Biochemical and molecular analysis of carboxylesterase-mediated hydrolysis of cocaine and heroin.

BACKGROUND AND PURPOSE: Carboxylesterases (CEs) metabolize a wide range of xenobiotic substrates including heroin, cocaine, meperidine and the anticancer agent CPT-11. In this study, we have purified to homogeneity human liver and intestinal CEs and compared their ability with hydrolyse heroin, cocaine and CPT-11. EXPERIMENTAL APPROACH: The hydrolysis of heroin and cocaine by recombinant human CEs was evaluated and the kinetic parameters determined. In addition, microsomal samples prepared from these tissues were subjected to chromatographic separation, and substrate hydrolysis and amounts of different CEs were determined. KEY RESULTS: In contrast to previous reports, cocaine was not hydrolysed by the human liver CE, hCE1 (CES1), either as highly active recombinant protein or as CEs isolated from human liver or intestinal extracts. These results correlated well with computer-assisted molecular modelling studies that suggested that hydrolysis of cocaine by hCE1 (CES1), would be unlikely to occur. However, cocaine, heroin and CPT-11 were all substrates for the intestinal CE, hiCE (CES2), as determined using both the recombinant protein and the tissue fractions. Again, these data were in agreement with the modelling results. CONCLUSIONS AND IMPLICATIONS: These results indicate that the human liver CE is unlikely to play a role in the metabolism of cocaine and that hydrolysis of this substrate by this class of enzymes is via the human intestinal protein hiCE (CES2). In addition, because no enzyme inhibition is observed at high cocaine concentrations, potentially this route of hydrolysis is important in individuals who overdose on this agent.

Gonococcal MinD affects cell division in Neisseria gonorrhoeae and Escherichia coli and exhibits a novel self-interaction.

The Min proteins are involved in determining cell division sites in bacteria and have been studied extensively in rod-shaped bacteria. We have recently shown that the gram-negative coccus Neisseria gonorrhoeae contains a min operon, and the present study investigates the role of minD from this operon. A gonococcal minD insertional mutant, CJSD1, was constructed and exhibited both grossly abnormal cell division and morphology as well as altered cell viability. Western blot analysis verified the absence of MinD from N. gonorrhoeae (MinD(Ng)) in this mutant. Hence, MinD(Ng) is required for maintaining proper cell division and growth in N. gonorrhoeae. Immunoblotting of soluble and insoluble gonococcal cell fractions revealed that MinD(Ng) is both cytosolic and associated with the insoluble membrane fraction. The joint overexpression of MinC(Ng) and MinD(Ng) from a shuttle vector resulted in a significant enlargement of gonococcal cells, while cells transformed with plasmids encoding either MinC(Ng) or MinD(Ng) alone did not display noticeable morphological changes. These studies suggest that MinD(Ng) is involved in inhibiting gonococcal cell division, likely in conjunction with MinC(Ng). The alignment of MinD sequences from various bacteria showed that the proteins are highly conserved and share several regions of identity, including a conserved ATP-binding cassette. The overexpression of MinD(Ng) in wild-type Escherichia coli led to cell filamentation, while overexpression in an E. coli minD mutant restored a wild-type morphology to the majority of cells; therefore, gonococcal MinD is functional across species. Yeast two-hybrid studies and gel-filtration and sedimentation equilibrium analyses of purified His-tagged MinD(Ng) revealed a novel MinD(Ng) self-interaction. We have also shown by yeast two-hybrid analysis that MinD from E. coli interacts with itself and with MinD(Ng). These results indicate that MinD(Ng) is required for maintaining proper cell division and growth in N. gonorrhoeae and suggests that the self-interaction of MinD may be important for cell division site selection across species.

Multiple cadherin extracellular repeats mediate homophilic binding and adhesion.

The extracellular homophilic-binding domain of the cadherins consists of 5 cadherin repeats (EC1-EC5). Studies on cadherin specificity have implicated the NH(2)-terminal EC1 domain in the homophilic binding interaction, but the roles of the other extracellular cadherin (EC) domains have not been evaluated. We have undertaken a systematic analysis of the binding properties of the entire cadherin extracellular domain and the contributions of the other EC domains to homophilic binding. Lateral (cis) dimerization of the extracellular domain is thought to be required for adhesive function. Sedimentation analysis of the soluble extracellular segment of C-cadherin revealed that it exists in a monomer-dimer equilibrium with an affinity constant of approximately 64 microm. No higher order oligomers were detected, indicating that homophilic binding between cis-dimers is of significantly lower affinity. The homophilic binding properties of a series of deletion constructs, lacking successive or individual EC domains fused at the COOH terminus to an Fc domain, were analyzed using a bead aggregation assay and a cell attachment-based adhesion assay. A protein with only the first two NH(2)-terminal EC domains (CEC1-2Fc) exhibited very low activity compared with the entire extracellular domain (CEC1-5Fc), demonstrating that EC1 alone is not sufficient for effective homophilic binding. CEC1-3Fc exhibited high activity, but not as much as CEC1-4Fc or CEC1-5Fc. EC3 is not required for homophilic binding, however, since CEC1-2-4Fc and CEC1-2-4-5Fc exhibited high activity in both assays. These and experiments using additional EC combinations show that many, if not all, the EC domains contribute to the formation of the cadherin homophilic bond, and specific one-to-one interaction between particular EC domains may not be required. These conclusions are consistent with a previous study on direct molecular force measurements between cadherin ectodomains demonstrating multiple adhesive interactions (Sivasankar, S., W. Brieher, N. Lavrik, B. Gumbiner, and D. Leckband. 1999. PROC: Natl. Acad. Sci. USA. 96:11820-11824; Sivasankar, S., B. Gumbiner, and D. Leckband. 2001. Biophys J. 80:1758-68). We propose new models for how the cadherin extracellular repeats may contribute to adhesive specificity and function.

Pig heart CoA transferase exists as two oligomeric forms separated by a large kinetic barrier.

Pig heart CoA transferase (EC 2.8.3.5) has been shown previously to adopt a homodimeric structure, in which each subunit has a molecular weight of 52 197 and consists of N- and C-domains linked by a hydrophilic linker or "hinge". Here we identify and characterize a second oligomeric form constituent in purified enzyme preparations, albeit at low concentrations. Both species catalyze the transfer of CoA with similar values for k(cat) and K(M). This second form sediments more rapidly than the homodimer under the conditions of conventional sedimentation velocity and active enzyme centrifugation. Apparent molecular weight values determined by sedimentation equilibrium and gel filtration chromatography are 4-fold greater than the subunit molecular weight, confirming that this form is a homotetramer. The subunits of both oligomeric forms are indistinguishable with respect to molecular mass, far-UV CD, intrinsic tryptophan fluorescence, and equilibrium unfolding. Dissociation of the homotetramer to the homodimer occurs very slowly in benign solutions containing high salt concentrations (0.25-2.0 M KCl). The homotetramer is fully converted to homodimer during refolding from denaturant at low protein concentrations. Disruption of the hydrophilic linker between the N- and C-domains by mutagenesis or mild proteolysis causes a decrease in the relative amount of the larger conformer. The homotetramer is stabilized by interactions involving the helical hinge region, and a substantial kinetic barrier hinders interconversion of the two oligomeric species under nondenaturing conditions.

Productive interactions between the two domains of pig heart CoA transferase during folding and assembly.

The enzyme CoA transferase from porcine heart (EC 2.8.3.5) is a homodimer; each subunit consists of two domains linked by a hydrophilic "hinge" region. We have prepared separate DNA segments encoding each of these domains. Incorporation of these two DNA segments within an operon or within two separate transcription units does not preclude the synthesis and assembly of CoA transferase in Escherichia coli. When the two domain fragments are produced and purified individually from separate cultures and subsequently mixed, enzyme activity accumulates to near wild-type levels only after a lengthy incubation. Each domain is more susceptible to aggregation than wild-type CoA transferase. Circular dichroism shows that, prior to mixing, the domains possess a different secondary structural profile compared to their counterparts in the native enzyme. However, mixing and incubation of the domains produces a complex with far-UV CD, fluorescence, and ultracentrifugation properties similar to those of wild-type CoA transferase. Finally, we show that the intact hydrophilic peptide which links the two domains is essential for the recovery of activity observed upon refolding of the denatured enzyme in vitro. These results indicate that the folding and assembly of pig heart CoA transferase require a productive interaction between its two domains, involving a substantial conformational rearrangement.

Properties of human plasma lipid transfer protein in aqueous solution and at interfaces.

Human plasma lipid transfer protein (cholesteryl ester transfer protein) has been characterized for its solution and surface properties. The protein is monomeric in aqueous solution up to 0.62 g/L (11.7 microM) as demonstrated by sedimentation equilibrium. It binds to the surface of a lipid microemulsion having an average diameter of 26 nm made from triolein and egg yolk phosphatidylcholine, with an estimated dissociation constant 1.2 x 10(-8) M, and the maximum saturation binding level is 8 protein molecules per particle regardless of the presence of apolipoprotein A-I. Circular dichroism measurement indicated that the protein in solution is predominantly in the beta-sheet/beta-turn conformation with some alpha-helix, and this profile does not undergo drastic change by its binding to the lipid surface. The analysis of the behavior of the protein in its monomolecular layer at the air-buffer interface indicated that it is also monomeric at the interface. LTP molecules occupied the same area per amino acid as other apolipoproteins in the monolayer but had a higher collapse pressure of its monolayer (18 dyn/cm), and the protein stayed at the interface even after the overcompressing monolayer far beyond the collapsing pressure up to 40 dyn/cm.

Physical properties of apolipoprotein A-I from the chicken, Gallus domesticus.

The amphipathic alpha-helices of exchangeable apolipoproteins (apo) function to simultaneously facilitate interaction with lipid surfaces and the aqueous environment. In contrast to mammalian apoA-I's, which self-associate in the absence of lipid, chicken apoA-I, which shares 66% sequence homology with human apoA-I, exists as a monomeric protein when dissociated from high-density lipoprotein (HDL). Sedimentation equilibrium studies conducted in the analytical ultracentrifuge yielded a weight-average molecular weight of 28,170. Corresponding sedimentation velocity and diffusion experiments gave rise to s0(20,w) = 2.23 S and D0(20,w) = 6.39 x 10(-7) cm2/s. A translational frictional ratio (f/fmin) of 1.18 and an axial ratio of 4.0 were also determined from this data. The Stokes radius (Rs,sed = 2.80 nm) and translational frictional ratio were subsequently used to calculate estimated molecular dimensions of 25.2 x 100.8 A for chicken apoA-I. Circular dichroism (CD) studies revealed a highly alpha-helical structure predicted to be 74% by Provencher-Glöckner analysis. Denaturation studies performed on lipid-free apoA-I and monitored by CD revealed a midpoint of denaturation of 0.64 M guanidine hydrochloride. From plots of delta G(app) versus guanidine hydrochloride concentration, a delta GDH2O of 1.86 kcal/mol was determined. In other studies, a midpoint of temperature-induced denaturation for apoA-I of 57 degrees C was obtained. The effect of solvent pH on the secondary structure content of apoA-I revealed a significant loss of alpha-helix below pH 4.0 and above pH 10, suggesting that lipid-free apoA-I may by partially stabilized by the formation of intra- or interhelix salt bridges between oppositely charged amino acid side chains.(ABSTRACT TRUNCATED AT 250 WORDS)

Biophysical studies on the lipid transfer particle from the hemolymph of the tobacco hornworm, Manduca sexta.

Hydrodynamic studies conducted in the analytical ultracentrifuge provided evidence for two populations of lipid transfer particle (LTP) when centrifuged in a buffer solution containing 10 mM Tris, pH 8.0/100 mM KCl. The apparent sedimentation coefficients of the two species was 23.3 S and 15.3 S. Upon changing the buffer pH to 7.0 or 5.7, two species of LTP were still present but the ratio of their relative abundance was altered. When the KCl concentration in the buffer was lowered to 50 mM the sample sedimented as a single species with an apparent S20,w of 22.9 S. In higher ionic strength buffers (10 mM succinate, pH 5.7/500 mM KCl) LTP sedimented with an apparent S20,w of 14.8 S. Further experiments revealed that these two forms are interconvertable as a function of buffer ionic strength. Given previous estimates of the molecular size of LTP we concluded that the slower sedimenting peak observed at high ionic strength represents monomeric LTP while the faster sedimenting material observed at low ionic strength is likely to be an aggregated state of LTP. This interpretation is supported by molecular weight determinations made by sedimentation equilibrium experiments conducted in 10 mM succinate, pH 5.7/500 mM KCl which yielded a particle Mr = 887,000. Circular dichroism spectra of monomeric LTP sample revealed 6% alpha-helix, 49% beta-sheet, 7% beta-turn and 35% random coil while aggregated LTP contained 13% alpha-helix, 66% beta-sheet and 21% random coil. The transfer activity of the two LTP forms was assayed and found to be the same indicating that either the state of LTP aggregation did not affect transfer activity or that upon exposure to a large excess of lipoprotein substrate disaggregation, without loss of activity, occurs.

American trypanosomiasis (Chagas' disease) in a Canadian immigrant infant.

A case of American trypanosomiasis (Chagas' disease) is reported. A 13-month-old Mennonite girl who immigrated to Canada from Paraguay, died at the Children's Centre in Winnipeg from an acute myocarditis due to infection with Trypanosoma cruzi. This diagnosis should be considered when a patient from an endemic area presents with a clinical picture of myocarditis.

The Bowen-Conradi syndrome -- a highly lethal autosomal recessive syndrome of microcephaly, micrognathia, low birth weight, and joint deformities.

This paper describes six Hutterite children from five families who appear to have been affected by the same syndrome that was described in two brothers by Bowen and Conradi [1]. Our additional cases confirm that the major features of the syndrome include porportionate intrauterine growth retardation, microcephaly, micrognathia, a prominent nose, rocker-bottom feet, joint limitation, and failure to thrive, with death within the first year of life. Bowen-Conradi syndrome is an autosomal recessive trait and pedigree records show that all six families now known are related to each other through two couples born in the late 1700s but that there are additional earlier possible sources of the responsible gene. The differential diagnosis of this syndrome is discussed.