97 research outputs found
Gut barrier-microbiota imbalances in early life lead to higher sensitivity to inflammation in a murine model of C-section delivery
Background Most interactions between the host and its microbiota occur at the gut barrier, and primary colonizers
are essential in the gut barrier maturation in the early life. The motherâofspring transmission of microorganisms is
the most important factor infuencing microbial colonization in mammals, and Câsection delivery (CSD) is an imporâ
tant disruptive factor of this transfer. Recently, the deregulation of symbiotic hostâmicrobe interactions in early life
has been shown to alter the maturation of the immune system, predisposing the host to gut barrier dysfunction and
infammation. The main goal of this study is to decipher the role of the earlyâlife gut microbiotaâbarrier alterations and
its links with laterâlife risks of intestinal infammation in a murine model of CSD.
Results The higher sensitivity to chemically induced infammation in CSD mice is related to excessive exposure to a
too diverse microbiota too early in life. This early microbial stimulus has shortâterm consequences on the host homeoâ
stasis. It switches the pupâs immune response to an infammatory context and alters the epithelium structure and
the mucusâproducing cells, disrupting gut homeostasis. This presence of a too diverse microbiota in the very early
life involves a disproportionate shortâchain fatty acids ratio and an excessive antigen exposure across the vulnerable
gut barrier in the frst days of life, before the gut closure. Besides, as shown by microbiota transfer experiments, the
microbiota is causal in the high sensitivity of CSD mice to chemicalâinduced colitis and in most of the phenotypical
parameters found altered in early life. Finally, supplementation with lactobacilli, the main bacterial group impacted by
CSD in mice, reverts the higher sensitivity to infammation in exâgermâfree mice colonized by CSD pupsâ microbiota.
Conclusions Earlyâlife gut microbiotaâhost crosstalk alterations related to CSD could be the linchpin behind the pheâ
notypic efects that lead to increased susceptibility to an induced infammation later in life in mice.
Keywords Câsection delivery, Microbiota, Primary colonization, Early life, Infammation, Gut barrier, Murine modelinfo:eu-repo/semantics/publishedVersio
Gut barrier-microbiota imbalances in early life lead to higher sensitivity to inflammation in a murine model of C-section delivery
Most interactions between the host and its microbiota occur at the gut barrier, and primary colonizers are essential in the gut barrier maturation in the early life. The mother-offspring transmission of microorganisms is the most important factor influencing microbial colonization in mammals, and C-section delivery (CSD) is an important disruptive factor of this transfer. Recently, the deregulation of symbiotic host-microbe interactions in early life has been shown to alter the maturation of the immune system, predisposing the host to gut barrier dysfunction and inflammation. The main goal of this study is to decipher the role of the early-life gut microbiota-barrier alterations and its links with later-life risks of intestinal inflammation in a murine model of CSD.
The higher sensitivity to chemically induced inflammation in CSD mice is related to excessive exposure to a too diverse microbiota too early in life. This early microbial stimulus has short-term consequences on the host homeostasis. It switches the pup's immune response to an inflammatory context and alters the epithelium structure and the mucus-producing cells, disrupting gut homeostasis. This presence of a too diverse microbiota in the very early life involves a disproportionate short-chain fatty acids ratio and an excessive antigen exposure across the vulnerable gut barrier in the first days of life, before the gut closure. Besides, as shown by microbiota transfer experiments, the microbiota is causal in the high sensitivity of CSD mice to chemical-induced colitis and in most of the phenotypical parameters found altered in early life. Finally, supplementation with lactobacilli, the main bacterial group impacted by CSD in mice, reverts the higher sensitivity to inflammation in ex-germ-free mice colonized by CSD pups' microbiota.
Early-life gut microbiota-host crosstalk alterations related to CSD could be the linchpin behind the phenotypic effects that lead to increased susceptibility to an induced inflammation later in life in mice
Nanostructured Pt(NH3)4Cl2/SiO2 for nanomedicine: catalytic degradation of DNA in cancer cells
In vivo suppression of glioblastoma multiforme (GBM) in Wistar rats using silica-shelled biocatalytic Pt(NH3)4Cl2 nanoparticles is reported. These nanoparticles were synthesized by a sol-gel technique and characterized by SEM and HRTEM imaging. We confirmed morphological uniformity (30 nm) and surface acidity of the nanoparticles, respectively, by TEM imaging and FTIR spectral analysis. Interestingly, treatment of Wistar rats intraperitoneally inoculated with C6 cells using the biocatalysts resulted in considerable tumor shrinkage. Efficiency of the biocatalyst to shrink a tumor is superior to that by the commercial cytotoxic agent cisplatin. The tumor suppression property of Pt(NH3)4Cl2 nanoparticles is attributed to catalytic damage of DNA in C6 cells
Enzymatic Activities of Isolated Cytochrome bc1-like Complexes Containing Fused Cytochrome b Subunits with Asymmetrically Inactivated Segments of Electron Transfer Chains
Homodimeric structure of cytochrome bc_1, a common component of biological energy conversion systems, builds in four catalytic quinone oxidation/reduction sites and four chains of cofactors (branches) that, connected by a centrally located bridge, form a symmetric H-shaped electron transfer system. The mechanism of operation of this complex system is under constant debate. Here, we report on isolation and enzymatic examination of cytochrome bc1-like complexes containing fused cytochrome b subunits in which asymmetrically introduced mutations inactivated individual branches in various combinations. The structural asymmetry of those forms was confirmed spectroscopically. All the asymmetric forms corresponding to cytochrome bc_1 with partial or full inactivation of one monomer retain high enzymatic activity but at the same time show a decrease in the maximum turnover rate by a factor close to 2. This strongly supports the model assuming independent operation of monomers. The cross-inactivated form corresponding to cytochrome bc_1 with disabled complementary parts of each monomer retains the enzymatic activity at the level that, for the first time on isolated from membranes and purified to homogeneity preparations, demonstrates that intermonomer electron transfer through the bridge effectively sustains the enzymatic turnover. The results fully support the concept that electrons freely distribute between the four catalytic sites of a dimer and that any path connecting the catalytic sites on the opposite sides of the membrane is enzymatically competent. The possibility to examine enzymatic properties of isolated forms of asymmetric complexes constructed using the cytochrome b fusion system extends the array of tools available for investigating the engineering of dimeric cytochrome bc1 from the mechanistic and physiological perspectives
Bistability of Mitochondrial Respiration Underlies Paradoxical Reactive Oxygen Species Generation Induced by Anoxia
Increased production of reactive oxygen species (ROS) in mitochondria underlies major systemic diseases, and this clinical problem stimulates a great scientific interest in the mechanism of ROS generation. However, the mechanism of hypoxia-induced change in ROS production is not fully understood. To mathematically analyze this mechanism in details, taking into consideration all the possible redox states formed in the process of electron transport, even for respiratory complex III, a system of hundreds of differential equations must be constructed. Aimed to facilitate such tasks, we developed a new methodology of modeling, which resides in the automated construction of large sets of differential equations. The detailed modeling of electron transport in mitochondria allowed for the identification of two steady state modes of operation (bistability) of respiratory complex III at the same microenvironmental conditions. Various perturbations could induce the transition of respiratory chain from one steady state to another. While normally complex III is in a low ROS producing mode, temporal anoxia could switch it to a high ROS producing state, which persists after the return to normal oxygen supply. This prediction, which we qualitatively validated experimentally, explains the mechanism of anoxia-induced cell damage. Recognition of bistability of complex III operation may enable novel therapeutic strategies for oxidative stress and our method of modeling could be widely used in systems biology studies
A Map of Dielectric Heterogeneity in a Membrane Protein: the Hetero-Oligomeric Cytochrome b 6 f Complex
The cytochrome b6f complex, a member of the cytochrome bc family that mediates energy transduction in photosynthetic and respiratory membranes, is a hetero-oligomeric complex that utilizes two pairs of b-hemes in a symmetric dimer to accomplish trans-membrane electron transfer, quinone oxidationâreduction, and generation of a proton electrochemical potential. Analysis of electron storage in this pathway, utilizing simultaneous measurement of heme reduction, and of circular dichroism (CD) spectra, to assay hemeâheme interactions, implies a heterogeneous distribution of the dielectric constants that mediate electrostatic interactions between the four hemes in the complex. Crystallographic information was used to determine the identity of the interacting hemes. The Soret band CD signal is dominated by excitonic interaction between the intramonomer b-hemes, bn and bp, on the electrochemically negative and positive sides of the complex. Kinetic data imply that the most probable pathway for transfer of the two electrons needed for quinone oxidationâreduction utilizes this intramonomer heme pair, contradicting the expectation based on heme redox potentials and thermodynamics, that the two higher potential hemes bn on different monomers would be preferentially reduced. Energetically preferred intramonomer electron storage of electrons on the intramonomer b-hemes is found to require heterogeneity of interheme dielectric constants. Relative to the medium separating the two higher potential hemes bn, a relatively large dielectric constant must exist between the intramonomer b-hemes, allowing a smaller electrostatic repulsion between the reduced hemes. Heterogeneity of dielectric constants is an additional structureâfunction parameter of membrane protein complexes
Proteomic Analysis of the Dysferlin Protein Complex Unveils Its Importance for Sarcolemmal Maintenance and Integrity
Dysferlin is critical for repair of muscle membranes after damage. Mutations in dysferlin lead to a progressive muscular dystrophy. Recent studies suggest additional roles for dysferlin. We set out to study dysferlin's protein-protein interactions to obtain comprehensive knowledge of dysferlin functionalities in a myogenic context. We developed a robust and reproducible method to isolate dysferlin protein complexes from cells and tissue. We analyzed the composition of these complexes in cultured myoblasts, myotubes and skeletal muscle tissue by mass spectrometry and subsequently inferred potential protein functions through bioinformatics analyses. Our data confirm previously reported interactions and support a function for dysferlin as a vesicle trafficking protein. In addition novel potential functionalities were uncovered, including phagocytosis and focal adhesion. Our data reveal that the dysferlin protein complex has a dynamic composition as a function of myogenic differentiation. We provide additional experimental evidence and show dysferlin localization to, and interaction with the focal adhesion protein vinculin at the sarcolemma. Finally, our studies reveal evidence for cross-talk between dysferlin and its protein family member myoferlin. Together our analyses show that dysferlin is not only a membrane repair protein but also important for muscle membrane maintenance and integrity
FisiopatogĂȘnese da dor
O estudo da dor Ă© um capĂtulo do estudo das bases neurofisiolĂłgicas da sensação, pois a dor nada mais Ă© que uma sensação de conteĂșdo desagradĂĄvel originada por estĂmulos nocivos. Enquanto a função das outras modalidades sensoriais Ă© informativa ou gnĂłsica, a dor Ă© de proteção. O estudo da fisiologĂa da dor compreende o estudo dos receptores, dos estĂmulos, das vias, das estruturas do sistema nervoso central que partici- pam da fisiologĂa da dor, da percepção dolorosa e das reaçÔes motoras e neurovegetativas. SĂŁo analisados os receptores e as vias e discutidas sua especificidade, assim como a transmissĂŁo da dor rĂĄpida e lenta por vias nervosas diferentes atĂ© o cĂłrtex cerebral. Ă comentada a influĂȘncia da atenção na intensidade da percepção dolorosa e, com base em estudos experimentais, Ă© considerado que o circuito retĂculo-cĂłrtico-reticular seja indispensĂĄvel para a percepção da dor. No tocante Ă patologia da dor Ă© examinada a insensibilidade congĂȘnita Ă dor, sendo admitida a hipĂłtese de que em algumas sinapses Ă© modificado o esquema de impulsos que darĂŁo lugar Ă sensação dolorosa. Ă destacado o papel do lobo frontal como parte de um mecanismo pĂČtenciador que condiciona o sofrimento geral do paciente. A dor referida Ă© explicada pela teoria da "convergĂȘncia-projeção" de fibras viscerais com fibras cutĂąneas dolorosas sĂŽbre o mesmo neurĂŽnio em algun ponto da via sensitiva. O resultado da hipofisectomia trazendo uma diminuição ou anulação da dor no cĂąncer do seio abre debates em tĂŽrno do papel dos hormĂŽnios na percepção dolorosa
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