Thermotolerance of cotton

Cottee, Nicola Sandra

January 2009

Doctor of Philosophy (PhD) / The Australian cotton industry has developed high yielding and high quality fibre production systems and attributes a significant contribution of this achievement to highly innovative breeding programs, specifically focused on the production of premium quality lint for the export market. Breeding programs have recently shifted attention to the development of new germplasm with superior stress tolerance to minimise yield losses attributed to adverse environmental conditions and inputs such as irrigation, fertilisers and pesticides. Various contributors to yield, such as physiology, biochemistry and gene expression have been implemented as screening tools for tolerance to high temperatures under growth cabinet and laboratory conditions but there has been little extension of these mechanisms to field based systems. This study evaluates tools for the identification of specific genotypic thermotolerance under field conditions using a multi-level ‘top down’ approach from crop to gene level. Field experiments were conducted in seasons 1 (2006) and 3 (2007) at Narrabri (Australia) and season 2 (2006) in Texas (The United States of America) and were supplemented by growth cabinet experiments to quantify cultivar differences in yield, physiology, biochemical function and gene expression under high temperatures. Whole plants were subjected to high temperatures in the field through the construction of Solarweave® tents and in the growth cabinet at a temperature of 42 oC. The effectiveness of these methods was then evaluated to establish a rapid and reliable screening tool for genotype specific thermotolerance that could potentially improve the efficiency of breeding programs and aid the development to high yielding cultivars for hot growing regions. Cotton cultivars Sicot 53 and Sicala 45 were evaluated for thermotolerance using crop level measurements (yield and fibre quality) and whole plant measurements (fruit retention) to determine the efficacy of these measurements as screening tools for thermotolerance under field conditions. Sicot 53 was selected as a relatively thermotolerant cultivar whereas Sicala 45 was selected as a cultivar with a lower relative thermotolerance and this assumption was made on the basis of yield in hot and cool environments under the CSIRO Australian cotton breeding program. Yield and fruit retention were lower under tents compared with ambient conditions in all 3 seasons. Yield and fruit retention were highly correlated in season 1 and were higher for Sicot 53 compared to Sicala 45 suggesting that fruit retention is a primary limitation to yield in a hot season. Thus yield and fruit retention are good indicators of thermotolerance in a hot season. Temperature treatment and cultivar differences were determined for fibre quality in seasons 1 and 3; however, quality exceeded the industry minimum thereby indicating that fibre quality is not a good determinant of thermotolerance. Physiological determinants of plant functionality such as photosynthesis, electron transport rate, stomatal conductance and transpiration rate were determined for cultivars Sicot 53 and Sicala 45 under the tents and an index of these parameters was also analysed to determine overall plant physiological capacity in the field. Physiological capacity was also determined under high temperatures in the growth cabinet using a light response curve at various levels of photosynthetically active radiation (PAR). Photosynthesis and electron transport rate decreased, whilst stomatal conductance and transpiration rate increased under the tents as well as under high temperatures in the growth cabinet. Photosynthesis and electron transport rate were higher for Sicot 53 but stomatal conductance and transpiration rate were higher for Sicala 45 under the tents. No cultivar differentiation was evident for plants grown under high temperatures in the growth cabinet. Temperature treatment and cultivar differences in physiological function were greater in a hot year (season 1), thereby indicating the importance of cultivar selection for thermotolerance in the presence of stress. Electron transport rate was correlated with yield in season 1, thus suggesting the suitability of this method for broad genotypic screening for thermotolerance under field conditions. Biochemical processes such as membrane integrity and enzyme viability were used to determine cultivar specific thermotolerance under high temperature stress in the laboratory, field and growth cabinet. Electrolyte leakage is an indicator of decreased membrane integrity and may be estimated by the relative electrical conductivity or relative cellular injury assays. The heat sensitivity of dehydrogenase activity, a proxy for cytochrome functionality and capacity for mitochondrial electron transport, may be quantified spectrophotometrically. Cellular membrane integrity and enzyme viability decreased sigmoidally with exposure to increasing temperatures in a water bath. Membrane integrity was higher for Sicot 53 compared with Sicala 45 under the tents and under high temperatures in the growth cabinet. No temperature treatment or cultivar differences were found for enzyme viability under the tents; however, enzyme viability for Sicala 45 was higher in the growth cabinet compared with Sicot 53. Relative electrical conductivity was strongly correlated with yield under ambient field conditions and under the tents, suggesting impairment of electron flow through photosynthetic and/or respiratory pathways, thus contributing to lower potential for ATP production and energy generation for yield contribution. Thus, the membrane integrity assay was considered to be a rapid and reliable tool for thermotolerance screening in cotton cultivars. Gene expression was examined for cultivars Sicot 53 and Sicala 45 grown under high (42 oC) temperatures in the growth cabinet. Rubisco activase expression was quantified using quantitative real-time polymerase chain reaction analysis and was decreased under high temperatures and was lower for Sicala 45 than Sicot 53. Maximum cultivar differentiation was found after 1.0 h exposure to high temperatures and hence, leaf tissue sampled from this time point was further analysed for global gene profiling using cDNA microarrays. Genes involved in metabolism, heat shock protein generation, electron flow and ATP generation were down-regulated under high temperatures in the growth cabinet and a greater number of genes were differentially expressed for Sicala 45, thereby indicating a higher level of heat stress and a greater requirement for mobilisation of protective and compensatory mechanisms compared with Sicot 53. Cultivar specific thermotolerance determination using gene profiling may be a useful tool for understanding the underlying basis of physiological and biochemical responses to high temperature stress in the growth cabinet. There is future opportunity for profiling genes associated with heat stress and heat tolerance for identification of key genes associated with superior cultivar performance under high temperature stress and characterisation of these genes under field conditions. This research has identified cultivar differences in yield under field conditions and has identified multiple physiological and biochemical pathways that may contribute to these differences. Future characterisation of genes associated with heat stress and heat tolerance under growth cabinet conditions may be extended to field conditions, thus providing the underlying basis of the response of cotton to high temperature stress. Electron transport rate and relative electrical conductivity were found to be rapid and reliable determinants of cultivar specific thermotolerance and hence may be extended to broad-spectrum screening of a range of cotton cultivars and species and under a range of abiotic stress. This will enable the identification of superior cotton cultivars for incorporation into local breeding programs for Australian and American cotton production systems.

high temperature stress

heat tolerance

upland cotton

Gossypium hirsutum L.

genetic variation

photosynthesis

electron transport rate

stomatal conductance

transpiration rate

cell membrane integrity

enzyme viability

rubisco activase

gene expression

Thermotolerance of cotton

Cottee, Nicola Sandra

January 2009

Doctor of Philosophy (PhD) / The Australian cotton industry has developed high yielding and high quality fibre production systems and attributes a significant contribution of this achievement to highly innovative breeding programs, specifically focused on the production of premium quality lint for the export market. Breeding programs have recently shifted attention to the development of new germplasm with superior stress tolerance to minimise yield losses attributed to adverse environmental conditions and inputs such as irrigation, fertilisers and pesticides. Various contributors to yield, such as physiology, biochemistry and gene expression have been implemented as screening tools for tolerance to high temperatures under growth cabinet and laboratory conditions but there has been little extension of these mechanisms to field based systems. This study evaluates tools for the identification of specific genotypic thermotolerance under field conditions using a multi-level ‘top down’ approach from crop to gene level. Field experiments were conducted in seasons 1 (2006) and 3 (2007) at Narrabri (Australia) and season 2 (2006) in Texas (The United States of America) and were supplemented by growth cabinet experiments to quantify cultivar differences in yield, physiology, biochemical function and gene expression under high temperatures. Whole plants were subjected to high temperatures in the field through the construction of Solarweave® tents and in the growth cabinet at a temperature of 42 oC. The effectiveness of these methods was then evaluated to establish a rapid and reliable screening tool for genotype specific thermotolerance that could potentially improve the efficiency of breeding programs and aid the development to high yielding cultivars for hot growing regions. Cotton cultivars Sicot 53 and Sicala 45 were evaluated for thermotolerance using crop level measurements (yield and fibre quality) and whole plant measurements (fruit retention) to determine the efficacy of these measurements as screening tools for thermotolerance under field conditions. Sicot 53 was selected as a relatively thermotolerant cultivar whereas Sicala 45 was selected as a cultivar with a lower relative thermotolerance and this assumption was made on the basis of yield in hot and cool environments under the CSIRO Australian cotton breeding program. Yield and fruit retention were lower under tents compared with ambient conditions in all 3 seasons. Yield and fruit retention were highly correlated in season 1 and were higher for Sicot 53 compared to Sicala 45 suggesting that fruit retention is a primary limitation to yield in a hot season. Thus yield and fruit retention are good indicators of thermotolerance in a hot season. Temperature treatment and cultivar differences were determined for fibre quality in seasons 1 and 3; however, quality exceeded the industry minimum thereby indicating that fibre quality is not a good determinant of thermotolerance. Physiological determinants of plant functionality such as photosynthesis, electron transport rate, stomatal conductance and transpiration rate were determined for cultivars Sicot 53 and Sicala 45 under the tents and an index of these parameters was also analysed to determine overall plant physiological capacity in the field. Physiological capacity was also determined under high temperatures in the growth cabinet using a light response curve at various levels of photosynthetically active radiation (PAR). Photosynthesis and electron transport rate decreased, whilst stomatal conductance and transpiration rate increased under the tents as well as under high temperatures in the growth cabinet. Photosynthesis and electron transport rate were higher for Sicot 53 but stomatal conductance and transpiration rate were higher for Sicala 45 under the tents. No cultivar differentiation was evident for plants grown under high temperatures in the growth cabinet. Temperature treatment and cultivar differences in physiological function were greater in a hot year (season 1), thereby indicating the importance of cultivar selection for thermotolerance in the presence of stress. Electron transport rate was correlated with yield in season 1, thus suggesting the suitability of this method for broad genotypic screening for thermotolerance under field conditions. Biochemical processes such as membrane integrity and enzyme viability were used to determine cultivar specific thermotolerance under high temperature stress in the laboratory, field and growth cabinet. Electrolyte leakage is an indicator of decreased membrane integrity and may be estimated by the relative electrical conductivity or relative cellular injury assays. The heat sensitivity of dehydrogenase activity, a proxy for cytochrome functionality and capacity for mitochondrial electron transport, may be quantified spectrophotometrically. Cellular membrane integrity and enzyme viability decreased sigmoidally with exposure to increasing temperatures in a water bath. Membrane integrity was higher for Sicot 53 compared with Sicala 45 under the tents and under high temperatures in the growth cabinet. No temperature treatment or cultivar differences were found for enzyme viability under the tents; however, enzyme viability for Sicala 45 was higher in the growth cabinet compared with Sicot 53. Relative electrical conductivity was strongly correlated with yield under ambient field conditions and under the tents, suggesting impairment of electron flow through photosynthetic and/or respiratory pathways, thus contributing to lower potential for ATP production and energy generation for yield contribution. Thus, the membrane integrity assay was considered to be a rapid and reliable tool for thermotolerance screening in cotton cultivars. Gene expression was examined for cultivars Sicot 53 and Sicala 45 grown under high (42 oC) temperatures in the growth cabinet. Rubisco activase expression was quantified using quantitative real-time polymerase chain reaction analysis and was decreased under high temperatures and was lower for Sicala 45 than Sicot 53. Maximum cultivar differentiation was found after 1.0 h exposure to high temperatures and hence, leaf tissue sampled from this time point was further analysed for global gene profiling using cDNA microarrays. Genes involved in metabolism, heat shock protein generation, electron flow and ATP generation were down-regulated under high temperatures in the growth cabinet and a greater number of genes were differentially expressed for Sicala 45, thereby indicating a higher level of heat stress and a greater requirement for mobilisation of protective and compensatory mechanisms compared with Sicot 53. Cultivar specific thermotolerance determination using gene profiling may be a useful tool for understanding the underlying basis of physiological and biochemical responses to high temperature stress in the growth cabinet. There is future opportunity for profiling genes associated with heat stress and heat tolerance for identification of key genes associated with superior cultivar performance under high temperature stress and characterisation of these genes under field conditions. This research has identified cultivar differences in yield under field conditions and has identified multiple physiological and biochemical pathways that may contribute to these differences. Future characterisation of genes associated with heat stress and heat tolerance under growth cabinet conditions may be extended to field conditions, thus providing the underlying basis of the response of cotton to high temperature stress. Electron transport rate and relative electrical conductivity were found to be rapid and reliable determinants of cultivar specific thermotolerance and hence may be extended to broad-spectrum screening of a range of cotton cultivars and species and under a range of abiotic stress. This will enable the identification of superior cotton cultivars for incorporation into local breeding programs for Australian and American cotton production systems.

high temperature stress

heat tolerance

upland cotton

Gossypium hirsutum L.

genetic variation

photosynthesis

electron transport rate

stomatal conductance

transpiration rate

cell membrane integrity

enzyme viability

rubisco activase

gene expression

Caractérisation des propriétés antibactériennes de textiles fonctionnalisés avec de l’argent ou du PolyHexaMéthylène Biguanide (PHMB) / Antibacterial properties characterization of functionalized textiles with silver or PolyHexaMethylene Biguanide (PHMB)

Chadeau, Élise

15 February 2011

Dans l’industrie agro-alimentaire, l’adhésion de micro-organismes altérants ou pathogènes sur les surfaces induit des effets néfastes à la fois en termes de qualité, d’hygiène et de santé publique. Les vêtements professionnels constituent un des vecteurs de contamination par le personnel. Ce travail de thèse concerne l’évaluation de l’activité antimicrobienne de textiles antimicrobiens développés pour le secteur hospitalier et le secteur agro-alimentaire et rentre dans le cadre du projet collaboratif Actiprotex. Trois méthodologies ont été employées pour le dépôt d’agents antimicrobiens sur les textiles : méthodologie plasma (PVD/PECVD) ou sol-gel pour le dépôt d’argent, foulardage avec une solution contenant du laurylsulfate et du Poly Hexaméthylène Biguanide (PHMB) pour provoquer une co-précipitation du PHMB. Les activités antimicrobiennes de chaque textile ont été évaluées après 24 h de contact (suivant la norme ISO 20743-2005). Les quantités d’agent antimicrobien à la surface des textiles ont été évaluées par 2 techniques d’analyses de surface : la spectroscopie photoélectronique par rayons X (XPS) et la spectrométrie de masse d’ions secondaires (ToF-SIMS). Les textiles traités par plasma à l’argent se sont avérés être efficaces vis-à-vis de Listeria innocua LRGIA 01. Pour le traitement sol-gel, les textiles testés étaient également très actifs vis-à-vis de L. innocua LRGIA 01 et d’Escherichia coli XL1 blue. Cependant, E. coli XL1 blue est apparue plus sensible à l’argent que L. innocua LRGIA 01. Les textiles traités au PHMB se sont également avérés être très actifs vis-à-vis de L. innocua LRGIA 01 et de Staphylococcus aureus méthi-R nosoco 3011 cependant des cellules viables mais non cultivables (VNC) ont également été mises en évidence après contact de ces 2 souches avec le textile traité au PHMB. Pseudomonas aeruginosa ATCC 15742 s’est quant à elle avérée être plus résistante que ces 2 souches. La tenue aux lavages industriels ou ménagers des dépôts plasma d’argent et de PHMB par foulardage a également été évaluée. Les dépôts plasma d’argent résistent mal au lavage alors que le dépôt PHMB par foulardage s’est avéré résister à 10 lavages industriels. Pour mieux comprendre le mécanisme d’action du PHMB vis-à-vis de L. innocua LRGIA 01 en milieu liquide, trois approches ont été mises en oeuvre : la microscopie à épifluorescence en présence de marqueurs fluorescents pour évaluer l’état de la membrane des cellules, la spectrofluorimétrie en présence de sondes fluorescentes (DPH et TMA-DPH) pour évaluer la fluidité de la membrane des cellules et enfin la spectroscopie infrarouge à transformée de Fourier (IRTF) pour évaluer les changements de conformation de la membrane. Les résultats obtenus par ces 3 méthodes permettent de proposer un mode d’action du PHMB de type « carpet », c’est à dire une fixation de l’agent antimicrobien en surface puis une désorganisation de la membrane conduisant à des changements de sa conformation puis à la formation de pores et à la mort cellulaire / Adhesion of pathogenic or spoilage microorganisms on the surfaces present in food industry can lead to contaminations of foods. Besides the economical impact for this industrial sector, these contaminations might alleviate food quality and hygiene and affect public health. Professional clothes constitute one of the vectors of contamination by the staff of food-processing industry. This work is a part of a collaborative project (Actiprotex) and concerns the evaluation of the antimicrobial activity of antimicrobial textiles developed for the hospital sector and the food-processing industry. Three methodologies were employed to obtain deposits of antimicrobial agents on textiles surfaces: plasma (PVD / PECVD) or sol-gel methodologies for the silver deposit and spin coating with a solution containing laurylsulfate and PolyHexamethylene Biguanide (PHMB). The antimicrobial activities of functionalized textiles were estimated after 24 hours of contact (according to the standard ISO 20743- 2005). The quantities of antimicrobial agent at the extreme surface of the textiles were estimated by two techniques of analyses of surface: the photoelectronic spectroscopy by X-rays (XPS) and the mass spectrometry of secondary ions (ToF-SIMS). Textiles functionalized by plasma methodology with silver were effective against Listeria innocua LRGIA 01. For the textiles functionalized by sol-gel methodology, the tested textiles were also very active towards L. innocua LRGIA 01 and Escherichia coli XL1 blue. However, E. coli XL1 blue seemed to be more sensitive to the silver on textiles than the L. innocua LRGIA 01 strain. Textiles treated with the PHMB also turned out to be very active towards L. innocua LRGIA 01 and Staphylococcus aureus methi-R nosoco 3011, however viable but not cultivable cell (VNC) were also revealed after contact of these 2 strains with the PHMB treated textile. Pseudomonas aeruginosa ATCC 15742 was more resistant to PHMB than these 2 strains. The washing resistance of silver- or PHMB-deposits was also estimated. Most of the silver deposit following plasma treatment was washed out while the PHMB deposit turned out to resist to 10 industrial washes. To understand the mechanism of action of the PHMB against L. innocua LRGIA 01, three approaches were considered: the epifluorescence microscopy in the presence of fluorescent dyes to estimate the state of the membrane cells, spectrofluorimetry in the presence of fluorescent probes (DPH and TMA-DPH) to estimate the membrane fluidity of cells and finally the infrared transformed Fourier spectroscopy (IRTF) to estimate the changes of conformation of the membrane

Textiles antibactériens

Argent

PHMB

PVD/PECVD

Sol-gel

Viabilité cellulaire

Fluidité membranaire

Intégrité membranaire

Antibacterial textiles

Silver

PHMB

PVD/PECVD

Sol-gel

Cell viability

Cell membrane fluidity

Cell membrane integrity

677