Kinetics of DNA synthesis in feeding-dependent and independent hepatocyte populations of rats after partial hepatectomy

The effects of food consumption on the kinetics of hepatic DNA synthesis after partial hepatectomy (PH) have been studied in rats. Short-term (4-24 hr) fasting before or after PH resulted in depression and/or delay of DNA synthesis on days 1, 2 and 3 of regeneration. This depression was found in hepatocytes and, to a lesser extent, in littoral cells. Re-feeding resulted in an increase of DNA synthesis within 3-8 hr. The results suggest that two different hepatocyte subpopulations exist in regenerating rat liver: one which proceeds to DNA synthesis without apparent exogenous signals, and another one which needs, in addition to the specific mitogenic action of PH, food intake as a secondary permissive signal in order to initiate DNA synthesis. In the latter population food consumption appears to be required at two different stages: (1) in G0 or the early pre-replicative phase (PRP); (2) in the late PRP 3-8 hr before initiation of DNA synthesis. In the latter stage dietary protein is needed, but no so in the former. The dependence on feeding in the late PRP increases relatively with time after PH. No evidence was found to suggest a different distribution of the two cell populations throughout the liver acinus. The findings support the hypothesis that the known effects of the light-dark rhythm on the timing of DNA synthesis after PH are mediated by the natural feeding rhythm of rats fed ad libitum. In addition they offer a means for improving the synchrony of hepatocyte proliferation in regenerating rat liver.     

Feedback inhibition of hepatic DNA synthesis

alpha-Hexachlorocyclohexane (alpha-HCH) and some other xenobiotic inducers were used to elicit adaptive increases in mono-oxygenase activity, size and DNA content of rat liver. After elimination of the inducers, organ size and mono-oxygenase activity returned to normal whereas the DNA content of the liver remained increased. Upon renewed treatment with an inducer the adaptive responses uncoupled. While mono-oxygenase induction and liver enlargement did occur, DNA replication was largely suppressed. These findings show that in the hyperplastic state the liver is resistant to stimulation of DNA synthesis by the inducers. It is concluded that the DNA content of the liver (or the number of liver cells) is controlled by a feedback system which monitors an excess of DNA (cells) and suppresses cell replication if the content of DNA exceeds the normal level. Organ mass has little, if any, effect on the operation of this feedback system.     

Liver growth, biosynthesis of cytidine nucleotides and level of cytochrome P-450 in rat liver after administration of alpha-hexachlorocyclohexane.

The biosynthesis of cytidine nucleotides and the level of microsomal cytochrome P-450 in intact and regenerating rat liver after repeated administration of alpha-hexachlorocyclohexane (alpha-HCH) were compared. In alpha-HCH treated animals the utilization of [2-14C] orotic acid for the synthesis of cytidine nucleotides is suppressed. In 24-h regenerating liver the incorporation of labelled orotic acid into cytidine nucleotides is markedly activated; the degree of activation is lower in regenerating livers of alpha-HCH treated animals. The changes in the level of cytochrome P-450 vary inversely with the changes in the utilization of [2-14C] orotic acid for the synthesis of cytidine nucleotides. The activity of cytidine triphosphate synthetase of liver cytosol increases shortly after the administration of alpha-HCH; uridine-cytidine kinase is enhanced in the later stages of the drug action. Within 15-45 min after the administration of alpha-HCH the uptake of [U-14 C] cytidine into the liver and its incorporation into RNA cytosine are increased. After the administration of the drug the uptake of [2-14 C] uridine and its incorporation into RNA uracil is also enhanced whereas its utilization for the synthesis of cytidine nucleotides of the acid-soluble extract as well as for the RNA cytosine are suppressed.     

Ontogeny of DNA synthetic rhythms in chick (Gallus domesticus) liver.

1. The diurnal pattern of DNA synthesis and mitotic activity in neonatal (1-4-day-old) chick liver were investigated under various feeding and lighting regimens. 2. In the meal-fed chicks under the condition of light-dark cycle, DNA synthesis exhibited a 12 hr cycle; the peaks occurring at 9:00 and 21:00. 3. Fasting caused a gradual decrease in the 21:00 peaks. 4. The changes in the lighting regimen to 24 hr continuous lighting also caused a profound change in the DNA-synthetic pattern, suggesting a complex interplay of feeding and lighting regimens in the manifestation of the DNA-synthetic rhythm in neonatal chick liver.     

Lipid peroxidation in regenerating rat liver

Rats entrained to a strictly regulated lighting and feeding schedule have been subjected to partial hepatectomy or a sham operation. In the partially hepatectomised animals the period of liver regeneration is characterised by regular bursts of thymidine kinase activity. Liver microsomes from rats, at times corresponding to maximum thymidine kinase activity, have much reduced rates of lipid peroxidation compared to control preparations: this is due in part to increased levels of lipid-soluble antioxidant at times of maximal DNA synthesis. This temporal relationship between thymidine kinase and lipid peroxidation is consistent with the view that lipid peroxidation is decreased prior to cell division.     

Relative value of light and food as synchronizers of liver phosphorylase circadian rhythm.

The role played by light and feeding schedules on the circadian rhythm of glycogen content and phosphorylase activity of the liver has been studied. In one experiment, mice were subjected to a regimem of constant darkness during 21 days and compared with mice kept in 12 hrs of light alternating with 12 hrs of darkness. Both groups received food and water ad libitum. Liver glycogen content as well as phosphorylase activity showed, with slight differences, similar circadian variations. In a second experiment, mice under similar lighting conditions (LD 12:12), with water access ad libitum, were divided into two groups; one was offered food ad libitum while the other group recieved food from 0700 to 1800 only. This experiment allowed up to compare two different schedules of food intake; ad libitum, normal schedule (from 1800 to 0600) and reversed schedule (from 0700 to 1800). A complete reversal of the circadian rhythm was observed after 21 days in the group with the reverted feeding schedule. We conclude that food can function as the primary synchronizer in spite of the lighting regimen.     

A high-fat diet suppresses de novo lipogenesis and desaturation but not elongation and triglyceride synthesis in mice

Intracellular lipids and their synthesis contribute to the mechanisms and complications of obesity-associated diseases. We describe an NMR approach that provides an abbreviated lipidomic analysis with concurrent lipid biosynthetic fluxes. Following deuterated water administration, positional isotopomer analysis by deuterium NMR of specific lipid species was used to examine flux through de novo lipogenesis (DNL), FA elongation, desaturation, and TG-glycerol synthesis. The NMR method obviated certain assumptions regarding sites of enrichment and exchangeable hydrogens required by mass isotope methods. The approach was responsive to genetic and pharmacological gain or loss of function of DNL, elongation, desaturation, and glyceride synthesis. BDF1 mice consuming a high-fat diet (HFD) or matched low-fat diet for 35 weeks were examined across feeding periods to determine how flux through these pathways contributes to diet induced fatty liver and obesity. HFD mice had increased rates of FA elongation and glyceride synthesis. However DNL was markedly suppressed despite insulin resistance and obesity. We conclude that most hepatic TGs in the liver of HFD mice were formed from the reesterification of existing or ingested lipids, not DNL.     

Feeding cues and injected nutrients induce acute expression of multiple clock genes in the mouse liver

The circadian clock is closely associated with energy metabolism. The liver clock can rapidly adapt to a new feeding cycle within a few days, whereas the lung clock is gradually entrained over one week. However, the mechanism underlying tissue-specific clock resetting is not fully understood. To characterize the rapid response to feeding cues in the liver clock, we examined the effects of a single time-delayed feeding on circadian rhythms in the liver and lungs of Per2::Luc reporter knockin mice. After adapting to a night-time restricted feeding schedule, the mice were fed according to a 4, 8, or 13 h delayed schedule on the last day. The phase of the liver clock was delayed in all groups with delayed feeding, whereas the lung clock remained unaffected. We then examined the acute response of clock and metabolism-related genes in the liver using focused DNA-microarrays. Clock mutant mice were bred under constant light to attenuate the endogenous circadian rhythm, and gene expression profiles were determined during 24 h of fasting followed by 8 h of feeding. Per2 and Dec1 were significantly increased within 1 h of feeding. Real-time RT-PCR analysis revealed a similarly acute response in hepatic clock gene expression caused by feeding wild type mice after an overnight fast. In addition to Per2 and Dec1, the expression of Per1 increased, and that of Rev-erbα decreased in the liver within 1 h of feeding after fasting, whereas none of these clock genes were affected in the lung. Moreover, an intraperitoneal injection of glucose combined with amino acids, but not either alone, reproduced a similar hepatic response. Our findings show that multiple clock genes respond to nutritional cues within 1 h in the liver but not in the lung.     

Daily Epinephrine but not Norepinephrine Administration Produces Anticipatory Drinking Behavior in Rats

Peripheral oscillators, especially in the liver, are thought to be part of the food entrained oscillator (FEO). The internal mediating signals involved in food entrainment are unknown. Catecholamines may be one signal, since they increase their blood concentration immediately after feeding, and their intraperitoneal (IP) administration produces hyperglycemia and a satiety response by their direct effect on the liver. The present study explored the role of epinephrine (EPI) and norepinephrine (NE) as entraining signals to the FEO. This effect was explored by daily IP administration of EPI (12.5 µg/100 g bw), NE (25 µg/100 g b) or vehicle on rhythmicity of drinking behavior in rats maintained under constant conditions. Behavioral effects were compared with those observed in a group entrained with a restricted feeding schedule (RFS). IP administration of EPI produced anticipatory drinking behavior, in a dosedependent manner but with a lower intensity than that produced by RFS. In contrast, daily NE or vehicle administration did not produce any changes in drinking rhythmicity. None of the manipulations produced effects on the SCN-dependent freerunning period. Present data suggest a role of EPI as a factor involved with the internal mediating signal for FEO; however, other preabsortive or postabsortive signals may also be part of this complex entraining pathway.     

Urethane inhibition of DNA synthesis in the hepatocytes of the regenerating liver in mice

Hepatocarcinogen urethane (ethyl carbamate) inhibits DNA synthesis in the regenerating mice liver when administered at the peak of stimulated proliferation--46 hours after partial hepatectomy. The inhibition is temporary and reversible. The maximum inhibition of 3H-thymidine incorporation in the cells is observed 12 hours after urethane administration, and the effect is removed following 20 hours after administration. Another effect of urethane consists in the lengthening of the period of DNA synthesis by 1.38 times, as estimated by the Quastler-Sherman method, though it does not affect the length of G2-period or mitosis. Possible mechanisms of the effect of urethane on the initiation of DNA synthesis and on the rate of DNA replication are discussed.     

Coupling between DNA replication and cell division mediated by the FtsA protein in Escherichia coli: a pathway independent of the SOS response, the "TER" pathway

Inhibition of DNA synthesis prevented the recovery of cell division in filaments of D-3R [ftsA3(Ts) recA56] returned to the permissive temperature. The FtsA protein may be a signal involved in the "TER" pathway, a series of events that coordinate cell division with DNA replication, that is independent of the SOS pathway.     

Intrinsic resistance to viral infection. Mouse macrophage restriction of herpes simplex virus replication

Macrophages isolated from mice resistant to acute (lethal) infection with a neurovirulent isolate of HSV-1 express intrinsic resistance to viral infection in vitro. Bone marrow (BM), spleen (S), peritoneal (P), and thioglycolate-stimulated peritoneal (Pthio) macrophages isolated from resistant C57BL/6 Cr (B6) mice consistently restrict HSV-1 macromolecular synthesis earlier in the viral replicative cycle than do macrophages isolated from the same tissue sources from more susceptible DBA/2Cr (D2) mice. B6-BM (BM macrophages from B6 mice) restrict HSV macromolecular synthesis at least at two points in the replicative cycle: 1) before the onset of alpha-protein synthesis and 2) between the onset of gamma 1 protein and DNA synthesis. D2-BM macrophages restrict HSV replication at about the time of DNA synthesis. B6-P macrophages restrict HSV replication shortly after gamma 1 protein synthesis, and D2-P macrophages inhibit the virus slightly later, but before DNA synthesis. B6-S macrophages restrict HSV replication at about the time of DNA synthesis, and D2-S macrophages inhibit replication after the onset of gamma 2 protein synthesis. Pthio macrophages are more permissive to HSV infection than BM, P, or S macrophages: restrictions in viral replication occur at the time of DNA synthesis in B6-Pthio macrophages, and after the onset of gamma 2 protein synthesis in D2-Pthio cells. These studies demonstrate that isolated macrophages from inbred mouse strains express intrinsic resistance to HSV infection that correlates with in vivo resistance to acute (lethal) infection. Intrinsic resistance to HSV-1 infection is due to restriction of viral macromolecular synthesis. HSV replication is inhibited in macrophages at multiple points in the viral growth cycle, depending on the tissue from which the cells are isolated.     

Enhancement of ribonucleic acid synthesis by chromium(III) in mouse liver

The effect of Cr(III) administration on hepatic RNA synthesis in mice was studied. It was found that Cr accumulated in mouse liver. Forty-eight hours after intraperitoneal injection of CrCl3 (0.005-5 mg Cr/kg body weight) approximately 10% of the administered dose per g of tissue remained. The accumulated Cr was still retained 64 days after administration (5 mg Cr/kg) with only a slight decrease. Approximately 20% of the hepatic Cr was detected in the nuclei. By administering CrCl3. RNA synthesis in mouse liver was markedly enhanced without altering the pool size of nucleotides. This enhancement was dose-dependent and statistically significant at doses of 0.05 (p less than 0.05), 0.5 (p less than 0.01), and 5 mg Cr/kg (p less than 0.01), and remained so for at least 16 days after administration of 5 mg Cr/kg. The synthesis of DNA and protein in mouse liver were not significantly changed by CrCl3 administration. On the other hand, Cr(VI) administration did not enhance but rather inhibited RNA synthesis in mouse liver. These results suggest that Cr(III) specifically enhances RNA synthesis in mouse liver.     

Inhibition of Hedgehog Delays Liver Regeneration through Disrupting the Cell Cycle

Liver regeneration is a complicated biological process orchestrated by various liver resident cells. Hepatic cell proliferation and reconstruction of the hepatic architecture involve multiple signaling pathways. It has been reported that the Hh signal is involved in liver regeneration. However, the signal transduction pathways and cell types involved are ill studied. This study aimed to investigate hedgehog signal response cell types and the specific molecular mechanism involved in the process of liver regeneration. Partial hepatectomy (PH) of 70% was performed on ICR (Institute of Cancer Research) mice to study the process of liver regeneration. We found that the hedgehog signal was activated significantly after PH, including hedgehog ligands, receptors and intracellular signaling molecules. Ligand signals were mainly expressed in bile duct cells and non-parenchymal hepatic cells, while receptors were expressed in hepatocytes and some non-parenchymal cells. Inhibition of the hedgehog signal treated with vismodegib reduced the liver regeneration rate after partial hepatectomy, including inhibition of hepatic cell proliferation by decreasing Cyclin D expression and disturbing the cell cycle through the accumulation of Cyclin B. The current study reveals the important role of the hedgehog signal and its participation in the regulation of hepatic cell proliferation and the cell cycle during liver regeneration. It provides new insight into the recovery of the liver after liver resection.     

Sequence of protein synthesis in cells infected by human cytomegalovirus: early and late virus-induced polypeptides.

At least 10 distinct early virus-induced polypeptides were synthesized within 0 to 6 h after infection of permissive cells with cytomegalovirus. These virus-induced polypeptides were synthesized before and independently of viral DNA replication. A majority of these early virus-induced polypeptides were also synthesized in nonpermissive cells, which do not permit viral DNA replication. The virus-induced polypeptides synthesized before viral DNA replication were hypothesized to be nonstructural proteins coded for by the cytomegalovirus genome. Their synthesis was found to be a sequential process, since three proteins preceded the synthesis of the others. Synthesis of all early cytomegalovirus-induced proteins was a transient process; the proteins reached their highest molar ratios before the onset of viral DNA replication. Late viral proteins were synthesized at the time of the onset of viral DNA replication, which was approximately 15 h after infection. Their synthesis was continuous and increased in molar ratios with the accumulation of newly synthesized viral DNA in the cells. The presence of the amino acid analog canavanine or azetadine during the early stage of infection suppressed viral DNA replication. The amount of viral DNA synthesis was directly correlated to the relative amount of late viral protein synthesis. Because synthesis of late viral proteins depended upon viral DNA replication, the proteins were not detected in permissive cells treated with an inhibitor of viral DNA synthesis or in nonpermissive cells that are restrictive for cytomegalovirus DNA replication.     

Brain PPAR-γ promotes obesity and is required for the insulin-sensitizing effect of thiazolidinediones

In adipose tissue, muscle, liver and macrophages, signaling by the nuclear receptor peroxisome proliferator-activated receptor-γ (PPAR-γ) is a determinant of insulin sensitivity and this receptor mediates the insulin-sensitizing effects of thiazolidinediones (TZDs). As PPAR-γ is also expressed in neurons, we generated mice with neuron-specific Pparg knockout (Pparg brain knockout (BKO)) to determine whether neuronal PPAR-γ signaling contributes to either weight gain or insulin sensitivity. During high-fat diet (HFD) feeding, food intake was reduced and energy expenditure increased in Pparg-BKO mice compared to Pparg(f/f) mice, resulting in reduced weight gain. Pparg-BKO mice also responded better to leptin administration than Pparg(f/f) mice. When treated with the TZD rosiglitazone, Pparg-BKO mice were resistant to rosiglitazone-induced hyperphagia and weight gain and, relative to rosiglitazone-treated Pparg(f/f) mice, experienced only a marginal improvement in glucose metabolism. Hyperinsulinemic euglycemic clamp studies showed that the increase in hepatic insulin sensitivity induced by rosiglitazone treatment during HFD feeding was completely abolished in Pparg-BKO mice, an effect associated with the failure of rosiglitazone to improve liver insulin receptor signal transduction. We conclude that excess weight gain induced by HFD feeding depends in part on the effect of neuronal PPAR-γ signaling to limit thermogenesis and increase food intake. Neuronal PPAR-γ signaling is also required for the hepatic insulin sensitizing effects of TZDs.     

Three additional genes required for deoxyribonucleic acid synthesis in Saccharomyces cerevisiae

Deoxyribonucleic acid (DNA) synthesis was examined in asynchronous and synchronous cultures of a number of cdc (cell division cycle) temperature-sensitive mutant strains. The kinetics of DNA synthesis after a shift to the restrictive temperature was compared with that obtained after inhibition of protein synthesis at the permissive temperature, a condition that specifically blocks the initiation of new rounds of DNA replication, but does not block those in progress. Mutations in three genes (cdc 4, 7, and 28) appear to block a precondition for DNA synthesis since cells carrying these lesions cannot start new rounds of DNA replication after a shift from permissive to restrictive temperature, but can finish rounds that were in progress. These three genes are classified as having roles in the "initiation" of DNA synthesis. Mutations in two genes (cdc 8 and 21) block DNA synthesis, itself, since cells harboring these lesions that had started DNA synthesis at the permissive temperature arrest synthesis abruptly upon a shift to the restrictive temperature. Mutations in 13 other cdc genes do not impair DNA synthesis in the first cell cycle at the restrictive temperature.     

The DNA damage checkpoint protein ATM promotes hepatocellular apoptosis and fibrosis in a mouse model of non-alcoholic fatty liver disease

Steatoapoptosis is a hallmark of non-alcoholic fatty liver disease (NAFLD) and is an important factor in liver disease progression. We hypothesized that increased reactive oxygen species resulting from excess dietary fat contribute to liver disease by causing DNA damage and apoptotic cell death, and tested this by investigating the effects of feeding mice high fat or standard diets for 8 weeks. High fat diet feeding resulted in increased hepatic H₂O₂, superoxide production, and expression of oxidative stress response genes, confirming that the high fat diet induced hepatic oxidative stress. High fat diet feeding also increased hepatic steatosis, hepatitis and DNA damage as exemplified by an increase in the percentage of 8-hydroxyguanosine (8-OHG) positive hepatocytes in high fat diet fed mice. Consistent with reports that the DNA damage checkpoint kinase Ataxia Telangiectasia Mutated (ATM) is activated by oxidative stress, ATM phosphorylation was induced in the livers of wild type mice following high fat diet feeding. We therefore examined the effects of high fat diet feeding in Atm-deficient mice. The prevalence of apoptosis and expression of the pro-apoptotic factor PUMA were significantly reduced in Atm-deficient mice fed the high fat diet when compared with wild type controls. Furthermore, high fat diet fed Atm^?/? mice had significantly less hepatic fibrosis than Atm^+/+ or Atm^+/? mice fed the same diet. Together, these data demonstrate a prominent role for the ATM pathway in the response to hepatic fat accumulation and link ATM activation to fatty liver-induced steatoapoptosis and fibrosis, key features of NAFLD progression.