Soft elasticity optimises dissipation in 3D-printed liquid crystal elastomers.

Soft-elasticity in monodomain liquid crystal elastomers (LCEs) is promising for impact-absorbing applications where strain energy is ideally absorbed at constant stress. Conventionally, compressive and impact studies on LCEs have not been performed given the notorious difficulty synthesizing sufficiently large monodomain devices. Here, we use direct-ink writing 3D printing to fabricate bulk (>cm3) monodomain LCE devices and study their compressive soft-elasticity over 8 decades of strain rate. At quasi-static rates, the monodomain soft-elastic LCE dissipated 45% of strain energy while comparator materials dissipated less than 20%. At strain rates up to 3000 s-1, our soft-elastic monodomain LCE consistently performed closest to an ideal-impact absorber. Drop testing reveals soft-elasticity as a likely mechanism for effectively reducing the severity of impacts - with soft elastic LCEs offering a Gadd Severity Index 40% lower than a comparable isotropic elastomer. Lastly, we demonstrate tailoring deformation and buckling behavior in monodomain LCEs via the printed director orientation.

Inertia effects on characterization of dynamic response of brain tissue.

Modeling and simulation of traumatic brain injury (TBI) resulted from collision or blast loading requires characterization of mechanical response over a wide range of loading rates under valid testing conditions. In this study, mechanical response of fresh bovine brain tissue was studied using the two modified Kolsky bar techniques. Radial deformation behavior of annular specimens, which are typically used to characterize the dynamic uniaxial compressive response of biological tissues, was examined using a modified Kolsky bar and a high speed camera to collect images while the specimen deforms at an axial strain rate of 2000s(-1). The high-speed images revealed inhomogeneous specimen deformation possibly brought about by radial inertia and causing a multi-axial stress state. To acquire valid stress-strain results that can be used to produce constitutive behavior of the soft materials, a novel torsion technique was developed to obtain pure shear response at dynamic loading rates. Experimental results show clear differences in the material response using the two methods. These results indicate that the previously demonstrated annular specimen geometry aimed at reducing inertia induced stress components for high rate soft materials uniaxial-compressive testing may still possess a significant component of radial inertia induced radial stress which consequently caused the observed inhomogeneous deformation in brain tissue test samples.

Assessment of analysis by gender in the Cochrane reviews as related to treatment of cardiovascular disease.

BACKGROUND: Cardiovascular disease (CVD) is the leading killer of women in the United States, yet medical care is often based on evidence from clinical trials performed predominantly with men. Numerous studies show that CVD risk factors, clinical presentation, treatment, and treatment outcomes can vary between men and women. METHODS: The Cochrane Library maintains a large database of critically appraised evidence including meta-analyses of clinical trials, called Systematic Reviews. There were 30 Systematic Reviews pertaining to the treatment of CVD published collectively by the Cochrane Heart Group, Hypertension Group, and Peripheral Vascular Diseases Groups at the time of our study. We examined these 30 Systematic Reviews and the great majority of the clinical trials used for their meta-analyses for inclusion of women and gender-based data analyses. Women comprised only 27% of the pooled population of 258 clinical trials. RESULTS: Of those trials that included both men and women (n = 196), only 33% examined outcomes by gender. In trials that performed a gender-based analysis, 20% reported significant (p < 0.05) differences in cardiovascular-related outcomes by gender. CONCLUSIONS: We conclude that (1) there are not enough large-scale clinical trials or meta-analyses concerning CVD in women to determine if their medical treatment should differ from that of men, (2) all clinical trials relating to CVD treatment should have significantly more female participants, and gender-based analyses should be performed, as currently recommended for National Institutes of Health (NIH)-sponsored research by the NIH Revitalization Act of 1993, and (3) the Cochrane Library would be a more useful tool for the evidence-based healthcare of women if the Systematic Reviews used all available gender-specific information in their analyses.

Hormones and calcium: mechanisms controlling uterine smooth muscle contractile activity. The Litchfield Lecture.

The regulation of myometrial contraction is of paramount importance for the maintenance of pregnancy and for parturition. Understanding this regulation involves delineating the pathways that control myometrial contraction and relaxation and defining the regulation of these pathways. The pathways can be broken down further into those signalling cascades controlling the concentration of intracellular free calcium (Ca(2+)(i)) and those controlling the contractile apparatus itself. This discussion focuses primarily on the former and their regulation during pregnancy. In particular, cross-talk between the contractant and relaxant signalling pathways mediated through cyclic AMP is markedly changed at the end of pregnancy. Experimental Physiology (2001) 86.2, 223-237.

KN-93 inhibition of G protein signaling is independent of the ability of Ca2+/calmodulin-dependent protein kinase II to phosphorylate phospholipase Cbeta3 on 537-Ser.

Stimulation of the phospholipase Cbeta (PLC) signaling pathway results in intracellular Ca2+ release and subsequent activation of calmodulin (CaM) and CaM kinase II (CaMK II). KN-93, an inhibitor of CaMK II, reduced the stimulation of phosphatidylinositide (PI) turnover by Galphai-coupled (formyl-Met-Leu-Phe, fMLP) or Galphaq-coupled [M1 muscarinic and oxytocin (OT)] receptors. The inhibitory effect of KN-93 was also observed when PLCbeta3 was stimulated directly by Galphaq or Gbetagamma in overexpression assays. CaMK II phosphorylated PLCbeta3 but not PLCbeta1 in vitro. Phosphorylation occurred exclusively on 537Ser in the X-Y linker region of PLCbeta3. 537Ser was also phosphorylated in the basal state in cells and phosphorylation was enhanced by ionomycin treatment. However, mutation of 537Ser to Glu had no effect on inhibition of Galphaq or Gbetagamma-stimulated PLCbeta3 activity by KN-93. KN-93 also inhibited Galphaq -stimulated PLCbeta1 activity, even though this enzyme is not a substrate for CaMK II. These data indicate that phosphorylation of PLCbeta3 by CaMK II is not directly involved in the inhibitory effect of KN-93 on phosphatidylinositide turnover.

Ecto-ATPase mRNA is regulated by FSH in Sertoli cells.

A putative messenger RNA (mRNA) sequence, designated C8, that was up-regulated in Sertoli cells prepared from hypophysectomized rats treated with testosterone, was isolated from a Sertoli cell complementary DNA (cDNA) library. The coding region of C8 exhibited 99% identity with rat brain ecto-ATPase and expressed a 60-kilodalton protein following in vitro transcription/translation. Transfection of COS7 cells with C8 cDNA resulted in a marked increase in Ca2+- and Mg2+-dependent ATPase activity in both whole cells and cell homogenates, which is consistent with localization of this enzyme in the plasma membrane. C8 ecto-ATPase steady state mRNA levels were increased within 6 hours and for 3 day, by follicle-stimulating hormone (FSH) in Sertoli cells but not in peritubular cells. In contrast, dibutyryl-cyclic adenosine monophosphate (cAMP) increased ecto-ATPase in both Sertoli and peritubular cells. Testosterone had no significant effect under these conditions. These data indicate that ecto-ATPase mRNA is positively regulated by FSH in Sertoli cells and by cAMP in both Sertoli and peritubular cells. This enzyme may play a role in the control of extracellular signaling by ATP, adenosine, or both in the cells of the seminiferous epithelium.

Phosphorylation and regulation of G-protein-activated phospholipase C-beta 3 by cGMP-dependent protein kinases.

Among the drugs that are known to relax the vascular smooth muscle and regulate other cellular functions, beta-adrenergic agonists and nitric oxide-containing compounds are some of the most effective ones. The mechanisms of these drugs are thought to lower agonist-induced intracellular [Ca(2+)] by increasing intracellular cAMP and cGMP, activating their respective protein kinases. However, the physiological targets of cyclic nucleotide-dependent protein kinases are not clear. The molecular basis for the regulation of intracellular Ca(2+) by signaling pathways coupled to cyclic nucleotides is not well defined. G-protein-activated phospholipase C (PLC-beta) catalyzes the hydrolysis of phosphatidylinositol 4,5-bisphosphates to generate diacylglycerol and inositol 1,4,5-triphosphate, leading to the activation of protein kinase C and the mobilization of intracellular Ca(2+). In this study, we shown that G-protein-activated PLC enzymes are the potential targets of cGMP-dependent protein kinases (PKG). PKG can directly phosphorylate PLC-beta2 and PLC-beta3 in vitro with purified proteins and in vivo with metabolic labeling. Phosphorylation of PLC-beta leads to the inhibition of G-protein-activated PLC-beta3 activity by 50-70% in COS-7 cell transfection assays. By using phosphopeptide mapping and site-directed mutagenesis, we further identified two key phosphorylation sites for the regulation of PLC-beta3 by PKG (Ser(26) and Ser(1105)). Mutation at these two sites (S26A and S1105A) of PLC-beta3 completely blocked the phosphorylation of PLC-beta3 protein catalyzed by PKG. Furthermore, mutation of these serine residues removed the inhibitory effect of PKG on the activation of the mutant PLC-beta3 proteins by G-protein subunits. Our results suggest a molecular mechanism for the regulation of G-protein-mediated intracellular [Ca(2+)] by the NO-cGMP-dependent signaling pathway.

Molecular mechanism of the inhibition of phospholipase C beta 3 by protein kinase C.

Activation of protein kinase C (PKC) can result from stimulation of the receptor-G protein-phospholipase C (PLCbeta) pathway. In turn, phosphorylation of PLCbeta by PKC may play a role in the regulation of receptor-mediated phosphatidylinositide (PI) turnover and intracellular Ca(2+) release. Activation of endogenous PKC by phorbol 12-myristate 13-acetate inhibited both Galpha(q)-coupled (oxytocin and M1 muscarinic) and Galpha(i)-coupled (formyl-Met-Leu-Phe) receptor-stimulated PI turnover by 50-100% in PHM1, HeLa, COSM6, and RBL-2H3 cells expressing PLCbeta(3). Activation of conventional PKCs with thymeleatoxin similarly inhibited oxytocin or formyl-Met-Leu-Phe receptor-stimulated PI turnover. The PKC inhibitory effect was also observed when PLCbeta(3) was stimulated directly by Galpha(q) or Gbetagamma in overexpression assays. PKC phosphorylated PLCbeta(3) at the same predominant site in vivo and in vitro. Peptide sequencing of in vitro phosphorylated recombinant PLCbeta(3) and site-directed mutagenesis identified Ser(1105) as the predominant phosphorylation site. Ser(1105) is also phosphorylated by protein kinase A (PKA; Yue, C., Dodge, K. L., Weber, G., and Sanborn, B. M. (1998) J. Biol. Chem. 273, 18023-18027). Similar to PKA, the inhibition by PKC of Galpha(q)-stimulated PLCbeta(3) activity was completely abolished by mutation of Ser(1105) to Ala. In contrast, mutation of Ser(1105) or Ser(26), another putative phosphorylation target, to Ala had no effect on inhibition of Gbetagamma-stimulated PLCbeta(3) activity by PKC or PKA. These data indicate that PKC and PKA act similarly in that they inhibit Galpha(q)-stimulated PLCbeta(3) as a result of phosphorylation of Ser(1105). Moreover, PKC and PKA both inhibit Gbetagamma-stimulated activity by mechanisms that do not involve Ser(1105).

Relationship of ion channel activity to control of myometrial calcium.

This article reviews the contribution of ion channels to membrane potential, the ion channels expressed in myometrium, and the effect of ion channel activity on the control of myometrial intracellular free calcium. Plasma membranes constitute barriers to permeability that establish concentration gradients of ions inside versus outside the cell. Na+, CA2+, and Cl- are normally in higher concentration outside than inside cells, whereas K+ is higher inside. In myometrium, Ca2+ entry into cells mediates myometrial membrane potential changes and serves as the internal signal for contraction. K+ efflux is thought to promote repolarization after an action potential and to participate in setting the resting membrane potential. Ions cross the cell membrane through channels that have different regulated properties and selectivities. Ion movement has been measured by a number of techniques, including radiolabeled ion flux, use of intracellular indicators, and patch-clamp methodology. A number of myometrial Ca2+ channels have been described, including voltage-regulated L-type channels and Ca2+ entry in response to intracellular Ca2+ store depletion. Fast Na+ channels may contribute to cation entry late in pregnancy. K+ channels in myometrium include Ca(2+)-activated channels, a delayed rectifier, and an inward rectifier. A Ca(2+)-activated Cl- channel is also present in myometrium. In addition to being regulated by Ca2+, the activity of a number of these channels can be regulated by uterine contractants and relaxants. Regulation of ion channel activity can affect intracellular free Ca2+ concentrations in the myometrium. Therefore, control of ion channel activity represents one of several approaches for controlling myometrial contractile activity.

A role for AKAP (A kinase anchoring protein) scaffolding in the loss of a cyclic adenosine 3',5'-monophosphate inhibitory response in late pregnant rat myometrium.

During pregnancy in the rat, there is a change in the ability of chlorophenylthio (CPT)-cAMP to inhibit myometrial phosphatidylinositide turnover. This is accompanied by a change in the association of proteins with a plasma membrane A kinase anchoring protein (AKAP). Both CPT-cAMP and isoproterenol inhibited oxytocin-stimulated phosphatidylinositide turnover on days 12 through 20 of gestation, whereas neither agent had an effect on day 21. Accompanying this change was a dramatic decrease in the concentration and activity of cAMP-dependent protein kinase [protein kinase A (PKA)] and an increase in the concentration of protein phosphatase 2B (PP2B) in plasma membranes from day 21 compared with day 19 pregnant rats. In contrast, both PKA and PP2B concentrations and activities increased in total myometrial homogenates. Both PKA and PP2B coimmunoprecipitated with an antibody against the 150-kDa AKAP found in rat myometrial plasma membranes. More PKA was associated with AKAP150 on day 19 than on day 21, while the reverse was true for PP2B. Disruption of PKA/AKAP association in day 19 pregnant rat myometrial cells with the specific interaction inhibitor peptide S-Ht31 resulted in the loss of the cAMP-inhibitory effect on phosphatidylinositide turnover. PP2B activity in myometrial homogenates dephosphorylated PLCbeta3, a PKA substrate targeted in the inhibition of Galphaq-stimulated phosphatidylinositide turnover. The dramatic loss of the cAMP-inhibitory effect on day 21 of pregnancy may alter the balance between uterine contraction and relaxation near parturition. The changes in the relative concentrations of PKA and PP2B associated with AKAP150 are consistent with a functional role for AKAP150 scaffolding in the alteration of cellular signaling.

Protein kinase A anchoring to the myometrial plasma membrane is required for cyclic adenosine 3',5'-monophosphate regulation of phosphatidylinositide turnover.

The importance of the localization of protein kinase A (PKA) to the plasma membrane for cAMP-mediated inhibition of phosphatidylinositide turnover was tested in an immortalized pregnant human myometrial (PHM1-41) cell line, and the putative A kinase anchoring protein (AKAP) involved was identified. Preincubation in PHM1-41 cells with chlorophenylthio-cAMP (CPT-cAMP), forskolin, or relaxin inhibited the ability of oxytocin to stimulate phosphatidylinositide turnover. The addition of a peptide that specifically disrupts interactions of PKA RII subunits with AKAPs (S-Ht31) reversed the effects of these agents, whereas a control peptide was ineffective. The pharmacology of S-Ht31 on this particular membrane event was further characterized. A 10-min incubation with S-Ht31 at a concentration of 1 microM completely reversed the inhibitory effect of relaxin on phosphatidylinositide turnover. S-Ht31 inhibited cAMP-stimulated PKA activity in PHM1-41 cell plasma membranes and decreased the concentration of PKA. Overlay analysis detected a single AKAP of approximately 86 kDa associated with the plasma membrane of PHM1-41 cells, suggesting that the association of PKA with this AKAP is important for the cAMP inhibitory mechanism. The mol wt of this AKAP was similar to that of an AKAP associated with the plasma membrane in the human brain, AKAP79. Antibodies against AKAP79 recognized a band at 86 kDa in purified plasma membranes from the PHM1-41 cells, indicating similar determinants in these proteins. These data suggest that PKA is anchored to the myometrial plasma membrane through association with an AKAP similar to AKAP79, and that this anchoring is required for the cAMP-mediated inhibition of phosphatidylinositide turnover in PHM1-41 cells.

Oxytocin-stimulated capacitative calcium entry in human myometrial cells.

OBJECTIVE: Our purpose was to investigate the relative contribution of extracellular calcium recruitment and release of calcium from intracellular stores in an immortalized myometrial cell line derived from a pregnant woman (PHM1-41) and to determine the importance of capacitative calcium entry in the oxytocin-stimulated rise in intracellular free calcium. STUDY DESIGN: The PHM1-41 immortalized myometrial cell line, which retains smooth muscle phenotype, estrogen, and oxytocin receptors and responds to oxytocin with an increase in intracellular free calcium, was used for this study. Intracellular free calcium was measured directly in cells loaded with Fura 2-AM. RESULTS: The oxytocin-stimulated rise in intracellular free calcium decreased in the absence of extracellular calcium or in the presence of phospholipase C inhibitors, suggesting mobilization of calcium from both extracellular and intracellular sources to increase intracellular free calcium. Phospholipase C inhibitors resulted in greater inhibition of the oxytocin-stimulated rise in intracellular free calcium than expected on the basis of experiments performed in the absence of extracellular calcium. This implies interdependence of the intracellular and extracellular pathways for elevation of intracellular free calcium and suggests some capacitative entry of calcium as a consequence of depletion of intracellular stores. The oxytocin-stimulated intracellular free calcium increase resulting from calcium entry was blocked by store depletion by thapsigargin or cyclopiazonic acid, consistent with a capacitative calcium entry mechanism. CONCLUSION: Oxytocin stimulates both capacitative and noncapacitative calcium entry in a pregnant human myometrium cell line.

Oxytocin-induced Ca2+ responses in human myometrial cells.

Complex spatiotemporal changes in intracellular Ca2+ were monitored in an immortalized human myometrial cell line (PHM1-41) and first-passage human myometrial cells after oxytocin stimulation (1. 0-1000 nM). Laser cytometry revealed intracellular Ca2+ oscillations in both culture systems starting at 1.0 nM, which were followed by repetitive Ca2+ transients by 10-15 min that lasted for at least 90 min. The amplitude of the initial Ca2+ spike was dose dependent, while the frequency of Ca2+ oscillations identified by Fast Fourier Transform (FFT) tended to increase with dose. Removal of oxytocin resulted in termination of oscillations. Analysis of the sources of the Ca2+ involved in oscillations indicated that the major contribution to oscillation frequencies of

G protein signalling pathways in myometrium: affecting the balance between contraction and relaxation.

Heterotrimeric G proteins are actively involved in intracellular signalling in the myometrium and play important roles in regulating myometrial contraction and relaxation. Increases in intracellular calcium can be induced by agents that stimulate uterine contractions. In a number of instances, these increases in intracellular calcium are attributed to stimulation of phospholipase C by either G alpha or G betagamma subunits as a result of activation of G protein-coupled plasma membrane receptors. This mechanism also stimulates calcium entry through calcium release-activated channels, either directly or indirectly. Thus, while phospholipase C can be activated by other pathways and calcium can enter myometrial cells through other channels, G proteins play a major role in these processes. Similarly, activation of protein kinase A and protein kinase C are consequences of G protein activation. Protein kinase A and protein kinase C exert a number of regulatory influences on phospholipase C, ion channel activity and other processes in the myometrium. The mitogen-activated protein kinase pathway can also be activated directly or indirectly by the action of G proteins in myometrium. Responsiveness to G proteins can be altered during pregnancy and depends on the relative expression of all of the components of the signalling pathways involved. The balance between G protein-mediated stimulatory and inhibitory signalling pathways has important consequences for the control of myometrial contractile activity.

Phosphorylation of serine 1105 by protein kinase A inhibits phospholipase Cbeta3 stimulation by Galphaq.

The mechanism by which protein kinase A (PKA) inhibits Galphaq -stimulated phospholipase C activity of the beta subclass (PLCbeta ) is unknown. We present evidence that phosphorylation of PLCbeta3 by PKA results in inhibition of Galphaq -stimulated PLCbeta3 activity, and we identify the site of phosphorylation. Two-dimensional phosphoamino acid analysis of in vitro phosphorylated PLCbeta3 revealed a single phosphoserine as the putative PKA site, and peptide mapping yielded one phosphopeptide. The residue was identified as Ser1105 by direct sequencing of reverse-phase high pressure liquid chromatography-isolated phosphopeptide and by site-directed mutagenesis. Overexpression of Galphaq with PLCbeta3 or PLCbeta (Ser1105--> Ala) mutant in COSM6 cells resulted in a 5-fold increase in [3H]phosphatidylinositol 1,4,5-trisphosphate formation compared with expression of Galphaq, PLCbeta3, or PLCbeta3 (Ser1105 --> Ala mutant alone. Whereas Galpha1-stimulated PLCbeta3, activity was inhibited by 58-71% by overexpression of PKA catalytic subunit, Galphaq-stimulated PLCbeta3 (Ser1105 --> Ala) mutant activity was not affected. Furthermore, phosphatidylinositide turnover stimulated by presumably Galpha1-coupled M1 muscarinic and oxytocin receptors was completely inhibited by pretreating cells with 8-[4-chlorophenythio]-cAMP in RBL-2H3 cells expressing only PLCbeta3. These data establish that direct phosphorylation by PKA of Ser1105 in the putative G-box of PLCbeta3 inhibits Galphaq-stimulated PLCbeta3 activity. This can at least partially explain the inhibitory effect of PKA on Galphaq-stimulated phosphatidylinositide turnover observed in a variety of cells and tissues.

Evidence for inhibition by protein kinase A of receptor/G alpha(q)/phospholipase C (PLC) coupling by a mechanism not involving PLCbeta2.

The effects of cAMP on the oxytocin-stimulated increase in phosphatidylinositide turnover and the possible pathways involved were investigated in a human myometrial cell line (PHM1-41) and in COS-M6 cells overexpressing the oxytocin receptor. Preincubation with chlorophenylthio-cAMP (CPT-cAMP), forskolin, or relaxin inhibited oxytocin-stimulated phosphatidylinositide turnover in PHM1-41 cells, and the inhibition was reversed by H-89, a relatively specific protein kinase A inhibitor. Both CPT-cAMP and transiently expressed protein kinase A catalytic subunit inhibited stimulation by oxytocin and carbachol of [3H]inositol 1,3,4-trisphosphate formation in COS-M6 cells expressing oxytocin or muscarinic M1 receptors, respectively. CPT-cAMP also inhibited phosphatidylinositide turnover stimulation by endothelin-1 in PHM1-41 cells, further demonstrating the generality of the cAMP-inhibitory mechanism. Since G betagamma activation of phospholipase Cbeta2 (PLCbeta2) is a suggested target of protein kinase A, the possibility that the oxytocin receptor couples to PLCbeta2 via G alpha(i)G betagamma activation was explored. Western blot analysis of PHM1-41 cells and COS-M6 cells detected PLCbeta1 and PLCbeta3, but not PLCbeta2. In PHM1-41 cells, pertussis toxin reduced the oxytocin-stimulated increase in [3H]inositol 1,3,4-trisphosphate by 53%, and this was reversed completely by H-89. Thus, the inhibitory effect of pertussis toxin may result from an indirect effect of cAMP elevation. These data suggest that receptor/G alpha(q)-coupled stimulation of PLCbeta1 or PLCbeta3 can be inhibited by cAMP through a phosphorylation mechanism involving protein kinase A that does not involve PLCbeta2. In smooth muscle, this mechanism could constitute potentially important cross-talk between pathways regulating contraction and relaxation.

Androgen regulation of the Pem homeodomain gene in mice and rat Sertoli and epididymal cells.

Although the role of homeodomain transcription factors during embryogenesis is well known, their developmental function in postnatal animals is only beginning to be understood. We examined the regulation and expression pattern of Pem, a homeodomain protein that may regulate androgen-dependent events in the testis and epididymis. Immunohistochemical analysis showed that Pem protein is expressed selectively in the nuclei of Sertoli cells during the androgen-dependent stage of the seminiferous epithelium cycle in vivo. RNase protection analysis revealed that a proximal promoter was responsible for androgen-dependent mouse Pem expression in testis and epididymis in vivo, whereas a distal promoter was used in placenta. The mouse Pem gene was expressed at approximately 10-fold higher levels in the testis than in the epididymis; conversely, the rat Pem gene was expressed at >10-fold higher levels in the epididymis than in the testis. Because androgen-binding protein has been proposed to transport androgens from the testis to the epididymis, we tested whether the > or = 20-fold higher levels of androgen-binding protein expression in the rat, compared to that of mouse, are responsible for the differential expression of Pem in these two rodent species. Studies with androgen-binding protein transgenic mice demonstrated that the species-specific difference in androgen-binding protein expression is unlikely to be responsible for the species-specific difference in Pem expression. We found that androgen is necessary but not sufficient for Pem expression, since purified Sertoli cells rapidly down-regulated Pem transcripts in culture, regardless of the presence of testosterone. We conclude that Pem gene expression in Sertoli cells requires other cell types or cellular factors in addition to androgen.

Evidence for the involvement of several intracellular domains in the coupling of oxytocin receptor to G alpha(q/11).

In order to probe the nature of oxytocin receptor (OTR)/G alpha(q/11) protein coupling, we examined the effect of co-expression of OTR intracellular domains on oxytocin-stimulated phosphoinositide turnover in COSM6 cells overexpressing OTR and G alpha(q). Co-expression of G alpha(q) enhanced the oxytocin response maximally at a pOTR/pG alpha(q) plasmid transfection ratio of 1:0.16. In cells co-expressing OTR and G alpha(q/11), oxytocin stimulated phosphoinositide turnover with an EC50 of 48 nM. Co-transfection with plasmids expressing OTR intracellular domains inhibited oxytocin-stimulated phosphoinositide turnover by 23 +/- 6% (1i), 37 +/- 4% (2i), 55 +/- 6% (3i), and 40 +/- 6% (4i), respectively (P < 0.01). Expression of the 3i loop of the alpha(1B)-adrenergic receptor, which also couples to G alpha(q/11), inhibited phosphoinositide turnover by 35 +/- 2% (P < 0.01), while expression of the 3i loop of the dopamine 1A receptor, which couples to G alpha(s), had no effect. While these data indicate a functional role for the OTR 3i loop, they also suggest that interactions with more than one intracellular domain probably mediate the coupling of OTR to the G alpha(q/11) class of GTP-binding proteins.

Molecular mechanisms regulating the effects of oxytocin on myometrial intracellular calcium.

Oxytocin stimulates an increase in intracellular calcium in uterine myometrium by several mechanisms. Several lines of evidence indicate that the oxytocin receptor is functionally coupled to GTP-binding proteins of the G alpha q/11 class which stimulate phospholipase C activity. The IP3 generated as a result of phospholipase C activation can trigger release of calcium from intracellular stores. The finding that the oxytocin-stimulated increase in intracellular calcium in myometrial cells is greater in the presence of extracellular calcium than that in its absence indicates that oxytocin also has effects on calcium entry. This action is nifedipine-insensitive but may involve indirect stimulation of calcium entry through release-operated channels. An anti-G alpha q/11 antibody inhibits both oxytocin-stimulated GTPase activity and phospholipase C activity in myometrial membranes. The stimulation by oxytocin of phosphoinositide turnover in COS cells transfected with a plasmid expressing the oxytocin receptor is enhanced by cotransfection of G alpha q. Co-transfection of intracellular domains of the oxytocin receptor causes varying degrees of interference with oxytocin-stimulated phosphoinositide turnover. The data suggest that more than one intracellular domain is involved in oxytocin receptor/G-protein coupling. Oxytocin receptor stimulation of phospholipase C is inhibited by cAMP. This occurs in myometrial cells and in COS cells transfected with a plasmid expressing the receptor. The inhibitory mechanism involves the action of protein kinase A and is probably targeted indirectly at the G alpha q/11 /phospholipase C coupling step.