Plant tissue culture and artificial seed production techniques for cauliflower and their use to study molecular analysis of abiotic stress tolerance

Rihan, Hail

January 2014

A protocol for cauliflower micro-propagule production was developed and optimised for both micropropagation and artificial seed production techniques using meristematic tissues from cauliflower curd. All steps in the protocol were empirically optimised including: blending, sieving, culture methods, liquid culture media composition and plant growth regulator combinations and concentrations. The cost of the micro-propagules could be reduced by as much as 50% on the initial costings reported previously since treatments doubled the number of microshoots produced per culture unit. The research confirmed the suitability of cauliflower microshoots to be encapsulated as artificial seeds and an effective protocol for microshoot encapsulation was designed through the optimization of 1) the production of cauliflower microshoots suitable for encapsulation, 2) encapsulation procedures, 3) artificial seed artificial endosperm structure, 4) conversion materials. The possibility of culturing cauliflower artificial seeds in commercial substrates such as perlite, sand, vermiculite and compost was confirmed. The use of plant preservative mixture (PPM) for the control of contamination in cauliflower culture media and artificial seeds was optimised and the effect of this material on the development of plant material was assessed. It was confirmed that cauliflower artificial seed could be stored in a domestic refrigerator for up to 6 months which could have a great impact in cauliflower breeding programmes. The huge number of cauliflower microshoots that could be produced using this protocol and the homogeneity of the culture system, provided a tool for the molecular analysis of cauliflower microshoots (and artificial seed) abiotic stress tolerance analysis. Various treatments were conducted to improve microshoot cold tolerance and the up-regulation of the CBF/DREB1 transcription factor including low temperature acclimation, mannitol, ABA (abscisic acid) and Mo (molybdenum). Microshoots were confirmed to acclimate successfully using low temperature. Mo was shown to improve the cold tolerance of cauliflower microshoots and to up-regulate CBF/DREB1 in the absence of low temperature acclimation. Acclimation did not increase the accumulation of dehydrin proteins and it is concluded that dehydrins do not play a significant role in the cold tolerance of cauliflower microshoots. Since cauliflower breeding and seed multiplication protocols make extensive use of micropropagation, the studies reported in this research could make a significant impact by decreasing the cost of micropropagation and increasing its reliability. It also opens new perspectives for further research for cauliflower artificial seed production and the possibility of sowing these seeds directly in the field. Furthermore, this research helps to facilitate cauliflower breeding programmes by improving the understanding of abiotic stress tolerance mechanisms and the relationship between different types of abiotic stresses such as cold and drought.

571.5

Bacterial Endophytes from Pioneer Desert Plants for Sustainable Agriculture

Eida, Abdul Aziz

06 1900

One of the major challenges for agricultural research in the 21st century is to increase crop productivity to meet the growing demand for food and feed. Biotic (e.g. plant pathogens) and abiotic stresses (e.g. soil salinity) have detrimental effects on agricultural productivity, with yield losses being as high as 60% for major crops such as barley, corn, potatoes, sorghum, soybean and wheat, especially in semi-arid regions such as Saudi Arabia. Plant growth promoting bacteria isolated from pioneer desert plants could serve as an eco-friendly, sustainable solution for improving plant growth, stress tolerance and health. In this dissertation, culture-independent amplicon sequencing of bacterial communities revealed how native desert plants influence their surrounding bacterial communities in a phylogeny-dependent manner. By culture-dependent isolation of the plant endosphere compartments and a number of bioassays, more than a hundred bacterial isolates with various biochemical properties, such as nutrient acquisition, hormone production and growth under stress conditions were obtained. From this collection, five phylogenetically diverse bacterial strains were able to promote the growth of the model plant Arabidopsis thaliana under salinity stress conditions in a common mechanism of inducing transcriptional changes of tissue-specific ion transporters and lowering Na+/K+ ratios in the shoots. By combining a number of in vitro bioassays, plant phenotyping and volatile-mediated inhibition assays with next-generation sequencing technology, gas chromatography–mass spectrometry and bioinformatics tools, a candidate strain was presented as a multi-stress tolerance promoting bacterium with potential use in agriculture. Since recent research showed the importance of microbial partners for enhancing the growth and health of plants, a review of the different factors influencing plant-associated microbial communities is presented and a framework for the successful application of microbial inoculants in agriculture is proposed. The presented work demonstrates a holistic approach for tackling agricultural challenges using microbial inoculants from desert plants by combining culturomics, phenomics, genomics and transcriptomics. Microbial inoculants are promising tools for studying abiotic stress tolerance mechanisms in plants, and they provide an eco-friendly solution for increasing crop yield in arid and semi-arid regions, especially in light of a dramatically growing human population and detrimental effects of global warming and climate change.

Desert microbes

Plant-microbe interactions

Plant growth promoting bacteria

Abiotic stress tolerance

Salinity stress

Bacterial genome

Weedy rice (Oryza sativa ssp.): an untapped genetic resource for abiotic stress tolerant traits for rice improvement

Stallworth, Shandrea D.

06 August 2021

Rice (Oryza sativa) is the staple food for more than 3.5 billion people worldwide. As the population continues to grow, rice yield will need to increase by 1% every year for the next 30 years to keep up with the growth. In the US, Arkansas accounts for more than 50% of rice production. Over the last 68 years, rice production has continued to grow in Mississippi, placing it in fourth place after Arkansas, Louisiana, and California. Due to increasing rice acreage, regionally and worldwide, the need to develop abiotic stress-tolerant rice has increased. Unfortunately, current rice breeding programs lack genetic diversity, and many traits have been lost through the domestication of cultivated rice. Currently, stressors stemming from the continued effects of climate change continue to impact rice. To counteract the impacts of climate change, research has shifted to evaluating wild and weedy relatives of rice to improve breeding techniques. Weedy rice (Oryza sativa ssp.) is a genetically similar, noxious weed in rice with increased competitive ability. Studies have demonstrated that weedy rice has increased genetic variability and inherent tolerance to abiotic stressors. The aims of this study were to 1) screen a weedy rice mini-germplasm for tolerance to cold, heat, and complete submergence-stress, 2) utilize simple sequence repeat (SSR) markers and single nucleotide polymorphisms to evaluate the genetic diversity of the weedy rice population, and 3) use genome-wide association (GWAS) to identify SNPs associated with candidate genes within the population.

rice

oryza sativa

oryza sativa ssp.

abiotic stress tolerance

SSR

genetic diversity

genome-wide association study (GWAS)

Ecophysiological Responses of Tall Fescue Genotypes to Endophyte Infection and Climate Change

Bourguignon, Marie

01 January 2013

Tall fescue is a widely used forage grass in the eastern USA and can form a symbiosis with a fungal endophyte, which can be beneficial for the plant but can cause livestock health issues. Little is known regarding the symbiotic response to predicted climate change. To address this knowledge gap, I analyzed tall fescue variety trial data collected throughout the U.S., exploring relationships between climate variables and yield for two different fescue cultivars that were either endophyte-free or infected. This study showed no endophyte or cultivar effect on fescue yield, but identified temperature, precipitation and location as significant predictors of yield, suggesting that local conditions were more important than endophyte presence or fescue genotype for this dataset. Using a field experiment located in central Kentucky, I quantified the ecophysiological responses of four tall fescue genotypes to endophyte presence, elevated temperature and increased growing season precipitation. In this study, tall fescue genotype was as important as endophyte presence in determining ecophysiological responses to climate change treatments. My thesis illustrates that tall fescue response to climate change will depend on host genetics, the presence and genetics of the fungal endophyte symbiont, and the specific changes to the environment experienced at a site.

Abiotic stress tolerance

Climate change

Genotype

Tall fescue Schedonorus arundinaceus

Agricultural Education

Agricultural Science

Agronomy and Crop Sciences

Other Ecology and Evolutionary Biology

Plant Biology

La détection des variants alléliques comme voie d'amélioration génétique des plantes fourragères : exemple de la luzerne / Allelic variant detection for genetic improvement of forage plants : lucerne case study

Gréard, Camille

28 March 2019

L’amélioration génétique de la luzerne (Medicago sativa), une légumineuse fourragère autotétraploïde, pourrait bénéficier de l’allele mining. Cette méthode consiste à rechercher, dans la diversité naturelle, des allèles ayant potentiellement un effet sur le phénotype. Pour évaluer l’intérêt de cette stratégie qui exploite la diversité naturelle, cinq gènes impliqués dans des caractères sélectionnés ont été retenus : CAD1 et CCoaOMT (digestibilité), CONSTANS-like (rendement fourrager), NHX1 (tolérance à la salinité) et WXP1 (tolérance à la sécheresse). La diversité de ces gènes a été étudiée en séquençant 387 génotypes cultivés et 20 génotypes sauvages. L’analyse des données confirme la présence d’un goulot d’étranglement durant la domestication et la sélection de la luzerne. CONSTANS-like et WXP1 révèlent de nombreux variants alors que CAD1, CCoaOMT et NHX1 sont très peu variables. Des variants ayant un effet potentiel sur le phénotype ont été identifiés dans les zones de la séquence protéique qui sont conservées au sein des Faboideae. L’impact sur le phénotype de deux variants du gène CONSTANS-like a été étudié : Constans-634, à l’origine d’un codon stop prématuré et Constans-4111, situé dans une région conservée du gène. Pour cela des croisements ont été réalisés afin d’obtenir une descendance avec toutes les doses possibles (AAAA, AAAB, AABB, ABBB and BBBB) pour chaque mutation étudiée. Des marqueurs KASPar ont été développés afin de déterminer les doses de mutations chez les descendants. Aucun génotype homozygote muté pour Constans-634 n’a été détecté parmi les 1505 descendants. Ce variant a induit une floraison plus précoce de trois jours pour les génotypes portant trois doses d’allèle muté. Le variant Constans-4111 a induit un effet additif sur la hauteur de tige. Les génotypes homozygotes de type sauvage étaient en moyenne 11,8 cm plus petits que les génotypes homozygotes portant trois ou quatre doses du variant. L’intégration de la stratégie allele mining dans les schémas de sélection des espèces végétales autotétraploïdes hétérozygotes a été discutée. / Lucerne (Medicago sativa) is an autotetraploid forage legume, whose breeding could beneficiate from allele mining. This strategy is based on the natural diversity and consists in seeking alleles with a potential effect on the phenotype. The interest of this approach was evaluated by studying five genes of agronomic interest: CAD1 and CCoaOMT (digestibility), CONSTANS-like (forage yield), NHX1 (salt tolerance) and WXP1 (drought tolerance). The diversity of these five genes was evaluated by sequencing 387 genotypes of cultivated accessions and 20 genotypes of wild accessions. The results confirmed a bottleneck during lucerne domestication and selection. CONSTANS-like and WXP1 were very variable whereas CAD1, CCoaOMT and NHX1 contained very few variants. Variants with a potential strong impact on the phenotype were identified in conserved parts of protein sequence within the Faboideae. The impact on phenotype was studied for two mutations of the CONSTANS-like gene: constans-634, causing a premature stop codon and constans-4111, located in a conserved region of the gene. Genotypes carrying one to three doses of the mutations (AAAB, AABB and ABBB) were polycrossed in order to obtain offsprings with every allele combination (AAAA, AAAB, AABB, ABBB and BBBB). KASPar markers were developed to determine the mutation doses in offspring progeny. No homozygous genotype was found for constans-634 in the 1505 offspring progeny. This mutation induced a premature flowering of three days for the genotypes carrying three doses of the mutation. The mutation constans-4111 induced an additive effect on stem height and the homozygous genotypes without the variant where on average 11.8 cm shorter than homozygous genotypes carrying three or four doses of the variant. The application of allele mining strategy in plant schemes of heterozygous autotetraploid species was discussed.

Allele mining

Diversité

Gènes candidats

Lignine

Mutation

Qualité

Rendement

Tolérance aux stress abiotiques.

Abiotic stress tolerance

Allele mining

Candidate gene

Diversity

Lignin

Mutation

Quality

Yield.

633.31

583.74