Mechanisms of JP-8 jet fuel toxicity. I. Induction of apoptosis in rat lung epithelial cells.

JP-8 is a kerosene-based fuel widely used by the U.S. military. Various models of human occupational and animal exposure to JP-8 have demonstrated the potential for local and systemic toxicity but the mechanisms involved are unknown. The purpose of our investigation was to study the molecular mechanisms of JP-8 toxicity by using an in vitro model. JP-8 exposure in a rat lung alveolar type II epithelial cell line (RLE-6TN) induces biochemical and morphological markers of apoptotic cell death: caspase-3 activation, poly(ADP-ribose) polymerase (PARP) cleavage, chromatin condensation, membrane blebbing, cytochrome c release from mitochondria, and genomic DNA cleavage into both oligonucleosomal (DNA ladder) and high-molecular-weight (HMW) fragments. The human histiocytic lymphoma cell line (U937) also responds to JP-8 with caspase-3 activation, cleavage of caspase substrates, including PARP, DNA-PK, and lamin B1, and degradation of genomic DNA with the production of HMW fragments. Caspase-3 activation and PARP cleavage also occur in the acute T-cell leukemia cell line (Jurkat) following treatment with JP-8. Furthermore, Jurkat cells stably transfected with a plasmid encoding the antiapoptotic protein Bcl-x(L) or pretreated with the pan-caspase inhibitor Boc-d-fmk, are relatively resistant to the cytotoxic effects of JP-8 compared to control cells. Finally, we demonstrate that PARP cleavage occurs in primary mouse thymocytes exposed to JP-8. In conclusion, our data support the hypothesis that apoptotic cell death is responsible at least partially for the cytotoxic effects of JP-8 and suggest that inhibition of the apoptotic cascade might reduce JP-8 toxicity.

Relationships amongst some bacterial and yeast lactate and mandelate dehydrogenases.

Five yeast strains were isolated by enrichment culture on the basis of their ability to grow on mandelate and two of these strains were identified as Rhodotorula glutinis. In addition, a range of yeasts from culture collections was screened for growth on mandelate. The results suggest that mandelate utilization is a widespread but not universal characteristic within the genus Rhodotorula. Several of the yeasts contained an inducible NAD-dependent D(-)-mandelate dehydrogenase and an inducible dye-linked (presumably flavoprotein) L(+)-mandelate dehydrogenase. All the D(-)-mandelate dehydrogenases from the yeasts showed immunological cross-reactivity with each other (as judged by both immunoinhibition and immunoblotting), as did all the yeast L(+)-mandelate dehydrogenases that were tested. Determination of N-terminal amino acid sequences of several bacterial and yeast lactate and mandelate dehydrogenases, together with the evidence from the immunological studies, confirmed and extended previous proposals that there are several major groups of such dehydrogenases: FMN-dependent, membrane-bound L(+)-lactate and L(+)-mandelate dehydrogenases (M(r) = approx. 44,000) in bacteria, mitochondrial flavocytochrome b2 L(+)-lactate and L(+)-mandelate dehydrogenases (M(r) = approx. 59,000) in yeasts, FAD-dependent, membrane-bound D(-)-lactate and D(-)-mandelate dehydrogenases in bacteria, and soluble NAD-dependent D(-)-mandelate dehydrogenases in both bacteria and yeasts.

Comparison of mandelate dehydrogenases from various strains of Acinetobacter calcoaceticus: similarity of natural and 'evolved' forms.

In previous work it had been shown that Acinetobacter calcoaceticus wild-type strain NCIB 8250 had only an L-mandelate deydrogenase but it could give rise to mutants that contained an evolved D-mandelate dehydrogenase; conversely, wild-type strain EBF 65/65 had only a D-mandelate dehydrogenase but gave rise to mutants that possessed an evolved L-mandelate dehydrogenase. Several other wild-type strains of A. calcoaceticus have now been shown to grow on both enantiomers of mandelate. In every case the L-mandelate dehydrogenases were found to be much more heat-stable and insensitive to inhibition by p-chloromercuribenzoate than were the D-mandelate dehydrogenases when measured in bacterial extracts. All the D-mandelate dehydrogenases in the wild-type strains were inactivated to about the same extent by an antiserum that had been raised in a rabbit against an evolved D-mandelate dehydrogenase. An evolved D-mandelate deydrogenase (from a mutant strain derived from strain NCIB 8250) and an original D-mandelate dehydrogenase (from a mutant strain derived from strain EBF 65/65) were purified to homogeneity by the same procedure and were indistinguishable as judged by immunological cross-reactivity of the native and the sodium-dodecyl-sulphate-denatured enzymes, solubility in cholate, net charge at pH 7.5, pI value, salting-out properties, Mr value, apparent K(m) value for D-mandelate, heat-stability and sensitivity to p-chloromercuribenzoate. The most likely explanation for the appearance of evolved mandelate dehydrogenases in strains of A. calcoaceticus is that cryptic genes become expressed.

Purification of the phosphorylated night form and dephosphorylated day form of phosphoenolpyruvate carboxylase from Bryophyllum fedtschenkoi.

Phosphoenolpyruvate carboxylase of Bryophyllum fedtschenkoi was shown to exist in two forms: a night form, which is phosphorylated and has low sensitivity to inhibition by malate, and a day form, which is dephosphorylated and 10 times more sensitive to malate. The day and night forms of the enzyme were purified retaining their distinct malate sensitivities and phosphorylation states. The purified enzymes contained a major protein (subunit Mr 112,000) and a minor protein (subunit Mr 123,000). The two polypeptides appeared to have closely related amino acid sequences and were present in a similar ratio in extracts that had been prepared rapidly. The phosphate present in the night form of the enzyme was covalently bound to serine. It was not a catalytic intermediate. Alkaline phosphatase removed the phosphate group in vitro and increased the malate sensitivity of the enzyme to that observed for the day form. Both the day and night forms of the enzyme were probably tetramers, and their apparent Mr was lowered by the presence of malate, but was unaffected by Mg2+ ions, EDTA, a rise in pH or a 10-fold change in enzyme concentration. The rapid loss of malate sensitivity, observed in extracts of leaves prepared during the day and at night, was shown to be due to proteolysis of the enzyme. It was slowed in the presence of malate and by phosphorylation of the enzyme.

Enzyme activity changes during cyclic AMP-induced stalk cell differentiation in P4, a variant of Dictyostelium discoideum.

The P4 variant of Dictyostelium discoideum is characterized by the production of fruiting structures in which the overall proportion of stalk to spore material is increased, relative to the wild type. The altered morphology of the mutant is due to increased sensitivity to cyclic AMP which promotes stalk cell differentiation. In the presence of 10-4 M-cyclic AMP the entire population of P4 amoebae forms clumps of stalk cells on the surface of the dialysis membrane support. Measurement of changes in activity of a range of developmentally-regulated enzymes during the development of P4 in the presence and absence of cyclic AMP has allowed us to identify three classes of enzyme: (i) Those, such as beta-glucosidase II, trehalose-6-phosphate synthetase and uridine diphosphogalactose-4-epimerase, which are required for the production of spores. (ii) Enzymes, primarily but perhaps not exclusively, required during stalk cell formation. Typical of these are N-acetylglucosaminidase and alkaline phosphatase. (iii) General enzymes, such as threonine dehydrase, alpha-mannosidase and uridine diphosphoglucose pyrophyosphorylase, which are present inboth pre-stalk and pre-spore cells and appear to be necessary for the development of both cell types.