gamma-Aminobutyric acid(A) receptor subunit expression predicts functional changes in hippocampal dentate granule cells during postnatal development.

Profound alterations in the function of GABA occur over the course of postnatal development. Changes in GABA(A) receptor expression are thought to contribute to these differences in GABAergic function, but how subunit changes correlate with receptor function in individual developing neurons has not been defined precisely. In the current study, we correlate expression of 14 different GABA(A) receptor subunit mRNAs with changes in the pharmacological properties of the receptor in individual hippocampal dentate granule cells over the course of postnatal development in rat. We demonstrate significant developmental differences in GABA(A) receptor subunit mRNA expression, including greater than two-fold lower expression of alpha1-, alpha4- and gamma2-subunit mRNAs and 10-fold higher expression of alpha5-mRNA in immature compared with adult neurons. These differences correlate both with regional changes in subunit protein level and with alterations in GABA(A) receptor function in immature dentate granule cells, including two-fold higher blockade by zinc and three-fold lower augmentation by type-I benzodiazepine site modulators. Further, we find an inverse correlation between changes in GABA(A) receptor zinc sensitivity and abundance of vesicular zinc in dentate gyrus during postnatal development. These findings suggest that developmental differences in subunit expression contribute to alterations in GABA(A) receptor function during postnatal development.

Effects of tumor necrosis factor-binding protein on hepatic protein synthesis during chronic sepsis.

BACKGROUND: Cytokines are thought to play a role in the stimulation of protein synthesis in liver during inflammation and sepsis. We previously showed that administration of tumor necrosis factor-binding protein (TNFbp) prevents the sepsis-induced inhibition of protein synthesis in skeletal muscle. The purpose of the present set of experiments was to investigate the effect of TNFbp on hepatic protein synthesis and its ability to modulate the mechanisms responsible for increased hepatic protein synthesis during chronic (5-day) intraabdominal sepsis. MATERIALS AND METHODS: We examined the effects of TNFbp on hepatic protein synthesis during sepsis in four groups of rats: control, control + TNFbp, septic, and septic + TNFbp. Saline (1.0 ml) or TNFbp (1 mg/kg, 1.0 ml) was injected daily starting 4 h prior to the induction of sepsis. The effect of sepsis and TNFbp administration on hepatic protein synthesis in vivo was examined 5 days later. RESULTS: Sepsis increased the rate of protein synthesis by 35% relative to controls. Accelerated rates of protein synthesis were accompanied by increased total RNA content, eukaryotic initiation factor (eIF) 2alpha content, and phosphorylation of p70S6 kinase. Injection of TNFbp into septic rats for 5 days did not diminish the sepsis-induced stimulation of hepatic protein synthesis. Compared with controls, septic rats treated with TNFbp also showed elevated total RNA content, elF2alpha content, and phosphorylation of p70S6 kinase. No significant differences in any of the parameters measured were observed between untreated and TNFbp-treated septic rats. Treatment of control animals with TNFbp for 5 days was without effect on any of the parameters examined. CONCLUSIONS: TNFbp did not prevent the sepsis-induced stimulation of hepatic protein metabolism or modulate the septic-induced changes in factors regulating protein synthesis. Global rates of protein synthesis in livers from septic rats are accelerated by increases in the abundance or activity of components of translational apparatus.

Growth hormone does not attenuate the inhibitory effects of sepsis on wound healing.

Chronic abdominal sepsis is associated with impaired tissue repair. Treatment of burn patients with growth hormone results in improved healing of skin graft donor sites. The goal of this study was to determine whether administration of growth hormone could attenuate the inhibitory effects of sepsis on cutaneous wound healing. Four groups of male Sprague Dawley rats were studied: control, control + growth hormone, sepsis, and sepsis + growth hormone. Sepsis was caused by implantation of a bacterial focus in the peritoneal cavity. Control animals underwent sham laparotomy, and polyvinyl alcohol sponge implants were placed in subdermal pockets in all animals. Saline or growth hormone (400 microg) was injected subcutaneously every 12 hours. On day 5, the incisional wounds and polyvinyl alcohol sponge implants were harvested. The breaking strength of abdominal incisions was measured. Granulation tissue penetration and quality were determined by scoring polyvinyl alcohol sponge implant histology from 1 to 4 in a blinded fashion. Collagen deposition in polyvinyl alcohol sponge implants was quantitated by hydroxyproline assay. Septic mortality was not altered by growth hormone administration. Septic animals showed a reduction in food consumption for 2 days after surgery (p < 0.05 vs. controls), which was not affected by growth hormone administration. The breaking strength of incisional wounds and hydroxyproline content of polyvinyl alcohol sponge implants was reduced in septic rats (p < 0.001 vs. controls) but administration of growth hormone for 5 days did not improve breaking strength or collagen deposition in either group. We conclude that the administration of growth hormone for 5 days did not improve collagen deposition or breaking strength in cutaneous wounds from control or septic animals. The results suggest that growth hormone treatment is unlikely to improve tissue repair in sepsis-induced catabolic illness.

Regionally selective blockade of GABAergic inhibition by zinc in the thalamocortical system: functional significance.

The thalamocortical (TC) system is a tightly coupled synaptic circuit in which GABAergic inhibition originating from the nucleus reticularis thalami (NRT) serves to synchronize oscillatory TC rhythmic behavior. Zinc is colocalized within nerve terminals throughout the TC system with dense staining for zinc observed in NRT, neocortex, and thalamus. Whole cell voltage-clamp recordings of GABA-evoked responses were conducted in neurons isolated from ventrobasal thalamus, NRT, and somatosensory cortex to investigate modulation of the GABA-mediated chloride conductance by zinc. Zinc blocked GABA responses in a regionally specific, noncompetitive manner within the TC system. The regional levels of GABA blockade efficacy by zinc were: thalamus > NRT > cortex. The relationship between clonazepam and zinc sensitivity of GABA(A)-mediated responses was examined to investigate possible presence or absence of specific GABA(A) receptor (GABAR) subunits. These properties of GABARs have been hypothesized previously to be dependent on presence or absence of the gamma2 subunit and seem to display an inverse relationship. In cross-correlation plots, thalamic and NRT neurons did not show a statistically significant relationship between clonazepam and zinc sensitivity; however, a statistically significant correlation was observed in cortical neurons. Spontaneous epileptic TC oscillations can be induced in vitro by perfusion of TC slices with an extracellular medium containing no added Mg(2+). Multiple varieties of oscillations are generated, including simple TC burst complexes (sTBCs), which resemble spike-wave discharge activity. A second variant was termed a complex TC burst complex (cTBC), which resembled generalized tonic clonic seizure activity. sTBCs were exacerbated by zinc, whereas cTBCs were blocked completely by zinc. This supported the concept that zinc release may modulate TC rhythms in vivo. Zinc interacts with a variety of ionic conductances, including GABAR currents, N-methyl-D-aspartate (NMDA) receptor currents, and transient potassium (A) currents. D-2-amino-5-phosphonovaleric acid and 4-aminopyridine blocked both s- and cTBCs in TC slices. Therefore NMDA and A current-blocking effects of zinc are insufficient to explain differential zinc sensitivity of these rhythms. This supports a significant role of zinc-induced GABAR modulation in differential TC rhythm effects. Zinc is localized in high levels within the TC system and appears to be released during TC activity. Furthermore application of exogenous zinc modulates TC rhythms and differentially blocks GABARs within the TC system. These data are consistent with the hypothesis that endogenously released zinc may have important neuromodulatory actions impacting generation of TC rhythms, mediated at least in part by effects on GABARs.

Human neuronal gamma-aminobutyric acid(A) receptors: coordinated subunit mRNA expression and functional correlates in individual dentate granule cells.

gamma-Aminobutyric acid(A) receptors (GABARs) are heteromeric proteins composed of multiple subunits. Numerous subunit subtypes are expressed in individual neurons, which assemble in specific preferred GABAR configurations. Little is known, however, about the coordination of subunit expression within individual neurons or the impact this may have on GABAR function. To investigate this, it is necessary to profile quantitatively the expression of multiple subunit mRNAs within individual cells. In this study, single-cell antisense RNA amplification was used to examine the expression of 14 different GABAR subunit mRNAs simultaneously in individual human dentate granule cells (DGCs) harvested during hippocampectomy for intractable epilepsy. alpha4, beta2, and delta-mRNA levels were tightly correlated within individual DGCs, indicating that these subunits are expressed coordinately. Levels of alpha3- and beta2-mRNAs, as well as epsilon- and beta1-mRNAs, also were strongly correlated. No other subunit correlations were identified. Coordinated expression could not be explained by the chromosomal clustering of GABAR genes and was observed in control and epileptic rats as well as in humans, suggesting that it was not species-specific or secondary to epileptogenesis. Benzodiazepine augmentation of GABA-evoked currents also was examined to determine whether levels of subunit mRNA expression correlated with receptor pharmacology. This analysis delineated two distinct cell populations that differed in clonazepam modulation and patterns of alpha-subunit expression. Clonazepam augmentation correlated positively with the relative expression of alpha1- and gamma2-mRNAs and negatively with alpha4- and delta-mRNAs. These data demonstrate that specific GABAR subunit mRNAs exhibit coordinated control of expression in individual DGCs, which has significant impact on inhibitory function.

Interleukin-1 receptor antagonist attenuates tumor necrosis factor-induced alterations in wound breaking strength.

BACKGROUND: Tumor necrosis factor (TNF) is an important mediator of impaired wound healing during sepsis. To determine whether the inhibitory effects of systemic TNF on wound healing are mediated directly by TNF or by means of the induction of interleukin-1 (IL-1), we investigated the effects of TNF and interleukin- receptor antagonist (IL-1ra) on wound healing in healthy rats. METHODS: Male Sprague-Dawley rats were anesthetized, and jugular catheters were placed. After recovery of 48 hours, osmotic minipumps were inserted into the peritoneal cavity and polyvinyl alcohol implants were placed subcutaneously. Control rats were infused with saline (24 microL/day, i.p., and 15 mL/day, i.v.). TNF rats received TNF i.p. (100 microg/kg per day) and saline i.v. (15 mL/day). TNF+IL-1ra rats received TNF i.p. (100 microg/kg per day) and IL-1ra i.v. (2 mg/kg per day;15 mL/day). All animals were pair fed to the TNF group. On day 6, the wounds were harvested. The breaking strength of the abdominal incision was measured. Granulation tissue penetration and quality were determined by scoring polyvinyl alcohol implant histology from 1 to 4 in a blinded manner. Collagen deposition in polyvinyl alcohol implants was quantified by hydroxyproline assay. RESULTS: TNF decreased the breaking strength of incisional wounds to 40% of control levels (p < 0.001). IL-1ra restored the breaking strength of incisions from TNF-infused animals to 80% of control levels. Similar reductions in granulation tissue penetration, quality, and hydroxyproline content were observed in TNF-treated animals and were partially ameliorated by IL-1ra. CONCLUSION: IL-1ra significantly attenuates the inhibitory effects of systemic TNF on wound healing. These results suggest that the inhibitory effects of TNF on cutaneous tissue repair are mediated in part by IL-1.

Chronic infusion of interleukin 1 induces hyperlactatemia and altered regulation of lactate metabolism in skeletal muscle.

BACKGROUND: Hyperlactatemia is observed commonly in patients with severe inflammation syndrome or sepsis. Elevated plasma lactate concentrations may be caused by cytokine-mediated alterations in specific organ systems responsible for lactate homeostasis. The role of interleukin 1 (IL-1) in inducing hyperlactatemia and derangements in skeletal muscle and hepatic lactate metabolism was investigated by examining the consequences of infusing IL-1 continuously into normal rats. METHODS: Male Sprague-Dawley rats were anesthetized, and catheters were placed in the jugular vein. Rats were allowed to recover for 48 hours and were infused subsequently with either saline (control) or human recombinant IL-1alpha (20 microg/kg/d) for 6 days. On day 6, plasma, liver, and muscle samples were extracted and assayed for lactate and pyruvate dehydrogenase (PDH) activity. RESULTS: Plasma glucose concentrations were not different in the two groups. IL-1 infusion resulted in a twofold (p < .05) increase in the plasma lactate concentration compared with controls. IL-1 infusion also resulted in an elevated lactate content in skeletal muscle (p < .05) but not in liver. The proportion of PDH in the active form (PDHa) was reduced significantly (p < .05) in the skeletal muscle of animals infused with IL-1 compared with controls. In contrast to muscle, hepatic PDHa did not differ between the two groups. Total PDH complex activity was not affected in either liver or skeletal muscle. CONCLUSIONS: IL-1 infusion results in hyperlactatemia, increased skeletal muscle lactate, and a reduced PDHa in skeletal muscle. We conclude that IL-1 is a potential mediator of the derangements in lactate metabolism in skeletal muscle but not in liver.

Mechanism of IL-1 induced inhibition of protein synthesis in skeletal muscle.

Chronic interleukin (IL)-1 administration is associated with negative nitrogen balance and the loss of lean body mass. To elucidate the molecular mechanism(s) by which IL-1 modulates protein metabolism in muscle, we investigated the effects of chronic (6 day) IL-1alpha infusion on protein synthesis in Individual muscles (gastrocnemius, soleus, heart) compared with saline-infused control rats. IL-1 significantly decreased muscle weight, protein content, and the rate of protein synthesis in gastrocnemius (fast-twitch muscle). IL-1 had no effect on these parameters in the heart, whereas only the rate of protein synthesis was reduced in soleus (slow-twitch muscle). The reduction in gastrocnemius protein synthesis was not the result of a decrease in total RNA content, but was associated with a diminished translational efficiency. The diminished translational efficiency correlated with a 40% reduction in the epsilon-subunit of eukaryotic initiation factor 2B (elF2Bepsilon) in gastrocnemius from IL-1 -treated animals. However, the content of the alpha-subunit of elF2 (elF2alpha) was unaffected. In contrast, the elF2alpha content in heart was increased by IL-1, although elF2Bepsilon levels were unchanged. Reductions in skeletal muscle protein synthesis were not associated with a concomitant reduction in circulating or tissue content of insulin-like growth factor I. In summary, the IL-1-induced decrease in gastrocnemius protein synthesis appears to be regulated at the level of RNA translation via a reduction in elF2Bepsilon. These findings support a regulatory role for IL-1 as a mediator of muscle protein synthesis and the alterations in body composition observed in catabolic states where this cytokine is overexpressed.

TNF-binding protein ameliorates inhibition of skeletal muscle protein synthesis during sepsis.

We examined the effects of TNF-binding protein (TNFBP) on regulatory mechanisms of muscle protein synthesis during sepsis in four groups of rats: Control; Control+TNFBP; Septic; and Septic+TNFBP. Saline (1. 0 ml) or TNFBP (1 mg/kg, 1.0 ml) was injected daily starting 4 h before the induction of sepsis. The effect of TNFBP on gastrocnemius weight, protein content, and the rate of protein synthesis was examined 5 days later. Sepsis reduced the rate of protein synthesis by 35% relative to controls by depressing translational efficiency. Decreases in protein synthesis were accompanied by similar reductions in protein content and muscle weight. Treatment of septic animals with TNFBP for 5 days prevented the sepsis-induced inhibition of protein synthesis and restored translational efficiency to control values. TNFBP treatment of Control rats for 5 days was without effect on muscle protein content or protein synthesis. We also assessed potential mechanisms regulating translational efficiency. The phosphorylation state of p70(S6) kinase was not altered by sepsis. Sepsis reduced the gastrocnemius content of eukaryotic initiation factor 2Bepsilon (eIF2Bepsilon), but not eIF2alpha. The decrease in eIF2Bepsilon content was prevented by treatment of septic rats with TNFBP. TNFBP ameliorates the sepsis-induced changes in protein metabolism in gastrocnemius, indicating a role for TNF in the septic process. The data suggest that TNF may impair muscle protein synthesis by reducing expression of specific initiation factors during sepsis.

Selective changes in single cell GABA(A) receptor subunit expression and function in temporal lobe epilepsy.

Temporal lobe epilepsy is the most prevalent seizure disorder in adults. Compromised inhibitory neurotransmitter function in the hippocampus contributes to the hyperexcitability generating this condition, but the underlying molecular mechanisms are unknown. Combining patch-clamp recording and single-cell mRNA amplification (aRNA) techniques in single dentate granule cells, we demonstrate that expression of GABA(A) receptor subunit mRNAs is substantially altered in neurons from epileptic rats. These changes in gene expression precede epilepsy onset by weeks and correlate with profound alterations in receptor function, indicating that aberrant GABA(A) receptor expression and function has an essential role in the process of epileptogenesis.

GABA(A) receptor function in epileptic human dentate granule cells: comparison to epileptic and control rat.

Using patch clamp recording techniques in dentate granule cells (DGCs) isolated from patients undergoing temporal lobectomy for intractable epilepsy, we investigated basic properties of GABA(A) receptors (GABA(A)Rs) and pharmacological sensitivity of GABA-evoked currents to modulation by zinc and benzodiazepines (BZ). Properties of human DGC GABA(A)Rs were compared to DGC GABA(A)R properties in control and epileptic rats. Blockade of GABA evoked currents by zinc was significantly enhanced in epileptic human relative to control rat DGCs. Augmentation of the GABA(A)R current by the non-subunit selective BZ agonist, clonazepam (CNZ) and by the BZ1 specific agonist, zolpidem (ZOL), were not significantly different in human DGCs relative to control or epileptic rat. GABA potency was significantly higher in epileptic human DGCs than in control or epileptic rat DGCs. The significantly enhanced efficacy of zinc in blocking GABA currents in epileptic human DGCs mirrors that seen in epileptic rat DGCs, and was coupled with mossy fiber sprouting evident in both epileptic human and rat dentate gyrus. The aberrant mossy fibers provide a novel zinc delivery system within the epileptic dentate gyrus. The mossy fiber release of zinc onto DGCs coupled with the enhanced zinc sensitivity of GABA(A)Rs in epileptic DGCs, may lead to 'dynamic disinhibition' which could compromise inhibitory efficacy in the epileptic rat and human hippocampus.

Tumor necrosis factor binding protein improves incisional wound healing in sepsis.

BACKGROUND: Sepsis is associated with poor wound healing; however, the exact role of tumor necrosis factor (TNF) as a mediator of sepsis-induced alterations in different types of tissue repair is unknown. This study examines the effects of a specific TNF antagonist (TNFbp) on the healing of intestinal anastomoses, incisional wounds, and polyvinyl (PVA) sponge implants in chronic abdominal sepsis. METHODS: Three groups of male Sprague-Dawley rats were studied: control, sepsis, and sepsis + TNFbp. Jejunal resection and anastomosis were performed through a 4-cm upper midline incision on day 1. On day 3, sepsis was induced by creation of a chronic abdominal abscess. Saline (0.1 ml) or TNFbp (1.0 mg/kg, 0.1 ml) was injected subcutaneously every day starting 4 h prior to sepsis. On day 7, the wound-breaking strength (WBS) of the skin incision and intestinal anastomoses was determined using a tensiometer. Wound histology and collagen deposition were evaluated by comparison of Sirius red-stained sections. The hydroxyproline content of PVA sponges was used to quantitate collagen content under the different experimental conditions. RESULTS: Septic mortality (20% vs 26%) was not significantly altered by TNFbp. Septic animals demonstrated a reduction in food consumption on days 3 to 5 that was not affected by TNFbp administration. Neither sepsis nor TNFbp altered the breaking strength or histologic appearance of intestinal anastomoses. However, the breaking strength of incisional wounds was decreased by 40% in septic rats (P < 0.001 vs controls). Administration of TNFbp to septic rats significantly improved incisional WBS (P < 0.01 vs sepsis), but not to control levels. Serius red staining of incisional wounds and PVA sponges demonstrated a decrease in collagen organization and deposition in septic rats that was ameliorated by TNFbp. Similarly, the reduction in hydroxyproline content of PVA sponges from septic animals was prevented by TNFbp. CONCLUSIONS: The process of tissue repair in intestine and skin wounds appears to be significantly different following the septic insult. The healing of jejunal anastomoses was refractory to the catabolic effects of sepsis. In contrast, collagen deposition and organization are significantly decreased in cutaneous wounds during chronic sepsis. TNFbp significantly ameliorated the inhibitory effects of sepsis on cutaneous wound healing. These results suggest that TNF is an important mediator of the decrease in collagen deposition observed in cutaneous wounds during the septic state.

Differential epilepsy-associated alterations in postsynaptic GABA(A) receptor function in dentate granule and CA1 neurons.

Alterations in GABAergic function associated with the development of temporal lobe epilepsy (TLE) were examined with the use of patch-clamp recording techniques in dentate granule (DG) and CA1 neurons acutely isolated from control and spontaneously epileptic rats in which TLE was elicited by pilocarpine injection 3-17 wk before use. The maximal efficacy of gamma-aminobutyric acid (GABA) in activating whole cell GABA currents increased significantly in epileptic DG neurons relative to controls. This efficacy increase was due to a 78% enhancement in the functional capacitance-normalized GABA(A) receptor (GABA(A)R) current density in epileptic DG neurons. Increased DG GABA(A)R current density was not accompanied by alterations in GABA potency (EC50). However, the maximal sensitivity of DG GABA-evoked currents to blockade by zinc increased 190% in epileptic neurons. Augmentation of epileptic DG neuron GABA-evoked currents by the broad-spectrum anticonvulsant benzodiazepine clonazepam (100 nM) was enhanced 114% relative to controls, whereas augmentation by the benzodiazepine, (BZ1)-selective agonist zolpidem (100 nM) was decreased by 66%. In contrast to DG neurons, maximal efficacy of GABA in activating GABA currents decreased in epileptic CA1 neurons relative to controls, due to a 52% decrease in functional capacitance-normalized GABA(A)R current density. This altered efficacy of GABA was accompanied by an increased GABA potency (GABA EC50 was 35.8 and 24.5 microM in control and epileptic neurons, respectively). Sensitivity of GABA-evoked currents to blockade by zinc was unchanged in epileptic CA1 neurons, whereas clonazepam (100 nM) augmentation of CA1 GABA-evoked currents decreased 81% relative to controls. These regionally distinct epilepsy-associated modifications in hippocampal GABAergic function may be due to discrete structural alterations in postsynaptic GABA(A)Rs accompanying epileptogenesis, could be therapeutically important, and undoubtedly could contribute to the enhanced limbic excitability underlying TLE.

Brain injury-induced enhanced limbic epileptogenesis: anatomical and physiological parallels to an animal model of temporal lobe epilepsy.

Traumatic brain injury (TBI) is a leading cause of symptomatic epilepsy in young adults. This study examined physiological and anatomical epileptogenic consequences of a prior incident of TBI in rats. Rats were subjected to a fluid percussion brain injury one week prior to experimentation, and in vitro electrophysiological recording studies were conducted using combined hippocampal-entorhinal cortical slices (HEC slices). Results were compared to sham operated controls and rats in which a condition of chronic temporal lobe epilepsy was induced by a 2 h bout of pilocarpine-induced status epilepticus 2 months prior to recording (PILO). In field potential recording, PILO HEC slices evidenced a greater degree of disinhibition in Ca1 than did TBI or control slices. TBI slices showed greater disinhibition in the dentate gyrus than did PILO or control rats. In in vitro kindling experiments, 86% of TBI HEC slices generated self-sustaining epileptic activity within 9 stimulus trains. This type of activity was never triggered in control slices. HEC slices prepared from PILO animals generated self-sustaining epileptic activity with fewer stimulus trains than did TBI slices. In anatomical studies, both TBI and PILO hippocampi evidenced significant loss of neurons within the hilar region. TBI induces a series of changes within the limbic system of rats, which are qualitatively similar in many aspects but quantitatively less severe than changes seen in rats with chronic temporal lobe epilepsy. These physiological and anatomical TBI-associated alterations in the limbic system may contribute to the development of epilepsy following head trauma.