Camptothecin overcomes MDR1-mediated resistance in human KB carcinoma cells

In order to understand the high efficacy of camptothecin derivatives against human colon tumor xenografts in nude mice, we have studied the transport properties of camptothecin derivatives across cellular membranes of MDR1-overexpressing cells. MDR1 overexpression was shown to have little effect on camptothecin cytotoxicity; camptothecin was equally cytotoxic to both the drug-sensitive parental cell line, KB 3-1, and its multidrug-resistant derivative, KB V1. The ability of camptothecin to overcome MDR1-mediated resistance is most likely due to unimpaired accumulation of camptothecin in MDR1 cells as suggested from the following experiments: (a) cytotoxicity of camptothecin against KB V1 cells was not altered by the known MDR1-reversing agent, verapamil; (b) camptothecin was ineffective as compared with vinblastine in competing with [3H]azidopine for photoaffinity labeling of MDR1; (c) camptothecin was equally efficient in trapping cellular topoisomerase I molecules on chromosomal DNA in the form of cleavable complexes in both KB 3-1 and KB V1 cells. The mechanism by which camptothecin overcomes MDR1-mediated resistance has been further studied using a number of uncharged and charged camptothecin derivatives. In contrast to the uncharged camptothecin derivatives, such as 9-amino-camptothecin and 10,11-methylenedioxy-camptothecin, the charged camptothecin derivative, topotecan, showed reduced cytotoxicity against MDR1-overexpressing KB V1 cells. The reduced cytotoxicity of topotecan in KB V1 cells was due to the overexpression of MDR1 in KB V1 cells since verapamil restored both topotecan accumulation and cytotoxicity. These results suggest that the charge on camptothecin can affect the drug's sensitivity to MDR1. The possible effect of membrane permeability in determining drug selectivity of MDR1 is discussed.

The conformation of echinomycin in DMSO solution

The conformation of the antibiotic echinomycin in DMSO solution has been determined from two-dimensional NMR and distance geometry calculation with distance constraints. Five converged conformations were calculated with NOE distance constraints followed by restraint energy minimization.

Common cis-acting region responsible for transcriptional regulation of Bradyrhizobium japonicum hydrogenase by nickel, oxygen, and hydrogen

Bradyrhizobium japonicum expresses hydrogenase in microaerophilic free-living conditions in the presence of nickel. Plasmid-borne hup-lacZ transcriptional fusion constructs were used to study the regulation of the hydrogenase gene. The hydrogenase gene was transcriptionally induced under microaerobic conditions (0.1 to 3.0% partial pressure O2). The hydrogenase gene was not transcribed or was poorly transcribed in strictly anaerobic conditions or conditions above 3.0% O2. Hydrogen gas at levels as low as 0.1% partial pressure induced hydrogenase transcription, and a high level of transcription was maintained up to at least 10% H2 concentration. No transcription was observed in the absence of H2. Hydrogenase was regulated by H2, O2, and Ni when the 5'-upstream sequence was pared down to include base number -168. However, when the upstream sequence was pared down to base number -118, the regulatory response to O2, H2, and Ni levels was negated. Thus, a common cis-acting regulatory region localized within 50 bp is critical for the regulation of hydrogenase by hydrogen, oxygen, and nickel. As a control, the B. japonicum hemA gene which codes for delta-aminolevulinic acid synthase was also fused to the promoterless lacZ gene, and its regulation was tested in the presence of various concentrations of O2 and H2. hemA-lacZ transcription was not dependent on levels of Ni, O2, or H2. Two different hup-lacZ fusions were tested in a Hup- background, strain JH47; these hup-lacZ constructs in JH47 demonstrated dependency on nickel, O2, and H2, indicating that the hydrogenase protein itself is not a sensor for regulation by O2, H2, or nickel.

Calcium, network activity, and the role of NMDA channels in synaptic plasticity in vitro

Functionally effective neuronal circuits are constructed through a competitive process that requires patterned neuronal activity elicited by structured input from the environment. To explore the mechanisms of this activity-dependent synaptic restructuring, we have developed an in vitro preparation of mouse spinal cord neurons maintained in a 3-chambered cell-culture system. Sensory afferents that received chronic electrical stimulation for 3-5 d developed stronger synaptic connections than unstimulated afferents converging onto the same postsynaptic spinal cord neuron. Exposure to 100 microM DL-2-amino-5-phosphonovaleric acid (APV), an antagonist of the NMDA channel, during the stimulation period prevented the competitive advantage associated with electric stimulation. However, when APV was applied with a higher concentration of calcium (3 mM), activity-dependent synaptic plasticity was no longer inhibited by the NMDA receptor antagonist. This reversal of APV block of the plasticity was not impaired by reducing transmitter release with 3 mM magnesium (in addition to 3 mM calcium and APV). A suppressant effect of APV on spontaneous activity was observed, which was attributed to loss of the NMDA component of the EPSP. Activity-dependent plasticity was also blocked if spontaneous activity was suppressed with dilute tetrodotoxin (TTX; 5-10 nM), a dosage that reduces excitability of neurons but is insufficient to block sodium-dependent action potentials. These experiments bring into question how NMDA channel activation is involved in the processes of synaptic remodeling during development. The data suggest that postsynaptic activity is required for synaptic remodeling, but this activity need not involve NMDA receptor activation specifically for activity-evoked synaptic plasticity. Instead, the mechanism for plasticity appears to operate through calcium-dependent processes in general.

Two-dimensional NMR studies and secondary structure of cobrotoxin in aqueous solution

The 1H-NMR spectra of cobrotoxin, a neurotoxic protein isolated from Formosan cobra Naja naja atra, have been studied by two-dimensional NMR techniques. Of 62 amino acid residues in cobrotoxin, the complete assignments of 58 residues have been made. The resonances from several of the remaining residues have been identified but not yet specifically assigned. The secondary structure of an antiparallel triple- and double-stranded beta-sheet has also been determined by observing the NOE.

A circulatory model for combined nitroprusside-dopamine therapy in acute heart failure

A computer model was developed to approximate the hemodynamic responses of dopamine and nitroprusside in acute left ventricular pump failure. The model is intended to aid the design of a multiple drug infusion system. A non-linear electrical analog model with baroreflex feedback was used to simulate the circulatory system. Heart failure was represented by a reduction in left ventricular inotropy. Pharmacodynamic relationships between the drugs studied and several elements of the system were incorporated into the model to simulate the overall drug responses which include secondary interactions between vascular components. Despite several shortcomings, the model showed good agreement with experimental and clinical data.

Multi-determinate regulation of neuronal survival: neuropeptides, excitatory amino acids and bioelectric activity

Neuronal survival of dorsal root ganglion-spinal cord cultures was determined after treatment with vasoactive intestinal peptide (VIP) and an antagonist to the N-methyl-D-aspartate receptor (NMDA). Blockade of NMDA receptors with 2-amino 5-phosphonovaleric acid (AP5) produced a biphasic response on neuronal survival: low concentrations (0.1 microM) resulting in greater survival and higher concentrations (100 microM) causing cell death. VIP, a substance with demonstrated neurotrophic properties in vitro, prevented the neuronal cell death associated with high concentrations of AP5, while having no additive effect on the survival-promoting action of low levels of AP5. Electrophysiological studies indicated that AP5, although reducing high frequency bursting activity, did not significantly reduce the abundant on-going asynchronous activity present in these cultures of high density neuronal networks. These data indicate that excitatory amino acids have more than one action that can influence neuronal survival during development and that VIP can increase neuronal survival in bioelectrically active cultures when NMDA channels are blocked. Together with previous studies, these data suggest that multiple neurochemical inputs serve to determine the survival of spinal cord neurons during development, perhaps through one final common pathway: intracellular calcium regulation.

Mechanisms involved in activity-dependent synapse formation in mammalian central nervous system cell cultures

Differences in neuronal activity produced by electrical stimulation lead to competition between synapses from sensory afferents converging on a common spinal cord neuron. Studies were performed on neurons dissociated from the mouse spinal cord and grown in culture dishes with three compartments. Synaptic efficacy from stimulated afferents was increased compared with unstimulated convergents, and the number of functional connections was increased by stimulation compared with control cultures. Blocking NMDA channel activation with 100 microM APV in medium containing 1.8 mM calcium inhibited this synaptic plasticity, but plasticity was not blocked by APV in medium in which the calcium concentration was elevated to 3 mM. These experiments support the view that electrical activity differentially influences processes that cause a persistent decrease in synaptic efficacy or lead to synapse elimination and those that increase synaptic strength or lead to synapse augmentation. We interpret our results in terms of a model in which these antagonistic mechanisms are both regulated via changes in calcium levels and second messengers that are modulated by electrical activity. A significant portion of the activity-related calcium influx relevant to synaptic plasticity passes through the NMDA channel, but other sources of calcium are involved. In particular, competitive elimination of synapses appears to occur during blockade of NMDA channels if the extracellular concentration of calcium is elevated moderately. The outcome of competition between the two calcium-dependent but antagonistic processes may depend either on their differential sensitivity to intracellular calcium concentration or separate specificities to NMDA and non-NMDA receptor-linked mechanisms.

Complete sequence of the lamprey fibrinogen alpha chain

The complete amino acid sequence of the lamprey fibrinogen alpha chain has been determined by a combination of peptide sequencing and cDNA and genomic cloning. The chain, which has an apparent molecular weight by dodecyl sulfate-polyacrylamide gel electrophoresis of ca. 100,000, is composed of 961 amino acid residues and has a calculated molecular weight of 96,722. It is distinguished by a large number of 18-residue repeats in a region where mammalian fibrinogens have 13-residue repeats. The data are in accord with our previous finding that the lamprey alpha chain has a distinctive amino acid composition, almost half the residues being glycine, serine, or threonine. The chain differs from mammalian alpha chains in that there are no cysteines in the carboxy-terminal half, and thus no intrachain loop, nor are there any RGD sequences in the lamprey alpha chain. Taken together with previous data on the sequences of the beta and gamma chains, the findings bear significantly on our understanding of fibrin formation. The alpha chain also provides an interesting case of structural convergence during evolution.

Synaptic connections in vitro: modulation of number and efficacy by electrical activity

The functional architecture of synaptic circuits is determined to a crucial degree by the patterns of electrical activity that occur during development. Studies with an in vitro preparation of mammalian sensory neurons projecting to ventral spinal cord neurons slow that electrical activity induces competitive processes that regulate synaptic efficacy so as to favor activated pathways over inactive convergent pathways. At the same time, electrical activity initiates noncompetitive processes that increase the number of axonal connections between these sensory and spinal cord neurons.

Prevention by gamma interferon of fatal infection with Listeria monocytogenes in mice treated with cyclosporin A

The significance of interferons (IFNs) induced by Listeria monocytogenes in the antilisterial defense mechanism was studied in mice. Cyclosporin A (CsA) had no effect on IFN-alpha production that was induced in the bloodstream after intravenous infection of mice with L. monocytogenes, whereas IFN-gamma that was induced in the bloodstreams of control mice 6 h after stimulation with specific antigen in the late phase of infection was suppressed in CsA-treated mice, depending on the dose of the drug injected. The decrease in IFN-gamma production caused an increase in bacterial growth in the spleens and livers of CsA-treated mice. Furthermore, administration of a daily dose of CsA at 80 or 100 mg/kg of body weight resulted in fatal listeriosis, even though the dose was nonlethal for normal mice. The administration of recombinant murine IFN-gamma on day 0 of L. monocytogenes infection prevented CsA-treated mice from developing fatal listeriosis and restored their ability to produce IFN-gamma in the bloodstream, in response to specific antigen in the late phase of infection.

Calcium agonist (BayK 8644) augments voltage-sensitive calcium currents but not synaptic transmission in cultured mouse spinal cord neurons

The effects of the calcium agonist, BayK 8644, and other agents upon voltage-dependent calcium conductance (VSCC) and evoked synaptic activity were studied in cultured mouse spinal cord and dorsal root ganglion neurons. As expected, BayK 8644 increased the VSCC corresponding to L channels. It had relatively little effect on evoked synaptic activity; the small but statistically significant effect that was noted was a decrease. Nitrendipine had either no effect or an increase with no statistically significant effect being seen with regard to synaptic activity over the population sampled. An increased extracellular Ca++ concentration increased both VSCC and synaptic activity. We conclude that VSCC with L channel properties are probably not involved in transmitter release produced by action potentials in the central synapses occurring in the dissociated mouse spinal cord cell culture system.

The sugar-specific adhesion/deadhesion apparatus of the marine bacterium Vibrio furnissii is a sensorium that continuously monitors nutrient levels in the environment

Our earlier studies on cell adhesion to immobilized carbohydrates are extended here to a marine bacterium, Vibrio furnissii. Apparently one lectin mediates the binding of these cells to glycosides of N-acetylglucosamine, mannose, and glucose covalently linked to Agarose beads. Kinetic studies show that protein synthesis is required for initiating and for maintaining adhesion to the glycosides. Furthermore, a pro- mutant binds to GlcNAc-beads at Pro concentrations insufficient to support cell growth. Expression of the functional lectin therefore predominates under conditions of limiting protein synthesis. Thus, cells adhere to the sugars in an environment compatible with protein synthesis, and deadhere when depleted of any required nutrient, presumably to migrate to a more favorable locale. The adhesion-deadhesion apparatus thereby permits constant monitoring of the surrounding environment, comprising a "nutrient sensorium".

Comparison of tremor responses to orally administered albuterol and terbutaline

This study was designed to compare the initial tremor response to 4.0 mg albuterol and 5.0 mg terbutaline orally administered and to study the question of tachyphylaxis by rechallenge after 3 wk of maintenance dosing. Twenty fasting patients with severe COPD in whom orally administered sympathomimetics were withheld for 2 wk were challenged with single doses of each drug in a crossover, randomized fashion 1 wk apart. Then after a further 3 wk of dosing 3 times a day of the second medication (10 patients received each medication), they were challenged once more 16 h after the last dose. Rest and postural tremor were measured at zero and 2 h using an accelerometer affixed to the finger, and measurements of subjective tremor, tremor power spectrum, plasma cyclic AMP and lactate, and forced vital capacity were also made. Postural tremor increased from 25.05 to 36.20 relative units for albuterol, an increase of 11.15 units, and from 24.90 to 57.70 units for terbutaline, an increase of 32.80 units (difference significant at p = 0.01). Plasma cyclic AMP (p less than 0.01) and lactate (p = 0.05) increases were also less for albuterol, and the FEV1 and FVC responses, though about one third less, did not differ significantly. After 3 wk, mean baseline tremor for both drugs was elevated even 16 h after the last 3 times a day dosing (38.00 and 33.10) for albuterol and terbutaline (difference, NS), and responses were much less to the single tablet (3.40 and 9.10, respectively).(ABSTRACT TRUNCATED AT 250 WORDS)

Conversion of serine to glycerate in intact spinach leaf peroxisomes: role of malate dehydrogenase

In photorespiration, leaf peroxisomes convert serine to glycerate via serine-glyoxylate aminotransferase and NADH-hydroxypyruvate reductase. We isolated intact spinach leaf peroxisomes in 0.25 M sucrose, and characterized their enzymatic conversion of serine to glycerate using physiological concentrations of substrates and coenzymes. In the presence of glycolate (glyoxylate), and NADH and NAD alone or together in physiological proportions, the rate of serine-to-glycerate conversion was enhanced and sustained by the addition of malate. The rate was similar at 1 and 5 mM serine, but was two to three times higher in 50 mM than 5 mM malate. In the presence of NAD and malate, there was 1:1 stoichiometric formation of glycerate and oxaloacetate. Addition of 1 or 5 mM glutamate resulted in a negligible enhancement of the conversion of hydroxypyruvate to glycerate. Intact peroxisomes produced glycerate from either serine or hydroxypyruvate at a rate two times higher than osmotically lysed peroxisomes. These results suggest that under physiological conditions, the peroxisomal malate dehydrogenase operates independent of aspartate-alpha-ketoglutarate aminotransferase in supplying NADH for hydroxypyruvate reduction. This supply of NADH is the rate-limiting step in the conversion of serine to glycerate. The compartmentation of hydroxypyruvate reductase and malate dehydrogenase in the peroxisomes confers a higher efficiency in the supply of NADH for hydroxypyruvate reduction under a normal, high NAD/NADH ratio in the cytosol.

Substrate specificities of lipases from corn and other seeds

Lipases from several seed species were shown to be relatively specific on triacylglycerols containing the major fatty acid components of the storage triacylglycerols in the same species. In a direct comparison using individual triacylglycerol as well as mixed triacylglycerol preparations, highest activities were observed in corn lipase on trilinolein and triolein, castor bean lipase on triricinolein, rapeseed lipase on trierucin, and elm seed lipase on tricaprin. This pattern of fatty acyl specificity was also observed on diacylglycerols, monoacylglycerols, and fatty acyl 4-methylumbelliferone, although the pattern became less distinct. The seed lipases were inactive on lecithins. Corn lipase was more active on tri- than di- or monolinolein, and released linoleic acids from both primary and secondary positions. As judged from the kinetics of hydrolysis of rac-glyceryl-2,3-stearate-1-oleate and rac-glyceryl-1,3-stearate-2-oleate, and of trilinolein and dilinoleins, corn lipase exerted some degree of preference in releasing fatty acid from the primary than the secondary position of a triacylglycerol. At the primary position, corn lipase was more active on oleyl ester than stearyl ester.

Conversion of glycerate to serine in intact spinach leaf peroxisomes

Intact spinach (Spinacia oleracea L.) leaf peroxisomes converted glycerate to serine in the presence of NAD and alanine. The reaction proceeded optimally at pH9. Addition of oxaloacetate or alpha-ketoglutarate plus aspartate enhanced the conversion about three-fold. Alteration of the concentration of one of the reaction components, consisting of 2 mM glycerate, 0.2 mM NAD, 0.5 mM oxaloacetate, and 2 mM alanine, revealed half-saturation constants of 0.45 mM for glycerate, 0.06 mM for NAD, 0.02 mM for oxaloacetate, and 0.33 mM for alanine. The conversion proceeded with the formation of hydroxypyruvate followed by serine; hydroxypyruvate did not accumulate to a high amount in the presence or absence of alanine. The amino group donor could be alanine (half-saturation constant, 0.33 mM), glycine (0.45 mM), or asparagine (0.67 mM); the three amino acids produced roughly similar Vmax values. The results indicate that, in the conversion of glycerate to serine, the transamination is catalyzed by a hydroxypyruvate aminotransferase with characteristics unknown among all other studied leaf peroxisomal aminotransferases. The peroxisomal membrane is sparsely permeable to NAD/NADH, and the participation of the peroxisomal malate dehydrogenase in an electron shuttle system across the membrane in the regeneration of NAD/NADH is suggested.

Glyoxylate transamination in intact leaf peroxisomes

Intact spinach (Spinacia oleracea L.) leaf peroxisomes were supplied with glycolate and one to three of the amino acids serine, glutamate, and alanine, and the amount of the respective alpha-keto acids formed in glyoxylate transamination was assayed. At 1 millimolar glycolate and 1 millimolar each of the three amino acids in combination, the transamination reaction reached saturation; reduction of either glycolate or amino acid concentration decreased the activity. The relative serine, glutamate, and alanine transamination at equal amino acid concentrations was roughly 40, 30, and 30%, respectively. The three amino acids exhibited mutual inhibition to one another in transamination due to the competition for the supply of glyoxylate. In addition to this competition for glyoxylate, competitive inhibition at the active site of enzymes occurred between glutamate and alanine, but not between serine and glutamate or alanine. Alteration of the relative concentrations of the three amino acids changed their relative transamination. Similar work was performed with intact oat (Avena sativa L.) leaf peroxisomes. At 1 millimolar of each of the three amino acids in combination, the relative serine, glutamate, and alanine transamination was roughly 60, 23, and 17%, respectively. Similarly, alteration of the relative concentration of the three amino acids changed their relative transamination. The contents of the three amino acids in leaf extracts were analyzed, and the relative contribution of the three amino acids in glycine production in photorespiration was assessed and discussed.