Response to ethanol reduced by past thiamine deficiency.

Ethanol-induced intoxication and hypothermia were studied in rats approximately 7 months after severe thiamine deficiency, when treated rats appeared to have recovered their physical health. Previously induced thiamine deficiency without prior ethanol exposure significantly decreased the area under the curve plotted for the concentration of ethanol in blood and also decreased behavioral impairment and hypothermia due to ethanol exposure. Pathophysiologic changes resulting from thiamine deficiency may contribute to both the pharmacodynamic and pharmacokinetic tolerance to ethanol in chronic alcoholics.

Effects of ethanol administration on parameters of immunocompetency in rats.

Ethanol administered to rats intragastrically in doses sufficient to cause dependency resulted in a rapid cell loss from the thymus and spleen. Cell loss from the peripheral blood was due primarily to a loss of lymphocytes, but a concomitant granulocytosis resulted in only small changes in the total leukocyte count. Lymphocyte proliferation to both T- and B-cell mitogens was severely compromised by ethanol treatment. The cell loss and functional lymphocyte impairment also occurred at half the ethanol dose required to induce dependency. Although cell numbers recovered relatively quickly after ethanol withdrawal, lymphocyte function, as measured by proliferation, recovered more slowly. Ethanol administration before or during immunization with sheep erythrocytes resulted in an impairment in the ability of animals to respond with a primary immune response to this antigen. These data suggest that ethanol given in quantities sufficient to produce dependence impairs in vitro and in vivo parameters of immunocompetency.

Expression of long-patch and short-patch DNA mismatch repair proteins in the embryonic and adult mammalian brain.

Expression of the DNA mismatch repair (MMR) pathway was examined in the adult and developing rat brain. Rat homologues of human GTBP and MSH2, which are essential components of the post-replicative DNA MMR system, were identified in nuclear extracts from the adult and developing rat brain. Developmental studies showed that both GTBP and MSH2 levels were higher in nuclei isolated from the embryonic brain (day 16) than adult brain. However, this difference was not as dramatic as the difference in the number of proliferating cells. Levels of thymine DNA glycosylase (TDG), the enzyme which catalyzes the first step in short patch G:T mismatch repair, were also decreased in adult compared to embryonic brain. In the adult brain, MMR proteins were elevated in nuclear extracts enriched for neuronal nuclei. These results suggest that adult brain cells have the capacity to carry out DNA mismatch repair, in spite of a lack of ongoing DNA replication.

Molecular and phylogenetic analysis of calmodulin-dependent protein phosphatase (calcineurin) catalytic subunit genes.

In the mammalian brain, there are multiple catalytic subunits for the Ca(2+)- and calmodulin-dependent protein phosphatase [also called protein phosphatase 2B (PP-2B) and calcineurin] that are derived from two structural genes. The coding sequences of these two genes are distinguished by the absence (PP2B alpha 1) or the presence (PP2B alpha 2) of an amino terminus containing polyproline. Both of these genes can produce intragenic isoforms through alternative splicing. In the present study, a potential phylogenetic relationship of these genes was inferred from analysis of genomic DNA and from studies of mRNA and protein expression. Southern blot analysis showed unique restriction fragments for both genes in seven mammalian species; however, in organisms from two nonmammalian vertebrates (chicken and lizard), hybridization was observed only for PP2B alpha 1. In agreement with these results, Northern blots of mammalian brain RNA showed transcripts for both genes, with about two to three times more of the PP2B alpha 1 mRNAs, whereas in chicken and lizard, only PP2B alpha 1 transcripts were detected. An analysis of protein expression by two-dimensional electrophoresis was also consistent with these findings. For the purified mammalian brain protein, eight to ten variants were observed with isoelectric points of 5.2-5.8; immunoblot analysis using anti-peptide antibodies indicated that the majority of these were PP2B alpha 1 forms. In chicken brain, multiple isoforms were recognized by antibodies against the PP2B alpha 1 forms, but no reactivity was seen with those against the PP2B alpha 2 forms. Taken together, these findings suggest that: (i) in mammals, the predominant catalytic subunit isoforms in brain are PP2B alpha 1 products and (ii) the gene for the polyproline-containing catalytic subunit of calmodulin-dependent phosphatase (PP2B alpha 2) may have evolved after the avian/reptilian branching point, perhaps to carry out a role(s) of particular significance in mammals.

Acute ethanol administration selectively alters localized cerebral glucose metabolism.

The effects of acute ethanol administration on glucose utilization in the CNS of rat were studied using the 2-deoxyglucose technique. Cerebral glucose utilization was determined for 53 brain regions at peak and descending blood ethanol concentrations averaging 14, 26 and 66 mM. Decreased glucose utilization was the predominant finding and was observed in 20% of the regions evaluated, with median raphe, vestibular nucleus, cerebellar vermis, and various structures associated with the auditory system showing the greatest reductions. The only structures that showed increased glucose utilization were the dentate region of the hippocampus and the superior olive, and this was only apparent at a blood ethanol concentration of 14 mM.

Ethanol-withdrawal syndrome associated with both general and localized increases in glucose uptake in rat brain.

Glucose uptake was studied in the brains of rats undergoing an overt ethanol-withdrawal syndrome by 2-deoxy-D-[14C]glucose autoradiography. In addition to a general increase in glucose uptake, localized alterations were observed in sensorimotor cortex, globus pallidus, thalamus and cerebellum. The results suggest that the ethanol-withdrawal syndrome is associated with a general increase in glucose metabolism as well as localized increases in functionally distinct regions of sensory and motor brain regions.

Cerebral glucose utilization during diazepam withdrawal in rats.

The diazepam withdrawal syndrome in rats was characterized behaviorally by an increase in spontaneous motor activity, slight body tremor and a lack of convulsions. The 2-deoxyglucose (2-DG) technique was used to measure quantitatively cerebral glucose utilization during diazepam withdrawal and revealed changes in glucose utilization in 30% of the 54 structures evaluated. Areas of increased glucose utilization included medial geniculate, inferior colliculus, visual cortex, mammillary body, dorsal hippocampus, cerebellar flocculus, and zona reticulata and globus pallidus, olfactory cortex, nucleus accumbens and internal capsule. There was no single or consistent relationship between reported benzodiazepine receptor densities and glucose utilization.

Cerebral glucose utilization in rat brain during phenobarbital withdrawal.

The phenobarbital withdrawal syndrome in rats is characterized by tremors, arched back, weight loss and hyperactivity. This syndrome is shown to be associated with both general and localized increases in cerebral glucose utilization. An increase in glucose utilization (significant at the P less than or equal to 0.001 level) was observed in 72% of the 57 structures examined. Increases in glucose utilization of greater than or equal to 180% of control values were noted in structures associated with the motor system (columns in the frontal sensorimotor cortex, globus pallidus, dentate nucleus of the cerebellum and ovoid areas in the cerebellar vermis), thalamic nuclei (lateral and posterior), dorsal lateral geniculate, mammillary body, cingulate cortex, locus ceruleus, and cerebellar flocculus and paraflocculus. The structures showing the greatest increase in glucose utilization were cerebellar paraflocculus (257% of control), columns in the frontal sensorimotor cortex (247% of control) and ovoid areas in the cerebellar vermis (223% of control). Areas of the brain that have been described as cell body areas for serotonergic (raphe), noradrenergic (locus ceruleus), dopaminergic (substantia nigra, zona compacta) and GABAergic (globus pallidus) neurons also showed increases in glucose utilization. The pattern of cerebral glucose utilization accompanying the phenobarbital withdrawal syndrome in rats contrasts with that for morphine withdrawal and exhibits both similarities and differences with respect to ethanol withdrawal.

Cerebral 2-deoxyglucose uptake in rats during ethanol withdrawal and postwithdrawal.

The overt ethanol withdrawal syndrome is associated with a generalized increase in cerebral uptake of 2-deoxyglucose. Relatively high elevations of 2-deoxyglucose were observed in many structures associated with motor function, the mamillary body-anterior thalamus-cingulate cortex pathway, many thalamic nuclei, and the raphe. Overtly withdrawing rats had higher levels of 2-deoxyglucose than postwithdrawing animals that had been abstinent for 1-5 weeks in 96% of the gray areas evaluated. Postwithdrawal was associated with increased amounts of 2-deoxyglucose in comparison to controls in 80% of the gray areas evaluated. Postwithdrawal and control rats did not differ in some areas involved with motor function and some limbic structures, such as the mamillary body-anterior thalamus-cingulate cortex pathway. It is concluded that the ethanol-withdrawal syndrome results in alterations in cerebral physiology, some of which persist for at least 5 weeks postwithdrawal.

Ethanol dependence and withdrawal selectively alter localized cerebral glucose utilization.

The 2-deoxyglucose technique was used to determine local cerebral glucose utilization (LCGU) in over 50 brain regions of rats physically dependent upon ethanol and compared to those of acutely intoxicated and those undergoing an overt ethanol-withdrawal syndrome. Dependent-intoxicated rats (average blood ethanol concentration 64 mM) had decreased LCGU in 13/54 regions, including those associated with the limbic system, cerebellum, and motor system. The ethanol withdrawal syndrome was associated with 17/50 gray regions showing an increase, including regions involved with motor function, auditory system, and mammillary bodies-anterior thalamus-cingulate cortex pathway. The most pronounced differences between these groups occurred in regions associated with motor function, cerebellar function, anterior thalamus, and median raphe. Comparisons between dependent-intoxicated and acutely intoxicated rats (average blood ethanol concentration 66 mM) revealed that acute intoxication was associated with a relatively greater reduction in LCGU in regions involved with sensory-related functions, mammillary bodies, and median raphe. With the development of dependence, adaptation occurred in these regions except for inferior colliculus and median raphe. Dependence was also associated with a relative decrease in LCGU in white matter, limbic system, and extrapyramidal motor system.

DNA mismatch repair and DNA methylation in adult brain neurons.

DNA repair is essential for maintaining the integrity of the nucleotide sequence of cellular DNA over time. Although much information has accumulated recently on the mechanisms of DNA repair in cultured cells, little is known about the DNA repair capabilities of cells in the adult brain. In the present study, we have investigated the capacity of nuclear extracts from adult rodent brain neurons to carry out DNA mismatch repair. We focused on the repair of G.T and G.U mismatches, which are caused by deamination of 5-methyl cytosine to thymine, or cytosine to uracil, respectively, because these are the only types of mismatches that can arise in nondividing cells. We found that nuclear extracts from adult brain neurons can correct G.T and G.U mismatches, restoring them to G:C base pairs. Several other types of DNA mismatches could not be processed. These data provide the first direct demonstration that neurons in the adult mammalian brain have the capability to carry out DNA mismatch repair. We also we report that adult brain contains high levels of DNA methyltransferase (MTase) activity. We propose that one function of DNA MTase in the adult brain is to remethylate newly incorporated cytosine residues from G.T mismatch repair after deamination of 5-methyl cytosine, thereby maintaining the original pattern of DNA methylation. The high levels of brain DNA MTase suggest further that this enzyme has additional functions in the brain.

Alterations in interleukin-2 utilization by T-cells from rats treated with an ethanol-containing diet.

Administration of ethanol to Sprague-Dawley rats has been shown to produce a defect in lymphocyte proliferation in response to concanavalin A. Because a critical element in T-cell proliferation is the production of interleukin-2, experiments were designed to evaluate the influence of ethanol on the production and utilization of interleukin-2 by spleen cells from ethanol-treated animals. To ensure that changes in spleen cell responses to mitogenic stimulation were not simply caused by a loss of responding T cells, we tested nylon wool-nonadherent cells. The response to concanavalin A of isolated T cells from ethanol-treated rats was consistently less than that of equivalent numbers of cells from control animals. The addition of recombinant interleukin-2 to cultures of T cells did not correct the defect in proliferation to concanavalin A noted in cells from ethanol-treated rats. Further study results demonstrated that interleukin-2 production by T cells from ethanol-treated animals was equal to or greater than that by cells from animals given control diet. Blast cells recovered from 48-hr concanavalin A-stimulated spleen cell cultures from ethanol-treated animals, however, showed a decreased ability to proliferate in response to exogenous interleukin-2. Binding of 125I-interleukin-2 to blast cells resulting from concanavalin A stimulation, under conditions that detected high-affinity binding, was similar in cells from treated and control animals. These data indicate that the deficiency in proliferation of lymphocytes from ethanol-treated animals is not caused by a lack of interleukin-2 production by the T cells.(ABSTRACT TRUNCATED AT 250 WORDS)

Effect of adrenalectomy on ethanol-associated immunosuppression.

The alterations in lymphoid cell numbers and lymphocyte function due to administration of ethanol was found to be associated with high levels of circulating corticosteroids. The role of corticosteroids in the ethanol-induced alterations in the immune system was studied by administering ethanol to adrenalectomized rats. The results of these experiments showed that the ethanol-induced loss of cells from the thymus was not completely prevented by adrenalectomy and the ethanol-induced loss of cells from the spleen was not affected by adrenalectomy. Likewise the ethanol-induced decrease in antibody production to the T-cell-dependent antigen sheep erythrocytes were not affected by adrenalectomy. The ability of animals to produce antibodies of the T-cell-independent antigen, TNP-Ficoll, was not affected by ethanol regardless of whether the animals had adrenal glands or not. These data indicate that adrenal corticosteroids are responsible for some but not all of the thymic involution due to ethanol intoxication. Also, adrenalectomized rats did not show as much impairment in lymphocyte proliferation as sham adrenalectomized animals after ethanol administration. However, this loss of cells from peripheral lymphoid organs such as the spleen and the decreased ability to respond to T-cell-dependent antigens is not influenced by adrenalectomy indicating mechanisms other than corticosteroids mediate these effects of ethanol.

Mechanisms of suppression of cellular immunity induced by ethanol.

Previous study findings from this laboratory and other laboratories have established that ethanol administration to experimental animals or ingestion by human beings results in many changes in the immune system. The major effort in this laboratory is the study of the mechanisms by which ethanol down-regulates the responses of thymus-derived lymphocytes. By using a rat model of ethanol intoxication we have described a defect in lymphocyte proliferation to concanavalin A. In the current report data, preliminary and definitive, are presented that show our approach to determining the mechanisms of ethanol-associated impairments in the immune system, especially the defect in lymphocyte proliferation. We have found that purified thymus-derived lymphocytes from the spleens of ethanol-treated rats have an inherent defect in their response to mitogenic stimulation. This defect is not caused by the direct effects of ethanol on the cells and probably is not caused by an inability of the cells from ethanol-treated animals to produce the lymphocyte growth factor interleukin 2. Data are also presented that indicate that corticosteroids, produced most abundantly in this model by withdrawal from ethanol, play a role in the down-regulation of the response of spleen cells to mitogenic stimulation.

Effects of long-term ethanol inhalation on the immune and hematopoietic systems of the rat.

An inhalation method of ethanol administration was used to study the effects of 14 days of ethanol administration on the immune and hematopoietic systems of the rat. A decrease in cellularity was found in the spleen, thymus, and bone marrow of ethanol-treated rats. Although the red blood cell count, white blood cell count, and hemoglobin concentration were not significantly different between treatment and control groups, treatment with ethanol altered the relative proportion of lymphocytes and polymorphonuclear leukocytes in the peripheral blood. The granulocyte-macrophage progenitor cells in the bone marrow were unaffected by ethanol treatment, but a significant decline in the number of erythroid progenitor cells was noted in ethanol-treated rats. Splenic lymphocytes, although fewer in number in the ethanol-treated rats, showed no significant difference in ability to proliferate when stimulated by nonspecific mitogens.

Cloning and characterization of molecular isoforms of the catalytic subunit of calcineurin using nonisotopic methods.

The cloning and characterization of cDNAs for the catalytic subunit of calcineurin (CN) from murine and human brain libraries were carried out using nonisotopic methods. A murine cDNA clone encoding a protein of 521 amino acids (Mr approximately 58,650) was isolated; overlapping clones established a 3'-untranslated region of 554 base pairs preceding the poly(A) tail. Homologous cDNAs from human brain showed greater than 92% nucleotide sequence identity in both coding and non-coding regions with greater than 99% conservation of amino acid sequence. A second class of cDNAs lacking a specific 30-base pair region following the calmodulin-binding domain was found in four murine and human libraries. Oligonucleotide probes for both cDNA isoforms hybridized to mRNA from several brain regions indicating the existence of transcripts in vivo. The nucleotide sequences of the two forms were identical except for the inserted sequence, and Southern blot analysis of mouse and rat DNA was consistent with their having originated from the same gene; these data suggest that alternative splicing may give rise to molecular isoforms of the catalytic subunit in brain. Northern blots showed a predominant mRNA for CN in most tissues of approximately 4.0 kilobases (kb) with lower amounts of a 3.6-kb species. Brain showed 10 times more of these mRNAs than skeletal muscle while other tissues had less than or equal to 5% that in brain. In testis, multiple mRNAs were observed, with the major forms being approximately 2.8 and 1.6 kb; the total amount of CN message was about 15% that in brain. The presence of mRNA isoforms of the catalytic subunit may provide for isoenzymes of this phosphatase having distinct phosphoprotein substrate specificities or regulatory properties. The structural relatedness of CN to other mammalian serine/threonine protein phosphatases was highest over a region of approximately 240 amino acids near the amino terminus of this subunit, with greater similarity to protein phosphatase 2A than protein phosphatase 1. The conservation of many regions found in lambda phage phosphatase (Cohen, P.T.W., and Cohen, P. (1989) Biochem. J. 260, 931-934) indicates a common origin for the catalytic domain of this enzyme.