Catalogue Search | MBRL
Search Results Heading
Explore the vast range of titles available.
MBRLSearchResults
-
DisciplineDiscipline
-
Is Peer ReviewedIs Peer Reviewed
-
Item TypeItem Type
-
SubjectSubject
-
YearFrom:-To:
-
More FiltersMore FiltersSourceLanguage
Done
Filters
Reset
1,403
result(s) for
"redox regulation"
Sort by:
The role of redox signaling in mitochondria and endoplasmic reticulum regulation in kidney diseases
by
Reyes-Fermín, Laura María
,
Pedraza-Chaverri, José
,
Aparicio-Trejo, Omar Emiliano
in
acute kidney injury
,
Animals
,
Archives & records
2025
Kidney diseases are among the fastest worldwide growing pathologies. This growth together with their high mortality rate emphasizes the importance of generating vital information about the mechanism involved in their pathophysiology to determine possible therapeutic targets. Recently, mitochondrial damage and their implication in the reactive oxygen spices (ROS) signaling and redox homeostasis have emerged as a hub point in the pathologic mechanism involved in renal pathologies. ROS in low levels are necessary to maintain cell processes as well as the mitochondria homeostasis and its association with other organelles, especially the with the endoplasmic reticulum (ER). However, the information about how redox signaling interacts and interferes with other cellular processes and the mechanism involved has not been fully integrated. Furthermore, in higher concentrations, these ROS promotes pathologic pathways linked to renal disease progression like, mitochondrial biogenesis reduction, ER stress, calcium overload, inflammation, cell death and fibrosis. Therefore, the aim of this review is to describe the molecular mechanisms involved in the redox signaling influence on mitochondrial and ER homeostasis, focusing on lipid metabolism and ß-oxidation, mitochondrial biogenesis, inflammations, ER stress and calcium homeostasis, as well as the effects of these alteration in the genesis and development of renal disease, with emphasis in acute kidney injury (AKI) and chronic kidney disease (CKD).
Journal Article
Endoplasmic reticulum protein 29 negatively regulates platelet functions and thrombosis in mice
2025
Background
Several members of protein disulfide isomerase (PDI) family with the CXYC active motif such as PDI, ERp57, ERp72, ERp46, ERp5 and TMX1 have important roles in platelet functions and thrombosis. These members contribute to the network of redox regulation of platelet activities. However, whether other PDI family members without the CXYC motif such as ERp29, have a role in these processes remains unknown.
Aims
To determine the role of ERp29 in platelet functions and thrombosis.
Methods
The phenotypes of platelet-specific ERp29-deficient (Pf4-Cre/ERp29
fl/fl
) mice were evaluated using tail bleeding assay and laser-induced and FeCl
3
-induced arterial injury models, as well as venous thrombosis model. In vitro, the functions of ERp29-deficient platelets were assessed in respect to aggregation, adhesion, spreading, clot retraction, granule secretion and integrin αIIbβ3 activation measured by flow cytometry. Redox state of integrin αIIbβ3 thiols was detected using 3-(N-maleimido-propionyl) biotin (MPB) labeling.
Results
Compared with WT mice, Pf4-Cre/ERp29
fl/fl
mice exhibited shortened tail-bleeding times, increased platelet accumulation in the two arterial thrombosis models, and enhanced thrombogenesis in the venous thrombosis model. ERp29-deficient platelets had enhanced response in aggregation, ATP release, spreading, clot retraction, αIIbβ3 activation, fibrinogen binding and P-selectin expression. As detected by MPB labeling, the free thiol content of integrin αIIbβ3 in ERp29-deficient platelets were increased compared with WT platelets, suggesting that the role of ERp29 is associated with oxidation of the functional disulfides of integrin αIIb and/or β3 subunits.
Conclusion(s)
ERp29 is the first disulfide isomerase without the CXYC motif that negatively regulates platelet function. This study provides new insight into the redox network controlling thrombosis.
Journal Article
Chloroplasts as source and target of cellular redox regulation: a discussion on chloroplast redox signals in the context of plant physiology
2005
During the evolution of plants, chloroplasts have lost the exclusive genetic control over redox regulation and antioxidant gene expression. Together with many other genes, all genes encoding antioxidant enzymes and enzymes involved in the biosynthesis of low molecular weight antioxidants were transferred to the nucleus. On the other hand, photosynthesis bears a high risk for photo-oxidative damage. Concomitantly, an intricate network for mutual regulation by anthero- and retrograde signals has emerged to co-ordinate the activities of the different genetic and metabolic compartments. A major focus of recent research in chloroplast regulation addressed the mechanisms of redox sensing and signal transmission, the identification of regulatory targets, and the understanding of adaptation mechanisms. In addition to redox signals communicated through signalling cascades also used in pathogen and wounding responses, specific chloroplast signals control nuclear gene expression. Signalling pathways are triggered by the redox state of the plastoquinone pool, the thioredoxin system, and the acceptor availability at photosystem I, in addition to control by oxolipins, tetrapyrroles, carbohydrates, and abscisic acid. The signalling function is discussed in the context of regulatory circuitries that control the expression of antioxidant enzymes and redox modulators, demonstrating the principal role of chloroplasts as the source and target of redox regulation.
Journal Article
Photosynthetic redox control of nuclear gene expression
by
Fey, Vidal
,
Bräutigam, Katharina
,
Pfannschmidt, Thomas
in
Acclimatization
,
Adaptation, Physiological
,
biosynthesis
2005
Chloroplasts contain 3000–4000 different proteins but only a small subset of them is encoded in the plastid genome while the majority is encoded in the nucleus. Expression of these genes therefore requires a high degree of co-ordination between nucleus and chloroplast. This is achieved by a bilateral information exchange between both compartments including nucleus-to-plastid (anterograde) and plastid-to-nucleus (retrograde) signals. The latter represent a functional feedback control which couples the expression of nuclear encoded plastid proteins to the actual functional state of the organelle. The efficiency of photosynthesis is a very important parameter in this context since it is influenced by many environmental conditions and therefore represents a sensor for the residing environment. Components of the photosynthetic electron transport chain exhibit significant changes in their reduction/oxidation (redox) state depending on the photosynthetic electron flow and therefore serve as signalling parameters which report environmental influences on photosynthesis. Such redox signals control chloroplast and nuclear gene expression events and play an important role in the co-ordination of both genetic compartments. It is discussed here which photosynthetic parameters are known to control nuclear gene expression, how these signals are transduced toward the nucleus, and how they interact with other plastid retrograde signals and cytosolic light perception systems.
Journal Article
Redox regulation of carbon storage and partitioning in response to light and sugars
by
Geigenberger, Peter
,
Kolbe, Anna
,
Tiessen, Axel
in
Acetyl-CoA carboxylase
,
Adaptation, Physiological
,
Adenosine diphosphate
2005
Redox signals generated by the photosynthetic electron transport chain are known to be involved in regulating the Calvin cycle, ATP synthesis, and NADPH export from chloroplasts in response to light. The signal cascade involves transfer of electrons from photosystem I via the ferredoxin–thioredoxin system to target enzymes that are activated by reduction of regulatory disulphide bonds. The purpose of this review is to discuss recent findings showing that this concept can be extended to the regulation of carbon storage and partitioning in plants. Starch is the major carbon store in plants, and ADP-glucose pyrophosphorylase (AGPase) is the key regulatory enzyme of starch synthesis in the plastid. It has been shown that AGPase from potato tubers is subject to post-translational redox modification, and here experimental data will be provided showing that the isozyme from pea leaf chloroplasts is activated by reduced thioredoxin f or m in a similar way. Recent reports will be summarized providing in planta evidence that this mechanism regulates storage starch synthesis in response to light and sugars. Post-translational redox activation of AGPase in response to sugars is part of a signalling mechanism linking the rate of starch synthesis to the availability of carbon in diverse plant tissues. Some of the components of the signalling pathway reporting changes in the cytosolic sugar status to the plastid have been postulated, but detailed work is in progress to confirm the exact mode of action. Recent evidence will be discussed showing that key enzymes of de novo fatty acid synthesis (acetyl-CoA carboxylase) and ammonium assimilation (glutamine synthetase and glutamine:oxoglutarate amino transferase) are regulated by reversible disulphide-bond formation similar to AGPase. Redox regulation is proposed to be the preferred strategy of plastidial enzymes to regulate various metabolic processes such as carbon fixation, starch metabolism, lipid synthesis, and amino acid synthesis in response to physiological and environmental inputs.
Journal Article
Structural Basis for Redox Regulation of Cytoplasmic and Chloroplastic Triosephosphate Isomerases from Arabidopsis thaliana
by
Trasviña-Arenas, Carlos H.
,
Lara-González, Samuel
,
Baruch-Torres, Noe
in
Accessibility
,
Amino acids
,
Arabidopsis thaliana
2016
In plants triosephosphate isomerase (TPI) interconverts glyceraldehyde 3-phosphate (G3P) and dihydroxyacetone phosphate (DHAP) during glycolysis, gluconeogenesis, and the Calvin-Benson cycle. The nuclear genome of land plants encodes two
genes, one gene product is located in the cytoplasm and the other is imported into the chloroplast. Herein we report the crystal structures of the TPIs from the vascular plant
(AtTPIs) and address their enzymatic modulation by redox agents. Cytoplasmic TPI (cTPI) and chloroplast TPI (pdTPI) share more than 60% amino acid identity and assemble as (β-α)
dimers with high structural homology. cTPI and pdTPI harbor two and one accessible thiol groups per monomer respectively. cTPI and pdTPI present a cysteine at an equivalent structural position (C13 and C15 respectively) and cTPI also contains a specific solvent accessible cysteine at residue 218 (cTPI-C218). Site directed mutagenesis of residues pdTPI-C15, cTPI-C13, and cTPI-C218 to serine substantially decreases enzymatic activity, indicating that the structural integrity of these cysteines is necessary for catalysis. AtTPIs exhibit differential responses to oxidative agents, cTPI is susceptible to oxidative agents such as diamide and H
O
, whereas pdTPI is resistant to inhibition. Incubation of AtTPIs with the sulfhydryl conjugating reagents methylmethane thiosulfonate (MMTS) and glutathione inhibits enzymatic activity. However, the concentration necessary to inhibit pdTPI is at least two orders of magnitude higher than the concentration needed to inhibit cTPI. Western-blot analysis indicates that residues cTPI-C13, cTPI-C218, and pdTPI-C15 conjugate with glutathione. In summary, our data indicate that AtTPIs could be redox regulated by the derivatization of specific AtTPI cysteines (cTPI-C13 and pdTPI-C15 and cTPI-C218). Since AtTPIs have evolved by gene duplication, the higher resistance of pdTPI to redox agents may be an adaptive consequence to the redox environment in the chloroplast.
Journal Article
Redox regulation in the chloroplast thylakoid lumen: a new frontier in photosynthesis research
2005
Initially linked to photosynthesis, regulation by change in the redox state of thiol groups (S-S←→2SH) is now known to occur throughout biology. Thus, in addition to serving important structural and catalytic functions, it is recognized that, in many cases, disulphide bonds can be broken and reformed for regulation. Several systems, each linking a hydrogen donor to an intermediary disulphide protein, act to effect changes that alter the activity of target proteins by change in the thiol redox state. Pertinent to the present discussion is the chloroplast ferredoxin/thioredoxin system, comprised of photoreduced ferredoxin, a thioredoxin, and the enzyme ferredoxin-thioredoxin reductase, that occur in the stroma. In this system, thioredoxin links the activity of enzymes to light: those enzymes functional in biosynthesis are reductively activated by light via thioredoxin (S-S→2SH), whereas counterparts acting in degradation are deactivated under illumination conditions and are oxidatively activated in the dark (2SH→S-S). Recent research has uncovered a new paradigm in which an immunophilin, FKBP13, and potentially other enzymes of the chloroplast thylakoid lumen are oxidatively activated in the light (2SH→S-S). The present review provides a perspective on this recent work.
Journal Article
Sulfur nutrition
Sulfur is an essential element for all organisms and has a wide variety of functions. Plant sulfur nutrition is particularly important as plants are our primary source of the essential amino acid methionine. Sulfur deficiency affects the growth, development, disease resistance, and performance of plants and has a great impact on the nutritional quality of crops. In this special issue, a collection of papers based mainly on contributions from the 11th International Plant Sulfur Workshop gives an overview of different facets of sulfur functions in plants and highlights the importance of sulfur nutrition for different parts of the plant life cycle.
Journal Article
Signaling by hydrogen sulfide and cyanide through post-translational modification
2019
Two cysteine metabolism-related molecules, hydrogen sulfide and hydrogen cyanide, which are considered toxic, have now been considered as signaling molecules. Hydrogen sulfide is produced in chloroplasts through the activity of sulfite reductase and in the cytosol and mitochondria by the action of sulfide-generating enzymes, and regulates/affects essential plant processes such as plant adaptation, development, photosynthesis, autophagy, and stomatal movement, where interplay with other signaling molecules occurs. The mechanism of action of sulfide, which modifies protein cysteine thiols to form persulfides, is related to its chemical features. This post-translational modification, called persulfidation, could play a protective role for thiols against oxidative damage. Hydrogen cyanide is produced during the biosynthesis of ethylene and camalexin in non-cyanogenic plants, and is detoxified by the action of sulfurrelated enzymes. Cyanide functions include the breaking of seed dormancy, modifying the plant responses to biotic stress, and inhibition of root hair elongation. The mode of action of cyanide is under investigation, although it has recently been demonstrated to perform post-translational modification of protein cysteine thiols to form thiocyanate, a process called S-cyanylation. Therefore, the signaling roles of sulfide and most probably of cyanide are performed through the modification of specific cysteine residues, altering protein functions.
Journal Article
Water physicochemical factors and oxidative stress physiology in fish, a review
by
Asthana, Monika
,
Subaramaniyam, Udayadharshini
,
Johnson, Rajee
in
abiotic factors
,
disease
,
economic value
2023
Fish are among the best-studied aquatic animals due to their economic and ecological values. Fish meat is the most affordable protein source for the economically weaker section of people. The environment of almost all aquatic ecosystems has a specific influential role on or by fishes. Therefore, studying their stress biology, especially oxidative stress, is vital because it can influence their growth, production, reproduction, etc. To review the above topic, peer-reviewed electronic databases, including Web of Science, science direct, PubMed, Google Scholar, Scopus, and AGRICOLA, were searched with specific keywords associated with fish, oxidative stress, diseases, etc. The influence of abiotic stress, such as the effects of water dissolved oxygen, temperature, salinity, water hardness, alkalinity, pH, pollutants, heavy metals, and anthropogenic activities, was reviewed in the current article to draw a conclusion on the updated relation that exists between fish physiology, disease, and abiotic stressors. Oxidative stress and redox regulatory levels under the above parameters were reviewed as the stress or anti-stress responses differ in various fish models. Undoubtedly, the reviewed abiotic factors modulate fish oxidative health status to a greater extent, and therefore, these factors must be considered on a priority basis to improve the general health and immunity status of fish. The statement above remains valid in both saline and freshwater habitats.
Journal Article