Natalee Carapia-Minero scite author profile

Natalee Carapia-Minero

4Publications

18Citation Statements Received

54Citation Statements Given

How they've been cited

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248

Affiliations

Instituto Politécnico Nacional

Publications

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Candida glabratasurvives and replicates in human osteoblasts

Muñoz-Duarte¹,

Castrejón-Jiménez²,

Baltierra‐Uribe³

et al. 2016

Pathogens and Disease

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Candida glabrata is an opportunistic pathogen that is considered the second most common cause of candidiasis after Candida albicans Many characteristics of its mechanisms of pathogenicity remain unknown. Recent studies have focused on determining the events that underlie interactions between C. glabrata and immune cells, but the relationship between this yeast and osteoblasts has not been studied in detail. The aim of this study was to determine the mechanisms of interaction between human osteoblasts and C. glabrata, and to identify the roles played by some of the molecules that are produced by these cells in response to infection. We show that C. glabrata adheres to and is internalized by human osteoblasts. Adhesion is independent of opsonization, and internalization depends on the rearrangement of the actin cytoskeleton. We show that C. glabrata survives and replicates in osteoblasts and that this intracellular behavior is related to the level of production of nitric oxide and reactive oxygen species. Opsonized C. glabrata stimulates the production of IL-6, IL-8 and MCP-1 cytokines. Adhesion and internalization of the pathogen and the innate immune response of osteoblasts require viable C. glabrata These results suggest that C. glabrata modulates immunological mechanisms in osteoblasts to survive inside the cell.

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The phosphorelay signal transduction system in Candida glabrata: an in silico analysis

Carapia-Minero

Castelán-Vega

Pérez³

et al. 2017

J Mol Model

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Signaling systems allow microorganisms to sense and respond to different stimuli through the modification of gene expression. The phosphorelay signal transduction system in eukaryotes involves three proteins: a sensor protein, an intermediate protein and a response regulator, and requires the transfer of a phosphate group between two histidine-aspartic residues. The SLN1-YPD1-SSK1 system enables yeast to adapt to hyperosmotic stress through the activation of the HOG1-MAPK pathway. The genetic sequences available from Saccharomyces cerevisiae were used to identify orthologous sequences in Candida glabrata, and putative genes were identified and characterized by in silico assays. An interactome analysis was carried out with the complete genome of C. glabrata and the putative proteins of the phosphorelay signal transduction system. Next, we modeled the complex formed between the sensor protein CgSln1p and the intermediate CgYpd1p. Finally, phosphate transfer was examined by a molecular dynamic assay. Our in silico analysis showed that the putative proteins of the C. glabrata phosphorelay signal transduction system present the functional domains of histidine kinase, a downstream response regulator protein, and an intermediate histidine phosphotransfer protein. All the sequences are phylogenetically more related to S. cerevisiae than to C. albicans. The interactome suggests that the C. glabrata phosphorelay signal transduction system interacts with different proteins that regulate cell wall biosynthesis and responds to oxidative and osmotic stress the same way as similar systems in S. cerevisiae and C. albicans. Molecular dynamics simulations showed complex formation between the response regulator domain of histidine kinase CgSln1 and intermediate protein CgYpd1 in the presence of a phosphate group and interactions between the aspartic residue and the histidine residue. Overall, our research showed that C. glabrata harbors a functional SLN1-YPD1-SSK1 phosphorelay system.

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Lipid-Like Biofilm from a Clinical Brain Isolate of Aspergillus terreus: Quantification, Structural Characterization and Stages of the Formation Cycle

et al. 2022

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Invasive infections caused by lamentous fungi have increased considerably due to the alteration of the host's immune response. Recently, Aspergillus terreus is considered an emerging pathogen and has shown resistance to amphotericin B treatment, resulting in high mortality. The development of fungal bio lm is a virulence factor, and it has been described in some cases of invasive aspergillosis. In addition, although the general composition of fungal bio lms is known, ndings related to bio lms of a lipid nature are rarely reported. In this study, we present the identi cation of a clinical strain of A. terreus by microbiological and molecular tools, also its in vitro bio lm development capacity: i) Bio lm formation was quanti ed by Crystal Violet (CV) and reduction of tetrazolium salts assays (MTT), and simultaneously the stages of bio lm development were described by Scanning Electron Microscopy in High Resolution (SEM-HR). ii) Characterization of the organizational structure of the bio lm was performed by SEM-HR. The hyphal networks developed on the surface, the abundant air channels created between the ECM (extracellular matrix) and the hyphae fused in anastomosis were described. Also, the presence of microhyphae is reported.iii) The chemical composition of the ECM was analyzed by SEM-HR and CLSM (Confocal Laser Scanning Microscopy). Proteins, carbohydrates, nucleic acids and a relevant presence of lipid components were identi ed. Some structures of apparent waxy appearance were highlighted by SEM-HR and backscatterelectron diffraction, for which CLSM was previously performed. To our knowledge, this work is the rst description of a lipid-type bio lm in lamentous fungi, speci cally of the species A. terreus from a clinical isolate.

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Lipid-like biofilm from a clinical brain isolate of Aspergillus terreus: quantification, structural characterization and stages of the formation cycle.

Rayón-López

Carapia-Minero

Medina-Canales

et al. 2022

Preprint

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Invasive infections caused by filamentous fungi have increased considerably due to the alteration of the host's immune response. Recently, Aspergillus terreus is considered an emerging pathogen and has shown resistance to amphotericin B treatment, resulting in high mortality. The development of fungal biofilm is a virulence factor, and it has been described in some cases of invasive aspergillosis. In addition, although the general composition of fungal biofilms is known, findings related to biofilms of a lipid nature are rarely reported. In this study, we present the identification of a clinical strain of A. terreus by microbiological and molecular tools, also its in vitro biofilm development capacity: i) Biofilm formation was quantified by Crystal Violet (CV) and reduction of tetrazolium salts assays (MTT), and simultaneously the stages of biofilm development were described by Scanning Electron Microscopy in High Resolution (SEM-HR). ii) Characterization of the organizational structure of the biofilm was performed by SEM-HR. The hyphal networks developed on the surface, the abundant air channels created between the ECM (extracellular matrix) and the hyphae fused in anastomosis were described. Also, the presence of microhyphae is reported. iii) The chemical composition of the ECM was analyzed by SEM-HR and CLSM (Confocal Laser Scanning Microscopy). Proteins, carbohydrates, nucleic acids and a relevant presence of lipid components were identified. Some structures of apparent waxy appearance were highlighted by SEM-HR and backscatter-electron diffraction, for which CLSM was previously performed. To our knowledge, this work is the first description of a lipid-type biofilm in filamentous fungi, specifically of the species A. terreus from a clinical isolate.

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