Project description:Project Description: The interaction between microorganisms and plants plays a key role in plant development and environmental adaptation. Among these microorganisms, plant growth-promoting bacteria (PGPB) enhance agricultural productivity sustainably. Beyond direct effects on plant physiology, epigenetic modifications such as DNA methylation regulate gene expression and adaptive responses. This study investigates how DNA hypomethylation influences early interactions between maize (Zea mays) and the PGPB Herbaspirillum seropedicae, focusing on plant growth, metabolism, and root microbiome. Treatment with the hypomethylating agent 5-azacytidine (5-azaC) did not affect bacterial growth but induced notable phenotypic changes in maize, particularly in root morphology. Inoculation with H. seropedicae enhanced plant growth across biometric parameters. Microscopy revealed bacterial colonization primarily in root mucilage, with higher bacterial accumulation in 5-azaC-treated roots. Global methylation analysis indicated that H. seropedicae modulates cytosine methylation similarly to 5-azaC, suggesting a role in epigenetic regulation. Gene expression analysis of DNA methylation machinery supports hypomethylation as a driver of plant-microbe interactions. Root microbiome profiling showed that 5-azaC significantly altered microbial composition, whereas bacterial inoculation partially restored it toward control profiles. Proteomic analysis identified 1,818 proteins, highlighting significant shifts in metabolic pathways, especially carbon metabolism and the citric acid cycle. These findings demonstrate that DNA hypomethylation, combined with bacterial interaction, profoundly impacts cellular and metabolic processes, offering new insights into early plant-microbe interactions. This knowledge may contribute to developing sustainable agricultural practices through epigenetic and microbial modulation.

Project description:Soybean is one of the most important sources of food, protein, and oil in the world. Reductions in grain number and quality are caused by different biotic stresses. One of the most common is the phytophagous mite Tetranychus urticae Koch (Acari: Tetranychidae), which inhibits plant growth and grain production. The identification of plant responses to early and late T. urticae infestation is important for a better understanding of the mite-plant interaction. We therefore aimed to evaluate the physiological and molecular responses of soybean plants to mite infestation for 5 and 21 days. Visual and microscopic symptoms of leaf damage, H2O2 accumulation, and lipid peroxidation increased consistently throughout the infestation period, while shoot length/dry weight, chlorophyll level, and number of days to reach specific developmental stages were negatively affected by T. urticae infestation. Using proteomic analysis, we identified 185 and 266 differentially abundant proteins after early (5 days) and late (21 days) mite infestation, respectively, which suggests a complex remodeling of diverse metabolic pathways. GO, KEGG, and protein-protein interaction analyses indicated that photorespiration, chlorophyll synthesis, amino acid metabolism, Krebs cycle/energy production, mitochondrial translation, nucleotide salvage, PS II assembly, and reductive pentose-P cycle are all impacted after both early and late infestation. Specific metabolic pathways modified only after early infestation include cell wall modification, cytoskeleton composition, cell division, and lysine/histidine metabolism, while JA biosynthesis, antioxidant system, S-adenosyl methionine cycle, PS II repair, cysteine/methionine/glutathione/ascorbate/-linolenic acid/selenocompound metabolism, arginine biosynthesis, and proteasome are modified only after late infestation. These differentially abundant proteins can be used as biotechnological tools in future breeding programs aiming at increased resistance to mite infestation.

Project description:Several factors influence the culture conditions and somatic embryogenesis responses, such as the role of plant growth regulators (PGRs) during the establishment of in vitro cultures. For instance, auxin is required for callus induction and the acquisition of embryogenic capacity in different species, but the removal of auxin is needed for the further differentiation of somatic embryos. Thus, we aimed to evaluate the effects of residual 2,4-dichlorophenoxyacetic acid (2,4-D) on the maturation of sugarcane somatic embryos. First, embryogenic calli were separated into two groups: the PGR-free group was cultured without 2,4-D and b) the control group was maintained on proliferation culture medium, which contains 2,4-D. After 21 days of culture in the dark, both groups were transferred to maturation culture medium under light. Our results showed that calli grown in PGR-free culture medium yielded more somatic embryos and exhibited a higher accumulation of protein and starch reserves. A proteomic analysis showed a decrease in the abundance of abscisic acid (ABA)-induced proteins in the control group. The levels of residual 2,4-D and endogenous 1-aminocyclopropane-1-carboxylic acid (ACC), an ethylene precursor, were higher in the control group than in the PGR-free group. Conversely, the level of ABA was higher in the PGR-free group than in the control group. A disruption in the ABA and ethylene levels might be responsible for the observed delay in the accumulation of storage reserves in the embryogenic calli of the control group, which might have affected the development of somatic embryos. Our results also showed that the efficient development of sugarcane somatic embryos appears to be preceded by an efficient accumulation of storage reserves in calli, which is related to hormone homeostasis.

Project description:Somatic embryogenesis is an important biological process in several plant species, including sugarcane. Proteomics approaches have shown that H+ pumps are differentially regulated during somatic embryogenesis; however, the relationship between H+ flux and embryogenic competence is still unclear. This work aimed to elucidate the association between extracellular H+ flux and somatic embryo maturation in sugarcane. We performed a microsomal proteomics analysis and analyzed changes in extracellular H+ flux and H+ pump (P-H+-ATPase, V-H+-ATPase and H+-PPase) activity in embryogenic and non-embryogenic callus. A total of 657 proteins were identified, 16 of which were H+ pumps. We observed that P-H+-ATPase and H+-PPase were more abundant in embryogenic callus. Compared with non-embryogenic callus, embryogenic callus showed high H+ influx, especially at maturation day 14 as well as higher H+ pump activity, mainly P-H+-ATPase and H+-PPase activity. The H+-PPase appears to be the major H+ pump in embryogenic callus during somatic embryo formation, functioning in both vacuole acidification and PPi homeostasis. These results provide evidence for an association between higher H+ pump protein abundance and, consequently, higher H+ flux and embryogenic competence acquisition in the callus of sugarcane.

Project description:Under soil water limitation and with adequate irrigation, we estimated growth measurements of the shoot and root system, as well as photosynthetic and proteomic profiles of two inbred lines of popcorn previously selected for tolerance to soil water limitation - L71, drought-tolerant; and L61, drought-sensitive - in an attempt to identify mechanisms related to tolerance to soil water limitation during the maturation phase. The plants were grown until grain filling in a substrate composed of perlite and peat in a 150 cm long PVC tube, under two water conditions (WC): i) irrigated (WW), at lysimeter capacity (LC - 100%); and ii) water-stressed (WS). The plants in the WS condition gradually reached 45% of the LC and were maintained like this for 10 days. Regardless of WC, L71 had the highest values of dry biomass of the shoot and root system, characterizing it as the most robust genotype. The imposed water limitation induced earlier senescence, degrading chlorophylls, and increasing anthocyanin values, with a more expressive impact in L61. The traits related to gas exchange expressed differences between lines only in the WS condition. In comparing WCs and most of the traits evaluated, the L71 genotype had the smallest proportional reductions. A total of 1,838 proteins were identified, with 169 differentially accumulated proteins (DAPs) in the tolerant line and 386 DAPs in the sensitive line. The pathways of energy metabolism, photosynthesis, oxidative stress response, and protein synthesis represented the main differences between L71 and L61. Therefore, our results provide important insights into the changes in proteomic profiles that occur in adaptation to water limitation in popcorn, providing useful information for breeding towards the expression of genotypic superiority to water deficit.

Project description:Aluminum toxicity is one of the most important abiotic stresses that affects crop production worldwide. The soluble form (Al3+) inhibits root growth, altering water and nutrients uptake reducing the plant growth and development. Under a long term of Al3+ exposure, plants can activate several tolerance mechanisms and, to date, there are no reports of large-scale proteomic data of maize in response to this ion. To investigate the post-transcriptional regulation in response to Al toxicity, we performed a label-free quantitative proteomics for comparative analysis of two Al-contrasting popcorn inbred lines and an Al-tolerant commercial hybrid during 72 h under Al-stress. A total of 489 differentially accumulated proteins (DAPs) were identified in the Al-sensitive inbred line, 491 in the Al-tolerant inbred line, and 277 in the commercial hybrid. Among then, 120 DAPs were co-expressed in both Al tolerant genotypes. Bioinformatics analysis indicated that starch and sucrose metabolism, glycolysis/gluconeogenesis, and carbohydrate metabolism were significant biochemical process regulated in response to Al toxicity. The up-accumulation of sucrose synthase and the increased of sucrose content and starch degradation suggest that these components may be enhance popcorn tolerance to Al stress. The up-accumulation of citrate synthase suggests a key role of this enzyme in the detoxification process in the Al-tolerant inbred line. The integration of transcriptomic and proteomic data indicated that Al tolerance response presents a complex regulatory network into the transcription and translation dynamics of popcorn roots development.

Project description:Somatic embryogenesis is an important biotechnological technique for large-scale propagation of elite genotypes. Correlations of stage-specific compounds associated with somatic embryo development can help elucidate the ontogenesis of Carica papaya L. somatic embryos and improve tissue culture protocols. To identify the stage-specific proteins that are present during the differentiation of C. papaya somatic embryos, proteomic analyses of embryos at the globular, heart, torpedo and cotyledonary stages were performed. Comparative proteomic analysis revealed a total of 801 proteins, 392 of which were classified as differentially accumulated proteins in at least one of the developmental stages. The globular stage presented a higher number of unique proteins (16), 7 of which were isoforms of 60S ribosomal proteins, suggesting high translational activity at the beginning of somatic embryogenesis. Proteins related to mitochondrial metabolism accumulated to a high degree at the early developmental stages, after which they decreased with increasing development, contributing to cell homeostasis in early somatic embryos. On the other hand, a progressive increase in the accumulation of vicilin, late embryogenesis abundant proteins and chloroplastic proteins leading to somatic embryo maturation was observed. Additionally, the differential accumulation of acetylornithine deacetylase and S-adenosylmethionine synthase 2 proteins correlated with increased contents of putrescine and spermidine, suggesting that polyamine metabolism is important to somatic embryo development. Taken together, the results showed that somatic embryo development in C. papaya is regulated by the differential accumulation of proteins, with ribosomal and mitochondrial proteins being more abundant during the early somatic embryo stages, while proteins involved in seed maturation are more abundant during the late stages.

Project description:Sour passion fruit (Passiflora edulis Sims) has economic and social relevance and is an alternative crop mainly for family farming agriculture. The use of micropropagation by somatic embryogenesis offers scale-up clonal propagation with high phytosanitary quality. The aim of this work was to evaluate the influence of polyethylene glycol (PEG) on the maturation of somatic embryos associated with differential accumulation of proteins and changes in the endogenous polyamines (PAs) content during somatic embryogenesis of P. edulis ‘UENF Rio Dourado’. Maturation of somatic embryos was performed using embryogenic callus in MS culture medium with PEG 6% or without PEG (control). PEG 6% promoted the maturation of a significantly higher number of somatic embryos at globular and cotyledonary stages when compared to control treatment. The higher somatic embryo formation induced by PEG 6% was associated with an increase in endogenous contents of free spermine, a PA with an important role in the maturation process of somatic embryogenesis cultures. PEG also promoted a significantly higher content of putrescine and total free PAs at the end of maturation, which was relevant for the increase in the number of somatic embryos. Comparative proteomic analyses of PEG 6%/control revealed that PEG 6% treatment induced the up-accumulation of proteins related to the glycolytic process, generation of precursor metabolites energy, and response to light stimulus, we can highlight the enolase ENO1, triosephosphate isomerase (TPI), ribulose bisphophate carboxylase/oxygenase activase chloroplastic (RCA), glyceraldehyde-3-phosphate dehydrogenase GAPCP-1, chloroplastic (GAPCP-1), succinate dehydrogenase [ubiquinone] flavoprotein subunit1, mitochondrial (SDH1-1), pyruvate dehydrogenase E1 component subunit alpha, mitochondrial (IAR4), ATP synthase CF1 beta subunit (PB), malate dehydrogenase [NADP], chloroplastic (AT5G58330) and chlorophyll a-b binding protein 21, chloroplastic (LHB1B1), and the down-accumulated proteins related mainly to the cellular metabolic process with proteins such as NADP-dependent malic enzyme (NADP-ME4), phosphoenolpyruvate carboxylase 2 (PPC1), UDP-glucose 6-dehydrogenase 1 and 4 (UGD2) and sucrose synthase 2 isoform X2 (SSA) and cell division cycle protein 48 homolog (ATCDC48B). The use of PEG induced thematuration and development of somatic embryos of P. edulis Sims ‘UENF Rio Dourado’ by the differential accumulation of proteins and modulation of endogenous contents of PAs

Project description:To better understand plant-pathogen interactions and the activation of defense mechanisms, this study proposes to identify the differentially abundant proteins in an interspecific hybrid of passion fruit and its parents, Passiflora edulis and P. setacea, inoculated with CABMV compared to their non-inoculated counterparts. Leaves from the three populations were inoculated and collected 72 h after inoculation. The experiment was set up as a completely randomized design with three replicates. Of the over 500 identified proteins, 100, 290, and 96 were differentially abundant for the hybrid, P. edulis, and P. setacea, respectively, in response to CABMV. In the interspecific hybrid, 41% of the proteins were down-regulated and 59% were up-regulated, compared to control. In the P. setacea parent, 39% of the protein being down-regulated. The P. edulis parent, in turn, showed a distinct profile, in which 82% of the protein were down-regulated and only 18% were up-regulated compared to control. It is suggested that CABMV suppresses accumulation of proteins in susceptible species that may have a key function in plant defense response, such as those linked to proteasome regulation and heat shock proteins. At the same time, it should regulate the accumulation of proteins that may impair viral signaling within the host such as glutathione peroxidase. Despite responding to the infection, P. edulis was not capable of stopping the disease establishment. Results suggest that the disease manifests due to a failure in the signaling system of susceptible species, whose activated response pathways are not sufficient to control it.

Project description:Antimicrobial peptides (AMPs) are a group of molecules that occur naturally in all living organisms and help them to defend against various pathogens, including fungi, bacteria and viruses (Gan et al., 2021). AMPs have a low molecular mass (~2-50 amino acids), are rich in hydrophobic amino acids and have a net positive charge (Huan et al., 2020). Some stable antimicrobial peptides can bind to chitin, an insoluble homopolymer present in several types of biological materials, such as the cell wall of fungi, insects and crustacean shells; however, chitin is not present in plants. Some peptides, including chitinases, vicilins, lectins, 2S albumins and hevein-like peptides, can bind to a matrix composed of chitin. These peptides exhibit antimicrobial activity against bacteria and fungal pathogens, and they interact with fungal chitin through the chitin binding site, which plays a significant role in inhibiting fungal growth (Slezina and Odintsova, 2023). The binding site shares structural similarity with hevein, an antimicrobial peptide from the latex of Hevea brasiliensis (Willd. exA. Juss.) Müll. Arg. The main element of all hevein-like peptides is that a conservative chitin-binding site is one of their essential structural modules (Slavokhotova et al., 2017; Azmil et al., 2021). Hevein-like peptides are AMPs that are rich in cysteine, contain 29-45 amino acids and 5-7 residues contain glycine. A main feature of hevein-like peptides is a conservative chitin binding site with the amino acid sequence SXFGY/SXYGY, in which X is any amino acid residue (Beintema, 1994). In addition, these peptides are present in the plant cysteine-rich antimicrobial peptide superfamily, are 2-6 kDa in weight, contain 6-10 Cys residues and contain three to five disulfide bridges (Tam et al., 2015). They also possess structural motifs composed of three antiparallel beta sheets and a short α-helix, which are stabilized by 3-5 disulfide bonds (Odintsova et al., 2020). Previously, hevein-like peptides have been reported to exhibit activity against several fungal microorganisms with or without chitin in their cell wall (Slezina and Odintsova, 2023). The mechanism underlying the activity of hevein-like peptides is mainly through depolarization of hyphae membrane (Azmil et al., 2021). Recently, several hevein-like peptides have been isolated from several plant species, such as wheat (Odintsova et al., 2020), quinoa (Loo et al., 2021) and moringa (Sousa et al., 2020). These peptides exhibited activity against a range of microorganisms, such as F. oxysporum, F. culmorum, Bipolaris sorokininana, Alternaria alternata and Cladosporium cucumerinum (Odintsova et al., 2020). These findings have encouraged further studies on the application of these molecules against pathogenic fungi, as the molecules exhibit great activity and could be used to create new antifungal medications. Peppers and chilies originate from the tropical Americas and belong to 22 families of Solanaceae and the genus Capsicum; 35 of these species have been domesticated, while the others remain semidomesticated and wild. The plants are dispersed worldwide, and in Brazil, they are cultivated mainly in the states of Rio de Janeiro, Minas Gerais, Bahia and Goiás; among the various locations, Rio de Janeiro is a special center of diversity (Moscone et al., 2006). These plants are essential solanaceous vegetables with high world economic value. However, the growth, quality and yield of these plants are reduced by biotic (fungal, bactéria and virus infections and pests) and abiotic (drought, salinity and extreme temperatures) factors (Mittler, 2006; Wang et al., 2003). Several AMPs have been isolated from different organs of plants within the Capsicum genus (Oliveira et al., 2022). For example, a hevein-like peptide was identified from C. annuum leaves; this peptide is approximately 4.2 kDa and was named HEVCAN. In addition, the peptide belongs to the chitin-binding domain family and exhibits antimicrobial activity (Oliveira et al., 2022). Our research group has previously isolated and identified several other antimicrobial peptides, such as defensin (Gebara et al., 2020), LTP (Diz et al., 2011), protease inhibitors (Ribeiro et al., 2013) and chitin-binding peptides (Gonçalves et al., 2024), from Capsicum seeds. In this study, we used a chitin affinity column to purify peptide fractions from C. chinense seeds, and these fractions exhibited chitin-binding capacity and activity against yeasts.