Investigating and correlating photoelectrochemical, photocatalytic, and antimicrobial properties of [Formula: see text] nanolayers.

Semiconducting transition metal oxides such as [Formula: see text] are promising photo(electro)catalysts for solar water splitting and photoreduction of [Formula: see text] as well as for antibacterial, self-, water and air-cleaning coatings and admixtures in paints, building materials, on window glass or medical devices. In photoelectrocatalytic applications [Formula: see text] is usually used as photoanode only catalyzing the oxidation reaction. In coatings and admixtures [Formula: see text] works as heterogeneous catalyst and has to catalyze a complete redox cycle. While photoelectrochemical charge transport parameters are usually quite well accessible by electrochemical measurements, the quantitative description of photocatalytic properties is more challenging. Here, we present a systematic structural, photoelectrocatalytic, photocatalytic and antimicrobial study to understand if and how photoelectrochemical parameters can be used to predict the photocatalytic activity of [Formula: see text]. For this purpose [Formula: see text] thin films on flourine-doped tin oxide substrates were prepared and annealed at temperatures between 200 and 600 [Formula: see text]. The film morphologies and thicknesses were studied by GIXRD, FESEM, and EDX. Photoelectrochemical properties were measured by linear sweep voltammetry, photoelectrochemical impedance spectroscopy, chopped light chronoamperometry, and intensity modulated photocurrent/ photovoltage spectroscopy. For comparison, photocatalytic rate constants were determined by methylene blue degradation and Escherichea coli inactivation and correlated with the deduced photoelectrocatalytic parameters. We found that the respective photoactivities of amorphous and crystalline [Formula: see text] nanolayers can be best correlated, if the extracted photoelectrochemical parameters such as charge transfer and recombination rates, charge transfer efficiencies and resistances are measured close to the open circuit potential (OCP). Hence, the interfacial charge transport parameters at the OCP can be indeed used as descriptors for predicting and understanding the photocatalytic activity of [Formula: see text] coatings.

Alterations in the expression, structure and function of progesterone receptor membrane component-1 (PGRMC1) in premature ovarian failure.

Premature ovarian failure (POF) is characterized by hypergonadotropic hypogonadism and amenorrhea before the age of 40. The condition has a heterogeneous background but genetic factors are demonstrated by the occurrence of familial cases. We identified a mother and daughter with POF both of whom carry an X;autosome translocation [t(X;11)(q24;q13)]. RNA expression studies of genes flanking the X-chromosome breakpoint revealed that both patients have reduced expression levels of the gene Progesterone Receptor Membrane Component-1 (PGRMC1). Mutation screening of 67 females with idiopathic POF identified a third patient with a missense mutation (H165R) located in the cytochrome b5 domain of PGRMC1. PGRMC1 mediates the anti-apoptotic action of progesterone in ovarian cells and it acts as a positive regulator of several cytochrome P450 (CYP)-catalyzed reactions. The CYPs are critical for intracellular sterol metabolism, including biosynthesis of steroid hormones. We show that the H165R mutation associated with POF abolishes the binding of cytochrome P450 7A1 (CYP7A1) to PGRMC1. In addition, the missense mutation attenuates PGRMC1's ability to mediate the anti-apoptotic action of progesterone in ovarian cells. These findings suggest that mutant or reduced levels of PGMRC1 may cause POF through impaired activation of the microsomal cytochrome P450 and increased apoptosis of ovarian cells.

Autoantibodies against the exocrine pancreas in autoimmune pancreatitis: gene and protein expression profiling and immunoassays identify pancreatic enzymes as a major target of the inflammatory process.

OBJECTIVES: Autoimmune pancreatitis (AIP) is thought to be an immune-mediated inflammatory process, directed against the epithelial components of the pancreas. The objective was to identify novel markers of disease and to unravel the pathogenesis of AIP. METHODS: To explore key targets of the inflammatory process, we analyzed the expression of proteins at the RNA and protein level using genomics and proteomics, immunohistochemistry, western blot, and immunoassay. An animal model of AIP with LP-BM5 murine leukemia virus-infected mice was studied in parallel. RNA microarrays of pancreatic tissue from 12 patients with AIP were compared with those of 8 patients with non-AIP chronic pancreatitis. RESULTS: Expression profiling showed 272 upregulated genes, including those encoding for immunoglobulins, chemokines and their receptors, and 86 downregulated genes, including those for pancreatic proteases such as three trypsinogen isoforms. Protein profiling showed that the expression of trypsinogens and other pancreatic enzymes was greatly reduced. Immunohistochemistry showed a near-loss of trypsin-positive acinar cells, which was also confirmed by western blotting. The serum of AIP patients contained high titers of autoantibodies against the trypsinogens PRSS1 and PRSS2 but not against PRSS3. In addition, there were autoantibodies against the trypsin inhibitor PSTI (the product of the SPINK1 gene). In the pancreas of AIP animals, we found similar protein patterns and a reduction in trypsinogen. CONCLUSIONS: These data indicate that the immune-mediated process characterizing AIP involves pancreatic acinar cells and their secretory enzymes such as trypsin isoforms. Demonstration of trypsinogen autoantibodies may be helpful for the diagnosis of AIP.

Classic versus non-classic receptors for nongenomic mineralocorticoid responses: emerging evidence.

Mineralocorticoids, which are synthesized locally in the central nervous system in addition to their adrenal production, trigger both genomic and nongenomic responses. Several functions of mineralocorticoids in the CNS are known to date, which are reviewed along with nongenomic responses in other tissues. A controversy regarding the identity of receptors that mediate nongenomic, transcription-independent cellular responses to steroids is presently attracting considerable scientific interest. While there is strong evidence for classic receptors belonging to the nuclear receptor superfamily to mediate nongenomic steroid effects in some cases, it does not exist for others. Recent findings on new and unexpected properties of classic receptors have partially withdrawn the interest from novel, non-classic membrane receptors, which are being progressively identified at present. This has been facilitated by the robust and elaborate toolkit for classic receptor studies in contrast to the comparably immature research tools for alternative receptors. To know the nature of receptors involved may be the key to beneficial medical translation of specific and targeted steroid responses.

Hypothermic injury: the mitochondrial calcium, ATP and ROS love-hate triangle out of balance.

BACKGROUND/AIMS: Catecholamines prevent hypothermic cell death which accounts for severe tissue damage and impaired allograft function after prolonged organ preservation. Here, we identified cellular processes which govern hypothermia-mediated cell death in endothelial cells and how they are influenced by dopamine. METHODS: Lactate dehydrogenase assay, intracellular ATP, reactive oxygen species and reduced thio-group measurement, intracellular calcium measurement and mitochondrial calcium staining were performed in the study. RESULTS: Intracellular ATP was almost completely depleted within 12 hrs of hypothermic preservation in untreated human umbilical vein endothelial cells (HUVEC), while dopamine pre-treatment significantly delayed ATP depletion. 4 hrs after hypothermia a redox imbalance was observed in untreated cells, which increased with the duration of hypothermia. The redox imbalance was primarily caused by depletion of SH reduction equivalents and was significantly inhibited by dopamine. In addition, hypothermia-induced Ca(2+) influx and mitochondrial Ca(2+) accumulation were both prevented by dopamine. The protective effect of dopamine was abrogated by ionomycin and sodium azide and partly by oligomycin and CCCP. CONCLUSIONS: Our data demonstrated that loss of intracellular ATP, generation of a redox imbalance and accumulation of intracellular Ca(2+) underlie cold preservation injury. Dopamine improves the redox balance, prevents intracellular Ca(2+) accumulation and delays ATP depletion.

Expression of progesterone receptor membrane component 1 and its partner serpine 1 mRNA binding protein in uterine and placental tissues of the mouse and human.

Although activation of the nuclear progesterone (P(4)) receptor (PGR) is required for uterine function, some of the actions of P(4) are mediated through a PGR-independent mechanism. The receptors that account for the PGR-independent actions have not been identified with certainty. The purpose of this study was to assess the expression, localization and hormonal regulation of two novel P(4) receptor candidates, P(4) receptor membrane component (PGRMC) 1 and PGRMC2, as well as the PGRMC1 partner Serpine 1 mRNA binding protein (SERBP1). Unlike Pgrmc1 and Serbp1, which remained unchanged throughout the estrous cycle, Pgrmc2 was highly up-regulated during proestrus and metestrus. Immunohistochemical analyses suggest that PGRMC1 and SERBP1 promote differentiation, since the expression of these proteins increased in endometrial cells undergoing steroid-depended terminal differentiation. Progesterone rather than estrogen appears to be primarily responsible for up-regulating the expression of PGRMCs. PGRMC1 and SERBP1 also showed overlapping patterns of expression in the human placenta and associated membranes with the most abundant expression in smooth muscle of the placental vasculature, villous capillaries and the syncytiotrophoblast. Based on these findings, it is proposed that PGRMC1:SERBP1 protein complex functions in events important to early pregnancy including cellular differentiation, modulation of apoptosis and steroidogenesis. These studies provide a platform from which to build a clearer understanding of P(4) actions in the female reproductive tract and placental tissues that are mediated by non-classical mechanisms.

Progesterone receptor membrane component 1--many tasks for a versatile protein.

The protein now called Progesterone Receptor Membrane Component 1 (PGRMC1) has been described independently by many groups in different cellular contexts. As a result it has been given an impressive diversity of names. While this protein was initially described on the basis of a singular property, e.g. expression or steroid binding, its possible physiological roles have only recently been reported. Current evidence supports the perception that PGRMC1 may be involved in sterol metabolism or homeostasis and cell survival. Here, we summarize a few sometimes neglected pieces of evidence from the literature along with unpublished findings on the properties and functions of PGRMC1.

To be or not to be (a receptor).

In addition to cellular responses that are elicited by steroids involving the modulation of transcription in the nucleus, it is now generally accepted that additional phenomena occur that do not depend on the genome. However, there is a puzzling variety of candidate receptors described in the literature.

Human homologs of the putative G protein-coupled membrane progestin receptors (mPRalpha, beta, and gamma) localize to the endoplasmic reticulum and are not activated by progesterone.

The steroid hormone progesterone exerts pleiotrophic functions in many cell types. Although progesterone controls transcriptional activation through binding to its nuclear receptors, it also initiates rapid nongenomic signaling events. Recently, three putative membrane progestin receptors (mPRalpha, beta, and gamma) with structural similarity to G protein-coupled receptors have been identified. These mPR isoforms are expressed in a tissue-specific manner and belong to the larger, highly conserved family of progestin and adiponectin receptors found in plants, eubacteria, and eukaryotes. The fish mPRalpha has been reported to mediate progesterone-dependent MAPK activation and inhibition of cAMP production through coupling to an inhibitory G protein. To functionally characterize the human homologs, we established human embryonic kidney 293 and MDA-MB-231 cell lines that stably express human mPRalpha, beta, or gamma. For comparison, we also established cell lines expressing the mPRalpha cloned from the spotted seatrout (Cynoscion nebulosus) and Japanese pufferfish (Takifugu rubripes). Surprisingly, we found no evidence that human or fish mPRs regulate cAMP production or MAPK (ERK1/2 or p38) activation upon progesterone stimulation. Furthermore, the mPRs did not couple to a highly promiscuous G protein subunit, Galpha(q5i), in transfection studies or provoke Ca(2+) mobilization in response to progesterone. Finally, we demonstrate that transfected mPRs, as well as endogenous human mPRalpha, localize to the endoplasmic reticulum, and that their expression does not lead to increased progestin binding either in membrane preparations or in intact cells. Our results therefore do not support the concept that mPRs are plasma membrane receptors involved in transducing nongenomic progesterone actions.

Progesterone membrane receptor component 1 expression in the immature rat ovary and its role in mediating progesterone's antiapoptotic action.

Progesterone receptor membrane component-1 (PGRMC1) interacts with plasminogen activator inhibitor RNA binding protein-1 (PAIRBP1), a membrane-associated protein involved in the antiapoptotic action of progesterone (P4). In this paper, the first studies were designed to assess the ovarian expression pattern of PGRMC1 and PAIRBP1. Western blot analysis revealed that spontaneously immortalized granulosa cells (SIGCs) as well as granulosa and luteal cells express both proteins. Luteal cells were shown to express more PGRMC1 than granulosa cells. Immunohistochemical studies confirmed this and demonstrated that PGRMC1 was present in thecal/stromal cells, ovarian surface epithelial cells, and oocytes. PAIRBP1 was also expressed in thecal/stromal cells and ovarian surface epithelial cells but not oocytes. Furthermore, PAIRBP1 and PGRMC1 were detected among the biotinylated surface proteins that were isolated by avidin affinity purification, indicating that they localized to the extracellular surface of the plasma membrane. Confocal microscopy revealed that both of these proteins colocalize to the plasma membrane as well as the cytoplasm. The second studies were designed to assess PGRMC1's role in P4's antiapoptotic actions. These studies showed that overexpression of PGRMC1 increased 3H-P4 binding and P4 responsiveness. Conversely, treatment with a PGRMC1 antibody blocked P4's antiapoptotic action. Taken together, the present findings indicate that both PAIRBP1 and PGRMC1 show a similar expression pattern within the ovary and colocalize to the extracellular surface of the plasma membrane. At the plasma membrane, these two proteins interact to form a complex that is required for P4 to transduce its antiapoptotic action.

Progesterone regulation of human granulosa/luteal cell viability by an RU486-independent mechanism.

CONTEXT: Progesterone (P4) inhibits human granulosa/luteal cell apoptosis by an unknown mechanism. OBJECTIVE: Our objective was to assess the role of the nuclear P4 receptor (PGR) and PGR membrane component 1 (PGRMC1) in mediating P4's antiapoptotic action in human granulosa/luteal cells. DESIGN, SETTING, AND PATIENTS: In vitro laboratory studies were designed in which human granulosa/luteal cells were harvested from in vitro fertilization patients from 2004-2006. MAIN OUTCOME MEASURE: Apoptosis was assessed by terminal deoxynucleotidyl transferase-mediated dUTP-biotin nick end-labeling assays and DNA staining. Protein expression was observed by Western blot and immunocytochemistry. RESULTS: PGR was detected in 20% of the human granulosa/luteal cells, and 25 and 50 microM RU486 induced at least 70% of the cells to undergo apoptosis. Five micromolar RU486 neither induced apoptosis nor attenuated the antiapoptotic action of 1 microM P4. PGRMC1 and its binding partner, plasminogen activator inhibitor RNA-binding protein-1 (PAIRBP1), were detected in human granulosa/luteal cells. Antibodies to either PGRMC1 or PAIRBP1 completely attenuated P4's action. CONCLUSIONS: PGR does not exclusively mediate P4's action because 1) 5 microM RU486 should have been able to override the antiapoptotic action of 1 microM P4 because RU486 binds to the PGR at a greater affinity than P4; 2) 25 and 50 microM RU486 induce three to four times more cells to undergo apoptosis than express PGR; 3) P4 must be continuously present to prevent apoptosis, which implies a rapid, possibly membrane-initiated mechanism of action; and 4) expression and blocking antibody studies suggest that PGRMC1 and PAIRBP1 account in part for P4's action in human granulosa/luteal cells.

Non-genomic steroid hormone effects: membrane or intracellular receptors?

A controversy regarding the identity of receptors that mediate nongenomic, transcription-independent cellular responses to steroids is presently attracting considerable scientific interest. While there is strong evidence for classic receptors belonging to the nuclear receptor superfamily to mediate nongenomic steroid effects in some cases, it does not exist for others. Nongenomic estrogen effects seem to predominantly involve classical estrogen receptors, both residing in cytoplasm and at the cell membrane. On the other hand, there is increasing evidence for the existence of nonrelated membrane receptors for estrogens, mediating CNS effects. Novel membrane receptors for other steroids have been recently cloned, with the demonstration of their biological relevance still largely pending. Recent findings on new and unexpected properties of classic receptors have partially deflected the interest from novel, nonclassic membrane receptors, which are being progressively identified at present. In addition, new findings pose challenges to some of the conclusions drawn from earlier experiments, and potential involvement of receptors and mechanisms of action need to be reconsidered. To know the nature of receptors involved will be key to beneficial medical translation of specific and targeted steroid responses. Differential pharmacological exploitation of different steroid receptors seems to become a tangible option.

Nongenomic actions of estrogens: exciting opportunities for pharmacology.

Estrogens, like other steroids, elicit a variety of rapid effects in many tissues in addition to their delayed action on gene expression in the cell nucleus. The rapid responses occur without participation of the genome, and are therefore termed nongenomic. Some of the estrogen induced effects acutely modulate vascular function and may contribute to the gender difference in cardiovascular susceptibility. While some actions may be mediated by novel, nonclassic receptors, the classic estrogen receptor has been shown to also act on signalling cascades. There are sparse examples for compounds structurally related to the endogenous hormone estradiol that bind to the estrogen receptor but may selectively elicit nongenomic responses. The further development of such selectively acting drugs holds much promise for better therapies with fewer side effects, e.g. for vascular malfunction, but also for estrogen-dependent cancer.

Porcine spermatozoa contain more than one membrane progesterone receptor.

Progesterone has been shown to be a physiologically relevant inducer of the sperm acrosome reaction. A novel protein intrinsic to microsomal membranes, membrane progesterone receptor (mPR, now termed progesterone membrane receptor component 1, PGMRC1) that binds progesterone with high affinity has been cloned from porcine liver previously, and corresponding antibodies mitigate the progesterone induced acrosome reaction. In this study we aimed at the localization of mPR in porcine spermatozoa. Immunostaining suggested the exclusive occurrence of mPR in a hardly accessible place, possibly the inner acrosomal membrane, with digitonin dramatically increasing the number of positively stained cells. Consistent with the structure prediction for mPR, its short N-terminus (NT) but not the large C-terminal part becomes accessible from outside after digitonin treatment as evidenced by the staining pattern of antibodies directed against different regions of the protein. However, digitonin treatment solubilizes a progesterone binding activity of approximately 140 kDa molecular weight, that is different from mPR, which remains in the cell membrane as demonstrated by Western blotting. Ligand binding studies confirm the dissimilarity of mPR and the digitonin-soluble progesterone binding protein. Chemical modification studies also indicate that the digitonin-soluble progesterone binding protein has a binding site that differs from that of mPR. It is concluded that more than one progesterone receptor is present in porcine spermatozoa.

Aldosterone rapidly activates Src kinase in M-1 cells involving the mineralocorticoid receptor and HSP84.

We investigated the effect of aldosterone on Src kinase. In the kidney cell line, M-1 aldosterone leads to a >2-fold transient activation of Src kinase seen as early as 2 min after aldosterone administration. Maximal Src kinase activation was measured at an aldosterone concentration of 1 nM. In parallel to activation, autophosphorylation at Tyr-416 of Src kinase increased. Src kinase activation was blocked by spironolactone. Aldosterone led to increased association of Src with HSP84. Furthermore, rapamycin blocked aldosterone-induced Src activation. We conclude that Src activation by aldosterone is mediated through the mineralocorticoid receptor and HSP84.

A quick glance at rapid aldosterone action.

Not all of the actions of aldosterone are mediated by the classic genomic pathway involving transcription and translation. Non-genomic or non-classical rapid responses that do not require these steps have been known for some time, but have only attracted significant interest in the last decade. At the cellular level, second messengers and kinase cascades are commonly involved. Most of these non-classical effects are insensitive to inhibitors of the classical cytosolic mineralocorticoid receptor. Non-genomic aldosterone action has been observed in clinical studies particularly in the cardiovascular system, and further research may improve the understanding of their participation in the pathogenesis of aldosterone related diseases and eventually enhance the options for therapy.

Non-genomic aldosterone action: from the cell membrane to human physiology.

According to the traditional model, steroid hormones bind to intracellular receptors and subsequently modulate transcription and protein synthesis, thus triggering genomic events finally responsible for delayed effects. In addition, very rapid effects of steroids mainly affecting intracellular signaling have been widely recognized which are clearly incompatible with the genomic model. These rapid, non-genomic steroid actions are likely to be transmitted via specific membrane receptors. Evidences for non-genomic steroid effects and distinct receptors involved are now presented for all steroid groups including vitamin D(3) and thyroid hormones. Mechanisms of action are being studied with regard to signal perception and transduction involved, and for various steroids including aldosterone a patchy sketch of a membrane receptor/second messenger cascade shows up being not essentially dissimilar to cascades involved in catecholamine or peptide hormone action. Aside non-classical membrane receptors with a high affinity for aldosterone, these effects involve phospholipase C, phosphoinositide turnover, intracellular pH and calcium, protein kinase C and tyrosine kinases. Increasing evidence is being accumulated for rapid physiological responses in humans, e.g. at the level of circulatory or metabolic effects, rendering clinical significance to these rapid actions.

Rapid effects of aldosterone on vascular cells: clinical implications.

Aldosterone has attracted considerable interest as an independent cardiovascular risk marker, which has been demonstrated in a number of studies. Furthermore, recent studies revealed the prevalence of hyperaldosteronism to be about tenfold higher than previously assumed, which underlines its clinical importance. Aldosterone affects virtually any part of the cardiovascular system, namely cardiac fibroblasts and myocytes, and vascular endothelial and smooth muscle cells. In the latter cells, our laboratory has demonstrated a variety of rapid effects of the steroid, e.g. on intracellular calcium, inositol trisphosphate, and cAMP. There is also evidence for a modulation of genomic events by rapid aldosterone effects that occur via phosphorylation of transcription factors such as CREB. Furthermore, rapid tyrosine phosphorylation has been observed in vascular cells. The majority of rapid responses reported to date are insensitive towards the classic mineralocorticoid receptor (MR) antagonist, spironolactone. The in vitro experiments are complemented by a series of clinical studies in healthy volunteers, which could demonstrate rapid modulation of cardiovascular parameters after aldosterone administration, e.g. of systemic vascular resistance. In addition, an interaction of aldosterone with the adrenergic system has been observed. Most recently, rapid aldosterone induced contraction of resistance arteries has been reported. In general, the rapid in vivo effects of aldosterone are likely to participate in the pathogenesis of cardiovascular disorders. As many rapid and thus nonclassic aldosterone responses cannot be blocked by spironolactone, further research is required in order to provide adequate inhibitors to interfere with these pathways.

Nongenomic effects of aldosterone: cellular aspects and clinical implications.

Nongenomic action of aldosterone has been observed in many cell types which often are different from the classic target tissues for mineralocorticoid action, such as vascular cells. As judged from their time scale and insensitivity toward inhibitors of protein synthesis, effects are not mediated by the classic mineralocorticoid receptor pathway. Here we summarize studies on rapid in vitro aldosterone effects, e.g. ion fluxes, and second messengers involved therein. Furthermore, several clinical studies on in vivo aldosterone action have shown rapid effects on cardiovascular parameters, among them baroreflex and vascular resistance. Taken together with the beneficial effect of aldosterone antagonism in heart failure patients that was demonstrated in the Randomized Aldactone Evaluation Study (RALES), aldosterone may be an equally important factor of the renin-angiotensin-aldosterone system in cardiovascular pathogenesis.

N-octanoyl dopamine, a non-hemodyanic dopamine derivative, for cell protection during hypothermic organ preservation.

BACKGROUND: Although donor dopamine treatment reduces the requirement for post transplantation dialysis in renal transplant recipients, implementation of dopamine in donor management is hampered by its hemodynamic side-effects. Therefore novel dopamine derivatives lacking any hemodynamic actions and yet are more efficacious in protecting tissue from cold preservation injury are warranted. We hypothesized that variation of the molecular structure would yield more efficacious compounds avoid of any hemodynamic effects. METHODOLOGY/PRINCIPAL FINDINGS: To this end, we assessed protection against cold preservation injury in HUVEC by the attenuation of lactate dehydrogenase (LDH) release. Modification of dopamine by an alkanoyl group increased cellular uptake and significantly improved efficacy of protection. Further variation revealed that only compounds bearing two hydroxy groups in ortho or para position at the benzene nucleus, i.e. strong reductants, were protective. However, other reducing agents like N-acetyl cysteine and ascorbate, or NADPH oxidase inhibition did not prevent cellular injury following cold storage. Unlike dopamine, a prototypic novel compound caused no hemodynamic side-effects. CONCLUSIONS/SIGNIFICANCE: In conclusion, we demonstrate that protection against cold preservation injury by catecholamines is exclusively governed by strong reducing capacity and sufficient lipophilicity. The novel dopamine derivatives might be of clinical relevance in donor pre-conditioning as they are completely devoid of hemodynamic action, their increased cellular uptake would reduce time of treatment and therefore also may have a potential use for non-heart beating donors.