Global ETD Search

1	Vitamin D and its in vitro therapeutic action mediated through VDR rather than PDIA3 Pyburn, Jaeden S, Hagg, T., Keasey, M. P. 06 April 2022 (has links) Brain calcification is a common occurrence in the aging process, with over 20% of individuals over the age of 65 showing hardened plaques in the basal ganglia. Loss of the vitamin D receptor (VDR) in transgenic mice leads to formation of calcified plaques in the basal ganglia and thalamus within the mice. Vitamin D signals through two known vitamin D responsive proteins, protein disulfide isomerase A3 (PDIA3) and VDR. In vitro, vitamin D has been demonstrated to suppress calcification in osteoblast-like cells. Here, we aim to elucidate which of PDIA3 or VDR transduce vitamin D mediated suppression of calcification in vitro. PDIA3 or VDR were selectively knocked out in human osteosarcoma (SaOs) cells using CRISPR/CAS9 technology to generate PDIA3 -/- or VDR -/- cells. Knockout for PDIA3 or VDR was confirmed by RT-qPCR assay or western blot analysis. The calcification of SaOs-2 cells was induced with treatment of β-glycerophosphate along with ascorbic acid allowing for determination of whether loss of PDIA3 or VDR would lead to altered calcium deposition. Cells null for PDIA3 but not VDR grew at a significantly slower rate than wild-type (WT) cells. Intriguingly, PDIA3 and VDR -/- cells displayed significantly more calcification relative to WT control cells. Calcitriol or the synthetic analogue EB-1089 suppressed calcification in vitro in WT and PDIA3 -/- but not VDR -/- cells as measured by alizarin red staining. These data suggest VDR is critical for mediating vitamin D’s inhibition of calcification in vitro, and that PDIA3 has a role in suppressing calcification. This study provides novel insights into vitamin D signaling and provides a foundation for further study and understanding of vitamin D related pathologies. Vitamin D calcification PDIA3 VDR Cell Biology
2	PDIA3 Inhibits Mitochondrial Respiratory Function in Brain Endothelial Cells and C. Elegans Through STAT3 Signaling and Decreases Survival After OGD Keasey, Matt P., Razskazovskiy, V., Jia, C., Peterknecht, E. D., Bradshaw, Patrick C., Hagg, T. 18 December 2021 (has links) BACKGROUND: Protein disulfide isomerase A3 (PDIA3, also named GRP58, ER-60, ERp57) is conserved across species and mediates protein folding in the endoplasmic reticulum. PDIA3 is, reportedly, a chaperone for STAT3. However, the role of PDIA3 in regulating mitochondrial bioenergetics and STAT3 phosphorylation at serine 727 (S727) has not been described. METHODS: Mitochondrial respiration was compared in immortalized human cerebral microvascular cells (CMEC) wild type or null for PDIA3 and in whole organism C. Elegans WT or null for pdi-3 (worm homologue). Mitochondrial morphology and cell signaling pathways in PDIA3-/- and WT cells were assessed. PDIA3-/- cells were subjected to oxygen-glucose deprivation (OGD) to determine the effects of PDIA3 on cell survival after injury. RESULTS: We show that PDIA3 gene deletion using CRISPR-Cas9 in cultured CMECs leads to an increase in mitochondrial bioenergetic function. In C. elegans, gene deletion or RNAi knockdown of pdi-3 also increased respiratory rates, confirming a conserved role for this gene in regulating mitochondrial bioenergetics. The PDIA3-/- bioenergetic phenotype was reversed by overexpression of WT PDIA3 in cultured PDIA3-/- CMECs. PDIA3-/- and siRNA knockdown caused an increase in phosphorylation of the S727 residue of STAT3, which is known to promote mitochondrial bioenergetic function. Increased respiration in PDIA3-/- CMECs was reversed by a STAT3 inhibitor. In PDIA3-/- CMECs, mitochondrial membrane potential and reactive oxygen species production, but not mitochondrial mass, was increased, suggesting an increased mitochondrial bioenergetic capacity. Finally, PDIA3-/- CMECs were more resistant to oxygen-glucose deprivation, while STAT3 inhibition reduced the protective effect. CONCLUSIONS: We have discovered a novel role for PDIA3 in suppressing mitochondrial bioenergetic function by inhibiting STAT3 S727 phosphorylation. mitochondria PDIA3 STAT3 endothelial cells Biomedical Sciences
3	Investigation of 1alpha,25-dihydroxy vitamin D3 membrane receptor ERp60 in adipocytes from male and female lean and obese mice McLane, Jesica Mata 19 October 2009 (has links) The purpose of this study is to determine whether or not adipocytes harvested directly from fat pads or induced from bone marrow in lean and obese mice exhibit a sex-dependent rapid response to vitamin D metabolite 1á,25(OH)2D3 and if so to elucidate if it is via an ERp60 receptor mediated signaling pathway. The role of 1á,25(OH)2D3 and specifically the membrane effect will be examined in two genetically distinct mice to see if their cells have a differing sensitivity. The results indicate that there are differing responses in adipocytes that are induced from bone marrow versus differentiated fat pad adipocytes, and the function of 1á,25(OH)2D3 is sex-specific in some cases. Additionally, all the adipocytes tested demonstrated a rapid response to 1á,25(OH)2D3; mRNA for nVDR and ERp60 were found in all cells however the only functional protein found in the plasma membrane was ERp60 indicating that it may be necessary for the rapid response whereas nVDR is not required. Vitamin D Pdia3 Vitmain D receptor ERp60 Adipocytes PKC Adipogenesis Fat cells Adipose tissues Cell receptors
4	The role of Pdia3 in vitamin D signaling in osteoblasts Chen, Jiaxuan 24 August 2012 (has links) 1a,25-Dihydroxyvitamin D3 (1a,25(OH)2D3) is a major functional metabolic form of vitamin D. 1a,25(OH)2D3 has drawn increasing attention due to its functions in addition to maintaining calcium phosphate homeostasis. It directly regulates mineralization by osteoblasts, matrix production and remodeling by chondrocytes, and contraction of cardiomyocytes. 1a,25(OH)2D3 and its analogues have shown beneficial effects in treating multiple sclerosis, diabetes and various types of cancer. In order to maximize the pharmaceutical potential of 1a,25(OH)2D3, a better understanding its cell signaling pathway is necessary. 1a,25(OH)2D3 regulates osteoblasts through both classical nuclear vitamin D receptor (nVDR) mediated genomic effects and plasma membrane receptor-mediated rapid responses. The identity of the plasma membrane receptor for 1a,25(OH)2D3 is controversial. Protein disulfide isomerase associated 3 (Pdia3) has been hypothesized as one of the putative plasma membrane receptors for 1a,25(OH)2D3. The overall goal of this thesis was to understand the general role and the molecular mechanism of Pdia3 in 1a,25(OH)2D3-initiated rapid responses, and to determine the role of Pdia3 and its dependent signaling in osteoblast biology. The results show that Pdia3 is required for membrane-mediated responses of 1a,25(OH)2D3. Moreover, both Pdia3 and nVDR are critical components of the plasma membrane receptor complex for 1a,25(OH)2D3. Finally, Pdia3 and signaling via Pdia3 regulate osteoblast differentiation and mineralization. Taken together, this study demonstrates the role of Pdia3 in rapid responses to 1a,25(OH)2D3 and osteoblast biology, reveals the unexpected complexity of the 1a,25(OH)2D3 plasma receptor complex and opens the new target, Pdia3, for pharmaceutical application and tissue engineering. Rapid response Osteoblasts Vitamin D VDR Pdia3 Cholecalciferol Cell receptors Steroid hormones
5	Interactions entre la signalisation estrogénique et la vitamine D dans les cellules testiculaires / Interactions between the estrogenic path and vitamin D in testicular cells Goncalves, Renata 28 February 2018 (has links) La 1α,25(OH)2 vitamine D3 (1,25-D3) est synthétisée à partir du cholestérol par l'exposition solaire de la peau. Les effets de cette hormone sont médiées par le récepteur de la vitamine D (VDR) dans le noyau et à la membrane plasmique, et avec le récepteur PDIA3 ils médient des effets génomiques et non-génomique. La vitamine D joue un rôle important dans la reproduction, puisque la réduction de la fertilité a été observée chez les rats déficients en vitamine D. L'estradiol (E2) est synthétisé à partir de la testostérone par l'enzyme aromatase (CYP19). L’E2 a des effets génomiques et non génomiques médiée par les récepteurs ESR1, ESR2 et GPER. L’objectif de ce travail a été d’étudier l’effet de l’E2 sur le métabolisme et les voies de signalisation de la vitamine D dans des testicules des rats à différents âges ainsi qu’une perturbation éventuelle initiée par un perturbateur endocrinien à activité estrogénique, le Bisphénol A (BPA). Dans le première axe de travail, trois protocoles expérimental (PE) ont été réalisés, où l’E2 et le BPA ont été administrés: traitement de J15pp à J30pp et euthanasie immédiate à J30 (PE1), traitement de J15 à J30 et euthanasie différée à J75 (PE2) et traitement à l’âge adulte de J60 à J75 et euthanasie immédiate à J75 (PE3). Dans le PE1, le traitement avec l’E2 a diminué l'expression du CYP27A1. L’E2 et le BPA ont diminué l'expression du VDR. Cet effet n'a pas été vérifié dans l'expression de la protéine VDR. Dans le PE2, l’E2 a augmenté l'expression des gènes VDR, PDIA3 et CYP27A1, et l'expression de la protéine VDR et CYP27A1. Les traitements n’ont eu aucun effet dans le PE3, ce qui indique qu’un traitement en période prépubère entraîne à la fois un effet immédiat et différé alors que le traitement à l’âge adulte semble sans effet. Dans le deuxième axe de travail, des effets non-génomiques du BPA ont été étudiés par la technique d’afflux de 45Ca2+ dans les testicules de rat prépubères. Le BPA a stimulé l’afflux de 45Ca2+ de manière un peu pareille avec les effets de l’E2. Cet effet semble ne pas impliquer les récepteurs classiques des estrogènes, mais semble se produire de manière compatible avec l'activation d'un récepteur couplé à la protéine G, comme le GPER. Cet effet se produit par la modulation de la fonction des canaux ioniques, comme des canaux potassiques, TRPV1 et des canaux chlorés. Aussi le BPA module le calcium du stock intracellulaire par l’inhibition de la SERCA et l’activation du récepteur IP3. Également des protéines kinases PKA, PKC, MEK et p38MAPK participent de l’effet du BPA, qui pourrait déclencher un cross talk avec les voies de signalisation nucléaires résultant la médiation des réponses génomiques. Dans le troisième axe de travail, l'expression de certains gènes impliqués dans le métabolisme et la signalisation de 1,25-D3 et E2 a été analysée dans des cellules de Leydig. La 1,25-D3 a diminué l'expression du CYP27A1, un effet qui a également été observé lorsque les cellules étaient co-incubées avec l'E2. L’E2 a diminué l'expression des gènes ESR1 et CYP19. Les deux hormones ont démontré un mécanisme de retours négatifs sur leur métabolisme dans ces cellules. Des effets non génomiques ont été étudiés dans ces cellules, où l’E2 semble avoir un effet inhibiteur tandis que la 1,25-D3 a stimulé l'afflux de 45CA2+. A partir de ces résultats, nous pouvons affirmer que la 1,25-D3, l’E2 et le BPA ont des effets moléculaires importants dans le système reproducteur masculin, par l'expression génique des récepteurs et des enzymes impliqués dans le métabolisme des hormones 1,25-D3 et E2. De plus, les résultats obtenus renforcent la théorie selon laquelle il existe une relation entre les voies de signalisation de la 1,25-D3 et l’E2. Comme la 1,25-D3 et l'E2, le BPA stimule également les effets non-génomiques impliqués dans la signalisation du calcium. / 1α,25-dihydroxyvitamin D3 (1,25-D3), the active form of vitamin D, is synthetized from cholesterol by skin exposure to the sun. This hormone’s actions are mediated by vitamin D receptor (VDR) in the nucleus and in the plasma membrane, resulting in genome actions like gene expression regulation. VDR can also be found in the plasmatic membrane, and together with PDIA3 receptor they mediate 1,25-D3 non-genomic actions. Vitamin D has an important role in reproductive function, since fertility reduction was observed in vitamin D deficient rats, as well as VDR and 1α-hydroxylase deficiency. In these animals, calcium and estrogen supplementation was able to reverse the deleterious effects in reproductive function, indicating that there is a relation between 1,25-D3 and estrogens signalling pathways. Estradiol (E2) is synthetized from testosterone by aromatase enzyme (CYP19). E2 is found in high levels in the male reproductive function, and like 1,25-D3 can induce genomic and non- genomic actions, mediated by ESR1, ESR2 and GPER receptors. Bisphenol A (BPA) is a xenoestrogen utilized in plastic industry, capable of modulating the endocrine system through E2 receptors. The aim of this work was to study metabolism and signaling pathways interactions between 1,25-D3 and E2, as well as BPA influence in testicular cells. In the first line of work, three treatment protocols (TP) were realized, where E2 and BPA were administrated in rats between 15th and 30th days, were a portion of the animals were euthanized at the last day of treatment (TP1) and another portion was kept alive after the treatment until euthanized at adult age with 75 days (TP2). A third animal group also received the same treatments when adults (TP3). In TP1, E2 treatment decreased CYP27A1 gene expression. E2 and BPA decreased VDR gene expression. This effect was not verified in VDR protein expression. In TP2, E2 increased VDR, PDIA3 and CYP27A1 gene expression, and VDR and CYP27A1 protein expression, indicating a compensatory effect over gene expression inhibition in prepubertal age. In TP3, treatments did not change gene expression, indicating that prepubertal age is more susceptible to estrogen exposure. In the second line of work, non-genomic effects of BPA were studied through 45Ca2+ influx in prepubertal rat testis. BPA stimulated 45Ca2+ influx in a similar manner to E2. This effect was independent of classical ERs, consistent with a G protein-coupled receptor mechanism, probably GPER. This effect involves the modulation of ionic channels, such as K+, TRPV1 and Cl- channels. Furthermore, BPA is able to modulate calcium from intracellular storages by inhibiting SERCA and activating IP3 receptor/Ca2+ channels at the endoplasmic reticulum and activate kinase proteins, such as PKA and PKC. The rapid responses of BPA on calcium influx could, in turn, trigger a cross talk by MEK and p38MAPK activation and also mediate genomic responses. In the third line of work, the expression of some genes involved in 1,25-D3 and E2 metabolism and signalling were analysed in Leydig cells. 1,25-D3 decreased CYP27A1 gene expression, an effect that was also observed when cells were coincubated with 1,25-D3 and E2. E2 decreased ESR1 and CYP19 gene expression. Both hormones demonstrated an negative feedback mechanism over their on metabolism in these cells. Non-genomic effects were also studied in these cells, where E2 seems to have an inhibitory effect while 1,25-D3 was able to stimulate calcium influx. From these results we can conclude that 1,25-D3, E2 and BPA have important molecular effects in the male reproductive system, through gene expression control over receptors and enzymes involved in the metabolism of the steroid hormones studied. These results also reinforce the theory that there is a relationship between 1,25-D3 and E2 signalling pathways, as well as 1,25-D3, E2 and BPA also have non-genomic actions in calcium signalling. Testicules VDR PDIA3 CYP27A1 Calcium Vitamin D3 Estradiol Leydig cells Testis
6	Development of PDIA3 and VDR Knockout Human Osteosarcoma SaOs-2 Cells Using CRISPR-Cas9 Pyburn, Jaeden, Keasey, Matthew 15 May 2020 (has links) Intro: Hypovitaminosis D (vitamin D deficiency) has been observed in ageing patients with brain calcification and loss of the vitamin D receptor leads to abnormal calcification of the basal ganglia and thalamus. We have found that vitamin D can reverse calcification of human osteosarcoma SaOs-2 cells in vitro, in apparent contrast to its known effects of increasing bone strength in patients with Rickets and Osteomalacia. Vitamin-D functions through binding to two Vitamin-D responsive proteins; the vitamin D receptor (VDR) and Protein Disulfide isomerase A3 (PDIA3). The aim of this project was to establish VDR and PDIA3 knockout SaOs-2 cells using CRISPR-Cas9 technology. Methods: We designed guide RNA (gRNA) sequences against PDIA3 and VDR using ChopChop, selecting only gRNAs with low predicting non-specific binding probabilities. These gRNA sequences were ordered as oligonucleotides and dimerised before directional cloning into a Cas-9 plasmid. Plasmids were amplified in DH5 E. coli and purified before transfection into SaOs-2 cells together with a plasmid containing the puromycin resistance gene. Cells were treated with puromycin (1 ug/ml) for 4 days to eliminate non-transfected cells. SaOs-2 cells were maintained for 7 days before being passaged and plated for colony selection. Results: Real Time quantitative PCR showed 1 SaOs-2 clone had non-detectable levels of PDIA3 while 4 out of 6 clones had no detectable VDR mRNA relative to wild type cells. Two clones were selected for further analysis. Western blotting of these two clones probing for VDR and PDIA3 confirmed there were no detectable levels of these two proteins. Conclusion: We successfully knocked out expression of the Vitamin-D receptors VDR and PDIA3 in SaOS2 cells. These cells will be used for further study of Vitamin-D related signaling. PDIA3 calcification VDR vitamin-D Cell Biology Molecular Biology Plasmids Polymerase Chain Reaction
7	Vitamin D and its in vitro therapeutic action mediated through VDR rather than PDIA3 Pyburn, Jaeden 01 May 2022 (has links) Brain calcification is a common occurrence in the aging process, with >20% of individuals over the age of 65 showing hardened plaques in the basal ganglia. Loss of the vitamin D receptor (VDR) in transgenic mice leads to formation of calcified plaques in the basal ganglia and thalamus within the mice. Vitamin D signals through two known vitamin D responsive proteins, protein disulfide isomerase A3 (PDIA3) and VDR. In vitro, vitamin D has been demonstrated to suppress calcification in osteoblast-like cells. Here, we aim to elucidate which of either PDIA3 or VDR transduce vitamin D mediated suppression of calcification in vitro. PDIA3 or VDR were selectively knocked out in human osteosarcoma (SaOs) cells using CRISPR-Cas9 technology to generate PDIA3 KO or VDR KO cells. Knockout for PDIA3 or VDR was confirmed by RT-qPCR assay or western blot analysis. The calcification of SaOs-2 cells was induced with treatment of β-glycerophosphate along with ascorbic acid allowing for determination of whether loss of PDIA3 or VDR would lead to altered calcium deposition. Cells null for PDIA3 but not VDR grew at a significantly slower rate than wild-type (WT) cells. Intriguingly, PDIA3 and VDR KO cells displayed significantly more calcification relative to WT control cells. Calcitriol or the synthetic analogue EB1089 suppressed calcification in vitro in WT and PDIA3 KO but not VDR KO cells as measured by alizarin red staining. These data suggest VDR is critical for mediating vitamin D’s inhibition of calcification in vitro, and that PDIA3 has a role in suppressing calcification. This study provides novel insights into vitamin D signaling and provides a foundation for further study and understanding of vitamin D related pathologies. Vitamin D CRISPR-Cas9 calcification PDIA3 VDR Biochemistry Molecular and Cellular Neuroscience Molecular Biology

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