Cations, enzymes and control of cell metabolism

Plasmodium falciparum DDX3X is a nucleocytoplasmic protein and requires N-terminal for DNA helicase activity

Malaria is a haemato-protozoan disease which causes thousands of deaths every year. Due to the alarming increase of drug resistant strains of P. falciparum, malaria is now becoming more deadly. Helicases are the most important components of the cellular machinery without which cells are unable to survive. The importance of helicases has been proven in variety of organisms. In this study we have reported detailed biochemical characterization of human homologue of DDX3X from Plasmodium falciparum (PfDDX3X). Our study revealed that PfDDX3X is ATP- dependent DNA helicase whereas in human host it is ATP-dependent RNA helicase. We show that N-terminal is essential for its activity and it is present in nucleus and cytoplasm in intraerythrocytic developmental stages of P. falciparum 3D7 strain. Also, it is highly expressed in the schizont stage of P. falciparum 3D7strain. The present study suggests that a protein can perform different functions in different systems. The present study will help to understand the basic biology of malaria parasite P. falciparum.

Antagonistic effect of insulin on glucagon-evoked hyperpolarization. A correlation between changes in membrane potential and gluconeogenesis

In the perfused rat liver, administration of glucagon causes a hyperpolarization of the liver cell membrane and increases gluconeogenesis. Insulin, a hormone which is known to antagonize the effect of glucagon on gluconeogenesis also blocks the hyperpolarizing effect of glucagon. Because of this inhibitory effect of insulin of the glucagon-evoked hyperpolarization, a systematic study of possible correlation between changes in membrane potential and gluconeogenesis was undertaken. The membrane potential was changed by valinomycin, tetracaine, or by varying the ionic composition of the perfusate. A highly significant correlation between changes in membrane potential and the rate of gluconeogenesis was noticed. The possibility was raised that changes in membrane potential might exert an influence on metabolic process by a yet unknown mechanism.

Calcium ion as second messenger

The role of calcium as an intracellular messenger in the activation of eukaryotic cells is discussed. Particular emphasis is devoted to: (1) the interrelationship between cell activation by chemical stimuli and alterations in intracellular calcium metabolism, and (2) the interrelated roles of calcium and the cyclic nucleotides, cyclic AMP and cyclic GMP, in achieving the final integrated, co-ordinated cellular response.

Bacitracin production by the neotype; bacillus licheniformis ATCC 14580

A small but significant bacitracin production has been observed in the neotype Bacillus licheniformis ATCC 14580. This strain produces bacitracin only during the phase of rapid growth. The bacitracin production ceases before growth is completed, and the relationship between growth and antibiotic production was not influenced by different environmental conditions. The maximum titre produced by the neotype strain was about 1 i.u. bacitracin/ml. This maximum titre was not influenced by the environmental conditions which resulted in a great variability of the maximum titre of the known bacitracin producer Bacillus licheniformis ATCC 10716. In contrast to B. licheniformis ATCC 10716, the bacitracin production of the neotype B. licheniformis ATCC 14580 was not stimulated by Mn(II)ions. It is suggested that bacitracin may be incidentally overproduced by certain strains grown in certain environments. The controlled bacitracin production by the neotype is not consistent with the definition of secondary metabolites and the hypothesis concerning the function of secondary metabolites after growth of the producer organisms.

On the function of the polypeptide antibiotic bacitracin in the producer strain Bacillus licheniformis

The growth of the bacitracin producing strain Bacillus licheniformis AL and the bacitracin-negative mutant SB 319 have been compared at different cultural conditions. Concentrations of the metal chelator EDTA which strongly inhibited the growth of the non-producer only slightly inhibited the growth of the bacitracin producer. The inhibitory effect of EDTA upon SB 319 was reversed by the addition of excess manganese(II)ions, cobalt(II)ions, or zinc(II)ions to the culture. The addition of several other ions had no such effect. The addition of bacitracin to the EDTA inhibited mutant also promoted growth. When the non-producer was mutated back to bacitracin production, the inhibitory effect of EDTA was lost. It is suggested that bacitracin may normally promote the uptake of several trace metals during growth of the producer organism.

Ionic dependence of adrenal steroidogenesis and ACTH-induced changes in the membrane potential of adrenocortical cells

1. The effects of changes of ionic environment upon corticosteroid production by rabbit adrenal glands have been investigated in vitro using a superfusion technique and on-line steroid analysis by an automated fluorescence method. In some experiments micro-electrode recordings of adrenocortical transmembrane potentials were made concomitantly with measurement of steroid output.2. Adrenocorticotrophic hormone (ACTH), 10 m-u./ml., induced a sevenfold increase in corticosteroid production rate in normal Krebs solution.3. The steroidogenic response to ACTH was not impaired after omission of [K](o) for 1 hr but was inhibited following exposure to K(+)-free medium for 3 hr. Increase of [K](o) tenfold to 47 mM increased the basal but not the ACTH-stimulated output of corticosteroid whereas raising [K](o) twentyfold to 94 mM enhanced both the basal and ACTH-stimulated steroid production rate. In K(+)-free solution the adrenocortical cells hyperpolarized from - 67 to - 86 mV; subsequently on addition of ACTH they depolarized. Reintroduction of K(+) restored the membrane potential.4. Omission of Ca(2+) partially depolarized the cells but only affected the steroidogenic response to ACTH in the presence of EDTA. A threefold increase of [Ca](o), to 7.68 mM, had no effect on either membrane potentials or steroid formation, but increasing [Ca](o) tenfold to 25.6 mM partially blocked ACTH action. Increasing [Mg](o) twentyfold to 22.6 mM had little effect on ACTH-stimulated corticosteroid output and Sr 2.56 mM, in substitution for Ca(2+), supported ACTH action, but La, 0.25 mM, completely blocked the steroidogenic effect of ACTH.5. Replacement of NaCl, 118 mM by choline chloride, 118 mM, was without effect on ACTH-induced steroidogenesis, whereas LiCl, 118 mM, reduced it by 50%. NaF, 1 and 10 mM, inhibited ACTH-induced steroidogenesis by approximately 60%.6. Nupercaine, 10(-4)M, inhibited the steroid response to ACTH with no effect upon membrane potentials: increasing the nupercaine concentration to 10(-3)M inhibited the steroid response and depolarized the cells. Ouabain, 10(-5)M, induced complete depolarization and suppression of the steroidogenic response to ACTH.7. Action-potential-like changes in membrane potential appeared in cells exposed to ACTH in a K(+)-free medium. The amplitude of the action potentials ranged from 10 to 60 mV according to cell, with a frequency up to 36/min; the frequency tended to increase with time. Tetrodotoxin, 10(-6) g/ml., did not inhibit ACTH-induced action potentials in K(+)-free medium.8. These observations are discussed in relation to the ionic requirements for the steroidogenic action of ACTH. The results further emphasize the dissociation of membrane polarization and the secretion of steroid. The mechanism of output of steroid hormone from the adrenocortical cell may thus differ fundamentally from the secretory mechanisms in other, particle-storing cells.