Nicotinamide nucleotide synthesis in regenerating rat liver

1. The concentrations and total content of the nicotinamide nucleotides were measured in the livers of rats at various times after partial hepatectomy and laparotomy (sham hepatectomy) and correlated with other events in the regeneration process. 2. The NAD content and concentration in rat liver were relatively unaffected by laparotomy, but fell to a minimum, 25 and 33% below control values respectively, 24h after partial hepatectomy. NADP content and concentration were affected similarly by both laparotomy and partial hepatectomy, falling rapidly and remaining depressed for up to 48h. 3. The effect of injecting various doses of nicotinamide on the liver DNA and NAD 18h after partial hepatectomy was studied and revealed an inverse correlation between NAD content and DNA content. 4. Injections of nicotinamide at various times after partial hepatectomy revealed that the ability to synthesize NAD from nicotinamide was impaired during the first 12h, rose to a peak at 26h and fell again by 48h after partial hepatectomy. 5. The total liver activity of NAD pyrophosphorylase (EC 2.7.7.1) remained at or slightly above the initial value for 12h after partial hepatectomy and then rose continuously until 48h after operation. The activity of NMN pyrophosphorylase (EC 2.4.2.12) showed a similar pattern of change after partial hepatectomy, but was at no time greater than 5% of the activity of NAD pyrophosphorylase. 6. The results are discussed with reference to the control of NAD synthesis in rapidly dividing tissue. It is suggested that the availability of cofactors and substrates for NAD synthesis is more important as a controlling factor than the maximum enzyme activities. It is concluded that the low concentrations of nicotinamide nucleotides in rapidly dividing tissues are the result of competition between NAD synthesis and nucleic acid synthesis for common precursor and cofactors.     

Ribonucleic acid synthesis in regenerating liver of irradiated adrenalectomized rats.

The effect of whole-body irradiation on RNA synthesis in regenerating and non-growing livers was studied in intact and adrenalectomized rats. The animals were divided into four sub-groups: (1) control; (2) irradiation only; (3) partially-hepatectomized; and (4) irradiated partially-hepatectomized. Newly-synthesized RNA was determined by 30 or 40 min uptake of (6-14C) orotic acid. Both nuclear and polyribosomal RNA synthesis in regenerating livers of adrenalectomized rats were depressed below their control levels, regardless of whether irradiation was 2 hours before or 2 hours after partial hepatectomy. Specific radioactivity values of regenerating livers of adrenal intact and adrenalectomized rats were elevated above those of the non-growing livers from irradiated and unirradiated rats.     

Fatty acid synthesis in the regenerating liver of the rat.

1. Synthesis de novo of fatty acids in the rat liver, measured per g wet wt. of tissue, was increased by a factor of about two, between 1 and 4 days after partial hepatectomy, compared with rates in sham-operated control rat livers. 2. There were no associated changes in the rates of liver cholesterol synthesis or of adipose-tissue fatty acid synthesis in rats after partial hepatectomy, compared with rates in sham-operated rats. 3. In regenerating livers, perfused under three different conditions, there was no alteration in the capacity for fatty acid synthesis compared with that of control rats. 4. The increased synthesis of fatty acids in regenerating liver was associated with insignificant increases in plasma concentrations of tricylglycerols and free fatty acids, with a decrease in content of liver glycogen, and with no change in hepatic activity of acetyl-CoA carboxylase. 5. The accelerated rate of synthesis of fatty adids in regenerating liver appears not to be due to any intrinsic alteration in hepatic capacity for fatty acid synthesis, but it may be caused by the continuous action on liver of unidentified circulating factors.     

Inhibition of polyamine accumulation and deoxyribonucleic acid synthesis in regenerating rat liver.

Repeated injections of 1,3-diaminopropane into rats after partial hepatectomy caused a repression-type inhibiton of liver ornithine decarboxylase (EC 4.1.1.17) and totally prevented the marked increases in liver putrescine and spermidine concentrations that normally occur in response to partial hepatectomy. The inhibition of polyamine synthesis by diaminopropane was accompanied by a profound decrease (about 80%) in the synthesis of DNA in the regenerating rat liver without any changes in the synthesis of RNA and total liver protein.     

Protein synthesis by microsomal particles from regenerating rat liver

1. Washed microsome particles from regenerating liver were shown to incorporate [(14)C]leucine into protein more actively than similar preparations from normal liver. 2. The total incorporation in the preparations from regenerating liver increased linearly with the amount of protein incubated, whereas this was not so with preparations from normal liver. 3. The greater activity of regenerating-liver microsomes appeared to be associated with the bound polysomes. 4. The size distribution of polysomes obtained after removal of membrane with deoxycholate was the same in normal and regenerating liver. 5. In general the activity of polysome preparations from normal and regenerating liver was similar. 6. It is concluded that the greater activity of the particles in the microsome fraction from regenerating liver is to be attributed to the ribosomes bound to membrane and that their activity is controlled by factors present in the membrane.     

Regulation of heme synthesis in the regenerating rat liver

This investigation shows that the regulation of heme synthesis in the regenerating rat liver does not differ from the regulation in the normal liver. The heme saturation of tryptophan pyrrolase was found to be low, indicating a reduced concentration of heme in the regulatory heme pool of the regenerating rat liver. As expected, ALAS in the mitochondrial fraction was found to be elevated. It was also shown that ALAS in the regenerating rat liver can be induced by the porphyrinogenic drugs AIA and DDC and that heme reduces its activity. The decrease observed in the activity of cytosolic ALAS might be due to impaired synthesis of the enzyme but does not affect the regulation of the heme biosynthetic pathway.     

Nuclear protein synthesis in regenerating rat liver. Selective histone inhibition by alpha-amanitin

Nuclear protein synthesis has been studied in regenerating rat hepatocytes after partial hepatectomy and α-amanitin treatment. The toxin induced a marked and precocious inhibition of histone synthesis without affecting the acidic nuclear proteins. This inhibition preceded the inhibition of DNA synthesis. The modification of polyribosome profile and of [¹⁴C]lysine incorporation on synthesized polypeptides were consistent with a reduction of specific mRNAs.     

Effects of formamidoxime on macromolecular synthesis in regenerating liver and hepatomas

Formamidoxime caused an inhibition of [³H]thymidine incorporation into DNA in regenerating liver and transplanted hepatomas of different growth rates when administered by i.p. injection to rats. A dose level of formamidoxime (500 mg/kg body weight) which caused at least a 75% inhibition of DNA synthesis in these tissues had little or no effect on the incorporation of [³H]orotate into total RNA. After administration of formamidoxime there was no significant effect on amino acid nitrogen concentration in the tissues. The incorporation of ³H-labeled amino acids into acid-soluble material, cytoplasmic proteins and acid-insoluble nuclear proteins were either unaffected or showed only small changes after treatment of rats with the drug. In regenerating rat liver and Morris hepatomas 7787 and 7777, formamidoxime caused an inhibition of incorporation of ³H-labeled amino acids into both lysine-rich and arginine-rich histones. In the host livers of rats bearing the transplanted hepatomas, histone synthesis was less affected. The data indicated that formamidoxime causes inhibitory effects which are similar in nature and extent to those previously shown for the structurally related compound, hydroxyurea, in the regenerating rat liver and demonstrated that these effects can also be observed in liver tumors.     

Fatty acid synthesis in chick embryonic heart and liver during development.

Fatty acid synthesis by subcellular fractions of heart and liver of chick embryos at varying stages of development has been studied. Fatty acid synthetase activity is associated with the embryonic heart at early stages of development, as suggested by substrate requirement, Schmidt decarboxylation of synthesized fatty acids and gas liquid chromatographic identification of the products as palmitic and stearic acids. The fatty acid synthetase activity decreases in heart cytosol with age of the embryo and is absent in the newly hatched chick and in older chicken. The acetyl CoA carboxylase activity is negligible in embryonic and adult chicken heart. The fatty acid synthetase activity in liver is low, but measurable during the entire embryonic development. The activity increases by about three-fold on hatching and thereafter in fed, newly hatched chicks by about 35-fold, over the basal embryonic activity. The acetyl and malonyl transacylase activities in the heart and liver cytosols during development followed closely the fatty acid synthetase activities in heart and liver, respectively. A non-coordinate induction of fatty acid synthetase and acetyl CoA carboxylase activities in liver was observed during development. The microsomal chain elongation in liver and heart followed the pattern of fatty acid synthetase activity in liver and heart, respectively. The mitochondrial chain elongation in embryonic heart is initially low and increases with age; while this activity in liver is higher in early stages of embryonic development than in the older embryos and the chicks. Measurement of lipogenesis from acetate-1-¹⁴C by liver and heart slices from chick embryos and newly hatched chicks support the conclusions reached in the studies with the subcellular fractions. The results obtained indicate that the major system of fatty acid synthesis in embryonic and adult heart is the mitochondrial chain elongation. In embryonic liver, fatty acid synthesis proceeds by chain elongation, while the de novo system is the major contributor to the lipogenic capacity of the liver after hatching.