M. S. Nijjar

The release of glutamate and aspartate from rat brain synaptosomes in response to domoic acid (amnesic shellfish toxin) and kainic acid

Kainic acid is known to stimulate the release of glutamate (GLU) and aspartate (ASP) from presynaptic neurons. It has been suggested that the enhanced release of these endogenous EAAs plays a significant role in the excitotoxic effects of KA. Domoic acid (DOM), a shellfish toxin, is structurally similar to KA, and has been shown to be 3–8 times more toxic than KA. In this study, effects of KA and DOM on the release of GLU and ASP from rat brain synaptosomes were investigated. Amino acid analysis was performed by the reversed phase HPLC, following derivatization with 9-fluorenylmethyl chloroformate (FMOC). Potassium chloride (40 mM) was used as a positive control, and stimulated GLU release from rat brain synaptosomes in presence or absence of Ca2+. DOM enhanced the release of GLU, whereas KA stimulated the release of both GLU and ASP from synaptosomes in the presence of Ca2+. However, their potency to stimulate GLU and ASP release was enhanced in absence of Ca2+. These results indicate that diferent mechanisms may be involved in the release of GLU and ASP in response to DOM and KA, and that neurotransmitter release appeared to be highly specific for these agonists. It would appear that DOM and KA may interact with different receptors on the presynaptic nerve terminal, and/or activate different subtypes of voltage-dependent Ca2+ channels to promote influx of Ca2+ which is targeted for different pools of neurotransmitters.

Domoic acid inhibits adenylate cyclase activity in rat brain membranes

Adenylate cyclase activity measured by the formation of cyclic AMP in rat brain membranes was inhibited by a shellfish toxin, domoic acid (DOM). The inhibition of enzyme was dependent on DOM concentration, but about 50% of enzyme activity was resistant to DOM-induced inhibition. Rat brain supernatant resulting from 105,000×g centrifugation for 60 min, stimulated adenylate cyclase activity in membranes. Domoic acid abolished the supernatant-stimulated adenylate cyclase activity. The brain supernatant contains factors which modulate adenylate cyclase activity in membranes. The stimulatory factors include calcium, calmodulin, and GTP. In view of these findings, we examined the role of calcium and calmodulin in DOM-induced inhibition of adenylate cyclase in brain membranes. Calcium stimulated adenylate cyclase activity in membranes, and further addition of calmodulin potentiated calcium-stimulated enzyme activity in a concentration dependent manner. Calmodulin also stimulated adenylate cyclase activity, but further addition of calcium did not potentiate calmodulin-stimulated enzyme activity. These results show that the rat brain membranes contain endogenous calcium and calmodulin which stimulate adenylate cyclase activity. However, calmodulin appears to be present in membranes in sub-optimal concentration for adenylate cyclase activation, whereas calcium is present at saturating concentration. Adenylate cyclase activity diminished as DOM concentration was increased, reaching a nadir at about 1 mM. Addition of calcium restored DOM-inhibited adenylate cyclase activity to the control level. Similarly, EGTA also inhibited adenylate cyclase activity in brain membranes in a concentration dependent manner, and addition of calcium restored EGTA-inhibited enzyme activity to above control level. The fact that EGTA is a specific chelator of calcium, and that DOM mimicked adenylate cyclase inhibition by EGTA, indicate that calcium mediates DOM-induced inhibition of adenylate cyclase activity in brain membranes. While DOM completely abolished the supernatant-, and Gpp (NH)p-stimulated adenylate cyclase activity, it partly blocked calmodulin-, and forskolin-stimulated adenylate cyclase activity in brain membranes. These results indicate that DOM may interact with guanine nucleotide-binding (G) protein and/or the catalytic subunit of adenylate cyclase to produce inhibition of enzyme in rat brain membranes.

A procedure for large-scale purification of domoic acid from toxic blue mussels (Mytilus edulis)

Pure domoic acid is required for use in research to investigate the biological effects of this new shellfish toxin. It may also prove to be a useful tool in studies exploring the basis of Alzheimers disease. In this paper we describe a procedure which is effective in obtaining adequate quantities of pure domoic acid from blue mussel (Mytilus edulis). The procedure involves tissue homogenization, treatment of homogenate with chloroform and methanol, and separation of different phases with the addition of water. The aqueous-methanolic phase (upper layer) contains water soluble components including domoic acid, the chloroform phase (lower layer) contains lipoid moieties, and the interphase contains denatured proteins. The aqueous phase containing domoic acid was removed, rotory evaporated to get rid of methanol, followed by ultrafiltration to remove high molecular weight contaminants. The filtrate was lyophilized, resuspended in 1 N HCl, centrifuged and the resulting clear solution subjected to column chromatography on C18 reversed phase silica gel. Fractions containing domoic acid were pooled, and lyophilized. A brownish dry powder contained pure domoic acid with 60–65% yield from the original tissue homogenate. Another 10–15% of domoic acid was mixed with its isomer, and can be further resolved to obtain an overall recovery of 75–80% of the starting material.

Mechanism of adenylate cyclase activation by the rat lung cytoplasmic factors

Epinephrine, histamine and prostaglandin E1 stimulated adenylate cyclase activity in lung membranes and their stimulation of the enzyme activity was completely blocked by propranolol, metiamide and indomethacin, respectively. A partially-purified activator from the adult rat lung also enhanced adenylate cyclase activity in membranes. However, stimulation of adenylate cyclase by the rat lung activator was not abolished by the above receptor antagonists. Further, epinephrine, NaF and Gpp(NH)p stimulated adenylate cyclase activity rather readily, whereas stimulation of the enzyme activity by the lung activator was evident after an initial lag phase of 10 min. Also, the lung activator produced additive activation of adenylate cyclase with epinephrine, NaF and Gpp(NH)p. These results indicate that the lung activator potentiates adenylate cyclase activity in membranes by a mechanism independent from those known for epinephrine, NaF and Gpp(NH)p. Incubation of lung membranes for 30 min at 40°C resulted in a loss of adenylate cyclase activation by NaF and Gpp(NH)p. Addition of the released proteins to the heat-treated membranes did not restore the enzyme response to these agonists. However, heat treatment of lung membranes in the presence of 2-mercaptoethanol or dithiothreitol prevented the loss of adenylate cyclase response to NaF and Gpp (NH)p. N-ethylmaleimide abolished adenylate cyclase activation by epinephrine, NaF, Gpp(NH)p and the lung activator. These results indicate that the sulfhydryl groups are important for adenylate cyclase function in rat lung membranes.

In situ heparin‐induced peroxisomal reticulum and biogenesis of peroxisomes in pulmonary intravascular macrophages (PIMs) of caprine lung: an ultrastructural and cytochemical study

Pulmonary intravascular macrophages (PIMs) contain a unique electron‐dense globular surface‐coat which is sensitive to heparin treatment, halothane anesthesia, and the digestive effect of lipolytic lipase (LPL), suggesting that the coat is predominantly composed of lipoproteins. In the present study, evidence is presented that heparin, when administered intravenously in goats, potentiated both the translocation of the surface‐coat into the vacuolar system and the expansion of the Golgi apparatus. Sequentially, these changes were followed by proliferation of peroxisomes in combination with peroxisomal reticulum (PR), a transient precursor of this organelle. The peroxisomes, as well as PR, reacted positively for catalase after aldehyde fixation and 3,3′‐diaminobenzidine (DAB) staining. In addition to their role as phagocytes, the ultrastructural and cytochemical detection of peroxisomes suggests a functional capacity of the PIMs, which may be adaptable to the circulating level of free fatty acids (FAAs). Anat Rec 266:69–80, 2002.

Regulation of Ca2+ homeostasis by glucose metabolism in rat brain

In a previous communication we reported that glucose deprivation from KHRB medium resulted in a marked stimulation of Ca2+ uptake by brain tissue, suggesting a relationship between glucose and Ca2+ homeostasis in brain tissue [17]. Experiments were carried out to investigate the significance of glucose in Ca2+ transport in brain cells. The replacement of glucose with either D-methylglucoside or 2-deoxyglucose, non-metabolizable analogues of glucose, resulted in stimulation of Ca2+ uptake just as by glucose deprivation. These data show that glucose metabolism rather than glucose transfer was necessary to stimulate Ca2+ uptake in brain tissue. Inhibition of glucose metabolism with either NaF, NaCN, or iodoacetate resulted in stimulation of Ca2+ uptake similar to that produced by glucose deprivation. These results lend further support for the concept that glucose metabolism is essential for Ca2+ homeostasis in brain. Anoxia promotes glucose metabolism through glycolytic pathway to keep up with the demand for ATP by cellular processes (the Pasteur effect). Incubation of brain slices under nitrogen gas did not alter Ca2+ uptake by brain tissue, as did glucose deprivation and the inhibitors of glucose metabolism. We conclude that glucose metabolism resulting in the synthesis of ATP is essential for Ca2+ homeostasis in brain. Verapamil and nifedipine which block voltage-gated Ca2+ channels, did not alter Ca2+ uptake stimulated by glucose deprivation, indicating that glucose deprivation-enhanced Ca2+ uptake was not mediated by Ca2+ channels. Tetrodotoxin which specifically blocks Na+ channels, abolished Ca2+ uptake enhanced by glucose deprivation, but had no effect on Ca2+ uptake in presence of glucose (controls). These results suggest that stimulation of Ca2+ uptake by glucose deprivation may be related to Na+ transfer via Na-Ca exchange in brain. (Mol Cell Biochem 176: 317–326, 1997)

Effect of pH on domoic acid toxicity in mice

Domoic acid is a shellfish toxin which produces gastrointestinal distress, followed by neurological symptoms such as headache, confusion, disorientation and severe deficits in short-term memory. Domoic acid is an amino acid which contains three carboxylic groups, and one imino group, and its solubility, rate of absorption, and elimination would vary depending on the protonation of these groups at different pHs. We propose that domoic acid toxicity varies with pH of administered domoic acid solution. Domoic acid toxicity was measured in mice as the onset times for scratching behaviour, seizure activity, and death, after the intraperitoneal administration of domoic acid at different pHs. Results of the present study show that the scratching behaviour, seizure activity, and death, occurred at 12, 40, and 55 min, after intraperitoneal administration of domoic acid at pH 3.7. Apparently, the onset times for three types of behaviours were relatively long, and well separated from each ot her. Domoic acid toxicity was lowest at pH 3.7, and highest at pH 7.4, with intermediate toxicity at other pHs. The onset time of scratching behaviour was not influenced by pH of domoic acid solution at three different doses. In contrast, the onset times for seizure activity, and death were significantly affected by pH of domoic acid, toxicity being higher at pH 7.4 than at pH 3.7. The pH effect on domoic acid toxicity diminished as the dose of domoic acid was increased. In fact, at 14.5 mg/kg domoic acid toxicity was similar at both pHs of 3.7 and 7.4. It is concluded that in vivo toxicity of domoic acid varies depending on pH of the administered solution. The differential toxicity of domoic acid at different pH may be related to its solubility, rate of absorption, and elimination, depending on the degree of protonation of domoic acid molecule. Domoic acid toxicity would also vary depending on the age of animal, receptor sensitivity and density in different regions of brain. (Mol Ce ll Biochem 167: 179-185, 1997)

Relationship between the cytoplasmic activator of adenylate cyclase and glycogen metabolism in rat lung.

SummaryThe role of cytoplasmic activator of adenylate cyclase in rat lung metabolism was investigated. Mouse adrenal tumor (MAT) cells undergo differentiation in response to choleratoxin which acts through cyclic AMP. The activator of adenylate cyclase from rat lung also produced cyclic AMP in a disrupted MAT cell preparation. However, unlike choleratoxin, it did not induce MAT cell differentiation in whole cells. These results suggest impermeability of MAT cells, and possibly other cells, to the activator. Thus, means of altering activator activity in lung cytoplasm were sought, and changes in activator activity were related to lung glycogen. Adrenalectomy (ADX) in rats led to a reduction in activator activity that was accompanied by an elevation in lung glycogen. Dexamethasone treatment of adrenalectomized rats reversed both of these effects. Streptozotocin-induced diabetes in rats elevated activator activity and lowered lung glycogen. Insulin treatment of the diabetic rats restored activator activity to the normal control values. Preweaning of rats on day 16 instead of day 22 increased activator activity on the 19th day over the controls and there was a concomitant decrease in lung glycogen. Feeding the separated pups with homogenized milk restored glycogen and activator activity to the control values. These results indicate that activator activity in rat lung cytoplasm was dependent on the circulating levels of cortisol and insulin, and that there appeared to be an inverse relationship between activator activity and glycogen level in rat lungs.

Further purification and partial characterization of the rat lung cytoplasmic factors modulating adenylate cyclase activity in plasma membrane

SummaryThe adult rat lung cytoplasm contains some factors which markedly stimulate adenylate cyclase activity in plasma membranes (Nijjar, M. S. Biochim. Biophys. Acta 584:43–50, 1979). Adenylate cyclase activator (ACA) was purified from rat lungs by DEAE-cellulose chromatography, preparative isoelectric focusing and by repeated high-performance liquid chromatography on a Sepharogel TSK 2000SW column. The final preparation showed about 200 fold purification in ACA activity over the original lung supernatant, and appeared to be homogeneous on the basis of its migration into a single band on SDS-polyacrylamide gel electrophoresis, and co-elution of ACA activity with protein from a gel exclusion column. ACA is an acidic (pl 4.8 ± 0.1), heat labile, monomeric protein of 40000 ± 2000 dalton molecular weight, and does not resemble calmodulin.

EFFECTS OF PREMATURE WEANING AND DIET ON LUNG GROWTH AND APPEARANCE OF ADENYLATE CYCLASE ACTIVATOR IN RAT LUNG

Early weaning of rat pups on day 16 to semi-ground Purina chow food and drinking water, ad libitum, delayed growth of body and lungs, and the appearance of adenylate cyclase activator (ACA) in lung after day 22. However, early weaning of pups to either milk or a gel diet containing semi-ground Purina chow food, agarose gel, water (30:1:69, w/w), and drinking water, restored lung and body growth and the appearance of ACA to control values. Early weaning of pups to dry semi-ground Purina chow food and drinking water also induced a transient rise in ACA on day 19. This early rise in ACA was completely absent in pups weaned on day 16 to milk, whereas it persisted in pups weaned similarly to a gel diet. Interestingly, lung glycogen decreased on day 19 in pups weaned early to dry semi-ground Purina chow food without (group 2) or with triiodothyronin administration (group 3), and on day 25 after normal weaning on day 22 (Nijjar, M.S. Biochim. Biophys. Acta 586: 464–472,1979). These data indicate 1) that reduced food intake (starvation) in pups weaned on day 16 to dry semi-ground Purina chow food was responsible for the delayed growth of body and lung, and the delayed appearance of ACA in lung after day 22, and 2) that a change in diet from milk to Purina chow food and associated alterations in hormones, possibly cortisol and insulin, were responsible for the appearance of ACA in rat lung. It would appear that reduced intake of food (starvation) and associated changes in hormones in rat pups at weaning induce ACA in lungs, stimulating adenylate cyclase to produce more cyclic AMP. A rise in cyclic AMP may initiate a cascade of enzymic reactions resulting in enhanced metabolism of glycogen to intermediates which are utilized for the production of energy during the time that the exogenous source of energy i.e. food, is restricted.