The Pro to glycine mutation of staphylococcal nuclease simplifies the unfolding—folding kinetics

Kinetics of unfolding and refolding of a staphylococcal nuclease mutant, in which Pro¹¹⁷ is replaced by glycine, have been investigated by stopped-flow circular dichroism, and the results are compared with those for the wild-type protein. In contrast to the biphasic unfolding of the wild-type nuclease, the unfolding of the mutant is represented by a single-phase reaction, indicating that the biphasic unfolding for the wild-type protein is caused by cis-trans isomerization about the prolyl peptide bond in the native state. The proline mutation also simplifies the kinetic refolding. Importance of the results in elucidating the folding mechanism is discussed.     

Putting the heat on sex determination

Sex determination and differentiation are inherently fascinating to both layperson and geneticist. Major advances have accelerated interest in the molecular genetic events mediating these processes in nematodes, flies, mice and humans. Far less attention has been paid to those organisms, particularly reptiles, where sex is determined by environmental cues. However, recent experimental evidence suggests that the two modes of sex determination may not only share common genetic elements, but may also be regulated by similar mechanisms. We argue that the ability to manipulate sex by temperature provides a particularly suitable model for exploring the molecular basis of this fundamental biological process.     

Expression of a chimeric CaMV 35S Bacillus thuringiensis insecticidal protein gene in transgenic tobacco

Insecticidal transgenic tobacco plants containing a truncated Bacillus thuringiensis cryIA(b) crystal protein (ICP) gene expressed from the CaMV 35S promoter were analyzed for ICP gene expression under field and greenhouse conditions over the course of a growing season. We present new information on temporal and tissue-specific expression of a CaMV 35S/cryIA(b) gene. Levels of cryIA(b) protein and mRNA were compared in both homozygous and hemizygous lines throughout plant development. Levels of ICP mRNA and protein increased during plant development with a pronounced rise in expression at the time of flowering. Homozygous ICP lines produced higher levels of ICP than the corresponding hemizygous lines. ELISA analysis of different tissues in the tobacco plant showed ICP gene expression in most tissues with a predominance of ICP in older tissue. All transgenic ICP tobacco lines which were studied in the field and greenhouse contained 400 ng to 1 g ICP per gram fresh weight in leaves from the mid-section of the plant at flowering. The amounts of ICP produced by field lines were directly comparable to levels observed in greenhouse-grown plants.     

Persistence of Cell Division Synchrony in Spirogyra Insignis (Gamophyceae): Membrane Proteoglycans Transmitting Synchronizing Information Throughout Generations

Spirogyra insignis shows a long-term persistence of cell division synchrony in the absence of the synchronizing Zeitgeber, so that at least six generations are involved in the process. This tentatively suggests that a mechanism of transmission throughout generations of synchronizing information could maintain this synchrony. Apparently, a vital part of the molecular basis of this mechanism is a membrane proteoglycan complex. This complex could obtain temporal information from a synchronizing Zeitgeber and be transmitted to the progeny by distribution of plasma membrane between daughter cells.     

Benzylic alcohols as stereospecific substrates and inhibitors for aryl sulfotransferase

Aryl sulfotransferase IV catalyzes the 3'-phosphoadenosine-5'-phosphosulfate (PAPS)-dependent formation of sulfuric acid esters of benzylic alcohols. Since the benzylic carbon bearing the hydroxyl group can be asymmetric, the possibility of stereochemical control of substrate specificity of the sulfotransferase was investigated with benzylic alcohols. Benzylic alcohols of known stereochemistry were examined as potential substrates and inhibitors for the homogeneous enzyme purified from rat liver. For 1-phenylethanol, both the (+)-(R)- and (-)-(S)-enantiomers were substrates for the enzyme, and the kcat/Km value for the (-)-(S)-enantiomer was twice that of the (+)-(R)-enantiomer. The enzyme displayed an absolute stereospecificity with ephedrine and pseudoephedrine, and with 2-methyl-1-phenyl-1-propanol; that is, only (-)-(1R,2S)-ephedrine, (-)-(1R,2R)-pseudoephedrine, and (-)-(S)-2-methyl-1-phenyl-1-propanol were substrates for the sulfotransferase. In the case of 1,2,3,4-tetrahydro-1-naphthol, only the (-)-(R)-enantiomer was a substrate for the enzyme. Both (+)-(R)-2-methyl-1-phenyl-1-propanol and (+)-(S)-1,2,3,4-tetrahydro-1-naphthol were competitive inhibitors of the aryl sulfotransferase-catalyzed sulfation of 1-naphthalenemethanol. Thus, the configuration of the benzylic carbon bearing the hydroxyl group determined whether these benzylic alcohols were substrates or inhibitors of the rat hepatic aryl sulfotransferase IV. Furthermore, benzylic alcohols such as (+)-(S)-1,2,3,4-tetrahydro-1-naphthol represent a new class of inhibitors for the aryl sulfotransferase.     

Calmodulin structure and function: Implication of arginine in the compaction related to ligand binding

Calmodulin (CAM) is a modulatory protein that regulates cellular activity by binding to a large number of proteins. Key elements in the Ca²⁺-dependent mechanism of interaction between CAM and the proteins it activates are the selectivity for Ca²⁺ ions and the requirement for Ca²⁺-dependent conformational changes. We report on results from a series of molecular dynamics simulations that identified discrete steps in the mechanism of structural rearrangement of CAM. The findings implicate the side chains of arginine residues in the bending of the central alpha helix. Structural and energetic considerations point to a dynamic hydrogen bonding pattern around the arginine residues as a ratcheting-type mechanism, causing the kinking of the central helix in consecutive steps stabilized by each new pattern of hydrogen bonds. Initial model building studies to locate potential binding sites of ligands such as trifluoperazine (TFP) indicate that the compaction of CAM results in several structural changes, that explain the selective binding of molecules such as TFP in the N-terminal domain. The present studies identify specific residues involved in the process of compaction and point to specific CAM residues involved in the binding of the ligand. These insights lead directly to propositions for experimental engineering of the molecular structure of CAM in order to probe the hypotheses and their consequences for the function of this important protein.     

Differential effects of paraoxon on the M3 muscarinic receptor and its effector system in rat submaxillary gland cells

The effects of the organophosphorus anticholinesterase paraoxon on the binding of radioactive ligands to the M₃ subtype of the muscarinic receptor and receptor-coupled synthesis of second messengers in intact rat submaxillary gland (SMG) cells were investigated. The binding of [³H]quinuclidinyl benzilate ([³H]QNB) was most sensitive to atropine and the M₃-specific antagonist 4-DAMP followed by pirenzepine and least sensitive to the cardioselective M₂ antagonist AFDX116. This, and the binding characteristics of [³H]4-DAMP, confirmed that the muscarinic receptors in this preparation are of the M₃ subtype. Activation of these muscarinic receptors by carbamylcholine (CBC) produced both stimulation of phosphoinositide (PI) hydrolysis and inhibition of cAMP synthesis, suggesting that this receptor subtype couples to both effector systems. Paraoxon (100 μM) reduced B_max of [³H]4-DAMP binding from 27 ± 4 to 13 ± 3 fmol/mg protein with nonsignificant change in affinity, suggesting noncompetitive inhibition of binding by paraoxon. Like the agonist CBC, paraoxon inhibited the forskolininduced cAMP formation in SMG cells with an EC₅₀ of 200 nM, but paraoxon was > 500 fold more potent than CBC. However, while the inhibition by CBC was counteracted by 2 μM atropine, that by paraoxon was unaffected by up to 100 μM atropine. It suggested that this effect of paraoxon was not via binding to the muscarinic receptor. Paraoxon did not affect β-adrenoreceptor function in the preparation, since it did not affect the 10 μM isoproterenol-induced cAMP synthesis, which was inhibited totally by 10 μM propranolol and partially by CBC. Paraoxon had a small but significant effect on CBC-stimulated PI metabolism in the SMG cells. It is suggested that paraoxon binds to two different sites in these SMG cells. One is an allosteric site on the M₃ muscarinic receptor which affects ligand binding and may modulate receptor function. The other site may be on the G_i proteinadenylyl cyclase system, and produces CBC-like action, that is, inhibition of the forskolin-stimulated [³H]cAMP synthesis, and is unaffected by atropine inhibition of the muscarinic receptor. This adds to the complexity of paraoxon actions on muscarinic receptors and their effector systems.     

Eating, drinking and temperature responses to intracerebroventricular cholecystokinin in the chick

The central effect of cholecystokinin-octapeptide (CCK), SQ 19,844 or sincalide, on the intake of food and water and on colonic temperature (Tc) was investigated using the broiler cockerel. Four-week old chicks were maintained in a thermoneutral environment of 23-24 degrees C. After food was removed for a 24 hr interval, CCK was infused in a volume of 10.0 microliters into the lateral cerebral ventricle (ICV) in doses ranging from 10-150 ng. Although lower doses of CCK had no effect on food intake, 100 or 150 ng of CCK significantly reduced consumption of food in a dose-dependent manner; water drinking was significantly decreased by 100 ng of CCK. In addition, CCK at doses of 100 and 150 ng prevented the slow rise in Tc observed following infusions of control CSF. This latter effect appeared to be a result of feeding activity associated with caloric intake and the heat increment in the control birds rather than a specific thermoregulatory effect. Overall, our results suggest that CCK may comprise a part of the central mechanism underlying the neural control of short term satiety in an avian species similar to that proposed for the mammal.     

Evidence for a two-state mobile carrier mechanism in erythrocyte choline transport: Effects of substrate analogs on inactivation of the carrier by N-ethylmaleimide

Summary Choline transport in erythrocytes is irreversibly inhibited by N-ethylmaleimide. The hypothesis that the carrier alternates between outwardfacing and inward-facing forms and that only the latter reacts with the inhibitor (Martin, K. (1971)J. Physiol. (London) 213:647–667; Edwards, P.A. (1973)Biochim. Biophys. Acta 311:123–140) is here subjected to a quantitative test. In this test the effects of a series of substrate analogs upon rates of inactivation and rates of choline exit are compared. By hypothesis the effect of an analog in the external solution on the inactivation rate depends only on how it affects the proportion of the inward-facing carrier. Since¹⁴C-choline efflux is necessarily proportional to the concentration of free carrier in the inward-facing form, the analogs should have related effects on the two rates. In every case the observed effects were identical, whether the analogs accelerated transport or inhibited it. Analysis of the results demonstrates that (1) the transport mechanism depends on the operation of a mobile element; (2) distinguishable inward-facing and outward-facing conformations of the free carrier, carrier-substrate complex, and carrier-inhibitor complex exist, and only the inwardfacing forms react at a significant rate with N-ethylmaleimide; (3) carrier mechanisms involving a single form of free carrier or a single form of carriersubstrate complex are ruled out; and (4) dissociation of the carrier-substrate complex is a rapid step with all substrate analogs.