Supravital Staining of Mammalian Brain with Intraarterial Methylene Blue Followed by Pressurized Oxygen

In 25-day-old rats, injected intraperitoneally with 0.2 ml aliquots of 6% methylene blue in saline over 1 hr followed by a single 4-6 ml intra-arterial injection; O₂ pressurized to 45 lb/in² was used to improve reblueing of 1.5-2 mm slices of cerebellum, thus increasing staining selectivity. Factors believed to influence this selectivity for axonal elements and fine dendrites are the rapidity and pressure (about 300 mm Hg) of the terminal intra-arterial injection, the hyperbaric O₂ treatment of tissue slabs for 1 hr as a substiute for room air, and immersion in 6% ammonium molybdate for 1 hr before return to atmospheric conditions.     

Hybridization and partial cDNA sequence analyses of bovine lung angiotensin I-converting enzyme

The mRNA encoding angiotensin I-converting enzyme, a zinc-metallo dipeptidyl carboxyhydrolase, has been identified in extracts prepared from bovine lung tissue. Bovine lung poly(A) + mRNAs were subjected to electrophoresis and northern blot hybridization analysis using a radiolabeled synthetic 24-deoxyoligonucleotide probe complementary to eight codons for amino acids at the active-site of the enzyme (Harris, R.B. & Wilson, I.B., J. Biol. Chem. 260, 2208-2211, 1985). This amino acid sequence contains the catalytic glutamic acid residue. A single RNA species (approximately equal to 4 kb) was detected which is 1 kb larger than predicted from the molecular weight of the enzyme. The excess nucleic acid composition may be due to leader and/or trailer sequences or the RNA may encode a high molecular weight precursor form of the enzyme. We have cloned an EcoR1-HindIII digest fragment (1400 bp) of the duplex cDNA derived from the bovine lung converting enzyme poly(A) + mRNA and also Bal31 deletion fragments generated from the 1400 bp clone. Several of the Bal31 clones contain the active-site sequence codons of the enzyme and the complete cDNA sequence of one of these (72 bp) has been determined. We found the amino acid sequence at the active site to be -Phe-Thr-Glu-Leu-Ala-Asn-Ser-, containing the catalytic Glu residue. This sequence is identical with the sequence that we previously determined by manual Edman degradation analysis of the appropriate active-site peptide except that we now find Asn instead of Asp. We have sequenced 670 bp of the 1400 bp clone but have not yet overlapped the active-site sequence.(ABSTRACT TRUNCATED AT 250 WORDS)     

Studies on the inhibition of gluconeogenesis by oxalate

Oxalate was shown to enter isolated rat hepatocytes and to inhibit gluconeogenesis from lactate, pyruvate, and alanine, but not from glutamine, proline, propionate or dihydroxyacetone. Oxalate apparently acts by inhibiting pyruvate carboxylase (EC 6.4.1.1). It is known to inhibit the isolated enzyme, and inhibition of gluconeogenesis was much greater in a bicarbonate-deficient medium where pyruvate carboxylase activity limits the overall rate of the pathway. A slight inhibition of gluconeogenesis from asparagine was observed, suggesting that oxalate may also inhibit gluconeogenesis at another site. Chelation of extracellular Ca²⁺ does not contribute to the inhibition of gluconeogenesis. Compared to oxalate, other Ca²⁺ chelators have little effect upon gluconeogenesis. Also, oxalate inhibits gluconeogenesis effectively both in low Ca²⁺ medium and in medium containing 2.6 mM Ca²⁺. Chelation of intracellular Ca²⁺ also appears to be of little importance, since oxalate does not block the glycogenolytic effects of epinephrine, vasopressin, and angiotensin which are thought to act via Ca²⁺ as the second messenger. The inhibition of gluconeogenesis could conceivably contribute to the toxic actions of oxalate and to the hypoglycemic action of dichloroacetate, a compound that is metabolized to oxalate. However, oxalate did not cause hypoglycemia in the suckling rat, a model in vivo system very dependent upon gluconeogenesis for maintenance of normal blood glucose levels. Thus, inhibition of gluconeogenesis is probably of little importance in oxalate toxicity and the hypoglycemic effects of dichloroacetate.