Proteomic response of the phytopathogen Phyllosticta citricarpa to antimicrobial volatile organic compounds from Saccharomyces cerevisiae.

Volatile organic compounds (VOCs) released by Saccharomyces cerevisiae inhibit plant pathogens, including the filamentous fungus Phyllosticta citricarpa, causal agent of citrus black spot. VOCs mediate relevant interactions between organisms in nature, and antimicrobial VOCs are promising, environmentally safer fumigants to control phytopathogens. As the mechanisms by which VOCs inhibit microorganisms are not well characterized, we evaluated the proteomic response in P. citricarpa after exposure for 12h to a reconstituted mixture of VOCs (alcohols and esters) originally identified in S. cerevisiae. Total protein was extracted and separated by 2D-PAGE, and differentially expressed proteins were identified by LC-MS/MS. About 600 proteins were detected, of which 29 were downregulated and 11 were upregulated. These proteins are involved in metabolism, genetic information processing, cellular processes, and transport. Enzymes related to energy-generating pathways, particularly glycolysis and the tricarboxylic acid cycle, were the most strongly affected. Thus, the data indicate that antimicrobial VOCs interfere with essential metabolic pathways in P. citricarpa to prevent fungal growth.

Regulation of Leishmania (L.) amazonensis protein expression by host T cell dependent responses: differential expression of oligopeptidase B, tryparedoxin peroxidase and HSP70 isoforms in amastigotes isolated from BALB/c and BALB/c nude mice.

Leishmaniasis is an important disease that affects 12 million people in 88 countries, with 2 million new cases every year. Leishmania amazonensis is an important agent in Brazil, leading to clinical forms varying from localized (LCL) to diffuse cutaneous leishmaniasis (DCL). One interesting issue rarely analyzed is how host immune response affects Leishmania phenotype and virulence. Aiming to study the effect of host immune system on Leishmania proteins we compared proteomes of amastigotes isolated from BALB/c and BALB/c nude mice. The athymic nude mice may resemble patients with diffuse cutaneous leishmaniasis, considered T-cell hyposensitive or anergic to Leishmania's antigens. This work is the first to compare modifications in amastigotes' proteomes driven by host immune response. Among the 44 differentially expressed spots, there were proteins related to oxidative/nitrosative stress and proteases. Some correspond to known Leishmania virulence factors such as OPB and tryparedoxin peroxidase. Specific isoforms of these two proteins were increased in parasites from nude mice, suggesting that T cells probably restrain their posttranslational modifications in BALB/c mice. On the other hand, an isoform of HSP70 was increased in amastigotes from BALB/c mice. We believe our study may allow identification of potential virulence factors and ways of regulating their expression.

Caracterização da proteína quinase C Beta I nuclear em células tronco embrionárias / Characterization of protein kinase C beta I in embryonic stem cell nucleus

As proteína quinases C (PKC) pertencem à família das serina/treonina quinases, que vem sendo apontadas como importantes enzimas para os processos de proliferação e diferenciação das células tronco embrionárias (CTE), todavia, a função exata de cada isoforma dessa família ainda não está clara. Dados anteriores do nosso laboratório indicam que dentre as PKCs expressas em CTE, formas cataliticamente ativas da PKCßI são altamente expressas no núcleo das CTE murinas. Estas ao se diferenciarem expressam essa quinase no seu citoplasma ou deixam de expressar a mesma, e que a maioria dos alvos da PKCßI em CTE indiferenciada estão envolvidos em processos de regulação da transcrição de proteínas envolvidas em processos de proliferação/ diferenciação. Dando continuidade aos resultados anteriores do laboratório, no presente trabalho, com técnicas de proteômica e fosfoproteômica identificamos outros alvos nucleares da PKCßI em CTE indiferenciadas. Vimos que de fato inibindo-se a PKCßI diminuiu-se a fostorilação de fatores envolvidos com a indiferenciação das CTE. Dentre os alvos da PKCßI encontramos a proteína adaptadora, TIF1 que recruta proteínas remodeladoras de cromatina. Essa proteína é essencial para a manutenção do estado indiferenciado das CTE. In vitro a PKCßI foi capaz de fosforilar a TIF1ß e inibindo-se a PKCßI por RNAi vimos uma diminuição na expressão da TIF1ß e no fator de indiferenciação Nanog cuja expressão já foi demonstrada ser regulada pela TIF1ß. Além disso vimos que inibindo-se a PKCßI com o peptídeo inibidor da PKCßI aumentou a expressão de proteínas reguladas pelo c-Myc. E que o RNAi para a PKCßI aumentou a expressão de proteínas que regulam a expressão do c-Myc. Não vimos nenhum efeito na fosforilação ou expressão do c-Myc após a inibição da PKCßI o que sugere que a PKCßI ative proteínas repressoras do c-Myc. Nossos estudos sugerem que a PKCßI regula a manutenção do estado indiferenciado das CTE regulando a expressão e atividade da Tif1ß um possível alvo direto da PKCßI. Levando a modificações da cromatina e regulação da expressão de genes que mantém as CTE indiferenciadas. Outro ponto de regulação da PKCßI parece ser a nibição da atividade de c-Myc o que seria importante para a manutenção do estado indiferenciado visto que o c-Myc é um amplificador das vias de sinalização que mantém as células proliferando. Desta forma a PKCßI parece ter um papel central na regulação da expressão gênica de CTE à nível de modificações epigenéticas e a nível transcricional mantendo as CTE indiferenciadas

The Protein kinase C (PKC) family of serine/treonine kinases, are being described as important enzymes for proliferation and diferentiation of embryonic stem cells (ESC), however, the exact function of the different isoenzymes of this family still is unclear. Previous data from our laboratory indicates that amongst the PKCs expressed in ESC, catalytically active forms of PKCßI are highly expressed in nucleus of murine ESC. When these cells differentiate this kinase can be found in the cytoplasm or not expressed at all, and that the majority of PKCßI targets in undifferentiated ESC are involved in the regulation of proteins involved in transcription of proteins involved in proliferation/ diferentiation. Continuing our previous work herewith using proteomics and phosphoproteomics techniques we identified other nuclear PKCßI targets in undifferentiated ESC. We indeed saw that inhibiting PKCßI decreased the phosphorylation of factors involved with maintainance of the undifferentiated state of ESC. Amongst the targets of PKCßI we found the adaptor protein, TIF1ßI, that recruits cromatin remodeling proteins. This protein is essential for the maintenance of the undifferentiated state of ESC. In vitro PKCßI phosphorylated TIF1ß and inhibiting PKCßI with RNAi decreased the expression of TIF1ß and of the undifferentiation factor Nanog whose expression has been shown to be regulated by TIF1ß. We also saw that inhibiting PKCßI with a peptide inhibitor increased the expression of proteins regulated by c-Myc, and that RNAi for PKCßI increased the expression of proteins that regulate the expression of c-Myc. We did not see any effect on the phosphorylation or expression of c-Myc after inhibition of PKCßI suggesting that PKCßI activates c-Myc repressor proteins. Our studies sugest that PKCßI regulates the maintenance of the undiferentiated state of ESC regulating the expression and activity of Tif1ß a possibly a direct target of PKCßI, leading to chromatin modifications and regulation of genes that maintain ESC undiferentiated. Another form of regulation of PKCßI seems to be by inhibiting the activity of c-Myc which is importante to maintain ESC undifferentiated since c-Myc is na an amplifyer of signaling patheways that maintain ESC proliferating. Together PKCßI has a central role in the regulation of the gene expression of ESC at the level of epigenetic modifications and transcriptional regulation

Activation of protein kinase C delta by ψδRACK peptide promotes embryonic stem cell proliferation through ERK 1/2.

The protein kinase C (PKC) family of serine/threonine kinases participate in embryonic stem cell (ESC) proliferation/self-renewal. A few stimuli that induce ESC proliferation activate several PKC isoenzymes including δPKC, however, the role of this isoenzyme under basal conditions that maintain undifferentiated ESCs remains to be determined. Herewith, we aimed to characterize signaling events that occur in undifferentiated ESCs upon δPKC activation. Using phosphoproteomics and a δPKC specific activator peptide, ψδRACK, it was seen that the majority of proteins whose phosphorylation increased upon δPKC activation participate in cell proliferation. Network analysis of these proteins directly connected δPKC to Raf1 and 14-3-3. Experimental validation studies showed that activation of δPKC increased its binding to 14-3-3, transiently activated ERK1/2 and increased ESC proliferation. Independently inhibiting MEK or PI3 kinase both led to a decrease in proliferation of approximately 50%, but δPKC activation only recovered the effect of PI3 kinase inhibition suggesting that ERK1/2 activation via δPKC is probably a parallel pathway to PI3 kinase and that both pathways are necessary for undifferentiated ESC proliferation. BIOLOGICAL SIGNIFICANCE: The use of embryonic stem cells and induced pluripotent stem cells for regenerative therapies is still a challenge. Understanding the underlying mechanisms that keep these cells proliferating with the ability to differentiate in more than 200 cell types (self-renewal) will aid in the future use of these cells therapeutically. Using a targeted phosphoproteomics study, insights into signaling pathways involved in ESC proliferation can be obtained. Modulating these pathways will aid the obtention of a larger number of self-renewing stem cells and induced pluripotent stem cells that can be used therapeutically.