Transgenic Plant and Fungal Expression to Assay in vitro and in planta Activity of Sus scrofa beta-Defensin 1 and Nicotiana tabacum Defensin 1

Atnaseo, Chuthamat

14 December 2011

To explore the use of defensins for transgenic plant disease resistance, expression by agroinfiltration of plants, stable transformation of plants and stable transformation of yeast were tested for porcine β-defensin 1 (pbd-1) and Nicotiana tabacum defensin 1 (Ntdef1). Attempts to screen constructs by agroinfiltration of Nicotiana benthamiana leaves revealed that agroinfiltration alone induced localized resistance against Colletotrichum destructivum. A comparison of Agrobacterium tumefaciens strains showed that the induced resistance required the transfer of type IV effectors into plant cells and was independent of salicylic acid or ethylene signaling. Stable expression of pbd-1 in N. tabacum and Pichia pastoris showed that PBD-1 purified from P. pastoris had varying degrees of antimicrobial activity against a broad range of microbes, including P. syringae pv. tabaci, C. destructivum and C. orbiculare, but in transgenic N. tabacum, the protein could not be detected and resistance increased only slightly to P. syringae pv. tabaci but not to C. destructivum or C. orbiculare. Stable expression of Ntdef1 in P. pastoris yielded a protein with no or little antimicrobial activity, and stable expression in N. tabacum did not result in detectable Ntdef1 or increased resistance to those pathogens. Although PBD-1 had strong antimicrobial activity against plant pathogens, plant disease resistance likely did not increase because of the low level of the protein in the plants, whereas resistance did not increase with Ntdef1 likely because of low antimicrobial activity and low levels of the protein in the plant. This research demonstrates that agroinfiltration is not appropriate for testing genes for antimicrobial activity in planta, while the P. pastoris expression system is useful for producing protein for in vitro tests of a gene prior to its transfer to plants.

Agroinfiltration

Antimicrobial peptide

Defensin

Plant-microbe interaction

Agrobacterium tumefaciens

Plant pathology

Molecular Quest for Avirulence Factors in Venturia inaequalis

Win, Joe

January 2004

The molecular basis for the gene-for-gene relationship of Vm-resistance in apple to Venturia inaequalis was investigated. Incompatible reactions involved a hypersensitive response (HR), which was accompanied by the accumulation of dark brown pigments and autofluorescent materials in epidermal and mesophyll cells at the site of invasion. Cell-free culture filtrates of the avirulent isolate elicited an HR in the Vm host (h5) leaves, but not in the susceptible host (h1). The elicitor activity was resistant to boiling but was abolished by proteinase K digestion. Elicitation of HR was used to monitor purification of the avirulence factor, AVRVm, from liquid cultures of the avirulent isolate following ultrafiltration, acetone precipitation and ion-exchange chromatography. The purest fraction contained three major proteins all with low isoelectric points (pI 3.0-4.5). The fraction also elicited HR on the differential host h4, but not on other resistant hosts (h2, h3 and h6) tested. Three candidate AVRVm proteins were identified and amino acid sequences were obtained using Edman degradation and mass spectrometry. Nucleotide sequences corresponding to these proteins were found in databases of V. inaequalis expressed sequence tags. There were no polymorphisms evident between avirulent and virulent isolates (representing races 1 and 5 respectively) either at genomic DNA or cDNA level of the full open reading frames. RT-PCR revealed that all genes were expressed in both avirulent and virulent isolates during in vitro and in planta growth. All three genes showed similar levels of expression between avirulent and virulent isolates during their in vitro growth. However, preliminary RT-PCR experiments showed that two of these genes were likely to be expressed at lower levels in the virulent compared with the avirulent isolate during compatible infection. Implications of this difference in expression and the future experiments to identify the genuine AvrVm gene were discussed.

Molecular Quest for Avirulence Factors in Venturia inaequalis

Win, Joe

January 2004

The molecular basis for the gene-for-gene relationship of Vm-resistance in apple to Venturia inaequalis was investigated. Incompatible reactions involved a hypersensitive response (HR), which was accompanied by the accumulation of dark brown pigments and autofluorescent materials in epidermal and mesophyll cells at the site of invasion. Cell-free culture filtrates of the avirulent isolate elicited an HR in the Vm host (h5) leaves, but not in the susceptible host (h1). The elicitor activity was resistant to boiling but was abolished by proteinase K digestion. Elicitation of HR was used to monitor purification of the avirulence factor, AVRVm, from liquid cultures of the avirulent isolate following ultrafiltration, acetone precipitation and ion-exchange chromatography. The purest fraction contained three major proteins all with low isoelectric points (pI 3.0-4.5). The fraction also elicited HR on the differential host h4, but not on other resistant hosts (h2, h3 and h6) tested. Three candidate AVRVm proteins were identified and amino acid sequences were obtained using Edman degradation and mass spectrometry. Nucleotide sequences corresponding to these proteins were found in databases of V. inaequalis expressed sequence tags. There were no polymorphisms evident between avirulent and virulent isolates (representing races 1 and 5 respectively) either at genomic DNA or cDNA level of the full open reading frames. RT-PCR revealed that all genes were expressed in both avirulent and virulent isolates during in vitro and in planta growth. All three genes showed similar levels of expression between avirulent and virulent isolates during their in vitro growth. However, preliminary RT-PCR experiments showed that two of these genes were likely to be expressed at lower levels in the virulent compared with the avirulent isolate during compatible infection. Implications of this difference in expression and the future experiments to identify the genuine AvrVm gene were discussed.

Molecular Quest for Avirulence Factors in Venturia inaequalis

Win, Joe

January 2004

The molecular basis for the gene-for-gene relationship of Vm-resistance in apple to Venturia inaequalis was investigated. Incompatible reactions involved a hypersensitive response (HR), which was accompanied by the accumulation of dark brown pigments and autofluorescent materials in epidermal and mesophyll cells at the site of invasion. Cell-free culture filtrates of the avirulent isolate elicited an HR in the Vm host (h5) leaves, but not in the susceptible host (h1). The elicitor activity was resistant to boiling but was abolished by proteinase K digestion. Elicitation of HR was used to monitor purification of the avirulence factor, AVRVm, from liquid cultures of the avirulent isolate following ultrafiltration, acetone precipitation and ion-exchange chromatography. The purest fraction contained three major proteins all with low isoelectric points (pI 3.0-4.5). The fraction also elicited HR on the differential host h4, but not on other resistant hosts (h2, h3 and h6) tested. Three candidate AVRVm proteins were identified and amino acid sequences were obtained using Edman degradation and mass spectrometry. Nucleotide sequences corresponding to these proteins were found in databases of V. inaequalis expressed sequence tags. There were no polymorphisms evident between avirulent and virulent isolates (representing races 1 and 5 respectively) either at genomic DNA or cDNA level of the full open reading frames. RT-PCR revealed that all genes were expressed in both avirulent and virulent isolates during in vitro and in planta growth. All three genes showed similar levels of expression between avirulent and virulent isolates during their in vitro growth. However, preliminary RT-PCR experiments showed that two of these genes were likely to be expressed at lower levels in the virulent compared with the avirulent isolate during compatible infection. Implications of this difference in expression and the future experiments to identify the genuine AvrVm gene were discussed.

Molecular Quest for Avirulence Factors in Venturia inaequalis

Win, Joe

January 2004

The molecular basis for the gene-for-gene relationship of Vm-resistance in apple to Venturia inaequalis was investigated. Incompatible reactions involved a hypersensitive response (HR), which was accompanied by the accumulation of dark brown pigments and autofluorescent materials in epidermal and mesophyll cells at the site of invasion. Cell-free culture filtrates of the avirulent isolate elicited an HR in the Vm host (h5) leaves, but not in the susceptible host (h1). The elicitor activity was resistant to boiling but was abolished by proteinase K digestion. Elicitation of HR was used to monitor purification of the avirulence factor, AVRVm, from liquid cultures of the avirulent isolate following ultrafiltration, acetone precipitation and ion-exchange chromatography. The purest fraction contained three major proteins all with low isoelectric points (pI 3.0-4.5). The fraction also elicited HR on the differential host h4, but not on other resistant hosts (h2, h3 and h6) tested. Three candidate AVRVm proteins were identified and amino acid sequences were obtained using Edman degradation and mass spectrometry. Nucleotide sequences corresponding to these proteins were found in databases of V. inaequalis expressed sequence tags. There were no polymorphisms evident between avirulent and virulent isolates (representing races 1 and 5 respectively) either at genomic DNA or cDNA level of the full open reading frames. RT-PCR revealed that all genes were expressed in both avirulent and virulent isolates during in vitro and in planta growth. All three genes showed similar levels of expression between avirulent and virulent isolates during their in vitro growth. However, preliminary RT-PCR experiments showed that two of these genes were likely to be expressed at lower levels in the virulent compared with the avirulent isolate during compatible infection. Implications of this difference in expression and the future experiments to identify the genuine AvrVm gene were discussed.

Molecular Quest for Avirulence Factors in Venturia inaequalis

Win, Joe

January 2004

The molecular basis for the gene-for-gene relationship of Vm-resistance in apple to Venturia inaequalis was investigated. Incompatible reactions involved a hypersensitive response (HR), which was accompanied by the accumulation of dark brown pigments and autofluorescent materials in epidermal and mesophyll cells at the site of invasion. Cell-free culture filtrates of the avirulent isolate elicited an HR in the Vm host (h5) leaves, but not in the susceptible host (h1). The elicitor activity was resistant to boiling but was abolished by proteinase K digestion. Elicitation of HR was used to monitor purification of the avirulence factor, AVRVm, from liquid cultures of the avirulent isolate following ultrafiltration, acetone precipitation and ion-exchange chromatography. The purest fraction contained three major proteins all with low isoelectric points (pI 3.0-4.5). The fraction also elicited HR on the differential host h4, but not on other resistant hosts (h2, h3 and h6) tested. Three candidate AVRVm proteins were identified and amino acid sequences were obtained using Edman degradation and mass spectrometry. Nucleotide sequences corresponding to these proteins were found in databases of V. inaequalis expressed sequence tags. There were no polymorphisms evident between avirulent and virulent isolates (representing races 1 and 5 respectively) either at genomic DNA or cDNA level of the full open reading frames. RT-PCR revealed that all genes were expressed in both avirulent and virulent isolates during in vitro and in planta growth. All three genes showed similar levels of expression between avirulent and virulent isolates during their in vitro growth. However, preliminary RT-PCR experiments showed that two of these genes were likely to be expressed at lower levels in the virulent compared with the avirulent isolate during compatible infection. Implications of this difference in expression and the future experiments to identify the genuine AvrVm gene were discussed.

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

The Environmental Microbiome In A Changing World: Microbial Processes And Biogeochemistry

Juice, Stephanie

01 January 2020

Climate change can alter ecosystem processes and organismal phenology through both long-term, gradual changes and alteration of disturbance regimes. Because microbes mediate decomposition, and therefore the initial stages of nutrient cycling, soil biogeochemical responses to climate change will be driven by microbial responses to changes in temperature, precipitation, and pulsed climatic events. Improving projections of soil ecological and biogeochemical responses to climate change effects therefore requires greater knowledge of microbial contributions to decomposition. This dissertation examines soil microbial and biogeochemical responses to the long-term and punctuated effects of climate change, as well as improvement to decomposition models following addition of microbial parameters. First, through a climate change mesocosm experiment on two soils, I determined that biogeochemical losses due to warming and snow reduction vary across soil types. Additionally, the length of time with soil microbial activity during plant dormancy increased under warming, and in some cases decreased following snow reduction. Asynchrony length was positively related to carbon and nitrogen loss. Next, I examined soil enzyme activity, carbon and nitrogen biodegradability, and fungal abundance in response to ice storms, an extreme event projected to occur more frequently under climate change in the northeastern United States. Enzyme activity response to ice storm treatments varied by both target nutrient and, for nitrogen, soil horizon. Soil horizons often experienced opposite response of enzyme activity to ice storm treatments, and increasing ice storm frequency also altered the direction of the microbial response. Mid-levels of ice storm treatment additionally increased fungal hyphal abundance. Finally, I added explicit microbial parameters to a global decomposition model that previously incorporated climate and litter quality. The best mass loss model simply added microbial flows between litter quality pools, and addition of a microbial biomass and products pool also improved model performance compared to the traditional implicit microbial model. Collectively, these results illustrate the importance of soil characteristics to the biogeochemical and microbial response to both gradual climate change effects and extreme events. Furthermore, they show that large-scale decomposition models can be improved by adding microbial parameters. This information is relevant to the effects of climate change and microbial activity on biogeochemical cycles.

Carbon

Decomposition

Ice storms

Nitrogen

Plant microbe interactions

Temporal asynchrony

Ecology and Evolutionary Biology

Soil Science

Studies on symbiosis-spesific phenotype of Mesorhizobium loti and its function to host plant / ミヤコグサ根粒菌の共生特異的な表現型と宿主への影響に関する研究

Tatsukami, Yohei

23 March 2017

京都大学 / 0048 / 新制・課程博士 / 博士(農学) / 甲第20438号 / 農博第2223号 / 新制||農||1049(附属図書館) / 学位論文||H29||N5059(農学部図書室) / 京都大学大学院農学研究科応用生命科学専攻 / (主査)教授 植田 充美, 教授 矢﨑 一史, 教授 森 直樹 / 学位規則第4条第1項該当 / Doctor of Agricultural Science / Kyoto University / DFAM

Mesorhizobium loti

Lotus japonicus

Gibberellin

Plant-Microbe Interaction

Proteome analysis

610

Molecular and Functional Characterization of Medicago Truncatula Npf17 Gene

Salehin, Mohammad

12 1900

Legumes are unique among plants for their ability to fix atmospheric nitrogen with the help of soil bacteria rhizobia. Medicago truncatula is used as a model legume to study different aspects of symbiotic nitrogen fixation. M. truncatula, in association with its symbiotic partner Sinorhizobium meliloti, fix atmospheric nitrogen into ammonia, which the plant uses for amino acid biosynthesis and the bacteria get reduced photosynthate in return. M. truncatula NPF1.7 previously called MtNIP/LATD is required for symbiotic nitrogen fixing root nodule development and for normal root architecture. Mutations in MtNPF1.7 have defects in these processes. MtNPF1.7 encodes a member of the NPF family of transporters. Experimental results showing that MtNPF1.7 functioning as a high-affinity nitrate transporter are its expression restoring chlorate susceptibility to the Arabidopsis chl1-5 mutant and high nitrate transport in Xenopus laevis oocyte system. However, the weakest Mtnip-3 mutant allele also displays high-affinity nitrate transport in X. laevis oocytes and chlorate susceptibility to the Atchl1-5 mutant, suggesting that MtNPF1.7 might have another biochemical function. Experimental evidence shows that MtNPF1.7 also functions in hormone signaling. Constitutive expression of MtNPF1.7 in several species including M. truncatula results in plants with a robust growth phenotype. Using a synthetic auxin reporter, the presence of higher auxin in both the Mtnip-1 mutant and in M. truncatula plants constitutively expressing MtNPF1.7 was observed. Previous experiments showed MtNPF1.7 expression is hormone regulated and the MtNPF1.7 promoter is active in root and nodule meristems and in the vasculature. Two potential binding sites for an auxin response factors (ARFs) were found in the MtNPF1.7 promoter. Chromatin immunoprecipitation-qRT-PCR confirmed MtARF1 binding these sites. Mutating the MtARF1 binding sites increases MtNPF1.7 expression, suggesting a mechanism for auxin repression of MtNPF1.7. Consistent with these results, constitutive expression of an ARF in wild-type plants partially phenocopies Mtnip-1 mutants’ phenotypes.

Symbiotic nitrogen fixation

legumes

nitrate transporter

NPF1.7 OE

plant microbe interaction