Individual differences in achievement goals among young children.

Developmental research has generally not found evidence of helpless responses to failure in young children; a prevailing view is that young children lack the cognitive prerequisite for helplessness. However, recent evidence suggests that even preschoolers are vulnerable to helplessness in some situations. In the present study with 4- and 5-year-olds, we tested a goal-confidence model that predicts achievement behavior during failure for older children. We first categorized preschoolers' orientations toward "learning" or "performance" goals based on their preference for a challenging or nonchallenging task. As for older children, goal orientation was independent of ability and predicted cognitions and emotions during failure. Further, consistent with the model, within a learning goal, children displayed the mastery-oriented pattern regardless of confidence level, whereas within a performance goal, children with low confidence were most susceptible to helplessness. These behavior patterns were found on a second task as well. Thus, our findings show that individual differences in achievement goals emerge very early.

Receptor-specific threshold effects of cyclic AMP are involved in the regulation of enzyme release and superoxide production from human neutrophils.

We have investigated the sequence of events leading from the activation of adenylate cyclase and increases in intracellular cyclic AMP to the modulation of enzyme release and superoxide production in human neutrophils. In the isolated plasma membrane, adenylate cyclase is activated by both prostaglandin E1 and isoproterenol. In the whole cell only a small increase in cyclic AMP is observed, though in the presence of the phosphodiesterase inhibitor, methylisobutylxanthine a substantial amplification in intracellular cyclic AMP is observed with both isoproterenol and prostaglandin E1. These conditions are relevant to the regulation of cell function, since fMet-Leu-Phe-stimulated superoxide production is inhibited by either prostaglandin E1 or isoproterenol in the absence of methylisobutylxanthine, while enzyme release is inhibited only via the prostaglandin E1 receptor and then only in the presence of methylisobutylxanthine. For enzyme release and superoxide production, the order of potency for three prostaglandins tested was prostaglandin E1 greater than prostaglandin D2 much greater than prostaglandin F2 alpha. Our results suggest that (a) superoxide production is more sensitive to regulation by cyclic AMP than enzyme release, (b) the type of receptor occupied as well as the threshold level of cyclic AMP attained are important to the regulation of enzyme release, and (c) although elevation in cyclic AMP is inhibitory to neutrophil function, phosphodiesterase inhibition is required in addition to adenylate cyclase activation to effect maximal inhibition.

Regulation of human neutrophil guanylate cyclase by metal ions, free radicals and the muscarinic cholinergic receptor.

We have examined the properties of soluble guanylate cyclase activity in the human neutrophil. The enzyme showed complex regulation by metal ions. A 10-fold higher activity was observed in the presence of Mn2+ than Mg2+, while Ca2+ caused an increase in activity only in the presence of Mg2+ ion. Sodium nitroprusside (SNP), azide and hydrogen peroxide were activators of the enzyme. Dithiothreitol blocked the activation by SNP, suggesting the involvement of thiol groups in the activation process. Carbachol acting through the muscarinic cholinergic receptor caused a dose-dependent activation, which was blocked by atropine. Higher concns of carbachol were required to activate guanylate cyclase than were required for the modulation of enzyme release elicited by N-formyl-L-methionyl-L-leucyl-L-phenylalanine. Nordihydroguaracetic acid inhibited carbachol stimulation of guanylate cyclase. By contrast, trifluoperazine (TFP), a calmodulin antagonist, caused a biphasic modulation of basal activity in the presence or absence of carbachol. Our results indicate that: allosteric interactions of metal ions are important to the regulation of the enzyme, the free radical nitroxide as well as hydrogen peroxide enhances enzyme activity, agonist occupancy of the muscarinic cholinergic receptor activates neutrophil guanylate cyclase probably through a mechanism involving calcium influx and the activation of the lipoxygenase pathway, and a TFP-sensitive site (possibly calmodulin) is involved in the selective regulation of basal enzyme activity.

Human platelet adenylate cyclase: persistent binding of guanine nucleotide is central to the regulation of both hormone-stimulated and basal activities.

Prostaglandin E1 stimulation of human platelet adenylate cyclase, in purified plasma membranes, occurs without the addition of exogenous GTP. Possible contamination of the adenylate cyclase assay mixture by GTP either from nonspecifically bound nucleotide in the plasma membrane or from the substrate ATP was ruled out as follows: (a) variation of the membrane concentration, repeated washing, inclusion of EDTA, GDP beta S, or GMP in the wash step, or UDP in the assay, are all without effect, and (b) analysis of the substrate by high-performance liquid chromatography revealed no contaminating GTP. Other prostaglandins (I2, E2, D2) also activate cyclase without the addition of GTP. In sharp contrast, stimulation of adenylate cyclase in the human neutrophil plasma membrane by prostaglandin E1 shows an obligatory requirement for GTP, under identical assay conditions. GDP beta S pretreatment amplifies the fold cyclase stimulation by GTP in the presence and absence of prostaglandin E1, by lowering the basal activity. This alteration occurs without lowering the GTP-independent prostaglandin E1 activation, and is specific for inhibitory guanine nucleotides (GDP beta S, GMP, GDP) in the pretreatment. Extensive washing with buffer or incubation with other nucleotides, epinephrine, or prostaglandin E1 prior to the assay, is without effect. GTP gamma S treatment of the membrane induces a high-activity state and abolishes the GDP beta S effect on basal activity as well as prostaglandin E1 activation of cyclase. The results suggest distinct patterns of prostaglandin stimulation in platelet and neutrophil cyclase systems, and further imply that guanine nucleotide, prebound to specific sites within the GTP-regulatory proteins, may modify the kinetic characteristics of platelet adenylate cyclase.

Association of the N-formyl-Met-Leu-Phe receptor in human neutrophils with a GTP-binding protein sensitive to pertussis toxin.

Pertussis toxin inhibits the N-formyl-Met-Leu-Phe (fMet-Leu-Phe) mediated human neutrophil functions of enzyme release, superoxide generation, aggregation, and chemotaxis. As pertussis toxin modifies the GTP binding receptor-regulatory protein "Ni," the association of the fMet-Leu-Phe receptor with such a protein was further examined in purified neutrophil plasma membranes. Both fMet-Leu-Phe-mediated guanine nucleotide exchange and nucleotide-mediated regulation of the fMet-Leu-Phe receptor are inhibited by pertussis toxin. In addition, membrane pretreatment with pertussis toxin abolishes the fMet-Leu-Phe-mediated inhibition of adenylate cyclase. Actions of pertussis toxin are due to the ADP-ribosylation of a single subunit at 41 kDa in the neutrophil plasma membrane, which comigrates on NaDodSO4 gels with the Ni GTP-binding protein in the platelet plasma membrane. Our results suggest that (i) the fMet-Leu-Phe receptor is associated with a Ni GTP regulatory protein, and (ii) a fMet-Leu-Phe-Ni complex is important in the control of several neutrophil functions, probably involving multiple transduction systems, including adenylate cyclase.

Identification of receptor regulatory proteins, membrane glycoproteins, and functional characteristics of adenylate cyclase in vesicles derived from the human neutrophil.

Human neutrophils were disrupted by brief sonication under conditions which preserve the hormone sensitivity of adenylate cyclase and yield minimal granule lysis. Fractions enriched in adenylate cyclase were analysed for hormonal and guanine nucleotide regulation of the enzyme as well as structural proteins. Adenylate cyclase was activated by PGE1 and isoproterenol in a GTP-dependent fashion, while f-met-leu-phe and C5a gave no stimulation. Cholera toxin treatment, which specifically modifies cyclase-related GTP-binding proteins, caused a dose-dependent enhancement of GTP activation, in which GTP alone activated maximally and PGE1 was without further effect. The following proteins were detected in the cyclase-containing vesicles: a 42 K mol. wt protein labeled selectively by cholera toxin; protein subunits observed in SDS gels at 214, 165, 105 and 47 K, of which the 47 K band was the most prominent and comigrated with actin; prominent lectin-binding activities at 165 K (concanavalin A and wheat germ agglutinin) as well as at 100 K (wheat germ agglutinin); and a set of proteins and lectin-binding activities in fractions containing beta-glucuronidase activity distinct from adenylate cyclase containing vesicles. The identification of receptor-controlled cyclase, GTP-binding regulatory proteins, cytoskeletal elements and unique lectin-binding activities in a single vesicle preparation should contribute to an understanding of receptor-mediated control of neutrophil function.

The beta-adrenergic receptor in the human neutrophil plasma membrane: receptor-cyclase uncoupling is associated with amplified GTP activation.

We compared the properties of the adenylate cyclase system in plasma membranes derived from gas cavitation and sonication of human neutrophils. In membranes prepared from cavitated cells, cyclase was stimulated by fluoride ion and Gpp(NH)p. Stimulation by isoproterenol (and PGE1) was absent, although the beta-receptor was present as judged by 125I-HYP binding. Two unusual characteristics of this cyclase system are a) substantial activation of cyclase by GTP in the absence of hormone, and b) reduction in the regulation of the beta-receptor by GTP. By contrast, vesicles isolated from sonicated cells displayed normal GTP-dependent activation by isoproterenol (as well as PGE1) and GTP regulation of the beta-receptor, while hormone-independent stimulation by GTP was negligible. Cholera toxin-catalyzed ADP ribosylation revealed a prominent band at 42K in both membranes, and a minor band at 35K, although the degree of labeling of this protein was lower in the "cavitated" vesicles. Our results suggest that the mode of cell lysis and membrane preparation influence receptor-cyclase interactions and that receptor-cyclase uncoupling is associated with amplified GTP activation and altered receptor regulation by GTP.

Ligand requirements for the relaxation of adenylate cyclase from activated and inhibited states.

The turkey erythrocyte adenylate cyclase system binds tightly the inhibitory nucleotide GDP, and a pretreatment step with isoproterenol and GMP is required to restore activation. Under identical pretreatment conditions, the release of labeled nucleotide is complete within 1 min whereas the restoration of activation by Gpp(NH)p requires 15 min. A study of the ligand requirements of the slow step shows the following: (a) The role of GMP is that of an obligatory allosteric regulator. (b) Cholera toxin modification of the system abolishes the requirement for GMP with a considerable enhancement in the reaction rate. (c) GMP is without effect on the relaxation process with the activator Gpp(NH)p as the resident nucleotide. In sharp contrast, ethylenediamine-tetraacetic acid (without effect in a GDP-occupied complex) markedly potentiates alterations from the Gpp(NH)p-occupied state. (d) Formation of a GDP/guanosine 5'-O-(2-thiodiphosphate) (GDP beta S) hybrid leads to the suppression of both F- and Gpp(NH)p activation. F- activation is restored by isoproterenol alone, while GMP is still required to restore Gpp(NH)p activation. The results suggest that covalent modification or nucleotide analogue occupancy of the regulatory complex can modify the allosteric role for GMP, with consequences for the rate of the slow step.