Demonstration of the synthesis of hydrocarbons in animal tissues

Incubation of tissue of homogenates of peripheral nerves, liver, and subcutaneous adipose tissue of rabbits with [1-14C]palmitic acid and intraperitoneal injection of this preparation into rats, in a dose of 20 muCi per 100 g of weight of the animals, permitted establishment of the presence of enzyme systems of biosynthesis of n-alkanes in the tissues of higher animals. Evidence of the biosynthesis of n-alkanes in the animal organism represents a new aspect of our knowledge of the metabolism of this class of compounds in animal tissues.     

Comparison of the requirements for ribonucleic acid synthesis with the requirements for deoxyribonucleic acid synthesis in animal tissues

Ribonucleic acid polymerase and deoxyribonucleic acid polymerase have been partially purified from bovine lymphosarcoma, lymph node, and thymus. An examination of the deoxyribonucleic acid requirements of the two enzymes indicates that “native” deoxyribonucleic acid is the preferred template for ribonucleic acid synthesis; heat-denatured deoxyribonucleic acid is considerably less active. The primer requirements for deoxyribonucleic acid synthesis differ: “native” deoxyribonucleic acid is usually inactive, while denatured deoxyribonucleic acid is active. The two enzymes also differ in pH optima and in their requirements for metal cofactors.     

Measurement of uridine diphosphate glucuronic acid concentrations and synthesis in animal tissues

1. A method for the isolation from animal tissues of UDP-glucuronic acid by one-dimensional paper chromatography is described and its concentrations in some tissues of several species of vertebrates are reported; the incorporation of [³²P]-phosphate into UDP-glucuronic acid in vivo was also investigated. 2. The concentration of UDP-glucuronic acid was higher in the liver of rats, rabbits and guinea pigs than in the same tissue of some species of birds, amphibia and fishes; also, the concentration of UDP-glucuronic acid in rat liver, kidney and small intestine was several times lower than that of the same tissues of guinea pigs. 3. The rate of [³²P]-phosphate incorporation into UDP-glucuronic acid was very high in rat liver and kidney and almost reached equilibrium with the radioactivity of UDP-glucose 30min after the administration of the [³²P]phosphate.     

A mechanistic model of nutritional control of protein synthesis in animal tissues

Regulation of mRNA translation has been held responsible for effects of diet, age, alcohol, hormones, hibernation, disease and hypoxia on protein synthesis in animal tissues. Dietary effects are due to concentrations of amino acids and insulin in circulation that affect activities of two key translational regulators, eukaryotic initiation factor 2 (F2) and eukaryotic initiation factor 4E binding protein 1 (Bp). To construct a platform for prediction of global protein synthesis to nutritional stimuli, a dynamic, mechanistic model of translational control in whole tissues was developed. The model was composed of a set of differential equations which describe the dynamics of 11 state variables: tRNA and acyl-tRNA for leucine (Leu), limiting (Laa) and other amino acids (Oaa), inactivated F2 with GDP (F2d), activated F2 with GTP (F2t), F4e, Bp and its complex with F4e (4eBp), available mRNA start codons (AUG), and active ribosomes (Arib). Material was assumed to flow from one variable to another according to mass-action kinetics or Michaelis-Menten form. Uncharged tRNA inhibit GTP exchange on eIF2, and free amino acids and insulin inhibit reversible sequestration of F4e by Bp. Initial conditions and parameters were set for a skeletal muscle fractional synthesis rate of 10%/d and ribosome transit time of 80 s. Between amino acid concentrations of 500 and 4000×10³ nM, protein synthesis increased from 0.9 to 11.7%/d at 0 μU/mL insulin, and from 5.0 to 12.8%/d at 30 μU/mL insulin. Predicted responses to graded levels of a deficient amino acid were asymptotic. A single parameter accomodated differences between tissues in insulin sensitivity. Seven parameters must be changed to simulate initiation and elongation rates in more active tissues such as liver, or in tissues of older mature animals. An increase in uncharged tRNA during insulin stimulation highlighted the physiological importance of coordinated regulation of amino acid supply by insulin. In conclusion, the regulation of F4e release from Bp by Ins and Leu, and of F2d recycling by uncharged tRNA can be tied together to describe a wide range of FSR values across tissues and physiological states.     

Acetoin metabolism in animal tissues

The acetoin-synthesizing activity has been studied in the skeletal muscles, brain, liver and spleen homogenates (numbered as the activity decreases). The acetoin-synthesizing activity drastically increases in case of the acetaldehyde excess and alcohol intoxication. The acetaldehyde concentrations of above 1.10(-3) M inhibit the liver pyruvate dehydrogenase activity and increase the non-oxidative transformation of pyruvate. Acetoin is rapidly metabolized in the organism eliminating from blood 10 minutes after its injection. Acetoin is an effective precursor in the biosynthesis of lipids.     

High-throughput non-heme iron assay for animal tissues

Iron has been widely studied in nearly every realm of biology. However, current methodologies, such as genetic mapping or mutation screening, have been difficult to apply due to the lack of robust high-throughput methods for quantifying iron levels from cells or tissues. The measurement of total iron levels in tissues, usually done with atomic absorption spectroscopy, is impractical for large numbers of samples and includes the contribution of heme iron from hemoglobin contained in red blood cells. The measurement of non-heme iron by reaction with a bathophenanthroline reagent, a commonly used assay reported more than 30 years ago, is also not feasible for large-scale analyses because it is cuvette-based. We therefore have modified this method to a microplate format that will facilitate large-scale analysis. The microplate assay is highly sensitive and specific, and is a simple and effective method for the measurement of non-heme iron for animal tissues that will enable the application of high-throughput of genetic methodologies.