The vertebrate homologue of sulfide-quinone reductase in mammalian mitochondria.

Hydrogen sulfide (H2S) is the first inorganic compound identified as both a substrate for mitochondrial oxidative phosphorylation and a transmitter in mammalian cells. H2S seems to mediate effects that are correlated with those of nitric oxide (NO) by a reciprocal regulation. Moreover, H2S is consumed by mitochondrial oxidation mediated by sulfide-quinone reductase-like protein (SQRDL)-the vertebrate homolog of sulfide-quinone oxidoreductase (SQR). There is evidence that SQR plays an essential role in regulating H2S levels in fission yeast. To start understanding the role of SQRDL in the mammalian metabolism of H2S, we examine rat tissues. Our results show that SQRDL protein is present in all tissues tested, albeit restricted to specific mitochondrial populations at the cellular level. We demonstrate a developmental regulation of Sqrdl transcription in the kidney, where SQRDL protein is detectable in glomerular podocytes and in tubular cells of the renal medulla. We also show that Sqrdl transcription in T cells is responsive to external H2S. Taken together, our results suggest that Sqrdl transcription is adaptively regulated, probably to meet the need of H2S oxidation. Thus far, SQRDL has only been studied in a limited set of tissues. The present report demonstrates the presence and specific localization of SQRDL in various mammalian tissues.

The vertebrate homolog of sulfide-quinone reductase is expressed in mitochondria of neuronal tissues.

Hydrogen sulfide (H2S) can be consumed by both invertebrates and vertebrates as an inorganic substrate. The pathway metabolizing H2S probably involves three mitochondrial enzymes, one of which is sulfide-quinone oxidoreductase (SQR), known as sulfide-quinone reductase-like protein (SQRDL) in vertebrates. Evidence from fission yeast suggests that SQR might have a role in regulating sulfide levels in the cell. Regulation might be essential for H2S to act as a gaseous transmitter (gasotransmitter). The brain is an organ with high activity of gasotransmitters, like nitric oxide (NO) and H2S, which are known to affect synaptic transmission. In this study, we provide evidence that SQRDL is expressed in the mammalian brain. Real-time polymerase chain reaction (PCR) showed an increase in the number of Sqrdl transcripts in the brain with increasing age. Cellular fractionation and subsequent analysis by Western blotting indicated that the protein is located in mitochondria, which is the site of sulfide consumption in the cell. With an immunohistochemical approach, we demonstrated that the SQRDL protein is expressed in neurons, oligodendrocytes, and endothelial cells. Taken together, our data suggest that brain tissue harbors the machinery required for local regulation of sulfide levels.

PV-1 is a component of the fenestral and stomatal diaphragms in fenestrated endothelia.

PV-1 is a novel endothelial protein shown by immunocytochemical tests to be specifically associated with the stomatal diaphragms of caveolae in lung endothelium. Although the highest expression levels of both mRNA and protein are in the lung, PV-1 also has been found to be expressed in other organs. Using a specific antibody to the extracellular domain of PV-1, we have extended the survey on the presence of this protein at light and electron microscope level in several rat organs. Here we show that by immunofluorescence the antibody recognizes with high specificity the endothelium of the fenestrated peritubular capillaries of the kidney and those of the intestinal villi, pancreas, and adrenals. By immunolocalization at electron microscope level, the antibody recognizes specifically the diaphragms of the fenestrae and the stomatal diaphragms of caveolae and transendothelial channels in the endothelia of these vascular beds. No signal was detected in the continuous endothelium of the heart, skeletal muscle, intestinal muscularis, or brain capillaries or the nondiaphragmed fenestrated endothelium of kidney glomeruli. Taken together, our findings define the only antigen to be localized thus far in fenestral diaphragms. They also show that the stomatal diaphragms of caveolae and transendothelial channels and the fenestral diaphragms might be biochemically related, in addition to being morphologically similar structures.

Influence of host microvascular environment on tumour vascular endothelium.

This review will focus on the tumour microvascular endothelium; how it is derived, modulated by angiogenic factors, and how the structure and function is influenced by the host tissue microenvironment.

Tonic neurogenic inhibition of interleukin-6 secretion from murine spleen caused by opioidergic transmission.

The peripheral nervous system and the immune system were shown to have neurohumoral interactions. This study extends observations that demonstrated neuronal modulation of spontaneous interleukin-6 (IL-6) secretion in the spleen by norepinephrine (NE) and beta-endorphin. Spontaneous IL-6 secretion in vivo was markedly reduced by removal of macrophages with the clodronate technique. Furthermore, spontaneous IL-6 secretion was significantly inhibited at physiological concentrations of cortisol (10(-7) M). In the presence of 10(-7) M cortisol, addition of norepinephrine (NE; 10(-5) M) and isoproterenol (10(-6) and 10(-5) M) significantly increased spontaneous IL-6 secretion (+20%; P = 0.0280, P = 0.0005, and P = 0.0050, respectively). In contrast, addition of beta-endorphin significantly inhibited spontaneous IL-6 secretion in the presence of 10(-7) M cortisol (-40%; 10(-11) M, P = 0.0410; 10(-10) M, P = 0.0005). To study the effect of endogenously released transmitters on spontaneous IL-6 secretion, spleen slices were electrically stimulated with 1, 5, 10, 50, and 100 Hz. Spontaneous IL-6 secretion was markedly reduced at a frequency of 10 Hz with 10(-7) M cortisol present (P < 0.0001). This indicates that the combination of nerve firing at 5-10 Hz and physiological cortisol conditions inhibits spontaneous IL-6 secretion. Inhibition of spontaneous IL-6 secretion from spleen macrophages is most probably due to a net inhibitory effect of opioidergic transmission under these conditions.

Development of renal podocytes cultured under medium perifusion.

BACKGROUND: In the past, podocytes have been described as highly susceptible to dedifferentiation under cell culture. Whether this process resulted from insufficient culture conditions or whether it was a consequence of missing cellular interactions remained unclear. A further reason could be that podocytes within the maturing kidney are irreversibly growth-arrested at a very early point of development because proliferating cells have been detected at the S-shaped body stage but not at the capillary loop stage or in the maturing glomeruli. These were important reasons that hindered the establishment of podocyte cell culture systems. EXPERIMENTAL DESIGN: The aim of our present study was to culture podocytes under the most organotypic conditions possible to maintain typical cellular characteristics. Cortex explants of neonatal rabbit kidneys consisting of nephrogenic tissue were used as a source for podocytes. No serum additives were given for the whole culture period of 13 days. An organ-specific environment was obtained by keeping the podocytes within the surrounding renal tissue and by ensuring a permanent exchange of medium. RESULTS: mAb were used to characterize podocytes and the other glomerular cell types. Cultured podocytes and parietal cells of Bowman's capsule were identified by EnPo 1. Ks 19.2.105, a marker for cytokeratin 19, was used to discriminate among these epithelial cells because cytokeratin 19 is expressed by the parietal cells of Bowman's capsule but not by podocytes. The Ab EC1 specifically detected endothelial cells. Glomerular endothelium cultured under medium perifusion expressed these typical Ag and thus could be unequivocally discriminated. Furthermore, by means of the proliferation marker Ki-67, it could be demonstrated that glomerulus-like structures developed under culture by proliferation of visceral and parietal cells of Bowman's capsule. CONCLUSIONS: A culture model is presented that allows the maintenance of developing podocytes within the organ-specific tissue environment and under permanent medium perifusion.

Stimulation of renal microvascular development under organotypic culture conditions.

The development of the renal vascular system requires the coordinated action of soluble morphogenic factors and specific extracellular matrix components. Despite intensive research it remains unknown whether the humoral or the environmental component is more important in the development of renal microvessels. The prolonged serum-free culture of embryonic kidney cortex explants was achieved by means of a newly developed perfusion culture system. This system made the investigation of renal vascular development under defined organotypic conditions possible. Thus, growth factors such as vascular endothelial growth factor (VEGF), basic fibroblast growth factor (bFGF), and hormones (aldosterone, vitamin D3) could be applied without the interference with serum components. Medium supplementation with VEGF or aldosterone in combination with vitamin D3 resulted in the coordinated proliferation of endothelial cells in the explant. A well-developed collecting duct epithelium and numerous tubular structures were always observed. In contrast, only a uniform cell layer was found between fibrous organ capsule and the collecting duct epithelium after bFGF application, but neither tubular structures nor endothelial cells. Thus, the experiments indicate that bFGF alone has no stimulating effect on the growth of the renal microvasculature under perfusion culture conditions.

Developing renal microvasculature can be maintained under perfusion culture conditions.

The cortex corticis of the neonatal rabbit kidney consists of developing nephrons, vessels, collecting duct ampullae and the nephrogenic mesenchyme. Inductive interactions between embryonic mesenchyme and collecting duct ampullae lead to the coordinated development of the nephrons and the collecting duct system. The factors regulating nephrogenesis and vascular development within this tissue region are unknown. In order to analyze the hormonal regulation of vascular development an organotypic culture system was established. Cortex explants from neonatal rabbit kidneys were prepared, mounted in a set of holding rings and cultured under serum-free conditions for 14 days in conventional culture plates or under permanent medium perfusion in a newly developed culture container. The detection of endothelial cells was carried out by means of two monoclonal antibodies. Within the renal cortex corticis EnPo 1 detected developing vasculature as well as podocytes and a subset of mesenchymal cells. EC1 displayed exclusive specificity for endothelial cells. The antibody did not discriminate between arteries and veins. Endothelial cells of different developmental stages were labeled with the same intensity. A combination of both antibodies allowed the discrimination between developing endothelial cells and podocytes. Following 14 days of culture under permanent medium exchange, excellent tissue preservation as well as endothelial cell proliferation was observed in cortex explants. In contrast, tissue kept in stationary culture revealed a high degree of disintegration. Endothelial antigen expression was also severely disturbed. Tissue maintenance under stationary conditions was improved by the application of a hormone mixture consisting of aldosterone and 1,25-hydroxyvitamin D3. However, the high degree of spatial organization shown by developing endothelial cells in vivo was maintained exclusively in explants cultured in the presence of hormone under permanent perfusion.

Maturation of renal collecting duct cells in vivo and under perifusion culture.

The embryonic collecting duct epithelium of neonatal kidney undergoes profound functional changes during maturation. In its initial state as inductor epithelium it appears homogeneous, but differentiates into a heterogeneously composed collecting duct epithelium consisting of principal and intercalated cells. The mechanism of this terminal differentiation process is unknown. We used morphological and immunohistochemical methods to investigate the maturation of the collecting duct system in neonatal rabbit kidney and under organotypic culture conditions. The new perifusion culturing method allowed us to follow the differentiation of the ampullary collecting duct epithelium under conditions as close as possible to the situation within the organ. With this technique we were able to induce a differentiation process similar to that in the in situ situation. This process led to the appearance of a mixed cell population consisting of principal and intercalated-like cells, respectively. A continuous perifusion of the medium made it possible to stabilize the microenvironment under culture conditions and thus to maintain the heterogeneous composed collecting duct epithelium in a differentiated status over long periods of time.

Aldosterone modulates PNA binding cell isoforms within renal collecting duct epithelium.

To investigate the differentiation of the ampullary collecting duct cells into adult principal and intercalated cells, the embryonic cortex of newborn New Zealand rabbit kidney was isolated and brought in culture. With this culture technique the ampullary cells formed a polarized collecting duct epithelium which was kept under permanent exchange of medium and in the presence of aldosterone, arginine vasopressin and/or insulin. After 14 days of perfusion culture the epithelia showed light and dark cells resembling the principal and intercalated cells of the adult collecting duct. The differentiation from embryonic into adult collecting duct cells was controlled by applying the monoclonal antibody CD 7. Independent of the hormonal treatment all of the epithelial cells matured in culture and expressed the CD 7 antigen. This corresponded with the situation found within the adult kidney, where the CD 7 antigen was localized in all principal and intercalated (IC) cells, whereas the embryonic ampullary epithelium in the neonatal kidney remained negative. A differentiation feature of the beta-type intercalated cell was investigated by labeling the cultured epithelia with peanut agglutinin (PNA). In contrast to the CD 7 antigen the development of PNA binding was highly dependent of time and individual hormone administration. While in control epithelia only 8% of PNA positive cells were found, aldosterone induced epithelia revealed 72% PNA labeled cells. The combination of aldosterone and insulin increased the number of PNA-positive cells to 90%. By scanning electron microscopy it could further be shown that several isoforms of cells were reactive with PNA. Thus, in culture the PNA label is not restricted to the typical beta-type IC cells.