Differential regulation of the C3a and C5a receptors (CD88) by IFN-gamma and PMA in U937 cells and related myeloblastic cell lines

We have analyzed the induction of the receptor for the anaphylatoxic peptide C3a (C3aR) by the immunomodulator IFN-gamma, the phorbol ester PMA, and dibutyryl cAMP (Bt2cAMP) in comparison with the C5a receptor (C5aR, CD88). For U937 cells, IFN-gamma and Bt2cAMP up-regulated the C3aR to the same extent, whereas Bt2cAMP was 20-fold more effective in C5aR induction. PMA increased the expression of the C5aR, and acted synergistically with IFN-gamma. In contrast, PMA did not increase specific 125I-hC3a binding, and actually antagonized C3aR induction by IFN-gamma. Two related human cell lines of the myeloblastic/monocytic lineage, HL-60 and Mono Mac 6, showed inducibility of the C3aR similar to U937 cells. The two receptors showed subtle differences in signal transduction. Despite comparable numbers of both receptors, IFN-gamma potentiated activation of the C5aR but not the C3aR, as measured by an increase in free cytosolic Ca2+ upon ligand activation. Interestingly, Bt2cAMP-treatment led to a functional response to C3a in U937 cells. Such differences in receptor regulation and signaling might underlie the partly differing physiologic effects of C3a and C5a on, for example, chemotaxis, induction of oxidative burst, or immunoregulatory functions.

Genetic depletion of histamine from the nervous system of Drosophila eliminates specific visual and mechanosensory behavior

The role of histamine as a fast neurotransmitter of imaginal insect photoreceptors is firmly established. In adult Drosophila, histamine is also found in mechanosensory receptors of cuticular hair sensilla and in a small number of nonreceptor neurons in head and body ganglia. Here we investigate the function of histamine by immunohistochemical and behavioral analysis of mutants deficient in the hdc gene that codes for histidine decarboxylase. The allele hdcJK910 appears to be a null mutation, as histamine immunoreactivity is almost entirely eliminated. Homozygous flies are blind in various behavioral paradigms. Mutant larvae, on the other hand, show normal photokinetic responses. Thus, adult Drosophila photoreceptors most likely utilize only a single substance, histamine, as a neurotransmitter, whereas larval photoreceptors apparently employ a different transmitter. With the alleles hdcP211, hdcP217, and hdcP218, variable amounts of histamine are found in photoreceptors and mechanoreceptors, but no histamine could be detected in any of the nonreceptor neurons. These mutants show various degrees of visual and mechanosensory impairment, as determined by quantitative behavioral assays. We conclude that histamine is required for normal function of cuticular hair sensilla and for efficient grooming of the body surface. Thus, in Drosophila, histamine represents a major functional neurotransmitter for mechanosensory receptors.

Cytokines and glomerular injury

Since reports of the first data on cytokines in renal diseases about 10 years ago, the field has seen an explosive growth over the last decade. It is now realized that cytokines can be synthesized by many different types of cells, including glomerular cells, upon adequate stimulation and exert a wide range of actions mostly in an autocrine or paracrine fashion. Cytokines not only contribute to developmental processes, but also to the maintenance of normal tissue integrity and in particular to the initiation and modulation of tissue injury, healing, or scarring. This review summarizes some recent data on the role of cytokines in glomerular disease and describes some of the first experimental approaches to therapeutically interfere with cytokine actions.

G alpha-16 complements the signal transduction cascade of chemotactic receptors for complement factor C5a (C5a-R) and N-formylated peptides (fMLF-R) in Xenopus laevis oocytes: G alpha-16 couples to chemotactic receptors in Xenopus oocytes

The human leukocyte chemoattractant receptors for complement factor C5a (C5a-R) and N-formylated peptides (fMLF-R) are important members of the superfamily of G-protein coupled receptors (GPCR). Uniquely among the GPCR, these two receptors cannot be expressed in a functionally active form in the oocytes of the frog Xenopus laevis, but require substitution of total RNA of the myelomonocytic U-937 or HL-60 cell lines, respectively. Recently, it was reported that the C5a-R may couple to the alpha subunit of G-16. We have tested this G-protein for its ability to complement the signal transduction cascade of the C5a-R and fMLF-R in Xenopus oocytes. Injection of cRNA for the C5a-R in combination with G alpha-16 led to expression of a functional C5a-R as measured by ligand-induced whole cell current. In contrast to a previous report, the fMLF-R exhibited some residual functional activity when transiently expressed in Xenopus oocytes the extent of which could, however, substantially be increased by coexpression of G alpha-16. Thus, G alpha-16 complements the signal transduction cascade of both receptors in Xenopus laevis oocytes and is most likely the complementing factor present in the U-937 and HL-60 cell lines.

IFN-gamma up-regulates the human C5a receptor (CD88) in myeloblastic U937 cells and related cell lines

On human mature monocytes the immunomodulator IFN-gamma has been shown to down-regulate the receptor for the anaphylatoxic peptide C5a (CD88, C5aR). In this study, we show that in immature myelo-/monoblastic U937, HL60, and MonoMac6 cells, IFN-gamma induces C5aR-ligand binding activity. In U937 cells, this induction cannot be blocked by the protein kinase C inhibitor staurosporine. An increase in free cytosolic Ca2+ upon ligand binding indicates functional coupling of this receptor in U937 and HL-60 cells. G-Proteins involved in this C5a responsiveness after IFN-gamma induction are completely pertussis toxin sensitive. Our data suggest that an additional pertussis toxin-resistant pathway exists in U937 cells after induction by dibutyryl cAMP. However, this is not due to changes in the mRNA level of the pertussis toxin-insensitive G-protein subunit G alpha 16. Induction by dibutyryl cAMP, but not that by IFN-gamma, resulted in C5a-dependent release of N-acetyl-beta-D-glucosaminidase, further highlighting functional differences in the effects of the inducers. Our data show an IFN-gamma-dependent increase in C5aR expression and suggest a maturation-related change in signaling of the C5aR, presumably at the level of receptor coupling.

IFN-gamma up-regulates the human C5a receptor (CD88) in myeloblastic U937 cells and related cell lines

On human mature monocytes the immunomodulator IFN-gamma has been shown to down-regulate the receptor for the anaphylatoxic peptide C5a (CD88, C5aR). In this study, we show that in immature myelo-/monoblastic U937, HL60, and MonoMac6 cells, IFN-gamma induces C5aR-ligand binding activity. In U937 cells, this induction cannot be blocked by the protein kinase C inhibitor staurosporine. An increase in free cytosolic Ca2+ upon ligand binding indicates functional coupling of this receptor in U937 and HL-60 cells. G-Proteins involved in this C5a responsiveness after IFN-gamma induction are completely pertussis toxin sensitive. Our data suggest that an additional pertussis toxin-resistant pathway exists in U937 cells after induction by dibutyryl cAMP. However, this is not due to changes in the mRNA level of the pertussis toxin-insensitive G-protein subunit G alpha 16. Induction by dibutyryl cAMP, but not that by IFN-gamma, resulted in C5a-dependent release of N-acetyl-beta-D-glucosaminidase, further highlighting functional differences in the effects of the inducers. Our data show an IFN-gamma-dependent increase in C5aR expression and suggest a maturation-related change in signaling of the C5aR, presumably at the level of receptor coupling.

Prognostic implications of mental stress-induced silent left ventricular dysfunction in patients with stable angina pectoris

Thirty patients with stable angina pectoris and ischemia on stress perfusion imaging underwent continuous ambulatory left ventricular (LV) function monitoring. Mental stress was induced by mental arithmetic. Fifteen patients developed transient LV dysfunction during mental arithmetic. Patients were followed for 2 years for adverse cardiac events. Twelve patients had cardiac events over 1 year (myocardial infarction in 4, and unstable angina in 8). Nine of 15 patients (60%) with and only 3 of 15 (20%) without mental stress-induced LV dysfunction developed cardiac events (p = 0.025). A higher proportion of patients with cardiac events were taking beta blockers (p = 0.01) and had lower resting heart rates (p = 0.002) than those without cardiac events. There was no difference in the baseline characteristics between the groups of patients with and without cardiac events. At 2-year follow-up, 10 of 15 patients (67%) with mental stress-induced LV dysfunction had adverse events compared with only 4 of 15 (27%) with no mental stress-induced LV dysfunction (p = 0.025). Thus, in this cohort of patients with stable angina pectoris, mental stress-induced LV dysfunction was associated with higher cardiac events on follow-up. The exact mechanism of this association is not clear. Mental stress may be a trigger for adverse cardiac events in these patients. Transient LV dysfunction in response to mental stress may be a marker of abnormal cardiovascular reactivity to emotional and psychological stimuli in patients with coronary artery disease and may be useful for risk stratification.

Molecular characterization of two Drosophila guanylate cyclases expressed in the nervous system

We have isolated, by interspecies hybridization, two classes of Drosophila cDNA each encoding a different guanylate cyclase (GC). One of them encodes an alpha subunit homolog of soluble GC, designated DGC alpha 1, and the other encodes a receptor-type GC, designated DrGC. The dgc alpha 1 cDNA encodes a protein of 676 amino acids and maps to 99B. In situ hybridization to adult tissue sections showed that dgc alpha 1 mRNA is found mainly in the cell bodies of the optic lobe, central brain, and thoracic ganglia. The DGC alpha 1 protein was also localized primarily to the nervous system by immunocytochemical staining, consistent with results of in situ hybridization. However, no detectable expression of this protein was found in the retina. The other class of cDNA, drgc, maps to 76C and encodes a 1525-amino acid protein displaying structural features similar to other known receptor-type guanylate cyclases. However, it has a C-terminal 430 amino acid region that has no homology to any known proteins. drgc RNA is expressed at low levels throughout development and in adult heads and bodies. In situ hybridizations to adult tissue sections showed that drgc mRNA is expressed in a wide range of tissues, including the optic lobe, central brain, thoracic ganglia, digestive tract, and the oocyte.

Intrathecal capsaicin enhances one-kidney renal wrap hypertension in the rat

Afferent renal nerves (ARN) have been implicated in the development of one-kidney renal wrap (1K-WRAP) hypertension. The role of renal nerves in desoxycorticosterone acetate-salt (DOCA) hypertension, a low-renin model of hypertension, is controversial. The present study was designed to determine if spinal substance P (SP) and/or calcitonin gene-related peptide (CGRP) in ARN affects the development of 1K-WRAP or DOCA hypertension in adult rats. Selective long-term partial depletion of spinal SP and CGRP within small primary afferent nerve fibers including unmyelinated ARN was achieved by intrathecal administration of capsaicin. After capsaicin treatment, 1K-WRAP hypertension was induced by removing the right kidney and wrapping the left kidney with a figure-8 ligature. In a second group of rats, DOCA hypertension was induced by subcutaneous application of desoxycorticosterone pellets after unilateral nephrectomy. Systolic arterial pressure was monitored for 8 weeks by tail cuff plethysmography after which direct blood pressure measurement was performed followed by immunohistochemistry. Intrathecal capsaicin administration had no significant effect on SP-ir and CGRP-ir of ARN soma located within thoracic dorsal root ganglia whereas immunoreactivity against these peptides was reduced by one third to one half in the dorsal horn, indicating effective long-term spinal depletion of these neuropeptides. Intrathecal capsaicin enhanced the development of 1K-WRAP hypertension, since arterial pressure was greater in the treated group. In contrast, DOCA hypertension was unaffected by capsaicin pretreatment. Considering the neurotoxic action of capsaicin for SP-ir and CGRP-ir unmyelinated primary afferent neurons, we hypothesize that spinal SP, CGRP and/or related peptides existing in ARN and other capsaicin-sensitive unmyelinated primary afferent neurons in the lower thoracic spinal cord may ameliorate 1K-WRAP hypertension, but not DOCA hypertension.

Effects of long duration space flight on rice seed (or embryo) radiation sensitivity and element microlocalizations

In long duration space experiments Rice caryopses and embryos, which are able to remain alive 10 years (or more) and tolerate extreme physical conditions (temperature, few water content) during irradiation and post-irradiation storage, were used (8, 40, 201 and 457 days on board of Salyut 7, 2107 days on LDEF). In certain experiments (Salyut 7), samples were irradiated either before or after the flight. Effects of the flight and radiosensitivity were observed in Rice seedlings cultivated in in vitro conditions. Statistical results indicate an increase in radiosensitivity when irradiations occur before the flight. Microanalyses were made in different parts of one caryopsis and of one embryo, and the results compared with those of control samples. With caryopses and embryos of the same Rice varieties, but from LDEF, we made the same kinds of experiments to compare results.

Immunocytochemical co-localization of substance P and calcitonin gene-related peptide in afferent renal nerve soma of the rat

Substance P, calcitonin gene-related peptide and somatostatin immunoreactivities have been demonstrated in putative afferent renal nerve fibers in the rat. Utilizing retrograde-tracing and immunohistochemistry, we labeled afferent renal nerve soma throughout dorsal root ganglia T9 to L1. Most (85%) of afferent renal nerve perikarya were immunoreactive for calcitonin gene-related peptide, 21% had substance P immunoreactivity and none had somatostatin immunoreactivity. All renal afferents immunoreactive for substance P also contained calcitonin gene-related peptide. These results provide evidence that calcitonin gene-related peptide and substance P are present and co-localized in afferent renal nerves, and therefore, mediate transmission of afferent renal input to the spinal cord in the rat.

Amino acids 327-350 of the human C5a-receptor are not essential for [125I]C5a binding in COS cells and signal transduction in Xenopus oocytes

The anaphylatoxic peptide C5a is an important inflammatory mediator of the complement system. We have generated human C5a-receptor (hC5aR) mutants with truncation of its cytosolic carboxyl-terminus (C-terminus). Both mutants were analysed for C5a-binding in transiently expressing COS cells, and one mutant additionally for GTP-binding regulatory protein (G-protein) coupling in cRNA-injected Xenopus oocytes. Our data suggest that (a) amino acids (aa) 314 to 326 as part of the C-terminus are necessary for proper receptor folding or expression and (b) the receptor C-terminus distal from position 327 is not critical for receptor expression, folding, binding and G-protein coupling.

The competitive NMDA antagonist CPP protects substantia nigra neurons from MPTP-induced degeneration in primates

Degeneration of nigrostriatal dopaminergic neurons is the primary histopathological feature of Parkinson's disease. The neurotoxin MPTP (1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine) induces a neurological syndrome in man and non-human primates very similar to idiopathic Parkinson's disease by selectively destroying dopaminergic nigrostriatal neurons. This gives rise to the hypothesis that Parkinson's disease may be caused by endogenous or environmental toxins. Endogenous excitatory amino acids (EAAs) such as L-glutamate could be involved in neurodegenerative disorders including Parkinson's disease. We report in this study that the competitive NMDA antagonist CPP (3-((+/-)-2-carboxypiperazin-4-yl)-propyl-1-phosphonic acid) protects nigral tyrosine hydroxylase (TH) positive neurons from degeneration induced by systemic treatment with MPTP in common marmosets. This indicates that EAAs are involved in the pathophysiological cascade of MPTP-induced neuronal cell death and that EAA antagonists may offer a neuroprotective therapy for Parkinson's disease.

C3a receptor on dibutyryl-cAMP-differentiated U937 cells and human neutrophils: the human C3a receptor characterized by functional responses and 125I-C3a binding

The anaphylatoxic peptide C3a is part of a basic immunological defense mechanism, the complement system. Research on the human C3a receptor and signal transduction is hampered by the lack of a suitable human cell or cell line. We screened tumor cell lines and human blood cells for a C3a-dependent increase in cytosolic Ca2+ ([Ca2+]i) and analyzed this reaction in a fura-2/AM fluorescence assay for cells in suspension. U937 cells, when differentiated with dibutyryl-cAMP (Bt2cAMP), and purified human neutrophils reacted in a dose-dependent fashion to C3a and a C3a analogue synthetic peptide. We found complete homologous desensitization of this response and no heterologous desensitization to human C5a. Pertussis toxin totally blocked the increase in [Ca2+]i, indicating the possible involvement of a G-protein. Single-cell analysis by digital imaging fluorescence microscopy indicated that neutrophilic granulocytes responded to C3a. In binding studies with Bt2cAMP-differentiated U937 cells and human granulocytes, the 125I-C3a binding was displaced by C3a, yielding one class of C3a binding sites with dissociation constants (Kd) in the low nanomolar range. We identified myo-inositol 1,4,5-trisphosphate (IP3) as the second messenger possibly causing the [Ca2+]i increase and the release of N-acetyl-beta-D-glucosaminidase as one secretory cell response. By functional and binding studies we demonstrated the expression of the C3a receptor on Bt2-cAMP-differentiated U937 cells and human neutrophils and characterized parts of the C3a signal pathway. Our data support a physiological concept in which C3a might be more important than presently thought.

Do NMDA receptor antagonists protect against MPTP-toxicity? Biochemical and immunocytochemical analyses in black mice

We investigated whether excitatory amino acids acting at the N-methyl-D-aspartate (NMDA) subtype of the L-glutamate receptor contribute to the dopaminergic neurotoxicity induced by systemic administration of the Parkinson's syndrome-inducing toxin 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP) in C57Bl/6 mice. The MPTP-regimen chosen (30-40 mg/kg body weight subcutaneously) resulted a 60-70% depletion of striatal dopamine (DA) content and a 20% reduction of tyrosine hydroxylase immunoreactive (TH-IR) cells in the substantia nigra pars compacta 20 days after administration. Repeated systemic coadministration of the non-competitive NMDA receptor antagonist MK-801 or of the novel competitive NMDA receptor antagonist CGP 40116 did not protect against MPTP-induced striatal DA depletion 20 days after toxin administration. Additionally, no short-term protective effects of MK-801 on striatal DA content were observed 24, 48, and 96 h, respectively, after exposure to MPTP. A slight and non-significant attenuation (approximately 10%) of the MPTP-induced decrease in the number of nigral TH-IR cells was observed after MK-801- and CGP 40116-treatment. We conclude that neurotoxicity of systemically administered MPTP is not substantially antagonized by NMDA receptor antagonists in mice.

Characterization of cell-associated proteoglycans synthesized by embryonic neural retinal cells

To begin to understand the properties of the neuronal heparan sulfate proteoglycan (HSPG) that interacts with the neural cell adhesion molecule (NCAM), we have analyzed proteoglycans synthesized by dissociated embryonic retinal cells in culture. Because NCAM plays an integral role in cell-cell interactions, we have focused on cell-associated HSPGs. Proteoglycans were isolated from embryonic Day 10 retinal cell cultures labeled with 35SO4 and separated into fractions that either flowed through or were retained on phenyl-Sepharose. Molecules binding phenyl-Sepharose have been proposed to be capable of insertion into the plasma membrane, and thus may be involved in binding to NCAM. Proteoglycans binding to phenyl-Sepharose had an estimated molecular mass of 400-500 kDa, and contained 60% HSPG and 40% chondroitin sulfate proteoglycan (CSPG). The putative membrane-associated HSPGs, with an average molecular weight of 360 kDa, were shown to contain heparan sulfate chains of 40 and 20 kDa, and multiple core proteins with the major core protein having a molecular weight of approximately 130 kDa. The membrane-associated CSPGs also exhibited multiple core proteins, with sizes ranging from 120 to 220 kDa. These data suggest that multiple membrane-associated HSPGs and CSPGs are synthesized by embryonic neural retina cells, which may explain the diversity in function of this class of proteoglycans.

Characterization of a heparan sulfate proteoglycan that copurifies with the neural cell adhesion molecule

We have demonstrated previously that the neural cell adhesion molecule (NCAM) interacts with a neuronal heparan sulfate proteoglycan. The binding of this proteoglycan(s) by NCAM appears to be required for NCAM-mediated cell adhesion, although the mechanism is unclear. In the present study we show that a heparan sulfate proteoglycan copurifies with NCAM, and provide an initial biochemical characterization of the proteoglycan. The copurification of a heparan sulfate proteoglycan with NCAM was demonstrated following immunopurification of NCAM from a detergent extract of cell membranes derived from Na2(35)SO4-labeled neural retinal cells. A large-molecular-weight, 35SO4-labeled molecule copurified with NCAM isolated from these neural cell cultures, and was resistant to chondroitinase ABC treatment, but degraded completely by nitrous acid treatment. These results indicate that the molecule is a heparan sulfate proteoglycan. Although this proteoglycan copurifies with NCAM, it is not detected when the neuron-glia cell adhesion molecule (NgCAM) is immunopurified using the 8D9 monoclonal antibody. The heparan sulfate proteoglycan may also be a membrane-associated proteoglycan since it interacts with phenyl-Sepharose. Molecular weight characterization of the proteoglycan by gel filtration chromatography indicates a molecular weight of 400-520 kDa. The heparan sulfate glycosaminoglycan chains were shown to have an average molecular weight of approximately 40 kDa, and the polypeptide backbone was estimated to be 120 kDa by polyacrylamide gel electrophoresis. These data therefore demonstrate that a neuronal heparan sulfate proteoglycan copurifies with NCAM.

Signal for induction of aldose reductase in renal medullary cells by high external NaCl

GRB-PAP1 is a continuous line of epithelial cells derived from rabbit renal inner medulla. These cells accumulate large amounts of sorbitol when extracellular NaCl concentration is elevated. The accumulation involves an increase in aldose reductase, an enzyme that catalyzes production of sorbitol from glucose. The purpose of the present studies was to investigate the mechanism by which high NaCl triggers an increase in aldose reductase activity. When NaCl was added to increase medium osmolality from 300 to 500 mosmol/kg, enzyme activity began to increase after 12-24 h, was half-maximal in 2 days, and was maximal by 4 days. To test the effect of other solutes, medium osmolality was increased to 500 mosmol/kg by adding raffinose, urea, or glycerol. Raffinose increased aldose reductase activity as much as NaCl did. In contrast, neither urea nor glycerol affected the enzyme activity. NaCl and raffinose caused a sustained decrease in cell water content and an increase in cell sodium and potassium concentration, but urea did not. In some experiments, ouabain was added either with or without an increase in osmolality. Taking into account all of the experiments, with and without ouabain, we found that aldose reductase activity did not correlate with either cell sodium concentration or cell water content alone. It did correlate, however, with cell potassium concentration and even more strongly with the sum of cell sodium plus potassium concentration. We conclude that the signal by which hyperosmolality triggers an increase in aldose reductase activity most likely involves an increase in intracellular ionic strength.

High NaCl induces stable changes in phenotype and karyotype of renal cells in culture

Extracellular fluid in the renal medulla normally is hyperosmotic. To test adaptation to such an environment, a continuous line of rabbit renal inner medullary epithelial cells (GRB-PAP1), which had been established in isosmotic medium, was switched to a medium containing high NaCl. The origin of these cells is described. When the osmolality was raised from 300 to 600 mosmol/kg by adding NaCl, cells eventually survived and proliferated, but unexpectedly, they underwent major changes in phenotype and karyotype that persisted during proliferation in isosmotic or hyperosmotic medium for at least 7 months. The threshold concentration for the changes was approximately 500 mosmol/kg. Cells of a typical strain (PAP-HT25) that formed in hyperosmotic medium were much larger and more often multinucleated than were GRB-PAP1. GRB-PAP1 cells were near diploid; PAP-HT25 cells were polyploid. The changes, since they occurred in most clones, were due to adaptation of the majority of cells and not to selection of a minority of cells already having these characteristics. Cloning efficiency was higher for GRB-PAP1 than PAP-HT25 in isosmotic medium, but the reverse occurred in hyperosmotic medium. Thus exposure to the hyperosmotic medium induced greater ability to clone in it. We suggest that these changes may involve persistent alterations in gene regulation, possibly like those previously reported in chicken embryo fibroblast cells after hyperosmotic NaCl (Cell 30: 131-139, 1982).

Predominant osmotically active organic solutes in rat and rabbit renal medullas

The mechanism that concentrates the urine to an osmolality several times that of systemic plasma results in high concentrations of solutes (particularly NaCl and urea) in extracellular fluid of renal medulla, but not in the labyrinth of the renal cortex. Intracellular and extracellular osmolality must be equal in animals, but the known intracellular levels of Na and K salts and urea in renal medullas are much too low to balance the high extracellular osmolality. The purpose of these studies was to identify the other intracellular osmolytes that must be present. Cortexes and medullas from rabbit and rat kidneys were analyzed by proton nuclear magnetic resonance, mass spectrometry, and chemical assays to determine the identity and amount of organic solutes. Large amounts of glycerophosphorylcholine, betaine, sorbitol, and inositol were found in both species localized almost exclusively to the inner medulla. In rabbits during antidiuresis glycerophosphorylcholine, betaine, and sorbitol were present in the inner medulla, at concentrations of 21.1, 34.8, and 20.8 mumol/g wet weight, respectively, but were not detected in the cortex. Inositol was present in rabbit inner medulla at 10.7 mumol/g wet weight and was also present in the cortex, but at lower concentration. None of the above metabolites was present in measurable amounts in urine or peripheral plasma. The accumulation in the cells of the inner medulla of relatively large amounts of betaine, sorbitol, glycerophosphorylcholine and inositol during antidiuresis suggests that they may play a significant role in the maintenance of intracellular osmotic balance.

Differentiated lines of cells from rabbit renal medullary thick ascending limbs grown on amnion

Previously we grew differentiated primary epithelial tissue cultures from rabbit renal medullary thick ascending limbs but were unable to subculture them into lines. Now, following the use of amnion as a support during the initial passages, two cell lines have grown from single fragments of medullary thick ascending limbs. Cells have now been in culture past 12 passages over more than 2 yr. On confluence they formed morphologically differentiated epithelial monolayers with polarization of the cells visible on electron microscopy. They had apical zonula occludens and microvilli, lateral cellular interdigitations, and basal membranes flat against the support. "Domes" often were visible when the epithelia formed on dishes, indicative of salt and water transport. Other functional differentiation in some passages of one line or the other included presence of Tamm-Horsfall protein (demonstrated by immunofluorescence) or transepithelial voltage oriented apical surface positive. Both the Tamm-Horsfall protein and the voltage are normally expressed by intact medullary thick ascending limbs and are characteristic of this particular nephron segment.

Lactate production in isolated segments of the rat nephron

Lactate production was measured directly in individual segments of the rat nephron. Tubules were dissected and then incubated in vitro with glucose as the only metabolic substrate. Each segment was incubated with and without antimycin A, an inhibitor of oxidative metabolism. Proximal tubules produced no lactate with or without antimycin A. The distal segments all produced lactate. The rate of lactate production without antimycin A ranged from 0.4 to 0.9 pmol X min-1 X mm-1 in all distal segments except one, the inner medullary collecting duct, which produced lactate at the significantly higher rate of 2.8 pmol X min-1 X mm-1. Antimycin A increased lactate production significantly in all of the distal segments. The increase was largest in medullary thick ascending limbs (1,400%) and cortical (798%) and outer medullary collecting ducts (357%). Increments were smaller in cortical thick ascending limbs (98%) and distal convoluted tubules (98%) and least in the inner medullary collecting ducts (28%). We conclude that lactate production occurs only in distal segments of the nephron and that under anoxic conditions significant amounts of ATP are produced by anaerobic glycolysis in these segments.

Methylation increases sodium transport into A6 apical membrane vesicles: possible mode of aldosterone action

When isolated apical membrane vesicles prepared from cultured A6 epithelia were incubated in vitro with the methyl donor S-adenosylmethionine, the control rate of amiloride-inhibitable sodium transport was doubled. The methylation inhibitors 3-deazaadenosine and S-adenosyl homocysteine returned the S-adenosyl-methionine-stimulated sodium transport to control levels. Neither these agents nor adenosine affected sodium transport into control vesicles. In vesicles incubated with S-adenosyl-[3H-methyl]methionine, both membrane phospholipids and proteins were labeled, and this labeling was inhibited by deazaadenosine. In vesicles prepared from A6 cells treated with aldosterone, sodium transport was twice the control value and S-adenosylmethionine did not cause any further stimulation of transport. In those vesicles, both lipid and protein methylation were increased. These results suggest that methylation, which increases the rate of amiloride-sensitive sodium transport is involved in the action of aldosterone at the apical membrane level in epithelia.

Amiloride-sensitive epithelial Na+ channels reconstituted into planar lipid bilayer membranes

High resistance epithelia actively transport sodium from the luminal side to the blood. Aldosterone and vasopressin stimulate this sodium transport system; the diuretic drug amiloride inhibits it in a reversible fashion. The first step in the transepithelial transport of Na+ is the facilitated diffusion of Na+ across the apical membrane via Na+-specific, amiloride-sensitive channels. We report here the first direct measurements of single, amiloride-sensitive Na+ channel activity. The channel was isolated after incorporation of purified apical membrane vesicles from A6 cells into planar lipid bilayers. The channel had the following characteristics: single-channel conductance ranged from 4 to 80 pS at 200 mM NaCl; it was perfectly cation-selective; amiloride reduced the open-state conductance in a dose-dependent fashion when present in the cis compartment, and induced flickering when present in the trans chamber; channel conductance and gating were voltage-independent; and the Na+/K+ selectivity ratio of the channel was 2:1.

Biological changes observed on rice and biological and genetic changes observed on tobacco [correction of tabacco] after space flight in the orbital station Salyut-7 (Biobloc III experiment)

Caryopses and isolated embryos from Rice (Oryza sativa L.) and Tobacco seeds (Nicotiana tabacum L. variety Xanthi) were studied in the Biobloc III container aboard the Soviet orbital space station SALYUT 7. The recovery from radiation damage under conditions of space flight was observed for rice caryopsis and embryos gamma irradiated (Co 60, 50 grays) prior to launch. There was a large decrease in the percentage of germinating seeds from the Tobacco strain tested when the seeds were exposed to heavy ions. Among the germinating plantlets there were few morphological anomalies. Furthermore, there was a significant greater amount of genetic change in those samples held in grids as compared to those in bags.

Sodium chloride coupled transport in mammalian nephrons

A number of possible modes of coupling of sodium chloride transport have been considered, and their roles in the various parts of the renal tubule have been reviewed. Many modes of coupling have been found in various combinations in one or another of the segments. Of special interest are the observations of carrier coupling of sodium to chloride transport in some of the segments, such as the thick ascending limbs of Henle's loop.

Organization of nephron function

Recent studies of mammalian nephron segments have revealed an unexpected diversity of renal transport functions. Most substances are transported by several segments, and the transport mechanisms differ from segment to segment. In this paper we review some of these findings in order to fit them into an integrated picture of kidney function. The main question we ask is what is the advantage of spatial separation of the various transporters along the nephron. We propose that spatial separation of transport functions allows independent and efficient control of the excretion of substances whose renal handling is interdependent. The organization of sodium and water handling along the nephron is considered in the greatest detail. Sodium and water play central roles in controlling the renal excretion of many other substances. Yet the excretion rates of sodium and water themselves are independently controlled. The intricate anatomical structure of the kidney not only provides spatial separation of transport processes along the nephron but also couples the function of different segments by juxtaposing them in specialized regions within the medulla and cortex. These anatomical arrangements provide a framework for integrating the complex array of renal functions.

Heterogeneity in the distal nephron of the salamander (Ambystoma tigrinum): a correlated structure function study of isolated tubule segments

Studies on isolated perfused tubules of the tiger salamander (Ambystoma tigrinum) have shown that the distal nephron is heterogeneous with respect to function (Stoner, 1977). In this study, the initial portion of the distal tubule (diluting segment) exhibited a voltage, positive in the lumen, and a net absorption of chloride. Since the chloride was transported against an electro-chemical gradient, its transport was active. More distad, the junctional segment exhibited a lumen-negative voltage and sodium, rather than chloride, was transported actively. More recently Delaney and Stoner (1981) have demonstrated in vitro that the collecting duct of this species also has a lumen-negative voltage which is probably associated with active sodium reabsorption. The primary objective of the present paper was to correlate the morphology of the diluting and junctional segments of the Ambystoma distal tubules with the physiologic data from the same isolated perfused tubules. The results indicate that the morphological heterogeneity previously demonstrated in distal tubules of Necturus exists with respect to both structure and function in Ambystoma. The cell types found in the amphibian distal nephron appear to be homologous to those seen in the mammalian nephron.

Ion regulation in potassium-sensitive mutants of Paramecium tetraurelia

Two recessive mutations of Paramecium tetraurelia confer sensitivity to potassium: While wild-type cells survive when up to 30 mM KCl is added to their growth medium, mutants cease to grow and die when levels of added KCl reach 20-25 mM. Similar sensitivities are seen to Rb+ and Cs+, but not to Na+. Swimming behavior of mutants is indistinguishable from wild type when placed in stimulating solutions containing Na+, K+, or Ba2+. Behavioral adaptation to low levels of K+ also is indistinguishable from wild type. Flame photometry reveals that one mutant is unable to keep out K+ and Na+ when those ions are at low levels in the medium. Both mutants have markedly lower internal Na+ than does wild type. Problems with K+ permeability account for the sensitivity of the one mutant to elevated external K+, but the basis of sensitivity in the other mutant is unclear. These mutants expand the range of ion regulation mutants in Paramecium and demonstrate that lesions in cellular ion regulation in this organism need not result in changes in swimming behavior.

Differentiated function in cultured epithelia derived from thick ascending limbs

Medullary thick ascending limbs were dissected from rabbit kidney and cultured on thin collagen membranes. The collagen membranes were supported by a special device that limited the exposed surface area to a disk 1 mm in diameter. The cells usually proliferated to form a confluent epithelial monolayer covering the collagen membrane within 8-10 days. Transepithelial voltage was measured between bridges immersed in the solutions bathing the bottom of the collagen membrane and the apical (upper) surface of the epithelium. The voltage typically was oriented positive toward the apical surface and persisted for a few weeks. Furosemide but not amiloride reduced the voltage reversibly. Both the orientation of the voltage and its reduction by furosemide are characteristic of thick ascending limbs. Therefore, the observed voltage supports the identification of the epithelial cells in culture and is evidence of differentiated function.

Organic solutes in fluid absorption by renal proximal convolutes tubules

Page 627: M. Burg, C. Patlak, N. Green, and D. Villey. “Organic solutes in fluid absorption by renal proximal convolutes tubules.” Page 628: the equation in the right column should read

(See PDF)

Control of renal bicarbonate transport

Single rabbit renal tubules were perfused in vitro to elucidate the factors that control bicarbonate transport. One factor studied was the preexisting acid-base status of the rabbits. Cortical collecting ducts from acidotic rabbits (given ammonium chloride) transported bicarbonate from lumen to bath. Collecting ducts from alkalotic rabbits (given sodium bicarbonate) transported bicarbonate in the opposite direction. Thus, bicarbonate transport by collecting ducts in vitro was conditioned by the preexisting state of the rabbit in vivo. In contrast, bicarbonate transport by proximal straight tubules and cortical thick ascending limbs was not affected by ammonium chloride or sodium bicarbonate given to the rabbits. Parathyroid hormone, the second factor studied, strongly inhibited bicarbonate absorption by proximal straight tubules.

Bicarbonate transport by isolated perfused rabbit proximal convoluted tubules

Proximal convoluted tubules were dissected from rabbit kidneys and perfused in vitro in order to investigate the relationship between the reabsorption of fluid and of bicarbonate. Bicarbonate was absorbed when it was initially present in the perfusate. At slow rates of perfusion the mean concentration of total CO2 was 9 mM in collected fluid with 25 mM bicarbonate in the bath. At faster rates of perfusion the mean rate of reabsorption was 13.6 pmol cm-1 tubule length s-1. Absorption of bicarbonate was inhibited to a large but not complete extent by elimination of sodium from the perfusate and bath or potassium from the bath, and by addition of ouabain. It was not inhibited by elimination of the organic solutes from the perfusate nor by elimination of chloride from the perfusate and bath. Considered with previous measurements of fluid absorption these results are consistent with the existence of a linked sodium-for-hydrogen ion exchange mechanism at the luminal border of the tubule cells, but there are other possibilities which are discussed. Additionally, the effect of acetazolamide was investigated. The drug virtually completely inhibited bicarbonate absorption and inhibited fluid absorption by 30-40%.

Organic solutes in fluid absorption by renal proximal convoluted tubules

Proximal convoluted tubules were dissected from rabbit kidneys and perfused with artificial solutions in vitro. The effect of various organic solutes on rate of fluid absorption and transepithelial voltage was tested by removing solutes from or adding them to perfusate and/or bath. Omission of albumin from the bath caused rate of fluid absorption to descrease 33% without any change in voltage. Omission of glucose, lactate, alanine, and citrate from the bath had no effect. In contrast, when they were removed from perfusate, rate of fluid absorption fell by 45-75% (depending on whether they were replaced by NaCl or mannitol and NaCl), and voltage (normally negative in lymen) decreased to near zero. Adding glucose or alanine individually to perfusate caused a small increase in rate of fluid absorption and a relatively large increase in voltage. alpha-Methyl-D-glucoside and cycloleucine (which are transported but not metabolized) had effects similar to glucose and alanine, except that voltage changes were not as great. Phlorizin (10(-5) M in perfusate) had the same effect as removing glucose from perfusate. When glucose and alanine were added to perfusate, epithelial cell swelled significantly. Lactate and citrate also caused rate of fluid absorption to increase when they were added to perfusate, but they did not affect transepithelial voltage nor did they cause cells to swell significantly. Possible mechanisms of these effects and the role of organic solutes in fluid absorption by proximal convoluted tubules are discussed.

Renal tubular chloride transport and the mode of action of some diuretics

The renal diluting segment (thick ascending limb of Henle's loop) reabsorbs sodium chloride in excess of water and is responsible for dilution of the urine as well as reabsorption of a large fraction of the salt present in the glomerular ultrafiltrate. There is active reabsorption of chloride, which causes the voltage to be positive in the tubule lumen. Most, if not all, of the sodium transport is passive, driven by the voltage. Three major diuretics (mersalyl, furosemide, and ethacrynic acid) act in the lumen of the diluting segment to inhibit active chloride transport, not sodium transport as previously believed. This specific action on chloride transport may explain how these drugs are able to inhibit salt transport in the kidney while having so little effect on the transport processes elsewhere in the body.