Pharmacokinetic and biochemical studies on acivicin in phase I clinical trials.

Acivicin pharmacokinetics were studied in Phase I patients receiving i.v. treatment on single-dose or daily x5 (daily times five doses) regimens repeated every 3 weeks. In 14 patients, the time course of plasma concentrations was characterized by a biexponential equation with a terminal (elimination-phase) half-life of 9.92 +/- 3.91 h (mean +/- SD), distribution phase half-life of 0.32 +/- 0.28 h, total body clearance of 1.69 +/- 0.48 liters/h/m2, and volume of distribution of 21.79 +/- 2.94 liters/m2. Acivicin kinetics appeared to be dose-independent over the range of 8.5-150 mg/m2/day. Urinary excretion of intact acivicin in nine patients ranged from 2-42% in the first 24 h following administration; interpatient variability in urinary excretion was large, but daily urinary recovery within patients on the daily x5 schedule was quite consistent. Measurements of acivicin effects on the activity of carbamyl phosphate synthetase II (CPS II) were conducted using leukocytes and/or malignant ascites of three colon cancer patients. Acivicin given to one patient at 8.5 mg/m2/day on the daily x5 schedule caused a 70% reduction in leukocyte CPS II activity within 5 h after therapy was initiated. Leukocyte CPS II activity remained suppressed at this level over the 5-day dosing regimen. In this patient, CPS II activity in malignant ascitic cells had decreased by 75% on day 4 of the daily x5 regimen. On the single dose schedule, treatment of two patients with 100 mg/m2 caused leukocyte CPS II activity to decrease by greater than 90% within 4 h of treatment with gradual recovery over the next 2 days.

Nature and environment of the sulfhydryls of membrane-associated D-lactate dehydrogenase of Escherichia coli.

Ellman's reagent, 5,5'-dithiobis(2-nitrobenzoic acid), has been used to titrate D-lactate dehydrogenase (D-LDH), a respiratory flavoenzyme of Escherichia coli. All six of the possible sulfhydryls titrate in the presence of 2% sodium dodecylsulfate, showing that D-lactate dehydrogenase does not contain any -S-S- bridges. In the native state, only two sulfhydryls are accessible in buffer and only one in the presence of lipid. Single-site mutations of each of the six cysteines of D-lactate dehydrogenase have been prepared. Each of the purified mutant proteins has full activity, demonstrating that an -SH group is not essential to the FAD-driven redox reaction. Ellman's titrations of the mutant proteins have led to the identification of cysteines 65, 146, 156, and 256 in the amino-terminal end as those containing the sulfhydryls that are not accessible in buffer or in buffer plus lipid. The cysteine at 422 is titrated only partially in buffer, while in buffer containing lipid, a necessary factor for full enzymatic activity, its sulfhydryl is inaccessible to the reagent. Cysteine 492 has been identified as containing the sulfhydryl that is accessible to the reagent under both conditions.

A biochemical study of the reconstitution of D-lactate dehydrogenase-deficient membrane vesicles using fluorine-labeled components.

Fluorine-19 labeled compounds have been incorporated into lipids and proteins of Escherichia coli. 19F-Labeled membrane vesicles, prepared by growing a fatty acid auxotroph of a D-lactate dehydrogenase-deficient strain on 8,8-difluoromyristic acid, can be reconstituted for oxidase and transport activities by binding exogenous D-lactate dehydrogenase. 19F-Labeled D-lactate dehydrogenases prepared by addition of fluorotryptophans to a tryptophan-requiring strain are able to reconstitute D-lactate dehydrogenase-deficient membrane vesicles. Thus, lipid and protein can be labeled independently and used to investigate protein-lipid interactions in membranes.

A 19F-NMR study of the membrane-binding region of D-lactate dehydrogenase of Escherichia coli.

D-Lactate dehydrogenase (D-LDH) is a membrane-associated respiratory enzyme of Escherichia coli. The protein is composed of 571 amino acid residues with a flavin adenine dinucleotide (FAD) cofactor, has a molecular weight of approximately 65,000, and requires lipids or detergents for full activity. We used NMR spectroscopy to investigate the structure of D-LDH and its interaction with phospholipids. We incorporated 5-fluorotryptophan (5F-Trp) into the native enzyme, which contains five tryptophan residues, and into mutant enzymes, where a sixth tryptophan is substituted into a specific site by oligonucleotide-directed mutagenesis, and studied the 5F-Trp-labeled enzymes using 19F-NMR spectroscopy. In this way, information was obtained about the local environment at each native and substituted tryptophan site. Using a nitroxide spin-labeled fatty acid, which broadens the resonance from any residue within 15 A, we have established that the membrane-binding area of the protein includes the region between Tyr 228 and Phe 369, but is not continuous within this region. This conclusion is strengthened by the results of 19F-NMR spectroscopy of wild-type enzyme labeled with fluorotyrosine or fluorophenylalanine in the presence and absence of a nitroxide spin-labeled fatty acid. These experiments indicate that 9-10 Phe and 3-4 Tyr residues are located near the lipid phase.

Preliminary toxicity studies with the DNA-binding antibiotic, CC-1065.

It was previously shown that the potent new DNA-binding antibiotic, CC-1065, prolonged life span, but was not curative, when administered to mice bearing a variety of transplantable tumors. In this paper we show results of preliminary studies indicating that CC-1065 caused lethal delayed hepatotoxicity at therapeutic antineoplastic doses. In non-tumor-bearing mice toxic deaths were delayed ca 50 days after a single iv dose of 12.5 micrograms/kg and as much as 70 days after 10 micrograms/kg was given ip. Intravenous mouse LD50's were 9 micrograms/kg, single dose, and 0.3 microgram/kg/day, five daily doses. Intraperitoneal LD50's were 0.53 approximately 6.90 micrograms/kg, single dose, and 0.14 microgram/kg/day, five daily doses. Mice treated with high doses iv died within 12 days with frank hepatic necrosis, whereas delayed deaths at lower doses were associated with changes in hepatic mitochondrial morphology. This suggested that separate mechanisms of hepatotoxicity were operative at high and low dose ranges. Attempts to prevent the delayed toxicity of CC-1065 in the mouse by treatment with WR-2721, N-acetylcysteine, phenobarbital, Aroclor 1254, and 3-methylcholanthrene were unsuccessful; no effect on the LD50 or the times of death was observed. Lethal doses in the rabbit were similar on a body surface area basis to those in the mouse; evidence of hepatotoxicity was also observed in the rabbit.

Incorporation of fluorotryptophans into proteins of escherichia coli.

A tryptophan-requiring strain of Escherichia coli can go through two doublings of optical density after L-tryptophan is replaced in the medium by 4-fluorotryptophan, during which the fluoro analog displaces approximately 75% of the L-tryptophan in cell protein. One doubling occurs in the presence of 5- or 6-fluorotryptophan, with 50-60% replacement of L-tryptophan by analog. When beta-galactosidase is induced at the time of addition of analog, it reaches 60% of the control specific activity in the presence of 4-fluorotryptophan, 10% of normal in the presence of 5- or 6-fluorotryptophan. Lactose permease activity is 35% of the control in the presence of 4- and 6-fluorotryptophan, less than 10% in the presence of 5-fluorotryptophan. D-Lactate dehydrogenase shows a specific activity twice that of the control in the presence of 4-fluorotryptophan, one-half with 5- or 6-fluorotryptophan. Thus fluorotryptophan can be incorporated into proteins and affect their activities, although the nature and magnitude of the effect cannot be predicted for any given enzyme. Such substituted proteins should be useful for the study of protein structure and function by 19F nuclear magnetic resonance and other techniques.

Interaction of the membrane-bound D-lactate dehydrogenase of Escherichia coli with phospholipid vesicles and reconstitution of activity using a spin-labeled fatty acid as an electron acceptor: a magnetic resonance and biochemical study.

The interaction with phospholipid vesicles of the membrane-bound respiratory enzyme D-lactate dehydrogenase of Escherichia coli has been studied. Proteolytic digestion studies show that D-lactate dehydrogenase is protected from trypsin digestion to a larger extent when it interacts with phosphatidylglycerol than with phosphatidylcholine vesicles. Wild-type D-lactate dehydrogenase and mutants in which an additional tryptophan is substituted in selected areas by site-specific oligonucleotide-directed mutagenesis have been labeled with 5-fluorotryptophan. 19F nuclear magnetic resonance studies of the interaction of these labeled enzymes with small unilamellar phospholipid vesicles show that Trp 243, 340, and 361 are exposed to the lipid phase, while Trp 384, 407, and 567 are accessible to the external aqueous phase. Reconstitution of enzymatic activity in phospholipid vesicles has been studied by adding enzyme and substrate to phospholipid vesicles containing a spin-labeled fatty acid as an electron acceptor. The reduction of the doxyl group of the spin-labeled fatty acid has been monitored indirectly by nuclear magnetic resonance and directly by electron paramagnetic resonance. These results indicate that an artificial electron-transfer system can be created by mixing D-lactate dehydrogenase and D-lactate together with phospholipid vesicles containing spin-labeled fatty acids.

The crystal structure of D-lactate dehydrogenase, a peripheral membrane respiratory enzyme.

d-Lactate dehydrogenase (d-LDH) of Escherichia coli is a peripheral membrane respiratory enzyme involved in electron transfer, located on the cytoplasmic side of the inner membrane. d-LDH catalyzes the oxidation of d-lactate to pyruvate, which is coupled to transmembrane transport of amino acids and sugars. Here we describe the crystal structure at 1.9 A resolution of the three domains of d-LDH: the flavin adenine dinucleotide (FAD)-binding domain, the cap domain, and the membrane-binding domain. The FAD-binding domain contains the site of d-lactate reduction by a noncovalently bound FAD cofactor and has an overall fold similar to other members of a recently discovered FAD-containing family of proteins. This structural similarity extends to the cap domain as well. The most prominent difference between d-LDH and the other members of the FAD-containing family is the membrane-binding domain, which is either absent in some of these proteins or differs significantly. The d-LDH membrane-binding domain presents an electropositive surface with six Arg and five Lys residues, which presumably interacts with the negatively charged phospholipid head groups of the membrane. Thus, d-LDH appears to bind the membrane through electrostatic rather than hydrophobic forces.

Inactive and temperature-sensitive folding mutants generated by tryptophan substitutions in the membrane-bound d-lactate dehydrogenase of Escherichia coli.

A combination of site-specific mutagenesis and 19F nuclear magnetic resonance has been used to investigate the structural properties of D-lactate dehydrogenase, a membrane-associated enzyme of Escherichia coli. The protein (65,000 Da) has been labeled with 5-fluorotryptophan for 19F nuclear magnetic resonance studies. Tryptophan has been substituted for individual phenylalanine, tyrosine, isoleucine, and leucine residues at various positions throughout the enzyme molecule, and the fluorinated native and substituted tryptophan residues have been used as probes of the local environment. All 24 mutants thus generated are expressed in E. coli. Ten are fully active and purfiable following the usual procedure, while 14 either are inactive or produce low levels of activity. The amount of active enzyme produced from the low-yield mutants is dependent on the temperature at which synthesis is carried out, with more active enzyme produced at 18 degrees C than at 27, 35, or 42 degrees C. Cells grown at 27 degrees C and then incubated at 42 degrees C retain 90-100% of their activity. All of the expressed protein from the inactive mutants is Triton-insoluble, aggregated, and not readily purfiable; the inactive mutant protein appears to be improperly folded. Most of the expressed D-lactate dehydrogenase from the partially active mutants is also Triton-insoluble; a small fraction, however, is soluble in Triton and can be purified to yield active enzyme. All the purified enzymes from these low-yield mutants of D-lactate dehydrogenase have essentially normal VmaxS, and all but two have normal KmS. Once purified, the low-yield mutant enzymes are stable at 42 degrees C.(ABSTRACT TRUNCATED AT 250 WORDS)

Overproduction and nucleotide sequence of the respiratory D-lactate dehydrogenase of Escherichia coli.

Recombinant DNA plasmids containing the gene for the membrane-bound D-lactate dehydrogenase (D-LDH) of Escherichia coli linked to the promoter PL from lambda were constructed. After induction, the levels of D-LDH were elevated 300-fold over that of the wild type and amounted to 35% of the total cellular protein. The nucleotide sequence of the D-LDH gene was determined and shown to agree with the amino acid composition and the amino-terminal sequence of the purified enzyme. Removal of the amino-terminal formyl-Met from D-LDH was not inhibited in cells which contained these high levels of D-LDH.

A 19F-NMR study of the equilibrium unfolding of membrane-associated D-lactate dehydrogenase of Escherichia coli.

Partially folded protein intermediates have been observed by 19F-NMR spectroscopy during the equilibrium unfolding of the membrane-associated D-lactate dehydrogenase (D-LDH) of Escherichia coli by a denaturant, guanidine hydrochloride (Gdn.HCl). The results from 19F-NMR and circular dichroism spectroscopic studies suggest that the intermediates observed at low Gdn.HCl concentrations (< 3.5 M) exhibit features similar to "molten globules" that contain considerable amounts of secondary and tertiary structure. The results of 19F-NMR studies on 5F-Trp-labeled D-LDH, such as the chemical shift changes, nuclear Overhauser effect, and solvent-induced isotopic shift effect, show that different regions of D-LDH unfold nonuniformly in Gdn.HCl in the presence of lysophosphatidylcholine. The polypeptide appears to unfold in a general order from the carboxyl end to the amino end, in agreement with previous findings from our laboratory that the carboxyl-terminal region of D-LDH is largely exposed to the solvent while the amino-terminal region is buried in the protein core. The structure of the partially unfolded intermediate forms of D-LDH is stabilized in the presence of lipid-like detergents, such as lysophosphatidylcholine.

Nuclear magnetic resonance and molecular genetic studies of the membrane-bound D-lactate dehydrogenase of Escherichia coli.

In this study we demonstrate the potential of combining fluorine-19 nuclear magnetic resonance (NMR) spectroscopy with molecular genetics. We are using the membrane-bound enzyme D-lactate dehydrogenase of Escherichia coli as a model system to characterize interactions between proteins and lipids. We have labeled D-lactate dehydrogenase with 4-, 5-, and 6-fluorotryptophans and obtained high-resolution fluorine-19 NMR spectra showing five resonances, in agreement with the five tryptophan residues expected from the DNA sequence. The five 19F resonances in the spectra have been assigned to the specific tryptophan residues in the primary sequence of D-lactate dehydrogenase by site-directed oligonucleotide mutagenesis of the cloned gene. We observe large differences in the relative fluorine-19 chemical shifts of each tryptophan residue when labeled by different isomers of fluorotryptophan. We have determined by NMR methods that two tryptophans are exposed to the solvent and that none of the tryptophan residues are within 10 A of the lipid phase. On the basis of 19F NMR spectroscopy of the labeled tryptophan residues, the conformation of D-lactate dehydrogenase is similar in aqueous solution and in the presence of a variety of lipids and detergents. This result indicates that the presence of lipids or detergents is not required to maintain the tertiary structure of this membrane-bound enzyme. In contrast, Triton X-100 induces a change to an abnormal conformation of the enzyme as judged from both NMR spectroscopy and the effect of temperature on the maximal velocity of the enzyme in the presence of this detergent.

Site-specific incorporation of 5-fluorotryptophan as a probe of the structure and function of the membrane-bound D-lactate dehydrogenase of Escherichia coli: a 19F nuclear magnetic resonance study.

The structure and function of the membrane-bound D-lactate dehydrogenase of Escherichia coli have been investigated by fluorine-19 nuclear magnetic resonance spectroscopy of 5-fluorotryptophan-labeled enzyme in conjunction with oligonucleotide-directed, site-specific mutagenesis. 5-Fluorotryptophan has been substituted for nine phenylalanine, tyrosine, and leucine residues in the enzyme molecule without loss of activity. The 19F signals from these additional tryptophan residues have been used as markers for sensitivity to substrate, exposure to aqueous solvent, and proximity to a lipid-bound spin-label. The nuclear magnetic resonance data show that two mutational sites, at amino acid residues 340 and 361, are near the lipid environment used to stabilize the enzyme. There are a number of amino acid residues on the carboxyl side of this region that are strongly sensitive to the aqueous solvent. The environment of the wild-type tryptophan residue at position 469 changes as a result of two of the substitution mutations, suggesting some amino acid residue-residue interactions. Secondary structure prediction methods indicate a possible binding site for the flavin adenine dinucleotide cofactor in the carboxyl end of the enzyme molecule. These results suggest that the membrane-bound D-lactate dehydrogenase may have the two-domain structure of many cytoplasmic dehydrogenases but with the addition of a membrane-binding domain between the catalytic and cofactor-binding domains. This type of three-domain structure may be of general significance for understanding the structure of membrane-bound proteins which do not traverse the lipid bilayer of membranes.