Cell bioenergetics in Leghorn male hepatoma cells and immortalized chicken liver cells in response to 4-hydroxy 2-nonenal-induced oxidative stress.

The major objectives of this study were to compare cell bioenergetics in 2 avian liver cell lines under control conditions and in response to oxidative stress imposed by 4-hydroxy 2-nonenal (4-HNE). Cells in this study were from a chemically immortalized Leghorn male hepatoma (LMH) cell line and a spontaneously immortalized chicken liver (CELi) cell line. Oxygen consumption rate (OCR) was monitored in specialized microtiter plates using an XF24 Flux Analyzer (Seahorse Bioscience, Billerica, MA). Cell bioenergetics was assessed by sequential additions of oligomycin, carbonyl cyanide-p-trifluoromethoxyphenylhydrazone (FCCP), and antimycin-A that enables the determination of a) OCR linked to adenosine triphosphate (ATP) synthase activity, b) mitochondrial oxygen reserve capacity, c) proton leak, and d) nonmitochondrial cytochrome c oxidase activity. Under control (unchallenged) conditions, LMH cells exhibited higher basal OCR and higher OCR attributed to each of the bioenergetic components listed above compared with CELi cells. When expressed as a percentage of maximal OCR (following uncoupling with FCCP), LMH cells exhibited higher OCR due to ATP synthase and proton leak activity, but lower mitochondrial oxygen reserve capacity compared with CELi cells; there were no differences in OCR associated with nonmitochondrial cytochrome c oxidase activity. Whereas the LMH cells exhibited robust ATP synthase activity up to 50 µM 4-HNE, CELi cells exhibited a progressive decline in ATP synthase activity with 10, 20, and 30 µM 4-HNE. The CELi cells exhibited higher mitochondrial oxygen reserve capacity compared with LMH cells with 0 and 20 µM 4-HNE but not with 30 µM 4-HNE. Both cell lines exhibited inducible proton leak in response to increasing levels of 4-HNE that was evident with 30 µM 4-HNE for CELi cells and with 40 and 50 µM 4-HNE in LMH cells. The results of these studies demonstrate fundamental differences in cell bioenergetics in 2 avian liver-derived cell lines under control conditions and in response to oxidative challenge due to 4-HNE.

Gene expression in breast muscle associated with feed efficiency in a single male broiler line using a chicken 44K microarray. II. Differentially expressed focus genes.

Global RNA expression in breast muscle obtained from a male broiler line phenotyped for high or low feed efficiency (FE) was investigated using microarray analysis. Microarray procedures and validation were reported previously. By using an overlay function of a software program (Ingenuity Pathway Analysis, IPA) in which canonical pathways are projected onto a set of genes, a subset of 27 differentially expressed focus genes were identified. Focus genes that were upregulated in the high FE phenotype were associated with important signal transduction pathways (Jnk, G-coupled, and retinoic acid) or in sensing cell energy status and stimulating energy production that would likely enhance growth and development of muscle tissue. In contrast, focus genes that were upregulated in the low FE muscle phenotype were associated with cytoskeletal architecture (e.g., actin-myosin filaments), fatty acid oxidation, growth factors, or ones that would likely be induced in response to oxidative stress. The results of this study provide additional information on gene expression and the cellular basis of feed efficiency in broilers.

Impact of in ovo administered pioneer colonizers on intestinal proteome on day of hatch.

Pioneer colonization of the gastrointestinal tract (GIT) by bacteria is thought to have major influence on neonatal tissue development. Previous studies have shown in ovo inoculation of embryos with saline (S), species of Citrobacter (C, C2), or lactic acid bacteria (L) resulted in an altered microbiome on day of the hatch (DOH). The present study investigated GIT proteomic changes at DOH in relation to different inoculations. Embryos were inoculated in ovo with S or ∼102 cfu of C, C2, or L at 18 embryonic days. On DOH, the GIT was collected, and tissue proteins were extracted for analysis via tandem mass spectrometry. A total of 493 proteins were identified for differential comparison with S at P ≤ 0.10. Different levels were noted in 107, 39, and 78 proteins in C, C2, and L groups, respectively, which were uploaded to Ingenuity Pathway Analysis to determine canonical pathways and biological functions related to these changes. Three members of the cytokine family (interleukin [IL]-1ß, IL6, and Oncostatin M) were predicted to be activated in C2, indicated with Z-score ≥ 1.50, which suggested an overall proinflammatory GIT condition. This was consistent with the activation of the acute-phase response signaling pathway seen exclusively in C2 (Z-score = 2.00, P < 0.01). However, activation (Z-score = 2.00) of IL-13, upregulation of peroxiredoxin-1 and superoxide dismutase 1, in addition to activation of nitric oxide signaling in the cardiovascular system of the L treatment may predict a state of increased antioxidant capacity and decreased inflammatory status. The nuclear factor erythroid 2-related factor 2 (NRF2)-mediated oxidative stress response (Z-score = 2.00, P < 0.01) was predicted to be upregulated in C which suggested that chicks were in an inflammatory state and associated oxidative stress, but the impact of these pathways differed from that of C2. These changes in the proteome suggest that pioneer colonizing microbiota may have a strong impact on pathways associated with GIT immune and cellular development.

A Proteomic View of the Cross-Talk Between Early Intestinal Microbiota and Poultry Immune System.

Proteomics has been used to investigate cross-talk between the intestinal microbiome and host biological processes. In this study, an in ovo technique and a proteomics approach was used to address how early bacterial colonization in the gastrointestinal tract (GIT) could modulate inflammatory and immune responses in young broilers. Embryos at 18 embryogenic days were inoculated with saline (S), 102 CFU of Citrobacter freundii (CF), Citrobacter species (C2), or lactic acid bacteria mixture (L) into the amnion. At 10 days posthatch, ileum samples from 12 birds per treatment were selected for tandem mass spectrometry analysis. Our further findings indicated that treatment-specific influences on early GIT microbiota resulted in different immune responses in mature broilers. Predicted functional analyses revealed activation of inflammation pathways in broilers treated in ovo with L and CF. Exposure to L enhanced functional annotation related to activation, trafficking of immune cells, and skeletal growth based-network, while CF inhibited biological functions associated with immune cell migration and inflammatory response. These results highlighted that proper immune function was dependent on specific GIT microbiota profiles, in which early-life exposure to L-based probiotic may have modulated the immune functions, whereas neonatal colonization of Enterobacteriaceae strains may have led to immune dysregulation associated with chronic inflammation.

Vaccination of chickens with recombinant Salmonella expressing M2e and CD154 epitopes increases protection and decreases viral shedding after low pathogenic avian influenza challenge.

Avian influenza (AI) is a significant public health concern and serious economic threat to the commercial poultry industry worldwide. Previous research demonstrates that antibodies against M2e confer protection against influenza challenge. Using the Red recombinase system in combination with overlapping extension PCR, we recently developed several novel attenuated Salmonella Enteritidis strains that express a protective M2e epitope in combination with a potential immune-enhancing CD154 peptide sequence on the Salmonella outer membrane protein lamB. Commercial Leghorn chicks were orally immunized (immunization dose: 10(6) to 10(8) cfu/chick) with saline (negative control) or one of the recombinant Salmonella strains [DeltaaroA M2e-CD154, DeltahtrA M2e-CD154, DeltaaroA-DeltahtrA M2e(4)-CD154] on day of hatch and 21 d posthatch. These candidate vaccine strains were evaluated for their ability to invade, colonize, and persist in tissues and elicit an M2e-specific antibody response. The vaccine candidate strain DeltaaroA M2e-CD154 exhibited significantly greater organ invasion in the liver and spleen at d 7 (P > 0.05); however, no marked differences in colonization of the cecal tonsils were observed. Vaccinated chickens exhibited significantly increased M2e-specific IgG responses, which were further enhanced by simultaneous expression of CD154 (P < 0.05). Virus neutralization assays gave neutralizing indices of 6.6, 6.3, and 6.3 for DeltaaroA M2e-CD154, DeltahtrA M2e-CD154, and DeltaaroA-DeltahtrA M2e(4)-CD154 seven days post booster immunization, respectively, indicating effective neutralization of AI by serum IgG of vaccinated chickens. In a subsequent direct challenge study, specific-pathogen-free Leghorn chicks immunized with DeltaaroA-DeltahtrA M2e(4)-CD154 offered significant protection against direct challenge with low pathogenic AI H7N2, but not highly pathogenic H5N1 AI. Taken together, these data suggest that these Salmonella-vectored vaccines expressing M2e in association with CD154 are effective at protecting chickens against low pathogenic AI.

Oxidative metabolism and efficiency: the delicate balancing act of mitochondria.

Mitochondria are responsible for roughly 90% of the ATP produced in a cell. A consequence of aerobic metabolism is oxidative stress that results from production of mitochondrial reactive oxygen species (ROS) due to inefficiency of electron transport. Several antioxidant-redox coupled reactions in the mitochondria help minimize oxidative damage in the mitochondria. These redox reactions not only protect mitochondria from oxidative damage but also are important in regulating cellular redox status. Oxidative stress from mitochondrial ROS occurs in broilers in pulmonary hypertension syndrome, heat stress, and in the phenotypic expression of feed efficiency. Low levels of mitochondrial ROS are now recognized to play important roles in signal transduction mechanisms. A topology of ROS production has been reported that indicates that ROS derived from Complex I primarily cause oxidative damage, whereas ROS generated from Complex III are primarily involved in cell signaling. Reverse electron transport, once considered an artifact of in vitro conditions, now plays significant roles in physiological conditions including inflammation, ischemia-reperfusion, muscle differentiation, and energy utilization. Understanding the balancing act that mitochondria play in health and disease will continue to be vital biological component of improving efficiency in animal production.

Identification of mitochondrial hormone receptors in avian muscle cells.

The major objective of this study was to assess the expression of mitochondrial hormone receptors for progesterone (PR), estrogen (ER), glucocorticoid (GR), thyroid (TR), and insulin (IR) in avian muscle cells (quail muscle 7, QM7) and in breast muscle of quail and broilers. Visualization of receptor location in QM7 cells was accomplished by immunofluorescence. QM7 cells were stained with Mito Tracker Deep Red CMX, fixed in methanol, immune stained with anti-PR, -GR, -TR, -IR, and -ER primary antibodies overnight at 4°C, and visualized with Alexa Fluor 488-conjugated secondary antibody. After staining the nucleus with 4',6-diamidino-2-phenylindole, images were obtained by immunofluorescence microscopy. Merged images revealed the presence of all 5 hormone receptors on mitochondria in QM7 cells. Western blot analysis identified; (a) the ß-isoform of the PR, (b) the α-isoform of GR, (c) the α-receptor of TR, (d) the ß-subunit of IR, and (e) the α-isoform of the ER on mitochondria isolated from broiler breast muscle. Similar results were obtained in quail breast muscle mitochondria with the exception that the α-isoform of the GR was not detected. To our knowledge, this is the first report of hormone receptors (PR, TR, GR, IR, and ER) on mitochondria in avian cells. We hypothesize that these receptors could play important roles in regulating mitochondrial function in avian muscle cells.

Gene expression in breast muscle and duodenum from low and high feed efficient broilers.

This study was conducted to evaluate messenger RNA (mRNA) expression of genes that are involved in energy metabolism and mitochondrial biogenesis: avian adenine nucleotide translocator (avANT), cytochrome oxidase III (COX III), inducible nitric oxide synthase (iNOS), peroxisome proliferator-activated receptor-gamma (PPAR-gamma), avian PPAR-gamma coactivator-1alpha (avPGC-1alpha), and avian uncoupling protein in breast muscle and duodenum of broilers with low and high feed efficiency (FE). Total RNA was extracted from snap-frozen tissues from male broilers with low (0.55 +/- 0.01) and high (0.72 +/- 0.01) FE (n = 8 per group). Total RNA was reverse-transcribed using oligo(dT), random primers, or both followed by real-time reverse transcription-PCR. Protein oxidation, measured as protein carbonyls, was also evaluated in duodenal mucosa. Protein carbonyls were higher in low FE mucosa in tissue homogenate and mitochondrial fraction. The mRNA expression of iNOS and PPAR-gamma in the duodenum was lower in the low FE broilers, with no differences in avANT, COX III, and avPGC-1alpha. In contrast, expression of avANT and COX III mRNA in breast muscle was lower in low FE broilers with no differences in iNOS, PPAR-gamma, and avPGC-1alpha. The avian uncoupling protein in breast muscle was higher in low FE birds (P = 0.068). These results indicate that there are differences in the expression of mRNA encoding for mitochondrial transcription factors and proteins in breast muscle and duodenal tissue between low and high FE birds. The differences that were observed may also reflect inherent metabolic and gene regulation differences between tissues.

Enhanced expression of proteins involved in energy production and transfer in breast muscle of pedigree male broilers exhibiting high feed efficiency.

In cells with fluctuating energy demand (e.g., skeletal muscle), a transfer system of proteins across the inner and outer mitochondrial membranes links mitochondrial oxidative phosphorylation to cytosolic phosphorylated creatine (PCr) that serves as a phosphate reservoir for rapid repletion of cytosolic adenosine triphosphate (ATP). Crucial proteins of this energy transfer system include several creatine kinase (CK) isoforms found in the cytosol and mitochondria. In a recent proteomic study (Kong et al., 2016), several components of this system were up-regulated in high feed efficiency (FE) compared to low FE breast muscle; notably adenine nucleotide translocase (ANT), voltage dependent activated channel (VDAC), the brain isoform of creatine kinase (CK-B), and several proteins of the electron transport chain. Reexamination of the original proteomic dataset revealed that the expression of two mitochondrial CK isoforms (CKMT1A and CKMT2) had been detected but were not recognized by the bioinformatics program used by Kong et al. (2016a). The CKMT1A isoform was up-regulated (7.8-fold, P = 0.05) in the high FE phenotype but there was no difference in CKMT2 expression (1.1-fold, P = 0.59). From these findings, we hypothesize that enhanced expression of the energy production and transfer system in breast muscle of the high FE pedigree broiler male could be fundamentally important in the phenotypic expression of feed efficiency.

Effects of In Ovo feeding of dextrin-iodinated casein in broilers: I. Hatch weights and early growth performance.

This study was conducted to determine the effect of in ovo feeding of dextrin (Dext) and iodinated casein (IC) on hatch and early growth in broilers. Three experiments were conducted at a commercial hatchery using a commercial Inovoject™ system with treatments occurring in conjunction with vaccination at transfer from incubator to hatcher units (18.5 to 19 d embryonic development). In all 3 experiments, approximately 15,000 eggs (2,500 eggs per group) were treated and transferred to a single hatcher unit. Treatments in Exp. 1 consisted of buffered saline solution alone (Control, Cont) or a dextrin solution (Dext, 18% maltodextrin, 10% potato starch dextrin) containing zero, 80, 240, 720, or 2,160 µg IC/mL. The results of this initial experiment indicated that broiler chicks at hatch that received 240 and 720 µg IC/mL in Dext were heavier (P < 0.05) compared to the other treatment groups; there were no differences in hatchability between groups. Based on these findings, subsequent studies used treatments of zero, 240, and 480 µg/mL IC in Dext or Cont. In Exp. 2, hatch weights in all treatment groups were higher (P < 0.05) compared to those receiving Cont. In Exp. 3, chicks given Dext alone or 240 and 480 µg/mL in saline weighed less at hatch compared to the other treatment groups. However, chicks provided Dext alone in Exp. 3 had less weight loss after a 24-hour holding period compared to the other groups. All treatment groups exhibited greater weight gain from one to 10 d compared to the Cont group. The results indicate that in ovo feeding of broiler embryos with Dext containing 240 and 480 µg IC/mL may have beneficial effects on broiler hatch weights and early growth rate.

Effect of in ovo feeding of dextrin-iodinated casein in broilers: II. Hatch window and growth performance.

Studies were conducted using a commercial InovojectTM system to determine effects of in ovo feeding of dextrin and iodinated casein (IC) on hatch and posthatch growth in broilers. At ∼18.5 d embryonic development, eggs were treated with 0, 240, or 480 µg IC/mL in saline (Cont, IC240, and IC480) or dextrin (Dext, DextIC240 and DextIC480). The Dext solution consisted of 18% maltodextrin and 10% potato starch dextrin; saline was the vehicle used by the company for in ovo vaccination. The volume for all in ovo treatments was 50 µL/injection. Eggs in Experiment 1 were transferred to a commercial hatcher unit whereas eggs in Experiments 2 and 3 were transferred to a research hatcher unit to assess effects of treatments on timing of hatch. At hatch, chicks were randomly selected and placed in floor pens and grown to 6 wk. In Experiment 1, there were no differences in hatch weights, but broilers provided Dext IC240 in ovo were heavier (P < 0.05) at 6 wk compared to other treatments with the exception of the Dext IC240 group. In Experiment 2, hatch weights were heavier (P < 0.05) in chicks receiving IC240 and DexIC480 treatments compared to Controls. At 6 wk, broilers in all treatments were heavier (P < 0.05) than Cont with the exception of IC480. In Experiment 3, hatch was stimulated by IC240 (in saline), but was delayed by Dext IC240. Serum analysis of ß-hydroxybutyrate (µM/mL), as an indicator of ketone accumulation from fat metabolism of chicks held in chick boxes for 24 h posthatch (to simulate delay in placement after hatch), indicated that chicks in the IC240 group (that hatched earlier) had higher blood ketones compared to chicks that received Dext or DextIC240 in ovo (that hatched later). We conclude dextrin and iodinated casein (240 µg/mL) provided in ovo (∼18.5 d of embryonic development) has the potential to improve chick quality and posthatch body weight by delaying or narrowing hatch window.

Growth performance, feed digestibility, body composition, and feeding behavior of high- and low-residual feed intake fat-tailed lambs under moderate feed restriction.

Two experiments were conducted to evaluate the effect of moderate feed restriction on productivity of lambs classified on the basis of phenotypic expression of residual feed intake (RFI). In Exp. 1, 58 fat-tailed Kurdi ram lambs (32.1 ± 4.2 kg BW) were individually fed, ad libitum, a pelleted diet (35% alfalfa hay and 65% concentrate). Feed intake and ADG were determined for a 6-wk period and 3 feed efficiency measures including RFI, G:F, and partial efficiency of maintenance (PEM) were calculated. The lambs were sorted based on RFI and the 16 highest RFI (RFI ≥ mean + 0.5 SD) and 16 lowest RFI (RFI ≤ mean - 0.5 SD) lambs were subjected to body composition (BC) and DM digestibility (DMD) analysis. Feeding behavior traits (FB) were also evaluated for 24 h using a regular 5-min interval observation method. The high- and low-RFI lambs (14 lambs/RFI group) so classified in Exp. 1 were used in Exp. 2. Half of the lambs in each RFI group were randomly selected to be fed ad libitum or 85% of ad libitum (restricted feeding), which resulted in 4 experimental groups: 1) ad libitum high-RFI, 2) feed restricted high-RFI, 3) ad libitum low-RFI, and 4) feed restricted low-RFI. The lambs were fed the same diet as Exp. 1, and growth efficiency during a 6-wk test period as well as BC, DMD, and FB were also determined in Exp. 2. In Exp. 1, the low-RFI lambs consumed 14% ( < 0.01) less feed than high-RFI lambs. Differences were also observed between high- and low-RFI groups for G:F ( = 0.01), RFI ( < 0.01), and PEM ( < 0.01) in Exp. 1, but no differences were detected between high- and low-RFI lambs for ADG ( = 0.79), DMD ( = 0.42), BC ( > 0.72), and FB ( > 0.24). In Exp.2, the restriction feeding regime negatively affected ADG ( < 0.01) and G:F ( = 0.02) in low-RFI lambs, whereas G:F ( = 0.02) and PEM ( < 0.01) were improved in high-RFI lambs under the feed restriction condition. No effects of feed restriction on DMD ( = 0.87) and BC ( > 0.05) were observed. The lambs fed at the restricted level of intake presented a greater time ( < 0.01) and rate ( = 0.01) of eating than those fed ad libitum. Although bunk visits and feeding events were decreased ( < 0.01) with feed restriction, no interaction ( > 0.05) was detected between RFI phenotype and feeding regime for FB. In summary, feeding high-RFI lambs at 85% of ad libitum level improved G:F with no effect on ADG, whereas growth performance was reduced by feeding low-RFI lambs at 85% of ad libitum. However, these changes in feed efficiency were not related to DMD, BC, or FB.

Biochemical evaluation of mitochondrial respiratory chain in duodenum of low and high feed efficient broilers.

Increased H2O2 production, indicating higher oxidative stress, and lower mitochondrial function was previously observed in duodenal mitochondria isolated from broilers with low feed efficiency (FE, gain:feed). Thus, experiments were conducted to 1) evaluate the activity of the respiratory chain complexes (complexes I to V) and 2) assess protein oxidation and mitochondrial protein expression in broilers with low and high FE. Duodenal mitochondria were isolated from broiler breeders with low (0.52 +/- 0.01) and high (0.68 +/- 0.01) FE (n = 8/group). Respiratory chain complex activities were measured spectrophotometrically, whereas mitochondrial protein expression and protein oxidation (carbonyls) were assessed with Western blots. The activities of all complexes, except complex IV, were lower in the low FE compared with high FE mitochondria, whereas protein carbonyl levels were higher in low FE mitochondria. Steady-state levels of 6 out of 7 nuclear-encoded respiratory chain subunits [70S(FP), core I, core II, cytochrome c (cyt c)1, iron-sulfur protein (ISP), and ATPase-alpha] were higher, whereas 3 out of 6 mitochondrial-encoded subunits (ND4, ND6-C, and COX II) were lower in the low FE group, suggesting that sensitivity of mitochondrial proteins to H2O2 or oxidation varies. The general reduction in complex activity and differential protein expression concomitant with higher oxidized proteins in low FE mitochondria suggest that oxidative stress could be contributing to the lower mitochondrial function observed in low FE duodenal mitochondria.

Prostacyclin elevation following glutathione depletion in vivo. Possible threshold dependency in liver and lung.

The major objective of this study was to determine if a threshold level of glutathione (GSH) depletion is required to elevate plasma prostacyclin (6-ketoPGF1 alpha) in male Sprague-Dawley rats. Rats were treated i.p. with various doses of phorone, diethyl maleate (DEM), or GSH with and without DEM. Similar maximal depletions of hepatic GSH (to 10% of control) and renal GSH (to 50% of control) were observed with DEM and phorone, but lung GSH was depleted maximally by only 30% with phorone compared with a 70% depletion by DEM. Changes in lung GSH, but not kidney GSH, were closely correlated with changes in hepatic GSH 6-KetoPGF1 alpha levels in the lung were 10- to 30-fold higher than in kidney or liver, and there was a stronger correlation between lung and plasma 6-ketoPGF1 alpha than with the other two tissues. The increase in lung 6-ketoPGF1 alpha following GSH depletion did not appear to be due to a shift in prostaglandin metabolite synthesis since reciprocal changes in PGE2 were not observed; lung PGE2 levels were largely unaffected by DEM or phorone. Both DEM and phorone elevated plasma 6-ketoPGF1 alpha but the magnitude of increase for DEM (5- to 6-fold) was much greater than the 2-fold increase for phorone. The increase in plasma 6-ketoPGF1 alpha by 1.0 mL DEM/kg was attenuated by simultaneous administration of 2 mmol GSH/kg. The results indicate that the lung may be responsible for increases in plasma 6-ketoPGF1 alpha following GSH depletion and that a critical level of GSH depletion in the liver and/or lung may be necessary to elevate plasma 6-ketoPGF1 alpha levels.

Effect of glutathione depletion on tissue and plasma prostacyclin and thromboxane in rats.

Experiments were designed to determine the effects of glutathione (GSH) depletion with L-buthionine sulfoximine (BSO) or diethyl maleate (DEM) on tissue and plasma prostacyclin (6-keto-PGF1 alpha) and thromboxane (TxB2) levels in male Sprague-Dawley rats. Despite depleting hepatic GSH to as much as 34% of control, BSO at various levels (0.4, 0.8 and 1.2 g/kg body wt) had no effect on hepatic, renal, pulmonary or cardiac tissue levels of 6-keto-PGF1 alpha and TxB2 or circulating levels of 6-keto-PGF1 alpha in portal or arterial plasma. When rats were pretreated with 3-methylcholanthrene (3-MC) to induce cytochrome P450, BSO (0.8 g/kg body wt) also had no effect on tissue or plasma prostanoid levels with the exception of a slight, but significant, increase in hepatic 6-keto-PGF1 alpha in non-induced rats. In contrast, depletions of hepatic, renal and pulmonary tissue GSH by DEM (1 mL/kg body wt) to 12, 50 and 30% of control, respectively, were associated with elevations of 6-keto-PGF1 alpha in these tissues and in plasma obtained by right ventricular heart puncture. Pretreatment of rats with 3-MC had no significant effect on tissue GSH or prostanoid levels in controls or DEM-treated rats but plasma levels of 6-keto-PGF1 alpha were lower in comparison to non-induced rats. DEM with or without 3-MC pretreatment was associated with increased TxB2 in renal tissue, whereas DEM elevated TxB2 only in pulmonary tissue from non-induced rats. It appears that factors besides GSH depletion may be required to raise plasma and/or tissue 6-keto-PGF1 alpha levels in vivo.

Glutathione and bile acid synthesis. Effect of GSH content of HepG2 cells on the activity and mRNA levels of cholesterol 7 alpha-hydroxylase.

Cholesterol 7 alpha-hydroxylase (CH-7 alpha) activity in HepG2 cells depleted of glutathione (GSH) was reduced significantly (P < 0.05) compared to that in untreated controls. Northern blot analysis of poly A+ mRNA isolated from GSH-depleted and control HepG2 cells showed that there was a reduction in mRNA for CH-7 alpha in treated HepG2 cells that was commensurate with the reduction in CH-7 alpha activity. The fact that total RNA, rRNA, and mRNA for beta fibrinogen were unaltered by the depletion of GSH suggests that the change in steady-state CH-7 alpha mRNA content is specifically sensitive to GSH content. This observation represents the first demonstration, for human liver cells, that there is an interaction between GSH levels and the regulation of CH-7 alpha mRNA levels.

Glutathione levels in specific brain regions of genetically epileptic (tg/tg) mice.

The tottering (tg/tg) mouse is a genetic model of human generalized epilepsy; these mice exhibit spontaneous absence seizures accompanied by bilaterally synchronous spike-wave discharges (6). The mechanism(s) for seizure activity are unknown in these mice. Several recent studies have suggested that membrane lipid peroxidation may be causally involved in some forms of experimentally induced epilepsies (18). Since reduced glutathione (GSH) is the most important free radical scavenging compound in vivo that can prevent membrane lipid peroxidation, the objective of this study was to investigate GSH concentrations in specific central nervous system regions of genetically epileptic, tg/tg, mice as compared to age-matched controls. Three brain regions, cerebellum, hippocampus, and occipital cortex, were dissected, weighed and the concentrations of reduced and oxidized glutathione (GSH and GSSG, respectively) were measured in each of these tissues. GSH content was significantly lower in the occipital cortex of tg/tg mice compared to controls; no differences were observed in the other two brain regions examined. Total GSH content (GSH plus 2 x GSSG) paralleled GSH concentration differences. GSSG content from tg/tg mice was lower in the hippocampus and occipital cortex, compared to controls. This is the first report of an association between decreased central nervous system glutathione concentrations and seizure activity in animals exhibiting generalized seizures.

CD4, CD8 and TCR defined T-cell subsets in thymus and spleen of 2- and 7-week old commercial broiler chickens.

To better understand immune development and function in meat-type chickens (broilers), the proportions of T-cells expressing CD4, CD8, and T-cell receptors (TCR) in the thymus and spleen were determined by three-color fluorescence and flow cytometry in 2- and 7-week old broilers raised in commercial growing conditions. Broiler thymocytes consisted of single-(CD4+CD8- and CD4-CD8+) and double-(CD4+CD8+) positive subpopulations. Within these CD4+ and/or CD8+ thymocyte populations, all types of TCR (y delta, V beta 1 alpha beta, and V beta 2 alpha beta) could be identified. In the thymus, percentages of CD4+CD8- cells increased, CD4-CD8+ cells remained unchanged, and CD4+CD8+ cells decreased between 2 and 7 weeks of age. In the spleen, in addition to single-positive lymphocytes, double-positive populations were identified, expressing either y delta or alpha beta TCR. The percentage of CD4+CD8- splenocytes decreased, and the percentages of both CD4-CD8+ and CD4+CD8+ splenocytes increased between 2 and 7 weeks of age. Age-associated shifts in TCR usage (the proportion of cells expressing a certain type of TCR) were observed in the single-positive, but not in the double-positive, T-cell populations of both thymus and spleen. This multiparameter cell population analysis in broilers demonstrates thymic and splenic T-cell subsets similar to those previously described in layers. Differences in the proportions among T-cell subsets between 2- and 7-week old broilers likely reflect a more competent immune system in the older birds.

Degradation of protein by mixed cultures of rumen bacteria: identification of Streptococcus bovis as an actively proteolytic rumen bacterium.

Mixed cultures of rumen bacteria were inoculated into anaerobic buffer solutions containing mixed carbohydrates, casein and ammonia, and rates of bacterial growth, protein degradation, ammonia formation or utilization and lactate production were determined. Bacterial growth rate was varied by the provision of excess carbohydrate (one large dose at the onset of the incubation) or limited carbohydrate (small doses every hour or every 2 hr). When carbohydrate was limited, growth rate was slow, the extent of protein degradation was small and lactate did not accumulate in the fermentation vessels. Lactate production and protein degradation were also negligible during the initial phases of the high carbohydrate, fast growth rate incubations, but large increases in each were seen after 3 hours. Microscopic examination of the fast growth incubations revealed large numbers of small ovoid cells similar to Streptococcus bovis, while tha slow growth incubations exhibited a variety of morophological types and very few small ovoid cells. Because the lactic acid and morphological data suggested that proliferation of S. bovis might be responsible for rapid proteolysis, effects of gram-positive antibiotics were examined. When compared against a fast growth control, both thiopeptin (5 ppm) and monensin (5ppm) were found to decrease protein degradation, but the inhibition by thiopeptin (50%) was greater than that by monensin (13%). The ratios of protein degraded to bacteria protein synthesized were .659, .362 and .628 for the control, thiopeptin and monensin treatments, respectively. Actively proteolytic strains of S. bovis were isolated from fast growth incubations, and subsequent experiments showed that the ratio of protein degraded to bacterial protein synthesized was approximately 1.50. Collectively, the data indicate that S. bovis is a very proteolytic rumen bacterium.

Alpha adrenergic regulation of celiac blood flow and plasma catecholamine response during acute heat stress in fed cockerels.

Hubbard cockerels with chronically implanted electromagnetic blood flow probes on the celiac artery were used to establish a relationship between changes in postprandial celiac mean blood flow (MBF) and plasma catecholamines during a acute heat exposure. Five min after the elevation of ambient temperature from 25 to 37 C, there were concomitant reductions (P less than .05) in celiac MBF, norepinephrine (NE), and heart rate (HR). After 50 min of heat stress, rectal temperature (Tr), respiratory rate (RR), plasma epinephrine (E), and celiac vascular resistance (CVR) were significantly greater (P less than .05) than preheat stress thermoneutral control values. During the thermoneutral recovery period, all parameters returned to values comparable to preheat exposure control with the exception of NE, which tended (P less than .1) to remain lower. To determine the role of the sympathetic nervous system in regulating postprandial celiac MBF during acute heat exposure, chronically instrumented cockerels were infused with phenoxybenzamine, an alpha-adrenergic receptor-blocking agent. Alpha-receptor blockade attenuated both postprandial intestinal hyperemia under thermoneutral conditions as well as the heat-induced reduction of postprandial celiac MBF. The results of these studies implicate the sympathetic nervous system in the regulation of postprandial celiac MBF in heat-stressed cockerels and indicate a possible alpha-adrenergic-mediated mechanism involved in postprandial intestinal hyperemia.