Membrane Cholesterol Regulates Smooth Muscle Phasic Contraction

The regulation of contractile activity in smooth muscle cells involves rapid discrimination and processing of a multitude of simultaneous signals impinging on the membrane before an integrated functional response can be generated. The sarcolemma of smooth muscle cells is segregated into caveolar regions-largely identical with cholesterol-rich membrane rafts-and actin-attachment sites, localized in non-raft, glycerophospholipid regions. Here we demonstrate that selective extraction of cholesterol abolishes membrane segregation and disassembles caveolae. Simultaneous measurements of force and [Ca2+]i in rat ureters demonstrated that extraction of cholesterol resulted in inhibition of both force and intracellular Ca2+ signals. Considering the major structural reorganization of cholesterol-depleted sarcolemma, it is intriguing to note that decreased levels of membrane cholesterol are accompanied by a highly specific inhibition of phasic, but not tonic contractions. This implies that signalling cascades that ultimately lead to either phasic or tonic response may be spatially segregated in the plane of the sarcolemma. Replenishment of cholesterol restores normal contractile behavior. In addition, the tissue function is re-established by inhibiting the large-conductance K(+)-channel. Sucrose gradient ultracentrifugation in combination with Western blotting analysis demonstrates that its alpha-subunit is associated with detergent-resistant membranes, suggesting that the channel might be localized within the membrane rafts in vivo. These findings are important in understanding the complex signalling pathways in smooth muscle and conditions such as premature labor and hypertension.

Obstructed labour

Obstructed labour is an important cause of maternal deaths in communities in which undernutrition in childhood is common resulting in small pelves in women, and in which there is no easy access to functioning health facilities with the capability of carrying out operative deliveries. Obstructed labour also causes significant maternal morbidity in the short term (notably infection) and long term (notably obstetric fistulas). Fetal death from asphyxia is also common. There are differences in the behaviour of the uterus during obstructed labour, depending on whether the woman has delivered previously. The pattern in primigravid women (typically diminishing contractility with risk of infection and fistula) may result from tissue acidosis, whereas in parous women, contractility may be maintained with the risk of uterine rupture. Ultimately, tackling the problem of obstructed labour will require universal adequate nutritional intake from childhood and the ability to access adequately equipped and staffed clinical facilities when problems arise in labour. These seem still rather distant aspirations. In the meantime, strategies should be implemented to encourage early recognition of prolonged labour and appropriate clinical responses. The sequelae of obstructed labour can be an enormous source of human misery and the prevention of obstetric fistulas, and skilled treatment if they do occur, are important priorities in regions where obstructed labour is still common.

Lipopolysaccharide-induced oestrogen receptor regulation in the paraventricular hypothalamic nucleus of lewis and Fischer rats

Oestrogen receptor (ER) regulation of gene transcription in neurosecretory and pituitary cells has been proposed as an important mechanism for increased hypothalamic-pituitary-adrenal (HPA) axis responses in females of several mammalian species, including humans. Inbred female Fischer (F344/N) and Lewis (LEW/N) rats have similar oestrogen levels, although Fischer rats exhibit hyper- and Lewis rats hypo-HPA axis responses. The blunted HPA axis response of Lewis rats has been associated with their blunted hypothalamic corticotropin releasing hormone (CRH) expression. To determine if the female CRH expression deficiency in Lewis rats is associated with defective ER expression and regulation, hypothalamic paraventricular nucleus (PVN) transcript levels of CRH and ER were determined under basal conditions and after immune challenge. Microdissected PVN were obtained from control and lipopolysaccharide (LPS) treated Lewis and Fischer rats and CRH, ERalpha and beta mRNA levels were determined by semiquantitative reverse-transcriptase-polymerase chain reaction. In addition, ERalpha and beta protein levels were determined by semiquantitative Western blots. ERalpha and beta mRNA and protein levels in the PVN of control Fischer rats were significantly higher than in control Lewis rats. ERalpha and beta mRNA and protein levels in Fischer rats were reduced by LPS administration at the time of maximal CRH mRNA levels but did not change in Lewis rats, an effect independent of oestrogen levels. These data indicate that defective neuroendocrine HPA axis responses are associated with defective ER expression and regulation in Lewis PVN despite oestrogen concentrations.

17-Beta-estradiol regulates expression of genes that function in macrophage activation and cholesterol homeostasis

Macrophage activation and cholesterol processing can be affected by changes in estrogen concentrations. However, there is a paucity of information about the genes and mechanisms regulating this estrogen effect. In primary monocyte-derived macrophages we detected transcript and protein for estrogen receptor beta (ERbeta). Determination of genes regulated by estrogen was completed using cDNA arrays and semiquantitative RT-PCR on RNA isolated from macrophages cultured in serum free media containing (5-10) x 10(-9)M 17-beta-estradiol and subsequently deprived of estrogen for a 24h period. The data indicate that the transcript levels of interleukin 1 receptor antagonist (IL-1ra), beta 2-microglobulin, annexin XI and the LXR(alpha) receptor significantly increased and that Ly-GDI transcript levels significantly decreased after estrogen withdrawal; data congruent with estrogen depletion regulating macrophage inflammatory and biochemical processes. Treatment of THP-1 cells with phorbol 12-myristate-13-acetate in the presence or absence of estrogen indicate that differentiation to a macrophage-like cell type was a prerequisite for production of the estrogen response. In addition, experiments using cycloheximide treatment, that blocks nascent protein synthesis, indicated that estrogen withdrawal affected the transcript levels of LXR(alpha) and IL-1ra through dissimilar pathways.

Molecular mechanisms for migration of placodally derived GnRH neurons

Gonadotropin-releasing hormone (GnRH) neurons, critical for reproduction, are derived from the nasal placode and migrate into the brain along nasal axons. GnRH neurons appear to diverge from olfactory sensory cells during early stages of nasal placode differentiation. However, GnRH neurons rely on olfactory/vomeronasal axons as their pathway to the central nervous system (CNS). A novel factor, termed nasal embryonic luteinizing hormone-releasing hormone factor (NELF), was discovered in a differential screen of migrating versus nonmigrating GnRH neurons. NELF is expressed in olfactory sensory cells and GnRH cells in nasal areas. Antisense experiments demonstrated that knock-down of NELF decreased olfactory axon outgrowth and GnRH neuronal migration. These results indicate that NELF plays a role as a guidance molecule for olfactory axon projections and migration of GnRH cells. We hypothesize that NELF acts via a homophilic interaction and that NELF expression is critical for reproduction by insuring that GnRH cells reach the CNS. Furthermore, down-regulation of NELF on GnRH cells as they enter the telencephalon may allow GnRH cells to distinguish a different pathway(s) in the CNS (from those leading to olfactory regions) and thereby facilitate establishment of the appropriate adult-like GnRH distribution.

Development of gonadotropin-releasing hormone-1 neurons

Gonadotropin releasing hormone-1 (GnRH-1) neurons, critical for reproduction, are derived from the nasal placode and migrate into the brain during prenatal development. Once within the brain, GnRH-1 cells become integral components of the CNS-pituitary-gonadal axis, essential for reproductive maturation and maintenance of reproductive function in adults. This review focuses on the lineage and development of the GnRH-1 neuroendocrine system. Although the migration of these cells from nose to brain has been well documented in a variety of species, many questions remain concerning the melecules and cues directing GnRH-1 cell differentiation, migration, axon targeting, and establishment and control of GnRH-1 secretion. These process most likely involve multiple and redundant cues because if these mechanisms fail, reproduction dysfunction will ensue and guarantee that this defect does not remain in the gene pool.

Effect of inhibiting the sarcoplasmic reticulum on spontaneous and oxytocin-induced contractions of human myometrium

OBJECTIVE

1. To assess the contribution of the sarcoplasmic reticulum calcium store in the generation of uterine smooth muscle contractions; 2. to evaluate the contribution of calcium induced calcium release or ryanodine gated calcium channels to myometrial force production.

DESIGN

Laboratory scientific study.

METHODS

Myometrial strips were obtained from women undergoing elective prelabour caesarean section at term. These were loaded with the calcium sensitive indicator Indo-1 allowing simultaneous assessment of intracellular calcium concentrations and force production. The effect of exposing the strips to ryanodine (which abolishes calcium induced calcium release), caffeine (which activates calcium induced calcium release) and cyclopiazonic acid (which abolishes the sarcoplasmic reticulum calcium store) was examined.

RESULTS

Exposure to ryanodine had no appreciable effect on either the amplitude or the duration of the myometrial calcium and force transients but did increase the frequency of contractions (139+/-5%). Caffeine did not potentiate force. Cyclopiazonic acid increased frequency, duration and amplitude of both calcium and force transients. The ability of oxytocin to provoke calcium and force transients in the absence of extracellular calcium was abolished by cyclopiazonic acid but not by ryanodine.

CONCLUSIONS

These results demonstrate that calcium induced calcium release does not play a significant role in human myometrium and that no functioning role for the ryanodine receptors in human myometrial tissue could be shown. These data suggest that the sarcoplasmic reticulum may act to limit contractions and act as a calcium sink, rather than to amplify contractions.

The effects of inhibiting Rho-associated kinase with Y-27632 on force and intracellular calcium in human myometrium

Recent work has indicated that smooth muscle force production may be influenced by pathways not dependent upon the Ca2+-calmodulin phosphorylation of light chains. Few studies, however, have examined the importance of these pathways in intact muscles that contract phasically rather than tonically. Therefore, to determine whether the Ca2+-independent Rho-A and associated kinase (ROK) pathway can affect contractions of the intact human myometrium, we used Y-27632 to inhibit ROK. Three types of contractile activity were examined: spontaneous and those elicited by oxytocin and by depolarisation by high K+. Y-27632 decreased force significantly under all three conditions, without changing intracellular [Ca2+]. However, the effects on force were only large when the uterus was producing force tonically rather than phasically. This suggests that the Rho-A-ROK pathway may not be a potent modulator of force in the human myometrium under physiological conditions.

pH regulation and buffering power in gastric smooth muscle

Intracellular pH can have profound effects on tissue function, but little is known about how pH is regulated, buffered or affects the function of gastric smooth muscle. As the pH of gastric myocytes may alter with pathophysiological disturbance of the gastric lining, or reduction in blood flow to the stomach, these parameters were investigated. Intracellular pH was measured in strips of corpus from rats and guinea-pigs and pH perturbed by the addition of Na butyrate. pH regulation was investigated using pharmacological inhibitors and ionic substitutions. Resting pH was found to be around 7.0, and buffering power relatively high, compared to other muscles in both species. In the guinea-pig amiloride, EIPA and HOE694 prevented pH regulation from an acid load, but amiloride- and EIPA-insensitive pH-regulating mechanisms were found in the rat. The pH-regulatory mechanism present in the rat was also insensitive to DIDS, SITS and removal of external Cl-, but inhibited by Na+ substitution and HOE694. Acidification reduced gastric tone in both species. We conclude that pH alteration will significantly affect gastric contractility, despite a high capacity of the tissue to buffer and regulate pH change. The sensitivity to NHE inhibitors differs between rat and guinea-pig, suggesting that Na+/H+ exchanger isoform expression differs between gastric tissue.

Simultaneous measurements of changes in sarcoplasmic reticulum and cytosolic

1. The role of the sarcoplasmic reticulum (SR) was investigated in spontaneous and agonist-induced uterine Ca2+ transients, by combining low- (mag-fluo-4) and high-affinity (fura-2) indicators to measure intraluminal SR ([Ca2+]L) and cytosolic ([Ca2+]i) calcium concentration, simultaneously, in single smooth muscle cells from pregnant rat uterus. 2. Carbachol or ATP, in the absence of extracellular Ca2+, decreased [Ca2+]L and increased [Ca2+]i. Although some replenishment (around 50 %) occurred in its absence, extracellular Ca2+ was required for full replenishment of the SR Ca2+. 3. In 4/15 cells, ATP evoked oscillations of [Ca2+]i. These were accompanied by successive release and re-uptake of SR Ca2+. Inhibition of the SR Ca2+-ATPase with thapsigargin abolished the oscillations and luminal changes. 4. Spontaneous [Ca2+]i transients produced no detectable changes in [Ca2+]L. The larger [Ca2+]i transients evoked by high-K+ depolarisation increased [Ca2+]L. Spontaneous activity was inhibited when [Ca2+]L was increased. 5. These data show that it is possible to simultaneously measure SR and cytosolic [Ca2+], and to investigate their response to agonist application and spontaneous activity.

The physiological basis of uterine contractility: a short review

In this review we discuss our current understanding of the cellular basis of uterine contractility, highlighting those areas requiring further study. It is clear that the basic processes of excitation-contraction coupling lie within the myometrial cell, and that these may be modified by agonists. Pacemaker activity, however, remains a mystery. The contribution of extracellular calcium entry to contraction is shown to be vital, whilst the role of the sarcoplasmic reticulum remains controversial. Much current experimental focus is on pathways controlling and regulating contraction, and we discuss sensitisation mechanisms and question their role in intact uterine preparations. Experimental Physiology (2001) 86.2, 239-246.

Development of luteinizing hormone releasing hormone neurones

This review concentrates on some of the recent discoveries and future questions relevant to the development of the neuroendocrine luteinizing hormone releasing hormone (LHRH) cells. Neuroendocrine LHRH cells originate outside the central nervous system, in the nasal placode, and thereafter migrate into the forebrain during prenatal development. It is this population of LHRH cells that is responsible for reproductive function, becoming integral members of the hypothalamo-pituitary-gonadal axis postnatally. Disruption of the development of this system results in reproductive dysfunction. Increasing our understanding of LHRH neuroendocrine cells establishes conditions where we can look with greater precision at the mechanisms controlling reproductive development, both activation and failure. In addition, the ability to manipulate the molecular and cellular biology of the LHRH system opens the route to understanding critical neurobiological issues such as phenotypic commitment, axonal path finding and mechanisms involved in neuronal migration. Each of the topics is discussed in turn and potential mechanisms controlling the development of the neuroendocrine LHRH system are indicated.

Luteinizing hormone-releasing hormone (LHRH) biosynthesis and secretion in embryonic LHRH

Evidence indicates that LH-releasing hormone (LHRH) neurons can exhibit neuroendocrine secretory properties before entrance into the central nervous system. In this study, we evaluated LHRH biosynthesis and secretion in embryonic LHRH neurons maintained in nasal explants. Using ELISA and calcium imaging techniques, peptide content and single neuron activities were examined. LHRH neurons maintained for 7-10 days in vitro were found to possess a similar amount of LHRH/cell as the equivalent aged LHRH cells in vivo (postnatal day 1). LHRH peptide was measured in the medium of these relatively young cultures, and 40 mM KCl stimulated a 4-fold increase in LHRH secretion. KCl enhanced medium also resulted in a significant increase in LHRH content per culture (24.5 pg vs. 32.3). A similar effect was observed after muscimol-enhanced media (32.2 pg). Both agents also stimulated a substantial rise in intracellular calcium. Pretreatment of cultures with tetrodotoxin partially blocked the affects of muscimol on both peptide content and calcium activity, but not KCl. Calcium-depleted medium blocked the effects of KCl yet only attenuated the effects of muscimol. Treatment of cultures with cycloheximide blocked the effects of both muscimol and KCl. These results indicate that developing LHRH neurons are capable of synthesizing, secreting, and rapidly replenishing stores of LHRH peptide.

Midline nasal tissue influences nestin expression in nasal-placode-derived luteinizing hormone-releasing hormone neurons during development

Neurons differentiating into the luteinizing hormone-releasing hormone (LHRH) neuroendocrine phenotype are derived from the nasal placode. Cells within the vomeronasal organ anlage that turn on LHRH gene and peptide expression subsequently migrate into the forebrain where they influence reproductive function. The molecular and cellular cues regulating differentiation and migration of these cells are unknown. Discovery of developmental markers can indicate proteins directing or associated with differentiation. Analysis of such markers after manipulation of external cues can elucidate important extracellular differentiation signals. Embryonic LHRH neurons were examined in vivo for Mash-1 and nestin, two factors that delineate precursor populations in PNS and forebrain CNS cells. Nestin, but not Mash-1, was detected in early expressing LHRH cells in the vomeronasal organ anlage. These results were duplicated in LHRH neurons maintained in vitro in nasal explants. Such LHRH cells expressed nestin mRNA but not Mash-1 mRNA and were also negative for three other olfactory epithelial developmental transcription factors, Math4A, Math4C/neurogenin1, and NeuroD mRNA. Experimental manipulation of nasal explants revealed dual expression of nestin protein and LHRH in cells proximal to the vomeronasal organ anlage that was dependent upon midline cartilaginous/mesenchymal tissues. Prolonged nestin expression in LHRH cells after midline removal is consistent with nasal midline tissues modulating differentiation of LHRH neurons from the nasal placode.

A comparison of the contractile properties of human myometrium obtained from the upper and lower uterine segments

This study compared the contractile characteristics of myometrium taken from upper and lower uterine segments. Biopsies were obtained from women undergoing classical caesarean section. Myometrial strips were dissected and mounted in an organ bath, and the contractions were recorded. The cross sectional area of the contractile elements within the strips was measured enabling strips of differing dimensions to be compared. There were no significant differences in the contractile rate and force production produced by myometrium from the upper and lower segments. This study demonstrated that for contractile studies, the use of lower segment is appropriate. The results fail to demonstrate any functional regionality of the human uterus in terms of contractility.

Novel gene expressed in nasal region influences outgrowth of olfactory axons and migration of luteinizing hormone-releasing hormone (LHRH) neurons

Although a variety of cues have been implicated in axonal targeting during embryogenesis and regeneration, the precise mechanisms guiding olfactory axons remain unclear. Appropriate olfactory axon pathfinding is essential for functional chemoreceptive and pheromone receptive systems. Olfactory axon pathfinding is also necessary for establishment of the neuroendocrine LHRH system, cells critical for reproductive function. LHRH cells exhibit neurophilic migration moving from the nasal region along olfactory axons into the brain. Factors involved in the migration of these neuroendocrine cells are as yet unresolved. We report identification of a novel factor termed nasal embryonic LHRH factor (NELF) that was discovered in a differential screen of migrating versus nonmigrating primary LHRH neurons. NELF is expressed in PNS and CNS tissues during embryonic development, including olfactory sensory cells and LHRH cells. NELF antisense experiments indicate that a reduction in NELF expression decreases olfactory axon outgrowth and the number of LHRH neurons that migrate out of the nasal tissue. These results demonstrate that NELF plays a role as a common guidance molecule for olfactory axon projections and subsequently, either directly or indirectly, in the neurophilic migration of LHRH cells.

Two olfactory placode derived galanin subpopulations: luteinizing hormone-releasing hormone neurones and vomeronasal cells

In adult rodents, the peptide galanin is expressed in a subpopulation of hypothalamic luteinizing hormone-releasing hormone (LHRH) neurones in an activity-dependent manner. In this investigation, we examined whether galanin mRNA expression in mice was activated coincident with LHRH mRNA expression, as LHRH neurones differentiate from the olfactory placode. Using in situ hybridization, we show (i) that galanin mRNA is coexpressed in LHRH neurones prenatally, (ii) that there is a decrease in galanin mRNA expression relative to LHRH mRNA expression once LHRH mRNA positive/galanin mRNA positive neurones migrate out of the olfactory pit and into the nasal septum, and (iii) the presence of a novel population of galanin mRNA positive/LHRH mRNA negative expressing neurones in the olfactory pit/vomeronasal organ which do not migrate into the central nervous systenm (CNS). This study demonstrates that there are at least two populations of galanin mRNA expressing neurones arising from the olfactory placode; one that remains in nasal regions, is LHRH mRNA negative and whose function is unknown, and one which is coexpressed with LHRH. In addition, the temporal expression of galanin mRNA in LHRH cells indicates that initial activation and subsequent inactivation of galanin mRNA expression is independent of synaptic CNS connections.

Ectopic expression of luteinizing hormone-releasing hormone and peripherin in the respiratory epithelium of mice lacking transcription factor AP-2alpha

The vertebrate transcription factor activator protein-2 (AP-2alpha) is involved in craniofacial morphogenesis. In the nasal placode AP-2alpha expression delineates presumptive respiratory epithelia from olfactory epithelia, with AP-2alpha expression restricted to the anterior region of the respiratory epithelium (absent from the olfactory epithelium) at later stages. To address the role AP-2alpha plays in differentiation of cell groups in the nasal placode, the spatiotemporal expression pattern of four markers normally associated with olfactory epithelial structures was analyzed in mice lacking AP-2alpha. These markers were the intermediate filament protein peripherin, the neuropeptide luteinizing hormone-releasing hormone (LHRH), the neural cell adhesion molecule (NCAM) and the olfactory transcription factor Olf-1. Development of cells expressing these markers was similar in both genotypes until embryonic day 12.5 (E12.5), indicating that the main olfactory epithelium and olfactory pit formation was normal. At E13.5 in mutant mice, ectopic LHRH neurons and peripherin axons were detected in respiratory epithelial areas, areas devoid of Olf-1 and NCAM staining. Over the next few days, an increase in total nasal LHRH neurons occurred. The increase in nasal LHRH neurons could be accounted for by LHRH neurons arising and migrating out of respiratory epithelial regions on peripherin-positive fibers. These results indicate that AP-2alpha is not essential for the separation of the olfactory and respiratory epithelium from the nasal placode and is consistent with AP-2alpha preventing recapitulation of developmental programs within the respiratory epithelium that lead to expression of LHRH and peripherin phenotypes.

The effects of inhibiting myosin light chain kinase on contraction and calcium signalling in human and rat myometrium

The effect of inhibiting myosin light chain kinase on contractions of human and rat myometrium has been investigated, to determine whether force can be produced independently of myosin phosphorylation. Two inhibitors were used, wortmannin and ML-9, and their effects on spontaneous, high-K-depolarization-induced and oxytocin-induced force studied. Both inhibitors reduced and then abolished uterine force, irrespective of how it was produced; this was the case for both human and rat myometrium, and pregnant and non-pregnant tissue. The effects of wortmannin on intracellular [Ca2+] and inward Ca2+ current were examined. The data showed that the reduction in force produced by wortmannin occurs without a reduction of either the Ca2+ current or [Ca2+]. It is concluded that, under normal physiological conditions, myosin light chain kinase phosphorylation of myosin is essential for uterine force production and that there is little or no role for alternative force-producing pathways.

Transcription factor activator protein-2 is required for continued luteinizing hormone-releasing hormone expression in the forebrain of developing mice

LHRH is the neuropeptide responsible for reproductive function. Prenatally, LHRH expression begins when neurons are in the olfactory pit and continues as these cells migrate into the brain. Thus, LHRH neurons maintain neuropeptide expression through very distinct environments. The regulatory interactions that control onset and continued expression of the LHRH phenotype are unknown. To begin to address this question primary LHRH neurons were removed from nasal explants at different ages. A complementary DNA (cDNA) subtraction screen was performed comparing a 3.5-days in vitro LHRH neuron [approximately embryonic day 15 (E15) in vivo] to two 10.5-days in vitro LHRH neurons (approximately postnatal day 1 in vivo). The transcription factor activator protein-2 (AP-2alpha) was differentially expressed and was present in the developmentally younger LHRH neuron. In vivo analysis revealed that LHRH neurons expressed AP-2 as they migrated across the cribriform plate and into the forebrain beginning on E13.5, but that coexpression of LHRH and AP-2 was no longer detected in postnatal day 1 animals. This suggested a regulatory role for AP-2 in LHRH neurons. Analysis of animals lacking AP-2alpha revealed a dramatic decrease in forebrain LHRH neurons between E13.5 and E14.5, correlating with normal onset of AP-2 expression in LHRH neurons as they entered the central nervous system. Nasal cells robustly expressing LHRH were still present on E 14.5. The continued presence of forebrain LHRH cells is proposed based on a second marker, galanin, and lack of increased apoptotic/necrotic cells in this region. A decrease in LHRH messenger RNA in forebrain neurons indicates regulation of LHRH occurred at the transcriptional or posttranscriptional level in mutant animals. These results indicate a developmentally restricted involvement of the transcription factor AP-2 in LHRH expression once the LHRH neurons have migrated into the forebrain, but before establishment of an adult-like distribution.

Interactions between Ca(2+) and H(+) and functional consequences in vascular smooth muscle

Ca(2+) and H(+) ions can profoundly alter vascular tone. In many physiological and pathological processes, changes in the concentration of both ions occur. Thus, to understand the processes and mechanisms that modify force, it is necessary to understand what changes occur in these ions and, importantly, how they interact with each other. In this minireview, we highlight the quantitatively important mechanisms involved in the contractile responses of vascular tissues to pH change and discuss the cellular and molecular reasons underlying these responses.