Peter König

NOSIP, a novel modulator of endothelial nitric oxide synthase activity

Production of nitric oxide (NO) in endothelial cells is regulated by direct interactions of endothelial nitric oxide synthase (eNOS) with effector proteins such as Ca2+‐calmodulin, by posttranslational modifications such as phosphorylation via protein kinase B, and by translocation of the enzyme from the plasma membrane caveolae to intracellular compartments. Reversible acylation of eNOS is thought to contribute to the intracellular trafficking of the enzyme;however, protein factor(s) that govern the translocation of the enzyme are still unknown. Here we have used the yeast two‐hybrid system and identified a novel 34 kDa protein, termed NOSIP (eNOS interacting protein), which avidly binds to the carboxyl‐terminal region of the eNOS oxygenase domain. Coimmunoprecipitation studies demonstrated the specific interaction of eNOS and NOSIP in vitro and in vivo, and complex formation was inhibited by a synthetic peptide of the caveolin‐1 scaffolding domain. NO production was significantly reduced in eNOS‐expressing CHO cells (CHO‐eNOS) that transiently overexpressed NOSIP. Stimulation with the calcium ionophore A23187 induced the reversible translocation of eNOS from the detergentinsoluble to the detergent‐soluble fractions of CHO‐eNOS, and this translocation was completelyprevented by transient coexpression of NOSIP in CHO‐eNOS. Immunofluorescence studies revealed a prominent plasma membrane staining for eNOS in CHO‐eNOS that was abolished in the presence of NOSIP. Subcellular fractionation studies identified eNOS in the caveolin‐rich membrane fractions of CHO‐eNOS, and coexpression of NOSIP caused a shift of eNOS to intracellular compartments. We conclude that NOSIP is a novel type of modulator that promotes translocation of eNOS from the plasma membrane to intracellular sites, thereby uncoupling eNOS from plasma membrane caveolae and inhibiting NO synthesis.—Dedio, J., König, P., Wohlfart, P., Schroeder, C., Kummer, W., Muller‐Esterl, W. NOSIP, a novel modulator of endothelial nitric oxide synthase activity. FASEB J. 15, 79–89 (2001)

Ethanol reduces excitability in a subgroup of primary sensory neurons by activation of BKCa channels

Ethanol effects on the central nervous system have been well investigated and described in recent years; modulations, by ethanol, of several ligand‐gated and voltage‐gated ion channels have been found. In this paper, we describe a shortening of action potential duration (APD) by ethanol in ≈ 40% of small diameter neurons in rat dorsal root ganglia (DRG). In these neurons, designated as group A neurons, we observed an ethanol‐induced increase in whole‐cell outward‐current. As iberiotoxin, a specific blocker of large‐conductance calcium‐activated K+ channels (BKCa channels), blocks the effects of ethanol, we investigated the interaction between these channels and ethanol in outside‐out patches. Open probability of BKCa channels was increased 2–6 × depending on the concentration (40–80 mm≈ 2–4‰ v/v) of ethanol. Functional consequences were a prolongation of the refractory period, which was reversible after addition of iberiotoxin, and reduced firing frequency during ethanol application. In contrast, another type of neuron (group B) showed a prolonged APD during application of ethanol which was irreversible in most cases. In 90% of cases, neurons of group A showed a positive staining for isolectin B4 (I‐B4), a marker for nociceptive neurons. We suggest that the activation of BKCa channels induced by clinically relevant concentrations of ethanol, the resulting modulations of APD and refractory period of DRG neurons, might contribute to clinically well‐known ethanol‐induced analgesia and paresthesia.

Hypoxic vasoconstriction of partial muscular intra-acinar pulmonary arteries in murine precision cut lung slices.

BackgroundAcute alveolar hypoxia causes pulmonary vasoconstriction (HPV) which serves to match lung perfusion to ventilation. The underlying mechanisms are not fully resolved yet. The major vascular segment contributing to HPV, the intra-acinar artery, is mostly located in that part of the lung that cannot be selectively reached by the presently available techniques, e.g. hemodynamic studies of isolated perfused lungs, recordings from dissected proximal arterial segments or analysis of subpleural vessels. The aim of the present study was to establish a model which allows the investigation of HPV and its underlying mechanisms in small intra-acinar arteries.MethodsIntra-acinar arteries of the mouse lung were studied in 200 μm thick precision-cut lung slices (PCLS). The organisation of the muscle coat of these vessels was characterized by α-smooth muscle actin immunohistochemistry. Basic features of intra-acinar HPV were characterized, and then the impact of reactive oxygen species (ROS) scavengers, inhibitors of the respiratory chain and Krebs cycle metabolites was analysed.ResultsIntra-acinar arteries are equipped with a discontinuous spiral of α-smooth muscle actin-immunoreactive cells. They exhibit a monophasic HPV (medium gassed with 1% O2) that started to fade after 40 min and was lost after 80 min. This HPV, but not vasoconstriction induced by the thromboxane analogue U46619, was effectively blocked by nitro blue tetrazolium and diphenyleniodonium, indicating the involvement of ROS and flavoproteins. Inhibition of mitochondrial complexes II (3-nitropropionic acid, thenoyltrifluoroacetone) and III (antimycin A) specifically interfered with HPV, whereas blockade of complex IV (sodium azide) unspecifically inhibited both HPV and U46619-induced constriction. Succinate blocked HPV whereas fumarate had minor effects on vasoconstriction.ConclusionThis study establishes the first model for investigation of basic characteristics of HPV directly in intra-acinar murine pulmonary vessels. The data are consistent with a critical involvement of ROS, flavoproteins, and of mitochondrial complexes II and III in intra-acinar HPV. In view of the lack of specificity of any of the classical inhibitors used in such types of experiments, validation awaits the use of appropriate knockout strains and siRNA interference, for which the present model represents a well-suited approach.

Sensory Neurons Respond to Hypoxia with NO Production Associated with Mitochondria

Oxygen is pivotal for mammalian cell function, and recent studies suggest an involvement of NO in cellular adaptation to low oxygen supply. Here, we report that endothelial NO-synthase is ubiquitously expressed in rat and mice sensory neurons, and is targeted to juxtamitochondrial compartments of the ER. There it is activated in response to hypoxia while generation of reactive oxygen species remains unaltered. Developing a technique for ultrastructural localization of an NO-sensitive indicator allowed to identify the inner mitochondrial membrane as the target of NO under hypoxia. The demonstrated hypoxic stimulation of endothelial NOS in sensory neurons shall contribute to resistance against hypoxia, since NO promotes cellular survival by interfering with mitochondrial function.

FRET–CLSM and double-labeling indirect immunofluorescence to detect close association of proteins in tissue sections

It is pivotal to identify protein–protein interaction in situ to understand protein function. Conventional methods to determine the interaction of proteins destruct tissue or are applicable to cell culture only. To identify association of proteins in cells in tissue, we adapted indirect double-labeling immunofluorescence and combined it with conventional confocal laser scanning microscopy (CLSM) to measure fluorescence resonance energy transfer (FRET). As a model system, we chose caveolin-1α and caveolin-2, two major components of endothelial caveolae, and examined their interaction in the endothelium of vessels in fixed tissues of laboratory animals and human glomus tumors. Several methodological aspects were examined. Measuring the absolute increase in fluorescence (ΔIF) was superior compared to determining the relative FRET efficiency, because it is more robust against small increases of fluorescence during measurements that results from unavoidable minimal crossreactivity of the secondary antibodies. Both, sequential and simultaneous incubation of secondary antibodies result in robust and reliable increases in ΔIF. If incubated sequentially, however, the acceptor-labeled secondary antibody should be applied first. The size of the secondary reagent (F(ab′)2 vs whole antibody) has no major influence. In conclusion, CLSM–FRET can measure close spatial association of proteins in situ and can be applied to human surgical material.

Coexpression and spatial association of nicotinic acetylcholine receptor subunits α7 and α10 in rat sympathetic neurons

Fast excitatory synaptic transmission in sympathetic ganglia is mediated by nicotinic acetylcholine receptors (nAChRs). Although it is known that the nAChR alpha7-subunit occurs in sympathetic ganglia, the expression of the recently cloned subunit alpha10 (Elgoyhen et al., 2001; Lustig et al., 2001; Sgard et al., 2002) has not been analyzed. Until now, functional receptors containing alpha10-subunits have been found only in combination with alpha9-subunits (Elgoyhen et al., 2001; Lustig et al., 2001; Sgard et al., 2002). The alpha9-subunit exhibits a restricted expression pattern, whereas the alpha10-subunit is expressed more widely. This broad distribution resembles more closely that known for subunit alpha7 than for subunit alpha9. On this background, we investigated the distribution of nAChR subunits alpha7, alpha9, and alpha10 in rat sympathetic ganglia and studied a possible interaction between subunit alpha7 and potential partners by double-labeling immunofluorescence and fluorescence resonance energy transfer (FRET) (Kam et al., 1995; Jares-Erijman and Jovin, 2003).

Hypoxia induces production of nitric oxide and reactive oxygen species in glomus cells of rat carotid body

The carotid body is an arterial chemoreceptor organ that senses arterial pO2 and pH. Previous studies have indicated that both reactive oxygen species (ROS) and nitric oxide (NO) are important potential mediators that may be involved in the response of the carotid body to hypoxia. However, whether their production by the chemosensitive elements of the carotid body is indeed oxygen-dependent is currently unclear. Thus, we have investigated their production under normoxic (20% O2) and hypoxic (1% O2) conditions in slice preparations of the rat carotid body by using fluorescent indicators and confocal microscopy. NO-synthesizing enzymes were identified by immunohistochemistry and histochemistry, and the subcellular localization of the NO-sensitive indicator diaminofluorescein was determined by a photoconversion technique and electron microscopy. Glomus cells of the carotid body responded to hypoxia by increases in both ROS and NO production. The hypoxia-induced increase in NO generation required (to a large extent, but not completely) extracellular calcium. Glomus cells were immunoreactive to endothelial NO synthase but not to the neuronal or inducible isoforms. Ultrastructurally, the NO-sensitive indicator was observed in mitochondrial membranes after exposure to hypoxia. The data show that glomus cells respond to exposure to hypoxia by the enhanced production of both ROS and NO. NO production by glomus cells is probably mediated by endothelial NO synthase, which is activated by calcium influx. The presence of NO indicator in mitochondria suggests the hypoxic regulation of mitochondrial function via NO in glomus cells.

NOSIP and its interacting protein, eNOS, in the rat trachea and lung.

Endothelial nitric oxide synthase (eNOS), the major nitric oxide (NO)-generating enzyme of the vasculature, is regulated through multiple interactions with proteins, including caveolin-1, Hsp90, Ca2+-calmodulin, and the recently discovered eNOS-interacting protein, NOSIP. Previous studies indicate that NOSIP may contribute to the intricate regulation of eNOS activity and availability. Because eNOS has been shown to be abundantly expressed in the airways, we determined the expression and cellular localization of NOSIP in rat trachea and lung by RT-PCR and immunohistochemistry and examined the interaction of NOSIP with eNOS in lung by coimmunoprecipitation. In tracheal epithelium and lung, NOSIP mRNA expression was prevalent, as shown by RT-PCR, and the corresponding protein interacted with eNOS, as demonstrated by coimmunoprecipitation. Using immunohistochemistry, we found both NOSIP and eNOS immunoreactivity in ciliated epithelial cells of trachea and bronchi, while Clara cells showed immunoreactivity for NOSIP only. NOSIP and eNOS were present in vascular and bronchial smooth muscle cells of large arteries and airways, whereas endothelial cells, as well as bronchiolar and arteriolar smooth muscle cells, exclusively stained for NOSIP. Our results point to functional role(s) of NOSIP in the control of airway and vascular diameter, mucosal secretion, NO synthesis in ciliated epithelium, and, therefore, of mucociliary and bronchial function.

Down-regulation of vasoactive intestinal peptide and altered expression of its receptors in rat diabetic cardiomyopathy

Vasoactive intestinal peptide (VIP) is a vasorelaxant peptide that addresses two receptor subtypes, VPAC1 and VPAC2. It stimulates insulin secretion and mediates anti-inflammatory effects and has been proposed for treatment of type 2 and autoimmune diabetes. In the heart, VIP is produced and released primarily by intrinsic neurons and improves cardiac perfusion and function. Here, we investigated the involvement of this system in the events underlying development of experimentally induced diabetic cardiomyopathy. Rats received a single streptozotocin injection, and cardiac VIP content [radioimmune assay (RIA)], expression of the VIP precursors VPAC1 and VPAC2 [real-time reverse transcription-polymerase chain reaction (RT-PCR)], and VPAC1 and VPAC2 tissue distribution (immunohistochemistry) were assessed 4, 8, and 16 weeks thereafter and compared with corresponding vehicle-treated controls. Cardiac neuropathy manifests progressively during the first 4 months of diabetes at the preproVIP mRNA and VIP peptide level and is accompanied by initial down-regulation of VPAC2 at one prime target of VIP-containing axons, i.e., smooth muscle cells of coronary arterioles. VPAC1 is expressed by macrophages. After initial changes that are specific for atria and ventricles, respectively, VPAC1 and VPAC2 expression return to control levels at 16 weeks despite ongoing loss of VIP. Given the cardioprotective role of the VIP signaling system, the persistence of receptors has therapeutic implications since it is the prerequisite for trials with VPAC2 agonists.

Caveolin-1 and -2 in airway epithelium: expression and in situ association as detected by FRET-CLSM

BackgroundCaveolae are involved in diverse cellular functions such as signal transduction, cholesterol homeostasis, endo- and transcytosis, and also may serve as entry sites for microorganisms. Hence, their occurrence in epithelium of the airways might be expected but, nonetheless, has not yet been examined.MethodsWestern blotting, real-time quantitative PCR analysis of abraded tracheal epithelium and laser-assisted microdissection combined with subsequent mRNA analysis were used to examine the expression of cav-1 and cav-2, two major caveolar coat proteins, in rat tracheal epithelium. Fluorescence immunohistochemistry was performed to locate caveolae and cav-1 and -2 in the airway epithelium of rats, mice and humans. Electron-microscopic analysis was used for the identification of caveolae. CLSM-FRET analysis determined the interaction of cav-1α and cav-2 in situ.ResultsWestern blotting and laser-assisted microdissection identified protein and transcripts, respectively, of cav-1 and cav-2 in airway epithelium. Real-time quantitative RT-PCR analysis of abraded tracheal epithelium revealed a higher expression of cav-2 than of cav-1. Immunoreactivities for cav-1 and for cav-2 were co-localized in the cell membrane of the basal cells and basolaterally in the ciliated epithelial cells of large airways of rat and human. However, no labeling for cav-1 or cav-2 was observed in the epithelial cells of small bronchi. Using conventional double-labeling indirect immunofluorescence combined with CLSM-FRET analysis, we detected an association of cav-1α and -2 in epithelial cells. The presence of caveolae was confirmed by electron microscopy. In contrast to human and rat, cav-1-immunoreactivity and caveolae were confined to basal cells in mice. Epithelial caveolae were absent in cav-1-deficient mice, implicating a requirement of this caveolar protein in epithelial caveolae formation.ConclusionThese results show that caveolae and caveolins are integral membrane components in basal and ciliated epithelial cells, indicating a crucial role in these cell types. In addition to their physiological role, they may be involved in airway infection.