Transhydrogenase and the anaerobic mitochondrial metabolism of adult Hymenolepis diminuta.

The adult cestode, Hymenolepis diminuta, is essentially anaerobic energetically. Carbohydrate dissimilation results in acetate, lactate and succinate accumulation with succinate being the major end product. Succinate accumulation results from the anaerobic, mitochondrial, 'malic' enzyme-dependent utilization of malate coupled to ATP generation via the electron transport-linked fumarate reductase. A lesser peroxide-forming oxidase is apparent, however, fumarate reduction to succinate predominates even in air. The H. diminuta matrix-localized 'malic' enzyme is NADP-specific whereas the inner membrane (IM)-associated electron transport system prefers NADH. This dilemma is circumvented by the mitochondrial, IM-associated NADPH-->NAD+ transhydrogenase in catalyzing hydride ion transfer from NADPH to NAD+ on the IM matrix surface. Hydride transfer is reversible and phospholipid-dependent. NADP+ reduction occurs as a non energy-linked and energy-linked reaction with the latter requiring electron transport NADH utilization or ATP hydrolysis. With NAD+ reduction, the cestode transhydrogenase also engages in concomitant proton translocation from the mitochondrial matrix to the intermembrane space and supports net ATP generation. Thus, the cestode NADPH-->NAD+ system can serve not only as a metabolic connector, but an additional anaerobic phosphorylation site. Although its function(s) is unknown, a separate IM-associated NADH--> NAD+ transhydrogenation, catalyzed by the lipoamide and NADH dehydrogenases, is noted.

Catalysis of NADH-->NADP+ transhydrogenation by adult Hymenolepis diminuta mitochondria.

Hymenolepis diminuta mitochondria catalyze nonenergy-linked and energy-linked NADH-->NADP(+) transhydrogenations, with the latter driven by electron-transport dependent NADH oxidation (electron transport-driven, ETD) or ATP hydrolysis (ATP-driven, ATPD). Using submitochondrial particles, NADH-->NADP(+) transhydrogenations were characterized further. ETD and ATPD reactions were enhanced by bovine serum albumin (BSA) and were inhibited by N,N'-dicyclohexylcarbodiimide (DCCD), carbonyl cyanide 3-chlorophenylhydrazone (CCCP), carbonyl cyanide 4-(trifluoromethoxy) phenylhydrazone (FCCP), and niclosamide. The nonenergy-linked reaction was unaffected by these additives. Except for DCCD inhibition of the ATPD reaction, BSA mitigated inhibitor effects on energy-linked activities. BSA enhanced NADH oxidase (but not ATPase) activity. Although DCCD inhibited NADH oxidase and ATPase, BSA only lessened oxidase inhibition. With protonophores, an increase in NADH oxidase (but not ATPase) activity was suggested. Oxidase inhibition by rotenone was unaffected by BSA. The ATP-hydrolyzed/NADPH-formed for the ATPD reaction was almost unity. A model for H. diminuta energy-linked transhydrogenation is presented.

Hymenolepis diminuta: catalysis of transmembrane proton translocation by mitochondrial NADPH-->NAD transhydrogenase.

The mitochondrial, inner-membrane-associated, reversible NADPH-->NAD transhydrogenase of adult Hymenolepis diminuta physiologically couples matrix-localized, NADP-specific "malic" enzyme with NADH-dependent anaerobic electron transport. Employing submitochondrial particles (SMP) as the source of enzyme activity and both spectrophotometric and fluorometric assessments, the present study made evident that in its catalysis of transhydrogenation between NADPH and NAD, the cestode enzyme engages in the concomitant transmembrane translocation of protons. As assessed spectrophotometrically, the catalysis of NADPH-dependent NAD reduction by H. diminuta SMP was stimulated significantly by carbonyl cyanide 3-chlorophenylhydrazone (CCCP), carbonyl cyanide 4-(trifluoromethoxy) phenylhydrazone (FCCP), as well as by the protonophoric anthelmintic, niclosamide. In addition, N,N'-dicyclohexylcarbodiimide (DCCD) markedly diminished SMP-catalyzed hydride ion transfer between NADPH and NAD. The catalysis by SMP of concomitant, transhydrogenase-mediated proton translocation was evaluated more directly via fluorometric assays using 8-anilino-1-napthalenesulfonic acid (ANS) as the probe. These latter evaluations revealed a transhydrogenase-dependent enhancement of ANS fluorescence in accord with an intravesicular accumulation of protons. ANS fluorescence was quenched rapidly when the assay system was supplemented with CCCP, FCCP, or niclosamide. Consistent with the helminth transhydrogenase acting as a proton pump, transhydrogenase-mediated enhanced fluorescence also was inhibited by DCCD. Considered collectively, these data indicated, apparently for the first time for any invertebrate system, that the transhydrogenase, in catalyzing the NADPH-->NAD reaction, acts in the translocation of protons from the matrix to the intermembrane space mitochondrial compartment.

Metabolic transition in the development of Hymenolepis diminuta (Cestoda).

Cysticercoids as well as 6-, 10-, and 14-day Hymenolepis diminuta were evaluated in terms of enzymatic activities related to phosphoenolpyruvate (PEP) utilization and mitochondrial succinate accumulation. The data obtained support a transition toward anaerobic electron-transport-dependent succinate accumulation, characteristic of adult H. diminuta, with development from cysticercoid to adult. This transition was reflected most prominently in the increasing activities of PEP carboxykinase (PEPCK), malate dehydrogenase, NADPH-->NAD+ transhydrogenase, and fumarate reductase. Developmental increases in PEPCK/pyruvate kinase (PK), fumarate reductase (FR)/NADH oxidase (NO), and FR/succinate dehydrogenase (SDH) activity ratios were also apparent. Evaluations of "egg-free" immature, mature, and pregravid-gravid segments of adult H. diminuta revealed that in general the greater levels of activity were associated with the immature and mature segments. Whereas FR/NO and FR/SDH ratios remained relatively constant in segment comparisons, the greatest PEPCK/PK ratio was associated with the pregravid-gravid segment.

Hymenolepis diminuta: mitochondrial NADH --> NAD transhydrogenation and the lipoamide dehydrogenase system.

The occurrence of NADH --> NAD transhydrogenation and lipoamide dehydrogenase activities was demonstrated for cysticercoids of the intestinal cestode, Hymenolepis diminuta. In addition, both activities were catalyzed by the mitochondria of 6-, 10-, and 14-day H. diminuta and by the mitochondria from immature, mature, and pregravid/gravid regions of the adult cestode. A developmentally related increase in NADH --> NAD activity was suggested and the levels of both activities in the immature region of the helminth were consistent with it being a region of high metabolic activity. Adult H. diminuta mitochondrial lipoamide dehydrogenase was purified to homogeneity. The native enzyme was a homodimer with a monomeric and dimeric molecular mass of 47 and 93 kDa, respectively. Spectral analyses revealed that the enzyme contained flavin. More importantly, the purified enzyme catalyzed appreciable NADH --> NAD transhydrogenation activity, a premier finding for the phylum Platyhelminthes. The ratio of NADH --> NAD transhydrogenation to lipoamide reduction was 1:5. Both activities were inhibited by Cu2+ and Cd2+ with the NADH --> NAD activity being more resistant to inhibition. Interestingly, aside from NADH diaphorase activity, the cestode enzyme displayed NADH-ferricyanide reductase and, to a lesser degree, NADPH --> NAD transhydrogenation activities. The partial amino acid sequence of H. diminuta lipoamide dehydrogenase indicated that this enzyme was most similar to the corresponding enzymes of other parasitic helminths. Moreover, the phenylalanine for leucine substitution found in the redox-active disulfide site of the lipoamide dehydrogenases of some anaerobic systems was noted for the H. diminuta enzyme.

Mitochondrial NADH-->NAD transhydrogenation in adult Hymenolepis diminuta.

Adult Hymenolepis diminuta mitochondria catalyze a transhydrogenation reaction between NADPH and NAD and between NADH and NAD. The NADPH-->NAD reaction is catalyzed by an inner membrane-associated pyridine nucleotide transhydrogenase, whereas the NADH-->NAD reaction is ostensibly catalyzed by another system(s). The source(s) of NADH-->NAD activity was evaluated by assessments of its intramitochondrial distribution and thermal lability and by comparisons with the distribution/thermal lability of NADH dehydrogenase, lipoamide dehydrogenase, and NADPH-->NAD transhydrogenase. The occurrence of NADH and lipoamide dehydrogenase components was readily demonstrable. Like NADPH-->NAD transhydrogenase, NADH dehydrogenase was essentially membrane bound. Lipoamide dehydrogenase and NADH-->NAD activities were, at different levels, in the membrane and soluble fractions. Based on thermal profiles, NADH and lipoamide dehydrogenase differed from each other and from NADPH-->NAD transhydrogenase. Although the NADH-->NAD profile closely paralleled that for lipoamide dehydrogenase, it also was similar to the NADH dehydrogenase profile. Collectively, these data are consistent with the supposition that the H. diminuta mitochondrial NADH-->NAD transhydrogenation reaction is catalyzed by lipoamide dehydrogenase and possibly by NADH dehydrogenase rather than by an independent transhydrogenase system.

Energy-linked mitochondrial pyridine nucleotide transhydrogenase of adult Hymenolepis diminuta.

Employing "phosphorylating" submitochondrial particles as the source of pyridine nucleotide transhydrogenase, the occurrence of an energy-linked NADH----NADP+ transhydrogenation in the adult cestode Hymenolepis diminuta was demonstrated. The isolated particles displayed rotenone-sensitive NADH utilization and the reversible transhydrogenase, with the NADPH----NAD+ transhydrogenation being more prominent. Although not inhibiting the NADPH----NAD+ reaction, rotenone, but not oligomycin, inhibited the catalysis of NADH----NADP+ transhydrogenation. In the presence of rotenone, Mg2+ plus ATP stimulated by more than 3-fold NADH----NADP+ transhydrogenation. This stimulation was ATP specific and was abolished by EDTA or oligomycin. Succinate was essentially without effect on the NADH----NADP+ reaction. These data demonstrate the occurrence of an energy-linked transhydrogenation between NADH and NADP+ with energization resulting from either electron transport-dependent NADH oxidation or ATP utilization via the phosphorylating mechanism in accord with the preparation of "phosphorylating" particles. This is the first demonstration of an energy-linked transhydrogenation in the parasitic helminths and apparently in the invertebrates generally.

Mitochondrial hydrogen peroxide formation and the fumarate reductase of Hymenolepis diminuta.

The catalysis of hydrogen peroxide accumulation by the mitochondrial, membrane-associated NADH oxidase and less active succinoxidase of adult Hymenolepis diminuta was confirmed. NADH-dependent peroxide formation by isolated mitochondrial membranes occurred at about half the coincident rates of NADH and oxygen utilization, whereas succinate-dependent peroxide formation accounted for approximately 40% of the oxygen consumed. These findings, coupled with evaluations of the oxidases, indicated that both systems use in common 2 mechanisms for oxygen reduction, 1 of which is peroxide-forming. Neither system was sensitive to cyanide, azide, or antimycin A. Rotenone inhibition of NADH oxidation resulted in equivalent decreases in oxygen consumption by the peroxide-forming and nonperoxide-forming mechanisms. In contrast, malonate inhibition occurred via disruption of the peroxide-forming mechanism. Fumarate stimulated membrane-catalyzed NADH oxidation, despite aerobic conditions, and this fumarate reductase was rotenone-sensitive. NADH- or succinate-dependent peroxide formation virtually was abolished and oxygen consumption was minimal in the presence of fumarate. Malonate also inhibited fumarate-dependent NADH oxidation and succinate-dependent peroxide formation/oxygen consumption. Collectively, these findings clearly indicate that NADH- or succinate-dependent hydrogen peroxide accumulation involves the malonate-sensitive fumarate reductase, in the absence of fumarate. A model of the H. diminuta electron transport system is presented.

Hydroxymethylglutaryl coenzyme A reductase activity of adult Hymenolepis diminuta.

The occurrence of hydroxymethylglutaryl coenzyme A (HMG-CoA) reductase in adult Hymenolepis diminuta was demonstrated. This activity was negligible in the cestode's cytosolic fraction but was noted when the mitochondrial or microsomal fraction served as the enzyme source. The predominant localization of HMG-CoA reductase activity was with the microsomal fraction. This fraction did not contain appreciable mitochondrial contamination based on the distribution of marker enzymes. The enzymatic nature of HMG-CoA conversion to mevalonic acid by either fraction was apparent because the reaction was heat labile and responded linearly to time of assay and protein content. The enzymatic reduction of HMG-CoA absolutely required NADPH when either fraction was assayed. The lesser activity of the mitochondrial fraction was membrane-associated. The predominant localization of HMG-CoA reductase activity with microsomal membranes and its separation with the membranous component of the mitochondrial fraction suggest that mitochondrial activity reflects the presence of microsomal membranes. In its predominant localization and pyridine nucleotide requirement, the cestode's HMG-CoA reductase activity resembles that of mammalian systems. The finding of HMG-CoA reductase provides an enzymatic mechanism for the intermediate conversion of HMG-CoA to mevalonic acid that would be needed for acetate-dependent isoprenoid lipid synthesis by adult H. diminuta.

Rhodoquinone requirement of the Hymenolepis diminuta mitochondrial electron transport system.

The occurrence of rhodoquinone as a mitochondrial membrane component was demonstrated in adult Hymenolepis diminuta. Chromatographic separation of pentane extracts, from lyophilized mitochondrial membranes, coupled with spectral analyses of separated material demonstrated the presence of rhodoquinone. The presence of ubiquinone was not apparent. Rhodoquinone content of membranes was about 1.2 micrograms (mg protein)-1. The rhodoquinone requirement of the H. diminuta electron transport system was demonstrated both in terms of the less active NADH oxidase and the physiologically required, NADH-dependent fumarate reductase employing lyophilized mitochondrial membranes as the source of activities. Pentane extraction of membranes virtually abolished the oxidase and fumarate reductase systems. Supplementation of pentane-treated membranes with H. diminuta rhodoquinone restored oxidase and fumarate reductase activities to levels simulating those of lyophilized membranes. Ubiquinone did not substitute for rhodoquinone. The rhodoquinone-reconstituted membranes displayed rotenone sensitivity. These findings represent the first direct demonstration of the rhodoquinone requirement of helminth electron transport-coupled oxidase and fumarate reductase.

Localization of cytochrome C oxidase and cytochrome C peroxidase in mitochondria of Hymenolepis diminuta (Cestoda).

The intramitochondrial localization of cytochrome c oxidase and cytochrome c peroxidase in adult Hymenolepis diminuta was investigated. Mitochondria were fractionated into inner membrane, outer membrane, intermembrane space and matrix and the efficacy of fractionation was monitored employing marker enzymes. Cytochrome c oxidase was associated with the mitochondrial inner membrane. Whereas 55% of the cytochrome c peroxidase activity was in the matrix, 32% of the activity was in the intermembrane space fraction. Based upon the distribution of marker enzymes, a dual compartmentalization of cytochrome c peroxidase is apparent in H. diminuta mitochondria.

Intramitochondrial localization of fumarate reductase, NADPH----NAD transhydrogenase, 'malic' enzyme and fumarase in adult Hymenolepis diminuta.

The intramitochondrial localization of the fumarate reductase, NADPH----NAD transhydrogenase, 'malic' enzyme and fumarase was determined in adult Hymenolepis diminuta. The distribution of marker enzymes for the inner membrane, matrix, intermembrane space and outer membrane of H. diminuta mitochondria simulated that of the corresponding ascarid and mammalian organelles. The electron transport-coupled fumarate reductase and the NADPH----NAD transhydrogenase were components of the inner membrane whereas the 'malic' enzyme and fumarase were in the matrix soluble compartment. Assessments of NADH utilization, malate-dependent NADP reduction and NADPH----NAD transhydrogenation by presumedly intact and disrupted mitochondria supported the localization data. The findings presented indicate that in H. diminuta mitochondria (a) NADPH and fumarate are accumulated within the matrix compartment; (b) transhydrogenation between NADPH and NAD is an event associated with the matrix side of the inner membrane; and (c) electron transport-dependent NADH oxidation and fumarate reduction occur at sites on the matrix side of the inner membrane.

Reduction and oxidation of cytochrome C by Hymenolepis diminuta (Cestoda) mitochondria.

Mitochondrial membranes of adult Hymenolepis diminuta catalyzed inhibitor-sensitive ferricytochrome c reduction. Cytochrome c reductase activity was noted when NAD(P)H or succinate served as the reductant with the NADH-coupled reaction being most prominent. Both rotenone-sensitive and -insensitive reduced pyridine nucleotide-coupled activities were apparent. Ferrocytochrome c oxidase activity also was catalyzed by H. diminuta mitochondrial membranes and this reaction was sensitive to azide and cyanide. A cytochrome c peroxidase activity was associated primarily with the mitochondrial soluble fraction of adult H. diminuta. The possibility that the activities observed may contribute to the elimination of peroxide in the helminth system is considered.

Coupling of "malic" enzyme and NADPH:NAD transhydrogenase in the energetics of Hymenolepis diminuta (Cestoda).

Acetylpyridine NADP replaced NADP in promoting the Mn2+ ion-requiring mitochondrial "malic" enzyme of Hymenolepis diminuta. Disrupted mitochondria displayed low levels of an apparent oxaloacetate-forming malate dehydrogenase activity when NAD or acetylpyridine NAD served as the coenzyme. Significant malate-dependent reduction of acetylpyridine NAD by H. diminuta mitochondria required Mn2+ ion and NADP, thereby indicating the tandem operation of "malic" enzyme and NADPH:NAD transhydrogenase. Incubation of mitochondrial preparations with oxaloacetate resulted in a non-enzymatic decarboxylation reaction. Coupling of malate oxidation with electron transport via the "malic" enzyme and transhydrogenase was demonstrated by polarographic assessment of mitochondrial reduced pyridine nucleotide oxidase activity.

Phospholipid dependence of the Hymenolepis diminuta mitochondrial NADPH:NAD transhydrogenase.

The mitochondrial, membrane-associated, nonenergy -linked NADPH:NAD transhydrogenase of adult Hymenolepis diminuta exhibited a phospholipid dependence. This lipid dependence was suggested when mitochondrial membranes were subjected to organic solvent or phospholipase treatments. Although hexane extraction of lyophilized membranes enhanced transhydrogenase activity, subsequent aqueous acetone extraction significantly inhibited the transhydrogenase. An acetone/water-dependent extraction of phospholipids was reflected in the phosphorus content of released material. Incubation of mitochondrial membranes with phospholipase A2 or C markedly reduced transhydrogenase activity, and phospholipase A2 treatment resulted in the greater reduction in activity. The mitochondrial, membrane-associated, NADH-utilizing oxidase and fumarate reductase activities were diminished significantly by hexane as well as phospholipase treatments. Phospholipase A2 caused the greater inhibition of the NADH-utilizing systems. Thus, in contrast to the transhydrogenase, neutral lipids and phospholipids apparently were required by the electron transport-coupled activities. The transhydrogenase activity of organic solvent- or phospholipase-treated membranes was not stimulated effectively by phospholipid addition. However, phospholipid-dependent stimulation of transhydrogenase was accomplished employing a partially lipid-depleted preparation of the enzyme obtained by detergent treatment and ammonium sulfate precipitation. Of the phospholipids tested, only phosphatidylcholine significantly stimulated transhydrogenase activity. The stimulation noted with phosphatidylcholine was not duplicated by cholate or deoxycholate.

Mitochondrial malate dehydrogenase, decarboxylating ("malic" enzyme) and transhydrogenase activities of adult Hymenolepis microstoma (Cestoda).

Adult H. microstoma mitochondria catalyzed a malate dehydrogenase, decarboxylating ("malic" enzyme) activity. This "malic" enzyme was found as a soluble component of the mitochondrion, was specific for NADP, and required a divalent cation with Mn++ ion yielding the greatest activity. The H. microstoma "malic" enzyme could fulfill the need for generating intramitochondrial reducing equivalents required for electron transport. The H. microstoma mitochondria also exhibited an NADPH:NAD transhydrogenation reaction. The electron transport system of this cestode was apparently specific for NADH both in terms of the rotenone-sensitive oxidase and fumarate reductase systems. Electron transport-associated NADPH oxidation was increased markedly with the addition of NAD to the system. Coupling of NADPH utilization to fumarate reduction, in the presence of NAD, was apparent under conditions of reduced oxygen tension. This was consistent with the presence of the NADPH:NAD transhydrogenase which catalyzed a transfer of reducing equivalents from NADPH to NAD, producing NADH for electron transport function. The data presented suggest that H. microstoma mitochondria can engage in an anaerobic, electron transport-associated production of succinate, and presumably concomitant phosphorylation. Malate may serve as the mitochondrial substrate supplying reducing equivalents for electron transport via the activity of the "malic" enzyme coupled to the NADPH:NAD transhydrogenase. In addition to the NADPH:NAD transhydrogenase activity, H. microstoma mitochondria catalyzed an NADH:NAD transhydrogenation.

Mitochondrial NADH oxidase activity of adult Hymenolepis diminuta (Cestoda).

1. Mitochondria from adult Hymenolepis diminuta displayed a membrane-associated, rotenone-sensitive NADH oxidase and NADH-dependent fumarate reductase system. 2. Both the H. diminuta oxidase and fumarate reductase were relatively insensitive to antimycin A. potassium cyanide and sodium azide, at concentrations which significantly inhibited the NADH oxidase system of rat liver. 3. Malonate effectively depressed the mitochondrial NADH oxidase activity of both H. diminuta and adult Ascaris suum (Nematoda). 4. An involvement of Mn2+ ion, in NADH utilization by the H. diminuta oxidase, was apparent. 5. The utilization of NAD(P)H by H. diminuta, mitochondrial membranes resulted in hydrogen peroxide formation. Succinate utilization also resulted in peroxide accumulation but at a much slower rate than that found for NAD(P)H.

Coupling of mitochondrial NADPH : NAD transhydrogenase with electron transport in adult Hymenolepis diminuta.

The mitochondrial electron transport system of adult Hymenolepis diminuta exhibited an apparent specificity in terms of reduced pyridine nucleotide utilization. The preferred substrate for both the minor oxidase and the physiologically required fumarate reductase system was NADH. Intramitochondrial reducing equivalents, needed for phosphorylation via the anaerobic, electron transport-dependent, fumarate reductase, were generated as NADPH by the action of the cestode's NADP-specific "malic" enzyme. However, H. diminuta mitochondria catalyzed an NADPH : NAD transhydrogenation which would serve in hydride ion transfer from NADPH to NAD, thereby producing NADH required for the anaerobic, electron transport mechanism. Accordingly, NADPH utilization was increased when NAD was added to the mitochondrial system. The most significant increase occurred in the presence of both NAD and fumarate. These data indicate a coupling of the NADPH : NAD transhydrogenase with mitochondrial electron transport. This coupling of the transhydrogenase with electron transport was demonstrated using disrupted mitochondria and mitochondrial membrane preparations. Under conditions of reduced oxygen tension, the coupling of the transhydrogenase to fumarate reduction was apparent. In adult Ascaris suum, where the "malic" enzyme physiologically utilizes NAD, the mitochondria differ from those of H. diminuta because NADPH : NAD transhydrogenase activity was minimal under the conditions of assay. The rate of NADPH utilization by the nematode mitochondrial system is not increased appreciably in the presence of NAD when either oxygen or fumarate serves as the acceptor.

Metabolic indices for evaluating the in vitro maintenance of Hymenolepis diminuta in the presence and absence of various additives.

An in vitro maintenance system for H. diminuta was devised by modifying the cultivation procedure of Schiller (1965). In this diphasic maintenance system, tissue culture medium (Triple Eagle's or NCTC-135) was used, in lieu of whole blood, as the 30% supplement to the agar phase. This provides a more defined system suitable for studying the effects of various additives. Morphological criteria were established which aided in assessing the efficacy of media used for the maintenance of 6- and 8-day-old H. diminuta. When successfully maintained, worms exhibited an intact scolex and neck region, undulatory movements along the strobila as well as integumentary and strobilar integrity. A more sensitive method for evaluating the maintenance of 8-day-old worms employed metabolic indices. Wet weight, protein and glycogen levels for 8-day-old H. diminuta served as base-line data allowing estimation of protein and glycogen contents of each worm prior to maintenance. Following maintenance, ratio of final to initial protein and final to initial glycogen levels (metabolic indices). A metabolic index approaching or exceeding unity suggested a reasonably intact metabolism. The addition of sodium taurocholate to the maintenance media appeared beneficial to the worms by prolonging the retention of normal signs. A combination of additives, taurocholate-nucleosides-lipids, improved the maintenance of H. diminuta for periods exceeding 24 hr as determined by observational criteria and metabolic indices. However, addition of a lipid mixture, or a lipid mixture prepared with a low concentration of taurocholate was not beneficial over a 24 hr period. The maintenance system, observational criteria, base-line data and metabolic indices should be useful for future in vitro studies requiring long-term incubation.