The Contractile and Control Sites of Natural Actomyosin

The various contractile and control sites of natural actomyosin gel were studied by comparing the kinetics of ATP hydrolysis with those of gel contraction, measured as an increase in turbidity. Contraction of actomyosin gel seems to require the cooperative reaction of ATP (with Mg) at two different sites. One of these sites catalyzes the hydrolysis of ATP and most probably contributes the driving force for contraction; the binding of ATP to the other site appears to break certain links that retard movement of the gel components. At limiting concentrations of ATP, the rate of contraction seems to depend on the rate of breaking these links as well as on the rate of ATP hydrolysis. But when both sites are saturated, the rate of contraction appears to be limited only by the rate of ATP hydrolysis. In addition to these two contractile sites, there are also two different control sites. At one, the relaxing site, the binding of ATP with Mg inhibits ATP hydrolysis and gel contraction. At the other, the binding of calcium activates contraction by overcoming the inhibitory action of Mg and ATP at the relaxing site. This control system—inhibition by substrate and disinhibition by calcium—can be selectively inactivated by heat and reactivated by dithiothreitol, a disulfide-reducing agent. These observations on the isolated contractile system are discussed in relation to the contraction and relaxation of muscle.     

Immobilization of Escherichia coli JM103[pUC8] in kappa-carrageenan coupled with recombinant protein release by in situ cell membrane permeabilization.

Immobilization of Escherichia coli JM103[pUC8] was carried out with kappa-carrageenan as the support matrix. Substantial natural excretion of beta-lactamase, attributable to the less intact membrane of plasmid-harboring cells, was observed in immobilized cell cultures. Nevertheless, a significant portion of the beta-lactamase produced was retained in the cells. As compared to suspension cultures, much higher beta-lactamase activities, especially in the extracellular liquid, and much longer retention of plasmid-bearing cells (improved plasmid stability) were observed in immobilized cell cultures. Further enhancement in excretion of the recombinant protein (beta-lactamase) was achieved by permeabilization of cell membrane by periodic exposure of the immobilized cell cultures to ethylenediaminetetraacetic acid (EDTA). While the presence of EDTA led to some suppression of cell growth in suspension cultures, cell growth in gel beads was not affected by EDTA to the same extent, possibly due to lesser exposure of immobilized cells to EDTA. Exposure of immobilized cell cultures to EDTA presumably inhibited plasmid replication and led in turn to diversion of cellular resources for the support of expression of plasmid genes. Indeed, treatment of the immobilized cell cultures with EDTA resulted in increased production of beta-lactamase when compared to the enzyme production in EDTA-free cultures. More frequent addition of EDTA increased the period of retention of plasmid-bearing cells in these cultures but did not have any noticeable adverse effect on synthesis of beta-lactamase. Improvement in plasmid stability in EDTA-treated immobilized cell cultures was ascribed to the reduction in the growth rate differential between plasmid-free and plasmid-bearing cells, since plasmid-free cells were subject to more reduction in specific growth rate than were plasmid-bearing cells.     

Platelet activating factor (PAF) production by mouse embryos in vitro and its effect on embryonic metabolism

Factors affecting the production of platelet activating factor (PAF) by mouse embryos during culture in vitro were investigated. Detectable levels of embryo-derived PAF were produced within 1-4 hr with maximum PAF activity being observed after 6 hr of culture in vitro. The amount of PAF detected in media after 24 hr of culture of two-cell embryos was equivalent to 12.8 ng PAF/embryo. However, differences in activity were apparent with increased time in culture. Reduced synthesis of PAF during culture in vitro was supported by the observation that morulae stage embryos collected fresh from the reproductive tract displayed more PAF activity than morulae resulting from the 48 hr culture of two-cell embryos. In addition to determining production characteristics of PAF by embryos, we also show that the production of CO2 from carbon-1 position of lactate is positively correlated with the ability of embryos to develop during subsequent culture in vitro and therefore could be used as a measure of embryo viability. Furthermore, culture of embryos in media supplemented with PAF resulted in an increase in lactate utilization demonstrating a direct effect of PAF on the embryo. As PAF is produced by preimplantation embryos, an autocoid role of PAF in regulating embryo development is implicated. Therefore, the reduced production of PAF by embryos in vitro may explain the decreased viability of embryos commonly observed following their culture in vitro.     

Guanine nucleotide-dependent, pertussis toxin-insensitive regulation of phosphoinositide turnover by bradykinin in bovine pulmonary artery endothelial cells

In this paper we examine the effect of the vasodilator peptide bradykinin on endothelial cell regulation of phosphoinositide (PI) turnover. The data show that the activation of PI turnover by bradykinin in bovine pulmonary artery endothelial cells is insensitive to pertussis toxin, which ADP ribosylates a membrane protein of mol wt 40,000. However, this effect of bradykinin can be potentiated by guanosine 5'-O-(3-thio)triphosphate (GTP gamma S), an activator of G proteins, and depressed by guanosine 5'-O-(2-thio)diphosphate (GDP beta S), an inhibitor of G proteins. After endothelial cells were preincubated for 1 h with GTP gamma S, there was a three- to fourfold increase in PI turnover. Preincubation of cells with GDP beta S did not affect the basal level of PI turnover, but completely prevented activation of PI turnover by bradykinin. 4 beta-Phorbol-12 beta-myristate-13 alpha-acetate can block the bradykinin-stimulated inositol monophosphate formation in cultured endothelial cells. The effects of bradykinin on PI turnover were blocked by B2 antagonists but not by B1 antagonists. Taken together, these results indicate that in endothelial cells the bradykinin B2 receptor is coupled to phospholipase C via a G protein (or proteins) that is not a substrate for pertussis toxin (neither Gi nor Go).     

Maternal morbidity associated with in utero transfer.

OBJECTIVE--To determine the extent of maternal morbidity associated with in utero transfer. DESIGN--Retrospective study of 190 consecutive cases over two years. SETTING--Liverpool Maternity Hospital. PATIENTS--190 Pregnant women were transferred to the hospital under the in utero transfer arrangements from district general hospitals both within and outside the Mersey region. The women admitted were divided into two categories: those in threatened or established uncomplicated preterm labour and those who may or may not have been in threatened or established preterm labour but who had coexisting complicating factors affecting the mother or fetus, or both. INTERVENTIONS--Planned delivery of the fetus if indicated and arrangements for appropriate postpartum care of the mother. MAIN OUTCOME MEASURE--Assessment of the progress of labour and, if appropriate, resuscitation of the mother. RESULTS--Women who were transferred with no coexisting disease (124) had relatively uncomplicated deliveries whereas those transferred with coexisting diseases (66) exhibited considerable morbidity and 17 of these required prolonged intensive monitoring after delivery. CONCLUSIONS--In utero transfer in healthy mothers may have benefits for babies born very prematurely. If mothers have coexisting disease, however, the desirability of transfer should be reviewed urgently in the light of the considerable maternal morbidity associated with these problems. In these cases transfer may introduce an additional hazard.     

Oxidative metabolism of energy substrates by preimplantation mouse embryos in the presence of platelet-activating factor

The effects of exogenous platelet-activating factor (PAF, 0.0186-18.6 microM) on the production of CO2 from [U-14C]glucose and [1-14C]lactate by mouse embryos in vitro were investigated. Two-cell embryos displayed significant dose-dependent responses for both energy substrates. The maximal response was observed at 9.3 microM-PAF for glucose metabolism and 1.86 microM-PAF for lactate with increases of 62% and 18%, respectively, over control treatments. After culture from the 2-cell stage for 72 h in the presence of PAF, the resulting blastocysts exhibited a significant dose-dependent increase in metabolism of lactate. It was also apparent that such embryos were not desensitized to PAF as demonstrated by a further enhancement of the metabolic response after re-exposure to PAF. The specificity of action of PAF was confirmed by the absence of any effect on the oxidative metabolism of glucose by lyso-PAF (a catabolite of PAF) over a concentration range of 0.0202-20.2 microM and by the demonstration that SRI 63-441 (a PAF-receptor antagonist) significantly reduced the amount of CO2 produced from glucose in response to 9.3 microM-PAF and abolished the effect on lactate metabolism in response to 1.86 microM-PAF. These results demonstrate a specific, direct influence of exogenous PAF on the oxidative metabolism of glucose and lactate by the preimplantation mouse embryo and suggest an autocrine role for embryo-derived PAF in early pregnancy.