Entry of [(1,2-13C2)acetyl]-L-carnitine in liver tricarboxylic acid cycle and lipogenesis: a study by 13C NMR spectroscopy in conscious, freely moving rats.

The biochemical pathways involved in acetyl-L-carnitine utilization were investigated in conscious, freely moving rats by 13C NMR spectroscopy. Following 4-h [(1,2-13C2)acetyl]-L-carnitine infusion in fasted animals, the free carnitine levels in serum were increased, and an efflux of unlabelled acetyl-L-carnitine from tissues was observed. [(1,2-13C2)Acetyl]-L-carnitine was found to enter biosynthetic pathways in liver, and the acetyl moiety was incorporated into both cholesterol and 3-hydroxybutyrate carbon skeleton. In accord with the entry of [(1,2-13C2)acetyl]-L-carnitine in the mitochondrial acetylCoA pool associated with tricarboxylic acid cycle, the 13C label was also found in liver glutamate, glutamine, and glutathione. The analysis of the 13C-labelling pattern in 3-hydroxybutyrate and cholesterol carbon skeleton provided evidence that the acetyl-L-carnitine-derived acetylCoA pool used for ketone bodies synthesis in mitochondria was homogeneous, whereas cholesterol was synthesized from two different acetylCoA pools located in the extra- and intramitochondrial compartment, respectively. Furthermore, cholesterol molecules were shown to be preferentially synthesized by the metabolic route involving the direct channelling of CoA-activated mitochondria-derived ketone bodies into 3-hydroxy-3-methylglutarylCoA pathway, prior to equilibration of their acyl groups with extramitochondrial acetylCoA pool via acetoacetylCoA thiolase.     

The rep region of pR plasmid regulates the expression of SOS system

Summary By using an artificial hybrid between phage and the pR plasmid, we have shown that the rep region of the pR plasmid encodes a function which regulates the expression of the muc genes (plasmid genes that are under the negative control of lexA and responsible for an increased rate of spontaneous mutagenesis and resistance to UV and chemicals). Expression of the muc genes was monitored by a fusion between the muc promoter and the lacZ structural gene. When E. coli cells containing such a fusion are infected by the hybrid pR phasmid, -galactosidase activity is enhanced, indicating that pR encodes an antagonist of lexA. By deletion mapping we have located the gene encoding the antagonist of lexA (bat) in the rep region of the plasmid. The bat gene product can also antagonize the cI repressor as shown by the observation that pR phasmids are virulent on a homoimmune lysogen. We have exploited this latter property to carry out genetic and functional analysis of the bat region. This region is organized as a classical operon where the expression of the bat structural gene is negatively regulated by a repressor gene that encodes a proteic product.     

Voltage-dependent channels permeable to K+ and Na+ in the membrane ofAcer pseudoplatanus vacuoles

Summary The patch-clamp technique in whole-cell configuration was used to study the electrical properties of the tonoplast in isolated vacuoles fromAcer pseudoplatanus cultured cells. In symmetrical KCl or K₂ malate solutions, voltage- and time-dependent inward currents were elicited by hyperpolarizing the tonoplast (inside negative), while in the positive range of potential the conductance was very small. The specific conductance of the tonoplast at –100 mV, in 100mm symmetrical KCl was about 160 S/cm². The reversal potentials (E _rev) of the current, measured in symmetrical or asymmetrical ion concentrations (cation, anion or both) were very close to the values of the K⁺ equilibrium potential. Experiments performed in symmetrical or asymmetrical NaCl indicate that Na⁺ too can flow through the channels. NeitherE _rev nor amplitude and kinetics of the current changed by replacing NaCl with KCl in the external solution. These results indicate the presence of hyperpolarization-activated channels in tonoplasts, which are permeable to K⁺ as well as to Na⁺. Anions such as Cl^– or malate seem to contribute little to the channel current.     

Tricyclic Imipramine Modification of the Circadian Rhythms of Hypothalamic Serotonin, its Precursors and Acid Catabolite in Individually Housed Rats

Circadian rhythms of serotonin (5HT), its precursors tryptophan (TP) and 5-hydroxy-tryptophan (5HTP) and its acid catabolite 5-hydroxy-indoleacetic acid (5HIAA), were determined in the hypothalamus of control rats and rats which had been treated continuously with subcutaneous imipramine (10 mg/kg/day) for 2 weeks.

Rats were individually housed and entrained to LD12:12. Controls showed the 5HT and TP peaks in the light and dark periods respectively, as reported in the literature, but no inverted correlation (antiphase) between SHT and 5HIAA rhythms.

Imipramine significantly modified circadian rhythm characteristics: the 5HT acrophase was advanced, that of TP and 5HIAA was delayed. Imipramine also significantly increased hypothalamic SHT and TP concentrations.     

On the association of DNA polymerase alpha activity with the nuclear matrix in HeLa cells

The association of DNA polymerase alpha activity with the nuclear matrix has been reinvestigated in HeLa cells. Isolated nuclei were extracted with 2M NaCl and then digested with Dnase I and the final structures were recovered by centrifugation through a sucrose cushion. Typically over 98% of the total DNA synthesized in the matrix fraction on either endogenous matrix-associated DNA or activated calf thymus DNA was due to DNA polymerase alpha as defined by inhibition to n-ethylmaleimide or aphidicolin. DNA polymerase beta activity was absent or recovered in only trace amounts. Matrix-bound DNA polymerase alpha activity demonstrated a remarkable degree of stability: DNA synthesis was essentially linear up to 3 hours at 37 degrees C. Overall, these results substantiate previous findings from regenerating rat liver, unlike other data obtained from tissue culture cells.     

Protonated state of methotrexate, trimethoprim, and pyrimethamine bound to dihydrofolate reductase

13C nuclear magnetic resonance (NMR) of methotrexate, trimethoprim, and pyrimethamine enriched 90% with 13C at C2 has provided a sensitive means of detecting the state of protonation of the heterocyclic rings of these inhibitors. In each case, protonation of N1 causes an upfield movement of the chemical shift of C2 by more than 6 ppm. By this method it has been shown that, at pH values up to 9.2, methotrexate is bound to bovine liver dihydrofolate reductase with N1 of the inhibitor protonated, just as in the case of the complex with reductase from Streptococcus faecium and Lactobacillus casei. Furthermore, trimethoprim bound to reductase from any of the three sources, and pyrimethamine bound to either of the bacterial reductases also have N1 protonated even at pH values up to 10. This implies that in all cases there is a strong interaction between protonated N1 of the inhibitor and the carboxylate group of the active site aspartate or glutamate. In every case pKa of the bound inhibitor is increased by several units, a finding in accord with crystallographic evidence that inhibitor bound to L. casei reductase is in a hydrophobic environment and that N1 is not hydrogen-bonded to water. It was confirmed by titration of protein fluorescence that trimethoprim has greater affinity for bacterial reductase than for vertebrate (bovine) reductase, and that this selectivity is more marked in ternary complexes in which NADPH is also bound to the active site. However, the data cited above indicate that this difference in affinities is not due to a weaker ionic interaction between protonated N1 of trimethoprim and the bovine enzyme. Instead, binding of the trimethoprim side chain to hydrophobic sites on the enzyme must provide less binding energy in the case of the mammalian enzyme.