Functional brain mapping based on changes in local cerebral blood flow (lCBF) or glucose utilization (lCMRglc) induced by functional activation is generally carried out in animals under anesthesia, usually ␣-chloralose because of its lesser effects on cardiovascular, respiratory, and reflex functions. Results of studies on the role of nitric oxide (NO) in the mechanism of functional activation of lCBF have differed in unanesthetized and anesthetized animals. NO synthase inhibition markedly attenuates or eliminates the lCBF responses in anesthetized animals but not in unanesthetized animals. The present study examines in conscious rats and rats anesthetized with ␣-chloralose the effects of vibrissal stimulation on lCMRglc and lCBF in the whisker-to-barrel cortex pathway and on the effects of NO synthase inhibition with N G -nitro-L-arginine methyl ester (L-NAME) on the magnitude of the responses. Anesthesia markedly reduced the lCBF and lCMRglc responses in the ventral posteromedial thalamic nucleus and barrel cortex but not in the spinal and principal trigeminal nuclei. L-NAME did not alter the lCBF responses in any of the structures of the pathway in the unanesthetized rats and also not in the trigeminal nuclei of the anesthetized rats. In the thalamus and sensory cortex of the anesthetized rats, where the lCBF responses to stimulation had already been drastically diminished by the anesthesia, L-NAME treatment resulted in loss of statistically significant activation of lCBF by vibrissal stimulation. These results indicate that NO does not mediate functional activation of lCBF under physiological conditions. whisker-to-barrel cortex pathway ͉ cerebral glucose utilization ͉ deoxy[ 14 C]glucose ͉ functional brain imaging ͉ iodo[ 14 C]antipyrine N euronal functional activation is normally associated with increases in local cerebral glucose utilization (lCMR glc ) and blood flow (lCBF) in anatomic units of the activated neural pathways. These associations are now widely exploited to map regions of the brain involved in specific neural and cognitive processes. The mechanisms underlying the functional activation of lCMR glc are reasonably well understood. Glucose utilization is increased by functional activation in direct proportion to the increases in spike frequency in the afferent inputs to the activated areas, and the increases are localized in neuropil and not perikarya (1, 2). The increases in lCMR glc appear to result mainly from activation of Na ϩ ,K ϩ -ATPase activity (2, 3), needed to restore ionic gradients in the neuronal elements degraded by the spike activity. Neuropil contains not only axonal and dendritic processes but also astroglial processes, and glutamate stimulates glucose utilization in astroglia, also due in part to activation of Na ϩ ,K ϩ -ATPase activity by coupled uptake of Na ϩ ions with the glutamate released during functional activation (4, 5). Glucose utilization is also increased to support the ATPdependent conversion to glutamine of the glutamate taken up by the astroglia (6).The mechan...
. Regional differences in mechanisms of cerebral circulatory response to neuronal activation. Am J Physiol Heart Circ Physiol 280: H821-H829, 2001.-Vibrissal stimulation raises cerebral blood flow (CBF) in the ipsilateral spinal and principal sensory trigeminal nuclei and contralateral ventroposteromedial (VPM) thalamic nucleus and barrel cortex. To investigate possible roles of adenosine and nitric oxide (NO) in these increases, local CBF was determined during unilateral vibrissal stimulation in unanesthetized rats after adenosine receptor blockade with caffeine or NO synthase inhibition with N G -nitro-L-arginine methyl ester (L-NAME) or 7-nitroindazole (7-NI). Caffeine lowered baseline CBF in all structures but reduced the percent increase during stimulation only in the two trigeminal nuclei. L-NAME and 7-NI lowered baseline CBF but reduced the percent increase during stimulation only in the higher stations of this sensory pathway, i.e., L-NAME in the VPM nucleus and 7-NI in both the VPM nucleus and barrel cortex. Combinations of caffeine with 7-NI or L-NAME did not have additive effects, and none alone or in combination completely eliminated functional activation of CBF. These results suggest that caffeine-sensitive and NO-dependent mechanisms are involved but with different regional distributions, and neither fully accounts for the functional activation of CBF. adenosine; nitric oxide; caffeine; 7-nitroindazole; N G -nitro-Larginine NUMEROUS STUDIES HAVE ESTABLISHED that neuronal functional activation is associated with increases in both cerebral energy metabolism and blood flow (CBF) in components of the activated neural pathway (8,18,(30)(31)(32). The increases in energy metabolism evoked by functional activation have been shown to be proportional to the increases in spike frequency in the afferent inputs to the activated areas (13, 32) and to be due mainly to activation of Na ϩ -K ϩ -ATPase activity (21, 32). The mechanisms mediating the increases in CBF during functional activation remain, however, largely undefined. A popular hypothesis proposed by Roy and Sherrington (27) was that CBF is intrinsically regulated by products of energy metabolism to meet the altered metabolic demands associated with functional activity. This hypothesis received support from subsequent findings that CBF is raised by increased CO 2 tension, lowered pH, and decreased oxygen tension, all expected consequences of increased tissue metabolism, and reduced by changes in these chemical factors in the opposite direction, to be expected with decreased metabolism (14). Since then, many other endogenous agents that affect cerebral blood vessels, e.g., nitric oxide (NO), adenosine, adenine nucleotides, K ϩ , prostaglandins, vasoactive intestinal peptide, etc., have been identified and considered as possible candidates, but not one of them, alone or in combination with others, has yet been proven to account fully or even to be essential for the enhancement of CBF by neuronal activation.Inhibition of cerebral glucose utilization by hypo...
Overproduction of Acyloxyacyl Hydrolase by Macrophages and Dendritic Cells Prevents Prolonged Reactions to Bacterial Lipopolysaccharide In Vivo
Whereas recognition of LPS by the MD-2—TLR4 receptor complex is important for triggering protective inflammatory responses in animals, terminating many of these responses requires LPS inactivation by a host lipase, acyloxyacyl hydrolase (AOAH). To test if endogenously-produced recombinant AOAH can modulate responses to LPS and Gram-negative bacteria, we engineered transgenic mice that overexpress AOAH in dendritic cells and macrophages, cell types that normally produce it. Transgenic mice deacylated LPS more rapidly than did wildtype controls. They were also protected from LPS-induced hepatosplenomegaly, recovered more quickly from LPS-induced weight loss, and were more likely to survive when challenged with live E. coli. Constitutive overexpression of AOAH in vivo hastened recovery from LPS exposure without interfering with the normal acute inflammatory response to this important microbial signal molecule. Our results suggest that the extent to which macrophages and dendritic cells produce AOAH may influence the outcome of many Gram-negative bacterial diseases.
The possibility that adenosine and ATP-sensitive potassium channels (KATP) might be involved in the mechanisms of the increases in cerebral blood flow (CBF) that occur in insulin-induced hypoglycemia was examined. Cerebral blood flow was measured by the [14C]iodoantipyrine method in conscious rats during insulin-induced, moderate hypoglycemia (2 to 3 mmol/L glucose in arterial plasma) after intravenous injections of 10 to 20 mg/kg of caffeine, an adenosine receptor antagonist, or intracisternal infusion of 1 to 2 mumol/L glibenclamide, a KATP channel inhibitor. Cerebral blood flow was also measured in corresponding normoglycemic and drug-free control groups. Cerebral blood flow was 51% higher in untreated hypoglycemic than in untreated normoglycemic rats (P < 0.01). Caffeine had a small, statistically insignificant effect on CBF in normoglycemic rats, but reduced the CBF response to hypoglycemia in a dose-dependent manner, i.e., 27% increase with 10 mg/kg and complete elimination with 20 mg/kg. Chemical determinations by HPLC in extracts of freeze-blown brains showed significant increases in the levels of adenosine and its degradation products, inosine and hypoxanthine, during hypoglycemia (P < 0.05). Intracisternal glibenclamide had little effect on CBF in normoglycemia, but, like caffeine, produced dose-dependent reductions in the magnitude of the increases in CBF during hypoglycemia, i.e., +66% with glibenclamide-free artificial CSF administration, +25% with 1 mumol/L glibenclamide, and almost complete blockade (+5%) with 2 mumol/L glibenclamide. These results suggest that adenosine and KATP channels may play a role in the increases in CBF during hypoglycemia.
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