responsive proteins. Examples of differential expression patterns included glutathione S transferase and hydroxynitrile lyase proteins whose abundances were upregulated in both varieties, while the large subunit of RuBisCo was downregulated in AS6 but upregulated in MN1618. Qualitative spot expression differences in response to salt stress were also observed between the two sorghum varieties but these remained unidentified after both MALDI-TOF and MALDI-TOF-TOF MS, possibly indicating novel and previously uncharacterised sorghum proteins. The results of this study can be used as reference tools by proteomics researchers worldwide as well as a foundation for future studies.