Altered Functional Responses Research Articles

Effects of copper and cadmium exposure on functional responses of hemocytes in the clam, Tapes philippinarum.

The effects of Cu and Cd on functional responses of hemocytes in Tapes philippinarum, a Veneridae clam widespread in the lagoon of Venice, were evaluated. Bivalves were exposed for 7 days to various concentrations of CuCl(2) x 2H(2)O (0, 10, 60, and 110 microg/L) and CdCl(2) x H(2)O (0, 150, 300, and 450 microg/L). Hemocytes were collected from exposed clams, and the effects of Cu and Cd on phagocytosis, Neutral Red retention capacity, superoxide dismutase, and cytochrome oxidase activities were investigated. Hemocytes from animals exposed to Cu showed a significant decrease in phagocytic activity, whereas no inhibition was observed in cells from Cd-exposed animals. Diffusion of Neutral Red into the cytosol, an index of lysosomal membrane alteration, was enhanced by high concentrations of both metals. Different results in biochemical parameters were observed. Exposure to 60 and 110 microg Cu/L caused a significant reduction in hemocyte superoxide dismutase activity, whereas no changes resulted after Cd exposure. Increased cytochrome oxidase activity was observed in hemocytes from mollusks exposed to 60 microg Cu/L and 300 microg Cd/L; no significant differences were found in cells from bivalves exposed to 110 microg Cu/L and 450 microg Cd/L. These results suggest a relationship between heavy metal exposure and alterations in functional responses of hemocytes in T. philippinarum and indicate that the type of observed effects vary with the nature and concentration of heavy metals. Moreover, the data obtained in the analyzed clam support the possibility of using it as sentinel organism in biomonitoring studies, even if used biomarkers will be further evaluated in field conditions.

Altered functional and biochemical response by CD8+ T cells that remain after tolerance.

To further define the molecular basis of tolerance to a peripherally expressed antigen we have correlated differences in functional capacity with biochemical events in hemagglutinin (HA)-specific cytotoxic T lymphocyte (CTL) clones derived either from a conventional B10.D2 mouse that is not tolerant to HA (D2 Clone 6) or from an InsHA mouse that is tolerant to HA (InsHA Clone 12). D2 Clone 6, but not InsHA Clone 12, triggers diabetes following in vivo transfer into irradiated InsHA hosts. This diabetogenic clone shows complete and sustained phosphorylation of TCR zeta chain and ZAP-70 following stimulation with HA-pulsed antigen-presenting cells. In contrast, InsHA Clone 12 showed only partial phosphorylation of TCR zeta and no phosphorylation of ZAP-70. There was no defect in activation or recruitment of Lck to the TCR complex in both the clones following stimulation with the cognate antigen. This deficiency in the proximal signaling in the InsHA Clone 12 could be overcome by increasing the strength of signal through the CD3-TCR complex, indicating that the signaling machinery of InsHA Clone 12 was functional. These data demonstrate that the HA-responsive CD8(+) T cells that can be retrieved from InsHA mice after tolerance induction respond to HA as a partial agonist/antagonist.

Altered Functional Responses with Preserved Morphology of Gonadotrophic Cells in Congenitally Athymic Mice

Neonatal thymectomy or congenital absence of the thymus induces severe reproductive deficiencies in female mice, which are associated with reduced levels of circulating and pituitary gonadotropins. In contrast, the reproductive function is well preserved in nude males. It was therefore of interest to assess gonadotrophic cell morphology and function in congenitally athymic male mice. Circulating gonadotropins were measured under basal and stressful conditions, taking as a reference their haired counterparts. Adult normal (+/+), heterozygous nude (nu/+), and homozygous (nu/nu) CD-1 mice were subjected to 1-h immobilization stress. Serum levels of luteinizing hormone (LH) and follicle-stimulating hormone (FSH) were assessed by RIA at 0, 30, and 60 min poststress. Athymic animals showed significantly lower basal levels of serum LH and FSH than their heterozygous littermates. Immunohistochemical assessment of LH and FSH cell populations revealed a normal morphology and cell number in the athymic animals compared to their normal littermates. Immobilization stress induced a significant reduction in gonadotrophin levels, particularly LH, in normal mice but had only a weak effect in athymic animals. It is concluded that congenital athymia in the adult male mouse is associated with decreased basal levels of serum LH and FSH, in the presence of a normal gonadotroph number and morphology. The anomalous responses of athymic mice to stress do not appear to be due to primary hypopituitarism but, rather, to an altered modulation of pituitary hormone secretion.

Differences in the distribution of GABA- and GAD-immunoreactive neurons in the anterior and posterior piriform cortex of rats

There is accumulating evidence of anterior–posterior differences in the susceptibility of the piriform cortex to seizure induction and to functional alterations in response to seizures elicited from other limbic brain regions, but the reasons for such differences along the anterior–posterior axis of the piriform cortex are not clear. In the present study, GABAergic neurons have been identified in the piriform cortex of the rat at light microscopic level by immunocytochemical localization of GABA and the GABA-synthesizing enzyme glutamic acid decarboxylase. A monoclonal antibody to GABA and, for comparison, polyclonal antibodies to GABA and glutamic acid decarboxylase were used for this purpose. In both anterior and posterior piriform cortex, the highest number and density of GABA-immunoreactive cells was found in layer II. Lower density of GABAergic cells was found in layers I and III and the subjacent endopiriform cortex. When cells were quantified in 19 corresponding sections of the piriform cortex, covering most of anterior–posterior extension of this region, there appeared to be an increased density of GABAergic neurons in sections near to or within the transition zone between anterior and posterior piriform cortex. A more detailed analysis at 4 section levels in the anterior and posterior piriform cortex and the transition zone between the 2 parts substantiated a significantly higher density of GABAergic neurons in the transition zone, which was predominantly due to increased numbers of cells in layers II and III. We propose that the transition zone between anterior and posterior piriform cortex is a location where numerous GABAergic interneurons regulate the activity of neighbouring deep pyramidal cells which receive dense excitatory input from both the olfactory bulb and distant pyramidal cells in the more anterior and posterior parts of the piriform cortex at the same time, thus increasing the risk of paroxysmal activation within this restricted area. This proposal is in line with recent observations of increased susceptibility to epileptiform activation and to kindling-induced neurochemical alterations within the transition zone between anterior and posterior piriform cortex.

Stimulation of Intracellular Ca2+ Levels in Human Neutrophils by Soluble Immune Complexes

Soluble immune complexes bind to unprimed neutrophils and generate intracellular Ca2+ transients but fail to activate the NADPH oxidase. Following priming of the neutrophils with either tumor necrosis factor alpha or granulocyte-macrophage colony-stimulating factor, stimulation of the cells with the soluble immune complexes leads to an enhanced Ca2+ signal and significant secretion of reactive oxidants. The enhanced Ca2+ signal observed in primed neutrophils results from the influx of Ca2+ from the external environment and is partly sensitive to tyrosine kinase inhibitors. This is in contrast to the Ca2+ signal observed in unprimed neutrophils, which arises from the mobilization of intracellular stores. When the surface expression of FcgammaRIIIb on primed neutrophils was decreased either through incubation with Pronase or phosphoinositide-specific phospholipase C, the extra enhanced Ca2+ mobilization seen in primed cells was significantly lowered, while the initial rise in intracellular Ca2+ was unaffected. Depletion of FcgammaRIIIb had no significant effect on the Ca2+ transients in unprimed neutrophils. Cross-linking FcgammaRII, but not FcgammaRIIIb, induced increases in intracellular Ca2+ in unprimed neutrophils, while cross-linking either of these receptors increased Ca2+ levels in primed neutrophils. The FcgammaRII-dependent intracellular Ca2+ rise in primed cells was unaffected by incubation in Ca2+-free medium, whereas the FcgammaRIIIb-dependent transient was significantly decreased when Ca2+ influx was prevented in Ca2+-free medium supplemented with EGTA. Cross-linking either FcgammaRII or FcgammaRIIIb in primed or unprimed cells failed to stimulate substantial levels of inositol 1,4,5-trisphosphate production. These results indicate that following stimulation of primed neutrophils with soluble immune complexes the enhanced Ca2+ mobilization observed is the result of a functional activation of the glycosylphosphatidylinositol-linked FcgammaRIIIb.

Enhancement of muscarinic receptor-coupled phosphatidyl inositol hydrolysis in diabetic bladder.

We previously have shown an increase in muscarinic receptor density in streptozotocin (STZ)-induced diabetic and sucrose-fed diuretic rat detrusor that correlates with an increase in the contractile response to muscarinic agonist (J Pharmacol Exp Ther 248:81, 1989; Diabetes 40: 265, 1991). To investigate the signal transduction pathway involved in this altered functional response, we examined muscarinic receptor-coupled phosphatidylinositol metabolism in STZ-diabetic, sucrose-fed diuretic and age-matched control rat bladders. [3H]myo-inositol uptake was similar in all groups, but incorporation of myo-inositol into phosphatidylinositol (PI) was significantly increased in the diabetic bladder compared to the sucrose-fed and control rat bladders. Carbachol-induced increase in inositol phosphate (IPs) production was higher in the diabetic bladder than in bladders from control and sucrose-fed animals although the EC50 values were similar for all groups. Enhanced inositol phosphate production after muscarinic agonist stimulation may be due not only to the upregulation of muscarinic receptors but also the increased incorporation of myo-inositol into PI in the STZ-induced diabetic bladder.

Biology of the impaired endothelium

The endothelium is a regulatory organ that mediates hemostasis, contractility, cellular proliferation, and inflammatory mechanisms in the vessel wall. Injury to the endothelium from hypertension, smoking, hyperlipidemia, and diabetes mellitus disrupts normal regulatory properties and results in abnormal endothelial cell function. Clinically, endothelial cell dysfunction can be manifested as vasospasm, thrombus formation, atherosclerosis, or restenosis. The normal hemostatic properties of the endothelium include the maintenance of a nonadhesive luminal surface, antithrombotic properties, anticoagulant properties, and fibrinolytic properties. The endothelial cell regulates smooth muscle cell contractility by the production of relaxing and constricting factors in response to physiologic stimuli. Endothelial cell injury is also an initial event in the development of atherosclerosis and restenosis by facilitating platelet adhesion and aggregation and by signaling the release of mitogens from platelets, macrophages, and endothelial cells, which stimulate smooth muscle cell proliferation. In addition, endothelial cells undergo morphologic and functional alterations in response to cytokine signals, which may contribute to the pathogenesis of vasculitis and atherosclerosis. In sum, the normal endothelium performs many regulatory functions which become altered when the endothelium is injured.

Correlates of altered functional responses of partially denervated autonomic ganglia

Correlates of altered functional responses of partially denervated autonomic ganglia

Binding, Uptake, and Release of Nicotine by Human Gingival Fibroblasts

Previous studies of the effects of nicotine on fibroblasts have reported an altered morphology and attachment of fibroblasts to substrates and disturbances in protein synthesis and secretion. This altered functional and attachment response may be associated with changes in the cell membrane resulting from binding of the nicotine, or to disturbances in cell metabolism as a result of high intracellular levels of nicotine. The purpose of the present study, therefore, was to 1) determine whether gingival fibroblasts bound nicotine and if any binding observed was specific or non-specific in nature; 2) determine whether gingival fibroblasts internalized nicotine, and if so, at what rate; 3) determine whether gingival fibroblasts also released nicotine back into the extracellular environment; and 4) if gingival fibroblasts release nicotine intact or as a metabolite. Cultures of gingival fibroblasts were prepared from gingival connective tissue biopsies. Binding was evaluated at 4 degrees C using a mixture of 3H-nicotine and unlabeled nicotine. Specific binding was calculated as the difference between 3H-nicotine bound in the presence and absence of unlabeled nicotine. The cells bound 1.44 (+/- 0.42) pmols/10(6) cells in the presence of unlabeled nicotine and 1.66 (+/- 0.55) pmols/10(6) cells in the absence of unlabeled nicotine. The difference was not significant. Uptake of nicotine was measured at 37 degrees C after treating cells with 3H-nicotine for time periods up to 4 hours. Uptake in pmols/10(6) cells was 4.90 (+/- 0.34) at 15 minutes, 8.30 (+/- 0.75) at 30 minutes, 12.28 (+/- 2.62) at 1 hour and 26.31 (+/- 1.15) at 4 hours.(ABSTRACT TRUNCATED AT 250 WORDS)

Receptor interactions of dopamine and serotonin antagonists: binding in vitro and in vivo and receptor regulation.

The advent of receptor binding techniques has provided new ways of studying the mechanism of action of drugs. In vitro radioligand binding is now currently applied to investigate the specificity or multiple action of compounds. By using the same technique, the binding affinity of a drug can be measured for a variety of neurotransmitter, drug, peptide and ion channel receptor binding sites, providing the drug's receptor binding profile (LEYSEN et al. 1981; LEYSEN 1984). However, in vitro receptor binding is only the initial step in the investigation of drug-receptor interactions. Investigations in vivo are required to allow evaluation of how and where a drug acts. In fact, the study of drug-receptor interactions comprises three main stages: (a) in vitro radioligand receptor binding; (b) in vivo receptor binding, providing information on the accessibility of the drugs to the receptors localized in various central and peripheral tissues, on the drug potency for occupying various receptors, on the duration of receptor occupation and on the relationship between the degree of receptor occupation and pharmacological effects; and (c) the study of receptor regulation: the effect of chronic drug treatment on receptor alterations compared with alterations in functional responses in vivo. In this article, we will illustrate the three stages of investigation of receptor interactions and discuss the relevance and importance of the findings, using as examples three drugs known in psychopharmacological research: (a) the neuroleptic haloperidol, a prototype of a dopamine D2 antagonist: (b) Setoperone, a potential antipsychotic agent with very potent serotonin S2 and moderate D2 antagonistic activity (CEULEMANS et al. 1985; LEYSEN et al. 1986); and (c) ritanserin, a potent and long-acting S2 antagonist (LEYSEN et al. 1985), which has revealed therapeutic activity in dysthymia and negative symptoms of schizophrenia (REYNTJENS et al. 1986; GELDERS et al. 1986). Particular attention will be paid to the problem of receptor regulation. We challenge the general applicability of the receptor regulation theory, which states that persistent receptor stimulation causes desensitisation and receptor downregulation, whereas chronic deprivation of receptor stimulation leads to supersensitivity and receptor upregulation. Recent research has revealed that the theory does not hold for S2 receptor alterations, which were found to downregulate following chronic receptor blockade.

Altered cyclic-AMP receptor activity and morphogenesis in a chemosensory mutant of Dictyostelium discoideum

The functional properties of the cell-surface cyclic-AMP receptor that controls chemotaxis were found to be altered in an aggregation mutant of Dictyostelium discoideum. The mutant aggregated without stream formation and had a tenfold increased cell-density requirement for the initiation of aggregation. After aggregation, mounds formed multiple tips and subsequently subdivided to give multiple fruits that were small and abnormally proportioned. Cyclic-AMP-induced light-scattering changes in cell suspensions indicated that the mutant had a diminished response to external cyclic-AMP signals. Associated with these altered functional responses was a physical change in the cyclic-AMP sensory system. Cyclic-AMP-binding studies showed that the parent had two classes of cyclic-AMP binding sites, i.e., Kd = 32 and 110 nM. In contrast, the mutant had two- to threefold or more high-affinity sites (Kd = 25n M) and altered low-affinity sites (Kd < 3μ M). These results indicate that both affinity classes of binding site are independently mutable. This observation suggests that the two affinity classes can be interconverted by mutation, or the mutation alters a single molecular species and its equilibrium between binding sites with different affinities for cyclic AMP, as postulated in receptor cycling models.

Influenza virus infection induces functional alterations in peripheral blood lymphocytes.

This report describes alterations in functional responses to lectin-induced stimulation of peripheral blood lymphocytes and in the natural killer cell (NKC) activity, of college students, obtained during an outbreak of influenza A/Philippines/2/82(H3N2) virus infection. These results are compared with similar observations in college students with an acute, febrile, noninfluenzal respiratory illness that occurred during the same outbreak. The lymphopenia typical of influenza during acute illness was shown to be due to a reduction in both T and B cells without alteration in the CD4:CD8 ratio. In addition, phytohemagglutinin and concanavalin A responses were reduced and NKC activity was increased, while pokeweed mitogen reactivity was unaltered at the time of admission to the study. Patients with noninfluenzal illness showed early polymorphonuclear leukocytosis and a similar lymphopenia. Lymphocyte functions were virtually unchanged during acute illness in noninfluenza patients. The relatively specific alterations in lymphocyte responses to lectin-induced stimulation in influenza patients may indicate that the peripheral T cells are incapable of activation via the CD3 or CD2 activation pathways. In addition, increased NKC activity in the periphery may be reflective of increased NKC activity in the lung. Influenza-infected individuals with higher NKC activity at the time of admission to the study also took longer to recover. Finally, the early lymphopenia and the later neutropenia in the influenza-infected patient may represent migration of these cells from the circulation to the infected respiratory tract as a consequence of infection.

Altered cyclic-AMP receptor activity and morphogenesis in a chemosensory mutant of Dictyostelium discoideum

The functional properties of the cell-surface cyclic-AMP receptor that controls chemotaxis were found to be altered in an aggregation mutant of Dictyostelium discoideum. The mutant aggregated without stream formation and had a tenfold increased cell-density requirement for the initiation of aggregation. After aggregation, mounds formed multiple tips and subsequently subdivided to give multiple fruits that were small and abnormally proportioned. Cyclic-AMP-induced light-scattering changes in cell suspensions indicated that the mutant had a diminished response to external cyclic-AMP signals. Associated with these altered functional responses was a physical change in the cyclic-AMP sensory system. Cyclic-AMP-binding studies showed that the parent had two classes of cyclic- AMP binding sites, i.e., Kd = 32 and 110 n M. In contrast, the mutant had two- to threefold or more high-affinity sites (Kd = 25n M) and altered low-affinity sites (Kd<3 μ M). These results indicate that both affinity classes of binding site are independently mutable. This observation suggests that the two affinity classes can be interconverted by mutation, or the mutation alters a single molecular species and its equilibrium between binding sites with different affinities for cyclic AMP, as postulated in receptor cycling models.