RESUMO
Fungi colonizing plants are gaining attention because of their ability to promote plant growth and suppress pathogens. While most studies focus on endosymbionts from grasses and legumes, the large and diverse group of ericaceous plants has been much neglected. We recently described one of the very few fungal endophytes promoting the growth of the Ericaceae Vaccinium macrocarpon (American cranberry), notably the Codinaeella isolate EC4. Here, we show that EC4 also suppresses fungal pathogens, which makes it a promising endophyte for sustainable cranberry cultivation. By dual-culture assays on agar plates, we tested the potential growth suppression (or biocontrol) of EC4 on other microbes, notably 12 pathogenic fungi and one oomycete reported to infect not only cranberry but also blueberry, strawberry, tomato plants, rose bushes and olive trees. Under greenhouse conditions, EC4 protects cranberry plantlets infected with one of the most notorious cranberry-plant pathogens, Diaporthe vaccinii, known to cause upright dieback and berry rot. The nuclear genome sequence of EC4 revealed a large arsenal of genes potentially involved in biocontrol. About â¼60 distinct clusters of genes are homologs of secondary metabolite gene clusters, some of which were shown in other fungi to synthesize nonribosomal peptides and polyketides, but in most cases, the exact compounds these clusters may produce are unknown. The EC4 genome also encodes numerous homologs of hydrolytic enzymes known to degrade fungal cell walls. About half of the nearly 250 distinct glucanases and chitinases are likely involved in biocontrol because they are predicted to be secreted outside the cell. Transcriptome analysis shows that the expression of about a quarter of the predicted secondary-metabolite gene clusters and glucan and chitin-degrading genes of EC4 is stimulated when it is co-cultured with D. vaccinii. Some of the differentially expressed EC4 genes are alternatively spliced exclusively in the presence of the pathogen, altering the proteins' domain content and subcellular localization signal, thus adding a second level of proteome adaptation in response to habitat competition. To our knowledge, this is the first report of Diaporthe-induced alternative splicing of biocontrol genes.
RESUMO
Ericaceae thrive in poor soil, which we postulate is facilitated by microbes living inside those plants. Here, we investigate the growth stimulation of the American cranberry (Vaccinium macrocarpon) by one of its fungal endosymbionts, EC4. We show that the symbiont resides inside the epidermal root cells of the host but extends into the rhizosphere via its hyphae. Morphological classification of this fungus is ambiguous, but phylogenetic inference based on 28S rRNA identifies EC4 as a Codinaeella species (Chaetosphaeriaceae, Sordariomycetes, Ascomycetes). We sequenced the genome and transcriptome of EC4, providing the first 'Omics' information of a Chaetosphaeriaceae fungus. The 55.3-Mbp nuclear genome contains 17,582 potential protein-coding genes, of which nearly 500 have the capacity to promote plant growth. For comparing gene sets involved in biofertilization, we annotated the published genome assembly of the plant-growth-promoting Trichoderma hamatum. The number of proteins involved in phosphate transport and solubilization is similar in the two fungi. In contrast, EC4 has ~50% more genes associated with ammonium, nitrate/nitrite transport, and phytohormone synthesis. The expression of 36 presumed plant-growth-promoting EC4 genes is stimulated when the fungus is in contact with the plant. Thus, Omics and in-plantae tests make EC4 a promising candidate for cranberry biofertilization on nutrient-poor soils.
RESUMO
BACKGROUND: The glycolytic pathway plays an important role in tumor cells. Triosephosphate isomerase (TIM) catalyzes the reversible isomerization of D-glyceraldehyde-3-phosphate (GAP) to dihydroxyacetone phosphate (DHAP) in the glycolysis. Proteomics of a human prostate adenocarcinoma cell line revealed the presence of the G233D TIM variant, a new allelic type whose biochemical properties have not been reported [1]. OBJECTIVE: Provide the first biochemical and biophysical characterization of the allelic variant G233D of TIM. METHODS: The Michaelis-Menten curves using both substrates of TIM were obtained. Also the effect of the competitive inhibitor phosphoenolpyruvate (PEP) was assessed in presence of GAP and DHAP. The thermal stability in absence and presence of PEP was analyzed by circular dichroism spectroscopy. For comparison purposes, all the measurements were carried out on the wild type TIM and variant G233D. RESULTS: The G233D variant exhibited a kcat value 4-fold lower than that of the WT enzyme in the GAP isomerization to DHAP, which is the reverse reaction of the glycolytic pathway. The G233D variant exhibited Ki and IC50 values of 120 µM and 356 µM in the presence of several concentrations of GAP and 0.3 mM DHAP, respectively. These inhibition parameters are similar to those exhibited by the WT enzyme. The thermal unfolding cooperativity of G233D variant was significantly increased upon PEP binding, suggesting that the ligand-bound enzyme was trapped in a rigid conformation. CONCLUSION: We suggest that the flow of GAP through glycolysis could be enhanced by the decreased activity of the G233D variant in the formation of DHAP.
