Inhibition, by lanthanides, of neutral proteinases secreted by human, rheumatoid synovium

Fragments of human, rheumatoid synovium were maintained on organ culture for three days under serum-less conditions. Their conditioned media contained collagenolytic, gelatinolytic and caseinolytic activities, which were susceptible to inhibition by lanthanide ions. Of the four lanthanides tested, Sm3+ proved the best inhibitor of gelatinase and caseinase, while La3+ inhibited collagenase the most strongly. Inhibition of collagenase by La3+ was uncompetitive. A direct binding assay confirmed the greater association between collagen fibrils and collagenase in the presence of La3+. Ca2+ was not required for binding of the uninhibited enzyme to collagen, but acted to stabilize collagenase against thermoinactivation.     

Stimulation of ethylene production by hydroxamic acid, in particular, by benzohydroxamic acid

The effects on the ethylene production of known inhibitors ofa cyanide-insensitive, alternative respiration in plants wereinvestigated using cotyledonary segments of cocklebur (Xanthiumpennsylvanicum Wallr.) seeds. Benzohydroxamic acid (BHAM) at3 mM stimulated ethylene production 4- to 8-fold over the control,but respiration of the segments was hardly affected at thatconcentration. The stimulatory effects of 3-chlorobenzohydroxamicacid (CLAM) and salicylhydroxamic acid were far smaller thanthat of BHAM. BHAM at 3 mM also markedly stimulated the ethyleneformation in the epicotyl or hypocotyl sections of etiolatedpea (Pisum sativum L.) and mung bean (Vigna radiata [L.] Wilczek)seedlings. Moreover, 3 mM BHAM further promoted the increasedethylene formation which was caused by administration of 1-aminocyclopro-pane-1-carboxylicacid (ACC) to the cotyledonary segments. The promoting effectsby BHAM and CLAM were also found in the conversion of ACC intoethylene in pea stem homogenates. (Received July 26, 1980; )     

Stimulation of ethylene production by hydroxamic acid, in particular, by benzohydroxamic acid

The effects on the ethylene production of known inhibitors ofa cyanide-insensitive, alternative respiration in plants wereinvestigated using cotyledonary segments of cocklebur (Xanthiumpennsylvanicum Wallr.) seeds. Benzohydroxamic acid (BHAM) at3 mM stimulated ethylene production 4- to 8-fold over the control,but respiration of the segments was hardly affected at thatconcentration. The stimulatory effects of 3-chlorobenzohydroxamicacid (CLAM) and salicylhydroxamic acid were far smaller thanthat of BHAM. BHAM at 3 mM also markedly stimulated the ethyleneformation in the epicotyl or hypocotyl sections of etiolatedpea (Pisum sativum L.) and mung bean (Vigna radiata [L.] Wilczek)seedlings. Moreover, 3 mM BHAM further promoted the increasedethylene formation which was caused by administration of 1-aminocyclopro-pane-1-carboxylicacid (ACC) to the cotyledonary segments. The promoting effectsby BHAM and CLAM were also found in the conversion of ACC intoethylene in pea stem homogenates. (Received July 26, 1980; )     

Graft-versus-host response,measured by splenomegaly assay,by populations of allosensitized mouse lymphocytes

The graft-vs-host (G-v-H) reactivity of sensitized or nonsensitized mouse lymphoid cell populations was measured using a splenomegaly assay. Sensitized populations were obtained either from the local lymph nodes of alloimmunized animals or from the spleens of heavily irradiated mice previously infused iv with allogeneic lymphocytes (educated cells). Immunization of animals resulted in increased G-v-H responses of the cells in their local lymph nodes. This effect was more pronounced when the immunizing cells differed only at non-H-2 transplantation antigens than when H-2-disparate strain combinations were tested. There was no evidence of a changed doseresponse profile of lymphocytes obtained from immunized mice. The G-v-H reactivity of educated cell populations was complex. The slopes of the dose-response lines obtained for lymph node cells or thymic cells educated in an H-2-disparate strain were generally lower than those obtained for nonsensitized cells. This difference was particularly evident when testing educated thymocytes. By studying the G-v-H indices obtained in A/Sn × C57B1 hybrids after inoculation of nonsensitized C57B1 lymph node cells or specifically educated C57BL lymph node cells, it was observed that the latter cells were approximately 30 times more reactive when small cell inocula were compared. On the contrary, education of lymphocytes in H-2-compatible allogeneic hosts did not result in any increment of their G-v-H reactivity. The results indicate that different methods of sensitizing lymphocyte populations against alloantigens may lead to activation of different subclasses of T-cells which differ in their mode of antigen reactivity.     

Inch by inch, row by row

Bacterial chemotaxis systems have cooperatively interacting clusters of transmembrane receptors and signaling proteins to detect, amplify, integrate and adapt to environmental signals. A recent study provides experimental data to construct a new model of the signaling complex.     

Hemolysis of human erythrocytes by hypochlorous acid is modulated by amino acids,antioxidants, oxidants,membrane-perforating agents and by divalent metals

The optimal conditions under which hypochlorous acid (NaOCl) either hemolyzes human RBC or kills monkey kidney epithelial cells (BGM) in culture had been investigated. While in Hank's balanced salt solution (HBSS), micromolar amounts of NaOCl caused full hemolysis and also killed BGM cells, in D-MEM or RPMI media rich in amino acids, 25-40 mM of hypochlorite were needed to induce cell injury. Cells exposed to high amounts of NaOCl became highly refractory to strong detergents. Hemolysis by NaOCl was strongly inhibited by a large variety of antioxidants. RBC treated by subtoxic concentrations either of peroxide, peroxyl radical, NO, cholesterol, PLA2, PLC as well as by N2, argon or by mixture of CO2 (10%) and O2 (90%) became much more susceptible to lysis by NaOCl. On the other hand, while RBC treated by Fe2+, Co2+, and V2+ and to a lesser extent with Cu2+ became highly resistant to NaOCl hemolysis presumably due to NaOCl decomposition, no such effect was found either with Co2+ or by Mn2+. RBC treated by azide to destroy catalase and then incubated with peroxide and with NaOCl failed to undergo hemolysis due to the ability of peroxide to decompose NaOCl. The inhibitory effects of the divalent metals on NaOCl-induced hemolysis were also substantiated by measuring the decrease in pH and by cyclic voltammetry. The findings that like peroxide, NaOCl also synergizes with membrane-perforating agents and with a protease to kill epithelial cells further implicate such "cocktails" in cell injury in inflammatory conditions. Taken together, because of the capacity of many agents to scavenge NaOCl, tissue damage by NaOCl-generated neutrophils can take place primarily if activated neutrophils closely adhere to target cells to avoid the scavenging effects of amino acids and of antioxidants. Therefore, the significance of the data which had tested the cytotoxic effects of NaOCl using cells suspended only in salt solutions, should be reconsidered.     

Hemolysis of Human Erythrocytes by Hypochlorous Acid is Modulated by Amino Acids,Antioxidants, Oxidants,Membrane-perforating Agents and by Divalent Metals

The optimal conditions under which hypochlorous acid (NaOCl) either hemolyzes human RBC or kills monkey kidney epithelial cells (BGM) in culture had been investigated. While in Hank's balanced salt solution (HBSS), micromolar amounts of NaOCl caused full hemolysis and also killed BGM cells, in D-MEM or RPMI media rich in amino acids, 25-40 mM of hypochlorite were needed to induce cell injury. Cells exposed to high amounts of NaOCl became highly refractory to strong detergents. Hemolysis by NaOCl was strongly inhibited by a large variety of antioxidants. RBC treated by subtoxic concentrations either of peroxide, peroxyl radical, NO, cholesterol, PLA?, PLC as well as by N?, argon or by mixture of CO?, (10%) and 0? (90%) became much more susceptible to lysis by NaOCl. On the other hand, while RBC treated by FE²?, Co²?, and V²? and to a lesser extent with Cu²? became highly resistant to NaOCl hemolysis presumably due to NaOCl decomposition, no such effect was found either with Co²? or by Mn²?. RBC treated by azide to destroy catalase and then incubated with peroxide and with NaOCl failed to undergo hemolysis due to the ability of peroxide to decompose NaOCl. The inhibitory effects of the divalent metals on NaOCl -induced hemolysis were also substantiated by measuring the decrease in pH and by cyclic voltammetry. The findings that like peroxide, NaOCl also synergizes with membrane-perforating agents and with a protease to kill epithelial cells further implicate such "cocktails" in cell injury in inflammatory conditions.

Taken together, because of the capacity of many agents to scavenge NaOCl, tissue damage by NaOCl generated neutrophils can take place primarily if activated neutrophils closely adhere to target cells to avoid the scavenging effects of amino acids and of antioxidants. Therefore, the significance of the data which had tested the cytotoxic effects of NaOCl using cells suspended only in salt solutions, should be considered.     

Suppression of Mitochondrial Function by Oxidatively Truncated Phospholipids Is Reversible, Aided by Bid, and Suppressed by Bcl-XL

Oxidatively truncated phospholipids are present in atherosclerotic lesions, apoptotic cells, and oxidized low density lipoproteins. Some of these lipids rapidly enter cells to induce apoptosis by the intrinsic pathway, but how such lipids initiate this process is unknown. We show the truncated phospholipid hexadecyl azelaoyl glycerophosphocholine (Az-LPAF), derived from the fragmentation of abundant sn-2 linoleoyl residues, depolarized mitochondria of intact cells. Az-LPAF also depolarized isolated mitochondria and allowed NADH loss, but did not directly interfere with complex I function. Cyclosporin A blockade of the mitochondrial permeability transition pore partially prevented the loss of electrochemical potential. Depolarization of isolated mitochondria by the truncated phospholipid was readily reversed by the addition of albumin that sequestered this lipid. Ectopic expression of the anti-apoptotic protein Bcl-X_L in HL-60 cells reduced apoptosis by the truncated phospholipid by protecting their mitochondria. Mitochondria isolated from these cells were also protected from Az-LPAF-induced depolarization. Conversely mitochondria isolated from Bid^−/− animals that lack this pro-apoptotic Bcl-2 family member were resistant to Az-LPAF depolarization. Addition of recombinant full-length Bid, which has phospholipid transfer activity, restored this sensitivity. Thus, phospholipid oxidation products physically interact with mitochondria to continually depolarize this organelle without permanent harm, and Bcl-2 family members modulate this interaction with full-length Bid acting as a co-factor for pro-apoptotic, oxidatively truncated phospholipids.Vascular cells are exposed to oxidizing radicals during normal metabolism, but especially so during physiologic and pathologic inflammatory processes. The double bonds of polyunsaturated fatty acyl residues are particularly prone to attack by radicals because the C-H bond situated between two double bonds is relatively weak, allowing a more facile abstraction of hydrogen to produce a radical (1). Because polyunsaturated fatty acyl residues are abundant and are generally esterified in the sn-2 position of the glycerol backbone, common products of oxidative attack on cells and circulating lipoproteins are phospholipids that have been peroxidized at their sn-2 position. These peroxy radicals abstract hydrogen to form hydroperoxy phospholipids, may be reduced to the corresponding alcohol, rearrange (2, 3), or fragment to generate a host of oxidatively truncated phospholipids (4–7).The shortened sn-2 residue of truncated phospholipids, which may also contain a newly introduced polar oxygen function, does not intercalate into the membrane well and is energetically favored to protrude into the aqueous phase, a conformation that disorders phospholipid packing into a bilayer (8–10). Oxidatively truncated phospholipids are more water soluble than their phospholipid precursors and readily associate with plasma albumin (11), plasma membranes (12), and even traffic into cells to lysosomes (12) or mitochondria (13) depending on the structure of the truncated phospholipid.Phospholipid oxidation products can be cytotoxic (14, 15), and at least some of these are toxic because they initiate the apoptotic process of regulated cell death (13). The manner by which oxidatively truncated phospholipids alter cell viability has been ascribed to solubilization of the plasma membrane (14), adduction of mitochondrial proteins (17), temporary physical distortion of the plasma membrane (18), or activation of acid sphingomyelinase activity that alters plasma membrane microdomains by generating ceramide (15, 19). We found that a common oxidatively truncated phospholipid, containing a 9-carbon azelaoyl fragment derived from fragmentation of sn-2 linoleoyl residues, induces apoptosis by the intrinsic caspase cascade with loss of mitochondrial function and not, apparently, from damage of the plasma membrane (13).Members of the Bcl-2 family modulate mitochondria-dependent apoptosis either by promoting apoptosis (Bid, Bad, and Bax) or obstructing this event (Bcl-2 and Bcl-X_L). Aggregation of Bax on the mitochondrial outer membrane forms ion conducting pores and Bcl-X_L associates with mitochondrial outer membranes to suppress this Bax activity (20). In contrast, Bid promotes apoptosis after cleavage to truncated Bid, a regulatory event catalyzed by activated caspase 8 (21). Bid, alone among Bcl-2 family members, displays homology to plant lipid transfer proteins and both truncated and full-length Bid will incorporate fluorescent phospholipids, and not the cognate fluorescent fatty acid, into mitochondrial membranes (22).We determined whether mitochondrial integrity or function were directly affected by oxidatively truncated phospholipids, and then whether Bcl-2 family members alter these effects as they do in other, established apoptotic signaling pathways. We find that truncated phospholipids accumulated from the extracellular environment depolarize intracellular mitochondria, that these bilayer challenged phospholipids reversibly interact with mitochondria to continually reduce their transmembrane potential, and that Bcl-2 family members modulate this interaction.     

Biotransformation of limonene by bacteria,fungi, yeasts,and plants

The past 5 years have seen significant progress in the field of limonene biotransformation, especially with regard to the regiospecificity of microbial biocatalysts. Whereas earlier only regiospecific biocatalysts for the 1,2 position (limonene-1,2-diol) and the 8-position (alpha-terpineol) were available, recent reports describe microbial biocatalysts specifically hydroxylating the 3-position (isopiperitenol), 6-position (carveol and carvone), and 7-position (perillyl alcohol, perillylaaldehyde, and perillic acid). The present review also includes the considerable progress made in the characterization of plant P-450 limonene hydroxylases and the cloning of the encoding genes.     

Drug, dosage, activity, studies of antimalarials by physical methods--II

Studies pertaining to drug-DNA interactions in treating a disease efficiently have taken an important place in recent times. Murthy and colleagues were active in correlating the drug activity, with physical parameters like refractivity, susceptibility, molecular electron ionization cross-section and the dosage. The molecular polarizability, diamagnetic susceptibility and molecular electron ionization cross section Q have been evaluated. An analysis of Q in the light of the data available on plasma protein binding, bio availability, Log P and half-Life show semblance of regular dependence of Q on them and hence an effort is made to bring this dependence into a regular mathematical relationship. The dosage of each drug is calculated. A critical look at the results arrived on Q and dosages reveal that a highly active drug with large Q need to be monitored in very small quantities and any minute increase in dosage is resulting in unwanted toxic effects and vice versa. The algebraic formulae enable one to calculate the dosages theoretically from the value of Q and other parameters and the calculated dosage through the formulae agreed favorably well with suggested dosages. For example, in primaquine phosphate, the calculated dosage is 30 mg per day against the suggested practical dosage of 26.3 mg per day. A similar observation is made in mepacrine with theoretical dosage of 60 mg per day as against the suggested practical dosage of 100 mg per day. In short, the molecular structure followed by refraction and susceptibility measurements and Q will throw light on dosage, toxicity of a drug. Thus the present investigations pave way for a new direction of approach for study of drug activity without recourse to techniques involving highly expensive instrumentation and highly theoretical approaches involving quantum mechanical methods.     

Modification, by lithium, of catalepsy induced by central cholinergic stimulants and morphine-like drugs

After unique injection LiCl enhances, in albino rat, catalepsy induced by arecoline and oxotremorine perhaps by adenylcyclase inhibition and/or decrease of acetylcholine synthesis. After repetitive injection of LiCl during 5 days, this phenomenon is not observable, probably owing to increase of acetylcholine synthesis. After unique injection of LiCl enhances catalepsy induced by dextromoramide, probably on account of cholinergic properties of this drug. In contrast catalepsy induced by morphine or pethidine is suppressed. This constatation would depend on opposite influence upon cerebral neuromediators : lithium diminishing cerebral serotonin and striatal acetylcholine levels and morphine increasing them. After repetitive injections these phenomenons are not observable.     

Fermentation of glucose, lactose, galactose, mannitol, and xylose by bifidobacteria

For six strains of Bifidobacterium bifidum (Lactobacillus bifidus), fermentation balances of glucose, lactose, galactose, mannitol, and xylose were determined. Products formed were acetate, l(+)-lactate, ethyl alcohol, and formate. l(+)-Lactate dehydrogenase of all strains studied was found to have an absolute requirement for fructose-1,6-diphosphate. The phosphoroclastic enzyme could not be demonstrated in cell-free extracts. Cell suspensions fermented pyruvate to equimolar amounts of acetate and formate. Alcohol dehydrogenase was shown in cell-free extracts. Possible explanations have been suggested for the differences in fermentation balances found for different strains and carbon sources. By enzyme determinations, it was shown that bifidobacteria convert mannitol to fructose-6-phosphate by an inducible polyol dehydrogenase and fructokinase. For one strain of B. bifidum, molar growth yields of glucose, lactose, galactose, and mannitol were determined. The mean value of Y (ATP), calculated from molar growth yields and fermentation balances, was 11.3.     

Chicks, like children, spontaneously reorient by three-dimensional environmental geometry, not by image matching

Spatial reorientation by layout geometry occurs in numerous species, but its underlying mechanisms are debated. While some argue that navigating animals' sense of place is based on geometric computations over three-dimensional representations, others claim it depends on panoramic image-matching processes. Because children reorient by subtle three-dimensional perturbations of the terrain and not by salient two-dimensional brightness contours on surfaces or freestanding columns, children's sense of place cannot be explained by image matching. To test image-matching theories in a different species, the present experiment investigates the reorientation performance of domestic chicks (Gallus gallus) in environments similar to those used with children. Chicks, like children, spontaneously reoriented by geometric relationships of subtle three-dimensional terrains, and not by salient two-dimensional brightness contours on surfaces or columns. These findings add to the evidence for homologous navigation systems in humans and other vertebrates, and they cast doubt on image-matching theories of reorientation in these species.     

Fermentation of D-xylose, xylitol, and D-xylulose by yeasts

Fifteen yeasts which can assimilate D-xylose were examined for the ability to convert this pentose to ethanol. In six of the seven genera investigated the conversion was enhanced when air had access to the medium. Therefore, the ability to convert D-xylose to ethanol under these conditions is probably common among yeasts. Growth under the same conditions on xylitol, a putative catabolite of D-xylose, led to only traces of ethanol. The effects of growth on another putative catabolite, D-xylose, were complex, but some of the strains which were among the better producers of ethanol from D-xylose produced less from D-xylulose.