The regulation of rat liver tryptophan pyrrolase activity by reduced nicotinamide-adenine dinucleotide (phosphate). Experiments with glucose and nicotinamide.

1. Chronic administration of glucose or nicotinamide in drinking water inhibits the activity of rat liver tryptophan pyrrolase, and subsequent withdrawal causes an enhancement. The enzyme activity is also inhibited by administration in drinking water of sucrose, but not fructose, which is capable of preventing the glucose effect. 2. The inhibition by glucose or nictinamide is not due to a defective apoenzyme synthesis nor a decreased cofactor availability. 3. The inhibition by nicotinamide is reversed by regeneration of liver NAD+ and NADP+ in vivo by administration of fructose, pyruvate or phenazine methosulphate. Inhibition by glucose is also reversed by the above agents and by NH4Cl. Reversal of inhibition by glucose or nicotinamide is also achieved in vitro by addition of NAD+ or NADP+. 4. Glucose or nicotinamide increases liver [NADPH]. [NADP+] is also increased by nicotinamide. [NADPH] is also increased by sucrose, but not by fructose, which prevents the glucose effect. Phenazine methosulphate prevents the increase in [NADPH] caused by both glucose and nicotinamide. 5. It is suggested that the inhibition of tryptophan pyrrolase activity by glucose or nicotinamide is mediated by both NADPH and NADH.     

Fluorescence studies of 1,N6-ethenoadenosine triphosphate bound to G-actin: the nucleotide base is inaccessible to water

When 1,N6-ethenoadenosine triphosphate (epsilon-ATP) is free in solution, its fluorescence is collisionally quenched by iodide ion, by methionine, by tryptophan, and by cysteine. None of these quenches the fluorescence of epsilon-ATP bound to G-actin. Thus, the ethenoadenine base is bound in a region of the protein which is inaccessible to collisions with these reagents. Since we have previously shown that the fluorescence of epsilon-ATP is quenched by water, the long lifetime of epsilon-ATP bound to G-actin (36 nsec, vs 27 nsec for epsilon-ATP in water) indicates that the bound nucleotide base is inaccessible to collisional quenching by water molecules.     

Specificity of cycloheximide in higher plant systems

Although cycloheximide is extremely inhibitory to protein synthesis in vivo in higher plants, the reported insensitivity of some plant ribosomes suggests that it may not invariably act at the ribosomal level. This suggestion is reinforced by results obtained with red beet storage tissue disks, the respiration of which is stimulated by cycloheximide at 1 microgram per milliliter. Inorganic ion uptake by these disks is inhibited by cycloheximide at 1 microgram per milliliter while the uptake of organic compounds, by comparison, is unaffected. Ion uptake by all nongreen tissues tested is inhibited by cycloheximide, but leaf tissue is unaffected, indicating that the ion absorption mechanism in the leaf may differ fundamentally from that in the root. It is concluded that cycloheximide can affect cellular metabolism other than by inhibiting protein synthesis and that the inhibition of ion uptake may be due to disruption of the energy supply.     

Overlapping and separate controls on the phosphate regulon in Escherichia coli K12

The physiological and genetic controls operating on phosphate-regulated promoters were studied in greater detail. This was done by defining the control for three phosphate-regulated genes: phoA, psiE, and psiO. Each is highly inducible by phosphate starvation. Individually, these phosphate-starvation-inducible, psi, genes at the same time show common and differing features in their molecular control. The phoA gene, encoding alkaline phosphatase, is specifically induced by phosphate starvation. It is negatively controlled by phoR as well as by the phosphate-specific transport (PST) system in Escherichia coli. phoA induction is positively controlled by the phoB, M, and R products; it is unaffected by the cAMP and CAP system. The psiE and psiO genes were studied by using strains with lacZ fused to their respective promoters. psiE-lacZ is induced by phosphate-, carbon- or nitrogen-limited growth. Genetically, psiE-lacZ induction is partially phoB and phoR-dependent. However, its expression is phoM-independent. This implies that phoB/phoR coupled control differs from phoB/phoM coupled control. Repression of psiE-lacZ is substantially altered in only some PST mutants, such as phoT. In addition, psiE-lacZ is negatively controlled by the cAMP and CAP system. psiO-lacZ is induced by phosphate-, carbon- or nitrogen-limited growth or by anaerobiosis. Its expression is unaffected by any pho mutation that has been previously described. A cell density-dependent induction of psiO-lacZ is observed in lon mutants. Also, psiO-lacZ is negatively controlled by the cAMP-CAP system. In summary, these results demonstrate that co-ordinately regulated promoters can have some common regulatory elements while, at the same time, not sharing other controlling factors.     

Stimulation of Na:H exchange by insulin

In frog skeletal muscle, the increase of intracellular pH (pHi) induced by insulin is correlated with an increase in intracellular Na+ when the sodium pump is inhibited by ouabain. Reversing the Na+ free energy gradient by substituting either Mg2+ or choline for extracellular Na+ converts the effect of insulin to a decrease in pHi, indicating that the action of insulin upon pHi is determined by the Na+ free energy gradient. Moreover, estimates of the Na+ free energy gradient indicate that both the direction and magnitude satisfy the hypothesis that this is the source of energy for the observed changes in pHi. Both the increase in intracellular pH induced by insulin and the associated increase in intracellular Na+ produced by this hormone in the presence of ouabain are blocked by amiloride. This drug also blocks the decrease in pHi by insulin when Mg2+ is substituted for Na+ in the Ringer. In Ringer containing Na+, the increase in pHi by insulin occurs when both metabolic and atmospheric sources of CO2 are eliminated by using a 100% N2 atmosphere. Thus, the mechanism stimulated by insulin is not a Na+-CO3(2-) cotransport system, but is either an Na:H exchange or a Na+-OH- cotransport system which can be inhibited by amiloride. The suggestion is advanced that the Na:H exchange mechanism is part of the membrane transduction system for insulin.     

Glutamine transport in brain mitochondria

Gln is transported into rat brain synaptic and non-synaptic mitochondria by a protein catalyzed process. The uptake is significantly higher in synaptic than in non-synaptic mitochondria. The transport is inhibited by the amino acids Glu, Asn and Asp, and by the TCA cycle intermediates succinate, malate and 2-OG. The inhibition by 2-OG is counteracted by AOA and is therefore assumed to be due to transamination of 2-OG, whereby Glu is formed. This presumes that Glu also binds to an inhibitory site on the matrix face of the inner membrane. The transport is complex and cannot be explained by the simple uniport mechanism which has been proposed for renal (Schoolwerth and LaNoue, 1985), and liver mitochondria (Soboll et al., 1991). Thus, Gln transport is stimulated by respiration and by the proton electrochemical gradient. Since it is indicated that both the neutral Gln zwitterion and the Gln anion are transported, there are probably different uptake mechanisms, but not necessarily different carriers. Gln may be transported by an electroneutral mechanism as a proton compensated anion, as well as electrophoretically as a zwitterion with a proton, and probably also by diffusion as a zwitterion. The properties of the brain mitochondrial Gln uptake mechanisms are also not identical with those of a purified renal Gln transporter. It is possible that the Gln transport is controlled by more than one protein, which may be situated on distinct species in a heterogeneous mitochondrial population. Since Gln is assumed to participate in energy production as well as in the synthesis of nucleic acid components and proteins in brain mitochondria, the control of Gln uptake in these organelles may be important.     

A comparison of phospholipid degradation by oxidation and hydrolysis during the mitochondrial permeability transition

The peroxidation and hydrolysis of mitochondrial phospholipids has been examined under conditions which are referable to induction of the permeability transition by t-butylhydroperoxide. Over a 30-min time course, the peroxide causes formation of 0.3 nmol/mg protein of malondialdehyde. This value is little effected by Ca2+, Sr2+, or Mn2+ but is increased approximately fivefold by Fe2+. The latter cation, but not the others, results in malondialdehyde formation in the absence of added peroxide. Partially oxidized phosphatidylethanolamine is present in normal mitochondria and is increased by approximately 50% following t-butylhydroperoxide treatment; however, the amounts observed are in the range of 0.4-0.6 mol% of total phosphatidylethanolamine. The minor degradation by peroxidation is in contrast to approximately 2.5 mol% degradation which occurs by hydrolysis. This degree of hydrolysis is accompanied by mitochondrial swelling and Mg2+ release, while a comparable level of peroxidation (malondialdehyde formation) is not. It is concluded that induction of the permeability transition by t-butylhydroperoxide does not represent damage to the membrane lipid phase caused by peroxidation. It is possible, however, that peroxidation accelerates the accumulation of phospholipid hydrolysis products and is thereby a factor which favors the transition.     

Molecular interactions in the hydrogen belts of membranes. Glucose-6-phosphatase, lysophosphatidylcholine, and cholesterol

Microsomal glucose-6-phosphatase from rat liver is activated by phosphatidylcholine but inhibited by lysophosphatidylcholine. Inhibition occurs not by membrane lysis but in an intact bilayer; it is reversible; and it is overcome by addition of cholesterol but not if the cholesterol-hydroxyl group is blocked. An analog of lysophosphatidylcholine deprived of hydrogen bonding sites, 1-ether-2- deoxylysophosphatidylcholine , is a partial activator, and its effect on the enzyme in a phosphatidylcholine bilayer is not modulated by cholesterol. It appears to be one of the functions of cholesterol to buffer the lysophospholipids in membranes by complexing with them through hydrogen bonding in the hydrogen belt region. Lysophosphatidylcholine/cholesterol association is favored over phosphatidylcholine/cholesterol association.     

Influence of extracellular calcium on cell permeabilization and growth regulation by the lymphokine leukoregulin

Permeablization of human K562 leukemia cells was measured in the presence and absence of extracellular ionic calcium to examine the relationship of ionic calcium to increased membrane permeability and the inhibition of cell proliferation by this lymphokine. In the absence of extracellular calcium, the ability of leukoregulin to permeabilize the cell membrane is diminished but is fully restored by addition of 1 mM extracellular Ca++ as shown flow cytometrically by loss of intracellular fluorescein. Membrane permeability is also increased by calcium ionophore A23187 but permeablization is completely blocked in calcium-free medium despite the intramembrane presence of the calcium ionophore. Membrane permeablization by the lectin phytohemagglutinin, in contrast, is independent of extracellular calcium. A similar divergence in cell proliferation activity of the three modulators of calcium flux and membrane permeability occurs in the absence of extracellular calcium. Leukoregulin inhibition of cell proliferation is abolished, inhibition by calcium ionophore A23817 is greatly reduced, and inhibition by phytohemagglutinin is unchanged. Leukoregulin permeabilized K562 cells isolated by fluorescence activated cell sorting resume proliferation after 72 h. In contrast cells permeablized by calcium ionophore A23187 or phytohemagglutinin fail to resume proliferation by 7 days. The membrane permeablizing action of leukoregulin is, therefore, partially dependent upon extracellular calcium. It is also effected through a mechanism other than calcium ionophore transport or lectin type transmembrane signaling, and is accompanied by a reversible inhibition of cell proliferation.     

In vitro activation of the Serratia marcescens hemolysin through modification and complementation.

The hemolytic activity of Serratia marcescens is determined by two polypeptides, termed ShlA and ShlB. ShlA is synthesized as an inactive precursor (ShlA*) and secreted with the help of ShlB, which is located in the outer membrane. In this study, it is shown that a cell lysate containing ShlB as well as partially purified ShlB converted ShlA* to the active ShlA hemolysin. ShlA remained active after removal of ShlB by column chromatography. In contrast to the stable modification of ShlA* by ShlB, a reversible activation was achieved by adding to ShlA* an N-terminal fragment of ShlA (ShlA16), consisting of 269 amino acid residues of ShlA and 18 residues of the vector. The nonhemolytic ShlA16 complemented ShlA* only when it was synthesized in an ShlB-producing cell. A deletion derivative of ShlA*, lacking residues 4 to 117, was complemented by ShlA16 but not activated by ShlB. Activation of ShlA* by ShlB at 4 degrees C proceeded at a much slower rate than complementation by ShlA16. It is concluded that ShlA* is modified by ShlB. ShlA16 modified by ShlB complements the missing modification of ShlA* in trans. Modification by ShlB occurs in the N-terminal part of ShlA*, which is also the reaction in vivo which results in active ShlA hemolysin in the culture supernatant. The HpmA hemolysin of Proteus mirabilis, which is very similar to ShlA, was also activated in vitro by ShlB and complemented by ShlA16.     

Regulation of capsule synthesis and cell motility in Salmonella enterica by the essential gene igaA

Mutants of Salmonella enterica carrying the igaA1 allele, selected as able to overgrow within fibroblast cells in culture, are mucoid and show reduced motility. Mucoidy is caused by derepression of wca genes (necessary for capsule synthesis); these genes are regulated by the RcsC/YojN/RcsB phosphorelay system and by the RcsA coregulator. The induction of wca expression in an igaA1 mutant is suppressed by mutations in rcsA and rcsC. Reduced motility is caused by lowered expression of the flagellar master operon, flhDC, and is suppressed by mutations in rcsB or rcsC, suggesting that mutations in the igaA gene reduce motility by activating the RcsB/C system. A null igaA allele can be maintained only in an igaA(+)/igaA merodiploid, indicating that igaA is an essential gene. Lethality is suppressed by mutations in rcsB, rcsC, and yojN, but not in rcsA, suggesting that the viability defect of an igaA null mutant is mediated by the RcsB/RcsC system, independently of RcsA (and therefore of the wca genes). Because all the defects associated with igaA mutations are suppressed by mutations that block the RcsB/RcsC system, we propose a functional interaction between the igaA gene product and either the Rcs regulatory network or one of its regulated products.     

Molecular interactions in the hydrogen belts of membranes glucose-6-phosphatase,lysophosphatidylcholine, and cholesterol

Microsomal glucose-6-phosphatase from rat liver is activated by phosphatidylcholine but inhibited by lysophosphatidylcholine. Inhibition occurs not by membrane lysis but in an intact bilayer; it is reversible; and it is overcome by addition of cholesterol but not if the cholesterol-hydroxyl group is blocked. An analog of lysophosphatidylcholine deprived of hydrogen bonding sites, 1-ether-2-deoxylysophosphatidylcholine, is a partial activator, and its effect on the enzyme in a phosphatidylcholine bilayer is not modulated by cholesterol. It appears to be one of the functions of cholesterol to buffer the lysophospholipids in membranes by complexing with them through hydrogen bonding in the hydrogen belt region. Lysophosphatidylcholine/cholesterol association is favored over phosphatidylcholine/cholesterol association.     

Metabolite-controlled phosphorylation of hepatic phosphofructokinase proceeds by cAMP-dependent protein kinase

In hepatocytes 32P-incorporation into rat liver phosphofructokinase is stimulated by glucose as well as by glucagon, the effects of both stimuli being prevented by L-alanine [Eur. J. Biochem. (1982) 122, 175]. The phosphopeptides of the enzyme derived from limited proteolysis by subtilisin and from exhaustive tryptic digestion were analyzed either by one-dimensional mapping on sodium dodecyl sulphate-polyacrylamide slab gels and by fingerprint mapping, respectively. It is shown that in vivo stimulation of 32P-incorporation by glucose or by glucose plus glucagon results in identical phosphopeptide maps, and that these maps were identical with those obtained from phosphofructokinase phosphorylated in vitro with catalytic subunit of cAMP-dependent protein kinase. It is concluded that in the intact liver cell phosphofructokinase is phosphorylated by cAMP-dependent protein kinase but that the state of phosphorylation is modified by metabolite control.     

Uptake of galactose and lactose by Kluyveromyces lactis: biochemical characteristics and attempted genetical analysis

Study of the lactose and galactose transport systems in Kluyveromyces lactis has shown that lactose uptake is by active transport. The transport system is under monogenic control and is inducible. Galactose uptake is also by active transport but the system is controlled by two genes which, in the four strains we studied, are present only in K. lactis CBS 2359. Galactose uptake in the other K. lactis strains is by a simple diffusion process.     

Downregulation of VRK1 by p53 in response to DNA damage is mediated by the autophagic pathway

Human VRK1 induces a stabilization and accumulation of p53 by specific phosphorylation in Thr18. This p53 accumulation is reversed by its downregulation mediated by Hdm2, requiring a dephosphorylated p53 and therefore also needs the removal of VRK1 as stabilizer. This process requires export of VRK1 to the cytosol and is inhibited by leptomycin B. We have identified that downregulation of VRK1 protein levels requires DRAM expression, a p53-induced gene. DRAM is located in the endosomal-lysosomal compartment. Induction of DNA damage by UV, IR, etoposide and doxorubicin stabilizes p53 and induces DRAM expression, followed by VRK1 downregulation and a reduction in p53 Thr18 phosphorylation. DRAM expression is induced by wild-type p53, but not by common human p53 mutants, R175H, R248W and R273H. Overexpression of DRAM induces VRK1 downregulation and the opposite effect was observed by its knockdown. LC3 and p62 were also downregulated, like VRK1, in response to UV-induced DNA damage. The implication of the autophagic pathway was confirmed by its requirement for Beclin1. We propose a model with a double regulatory loop in response to DNA damage, the accumulated p53 is removed by induction of Hdm2 and degradation in the proteasome, and the p53-stabilizer VRK1 is eliminated by the induction of DRAM that leads to its lysosomal degradation in the autophagic pathway, and thus permitting p53 degradation by Hdm2. This VRK1 downregulation is necessary to modulate the block in cell cycle progression induced by p53 as part of its DNA damage response.     

Ultrastructure of the anterior alimentary tract of a monogenean, Diclidophora merlangi

The anterior alimentary tract of Diclidophora merlangi is composed of a complex series of morphologically distinct epithelia interconnected by septate desmosomes and penetrated by the openings of numerous unicellular glands. The mouth and buccal cavity are lined by an infolding of modified body tegument, distinguished by uniciliate sense receptors, buccal gland openings, and in the buccal region by a dense, spiny appearance. The prepharynx is covered by an irregularly folded epithelium and, for part of its length, by the luminal cytoplasm of the prepharyngeal gland cells. The epithelium is syncytial and pleiomorphic, and regional variation in structure is common. A separate epithelium invests the lips of the pharynx and its free surface is greatly amplified by numerous, dense lamellae of varying dimensions. The lip epithelium is continuous with cytoplasmic processes of cells located external to the pharynx. A further, distinct epithelium borders the pharynx lumen and is composed of discrete cytoplasmic units connected by short septate desmosomes. The oesophagus is lined by a modified caecal epithelium, lacking haematin cells, and, in places, is perforated by the openings of oesophageal gland cells; it is continuous with the syncytial connecting tissue of the gut caeca.     

Dual regulation of adenylate cyclase and guanylate cyclase: alpha 2-adrenergic signal transduction in adrenocortical carcinoma cells

Isolated adrenocortical carcinoma cells of rat contain alpha 2- and beta-adrenergic receptors. When these cells are incubated with alpha 2-adrenergic agonists, there is a concentration-dependent increase of cyclic GMP that is blocked by the alpha 2-adrenergic antagonist yohimbine but not by the beta-antagonist propranolol. Concomitantly, both p-aminoclonidine (20 microM) and clonidine (100 microM), the alpha 2-adrenergic agonists, stimulate membrane guanylate cyclase activity. In calcium free medium there is no alpha 2-agonist-dependent increase in cyclic GMP. Isoproterenol, a beta-agonist, and forskolin cause an increase in cyclic AMP but not cyclic GMP. The cyclic AMP increase induced by isoproterenol is blocked by propranolol but not by yohimbine. Isoproterenol- and forskolin-dependent increases in cyclic AMP are inhibited by p-aminoclonidine and the inhibition is relieved by yohimbine. These results indicate a dual regulation of guanylate cyclase and adenylate cyclase by the alpha 2-receptor signal: guanylate cyclase is coupled to the receptor in a positive fashion, whereas adenylate cyclase is coupled in a negative fashion. Calcium is obligatory in the cyclic GMP-mediated response.     

Development of hormonal regulation of ion transport in embryonic chick red cells

We have found that cation transport in red cells from chick embryos is stimulated by the hormone epinephrine and that this response develops as the embryonic definitive cells mature. Sodium efflux and potassium influx are significantly stimulated (50%) by epinephrine in red cells from embryos incubated ten days or longer, whereas cation fluxes in erythroid cells from 8- or 9-day embryos are stimulated little or not at all. The effect of epinephrine may be mediated by cyclic AMP as adenylate cyclase activity in membranes isolated from embryonic red cells is only slightly stimulated at nine days, but the response increases as the cells mature to a maximum of about 180%. Also the stimulation of cation transport by epinephrine is blocked by propranolol, but not by phentolamine. Although the younger cells respond poorly to epinephrine, cyclic AMP significantly stimulates transport. The enhancement of cation fluxes by epinephrine or cyclic AMP occurs even in the presence of ouabain. Since both K influx and Na efflux are enhanced by these agents, their action is most likely on some form of the “Na-K” pump which is not ouabain sensitive resulting in a significant increase in the maximum velocity of the pump. We suggest the hypothesis that there are two classes of “Na-K” pump in these embryonic cells. One pump is similar to that found in many erythrocytes including mammalian cells in that it selectively pumps potassium in and sodium out, is ouabain-sensitive, and is primarily involved in maintaining intracellular cation concentrations. The second pump is enhanced by epinephrine via cyclic AMP, is not inhibited by ouabain, and may have lower ion selectivity. This hormone sensitive pump activity is lost as the cells mature, a process which is completed when the animal is fully grown and no longer has significant numbers of embryonic cells in its circulation.     

Endotoxin-induced zinc accumulation by liver cells is mediated by metallothionein synthesis

Endotoxin induces a decrease in zinc concentration in the serum and an increase in zinc levels in the liver. We have studied whether metallothionein (MT), which is a heavy metal-binding protein, is associated with this phenomenon in vitro. When MT of liver cells is induced by a factor secreted by endotoxin-stimulated macrophages, the cells accumulate zinc from the medium. The temporal accumulation of zinc is correlated with the induction of MT, and the accumulated zinc binds to MT. These results suggest that zinc accumulation by liver cells is mediated by metallothionein produced in response to a macrophage factor, which is elicited by endotoxin.