Constitutive coexpression of nitric oxide synthase-1 and soluble guanylyl cyclase in myoepithelial cells of mammary glands in mice.

An impact of nitric oxide (NO) on lactation and milk secretion in mammary glands has previously been documented, but the underlying molecular mechanisms for this modulatory effect remain unclear. Therefore, we investigated the expression patterns of NO synthase (NOS)-1, NOS-3 and the NO receptor soluble guanylyl cyclase (sGC) in mammary glands of lactating and non-lactating female C57/Bl6 mice. RT-PCR demonstrated the existence of NOS-1-mRNA and NOS-3-mRNA in both lactating and resting mammary tissue. Immunoblots loaded with equal amounts of homogenate proteins from lactating and resting mammary tissues revealed comparable intensities of NOS-1 and sGC bands. Performing catalytic NADPH diaphorase histochemistry and immunohistochemistry, NOS-1 was only detected in myoepithelial cells (MEC), while sGC was localized in alveolar epithelial cells (lactocytes) and MEC in both lactating and non-lactating mammary glands. The non-modulated co-expression of both enzymes suggests that NOS-1 and sGC contribute to the constitutive regulation of tone in MEC.

Endothelial NOS is main mediator for shear stress-dependent angiogenesis in skeletal muscle after prazosin administration.

The increase of wall shear stress in capillaries by oral administration of the alpha1-adrenergic receptor antagonist prazosin induces angiogenesis in skeletal muscles. Because endothelial nitric oxide synthase (eNOS) is upregulated in response to elevated wall shear stress, we investigated the relevance of eNOS for prazosin-induced angiogenesis in skeletal muscles. Prazosin and/or the NOS inhibitor Nomega-nitro-L-arginine methyl ester (L-NAME) were given to C57BL/6 wild-type mice and eNOS-knockout mice for 14 days. The capillary-to-fiber (C/F) ratio and capillary density (CD; no. of capillaries/mm2) were determined in frozen sections from extensor digitorum longus (EDL) muscles of these mice. Immunoblotting was performed to quantify eNOS expression in endothelial cells isolated from skeletal muscles, whereas VEGF (after precipitation with heparin-agarose) and neuronal NOS (nNOS) concentrations were determined in EDL solubilizates. In EDL muscles of C57BL/6 mice treated for 14 days, the C/F ratio was 28% higher after prazosin administration and 11% higher after prazosin and L-NAME feeding, whereas the CD increased by 21 and 13%, respectively. The C/F ratio was highest after day 4 of prazosin treatment and decreased gradually to almost constant values after day 8. Prazosin administration led to elevation of eNOS expression. VEGF levels were lowest at day 4, whereas nNOS values decreased after day 8. In EDL muscles of eNOS-knockout mice, no significant changes in C/F ratio, CD, or VEGF and nNOS expression were observed in response to prazosin administration. Our data suggest that the presence of eNOS is essential for prazosin-induced angiogenesis in skeletal muscle, albeit other signaling molecules might partially compensate for or contribute to this angiogenic activity. Furthermore, subsequent remodeling of the capillary system accompanied by sequential downregulation of VEGF and nNOS in skeletal muscle fibers characterizes shear stress-dependent angiogenesis.

Localization of NOS-1 in the sarcolemma region of a subpopulation of atrial cardiomyocytes including myoendocrine cells and NOS-3 in vascular and endocardial endothelial cells of the rat heart.

Cellular localization patterns of NOS isoforms 1 and 3 (nNOS and eNOS, respectively) in the mammalian heart under basal (non-stimulated) working conditions are still a matter of discussion. Therefore, this issue was reinvestigated in rats using RT-PCR, Western blotting, catalytic histochemistry, immunohistochemistry and image analysis. Tongue and extensor digitorum longus muscles served as positive controls for NOS-1 and NOS-3. RT-PCR revealed NOS-1 mRNA and NOS-3 mRNA in atria and ventricles. Western blotting showed NOS-1 protein in atria and NOS-3 protein in the walls of both heart chambers. Localization of the activity of urea-resistant (and therefore specific) NADPH diaphorase (NADPH-D) and NOS-1 immunohistochemistry showed that NOS-1 is present in the sarcolemma region of a subpopulation of atrial cardiomyocytes but not in working and impulse-conducting cardiomyocytes of atria and ventricles. Atrial natriuretic peptide (ANP) immunohistochemistry revealed that a minority of the NOS-1-expressing atrial cardiomyocytes are myoendocrine cells. eNOS immunostaining was present in endothelial cells of capillaries of the conducting and working myocardium and endocardial cells. Image analysis of the activity of urea-resistant NOS diaphorase showed that NOS-1 activity is lower in the sarcolemma region of atrial cardiomyocytes than in that of tongue and extensor digitorum longus myofibers. These data suggest that, in the non-stimulated rat heart. NOS-1 is expressed in a subpopulation of atrial cardiomyocytes including myoendocrine cells, and that NOS-3 is expressed in the vascular and endocardial endothelium.

The specificity of the histochemical NADPH diaphorase reaction for nitric oxide synthase-1 in skeletal muscles is increased in the presence of urea.

Nitric oxide synthase-1 (NOS-1) can be demonstrated in the sarcolemma region of myofibers in rodent skeletal muscles with the use of NADPH diaphorase histochemistry. Since other, especially intrafibrar enzymes also exhibit NADPH diaphorase activity, we tried to increase the specificity of the histochemical reaction for NOS-1. A qualitative and quantitative analysis was performed on cryostat sections of fast-twitch oxidative myofiber-rich tongue and fast-twitch glycolytic myofibers-rich tibialis anterior muscle derived from C57 mice and NOS-1 deficient knockout mice. All myofibers of both C57 mice and NOS-1 knockout mice contained significant intrafibrar NADPH diaphorase activity which was inhibited to almost background levels when 2 M urea was added to the incubation medium. On the other hand, myofibers of C57 mice but not of NOS-1-deficient knockout mice exhibited NADPH diaphorase activity in their sarcolemma region which was only weakly reduced in the presence of 2 M urea as was demonstrated by image analysis. Quantitative data on the activity of NADPH diaphorase(s) were obtained in situ by photometric analysis of formazan extracted from cryostat sections. The catalytic activity in tongue and tibialis anterior muscle was reduced in presence of 2 M urea to approximately 27% in C57 mice and to 7-17% in NOS-1 knockout mice, respectively. An in vitro NADPH diaphorase assay performed on homogenates of skeletal muscles also revealed an inhibitory effect of 2 M urea in both mouse strains and, additionally, indicated an upregulation of NADPH diaphorase activity in NOS-1 knockout mice. Finally, an immunodepletion analysis demonstrated that NOS-1 comprises 38% of the total NADPH diaphorase activity in tongue and approximately 59% in tibialis anterior muscle in C57 mice. In conclusion, we recommend the addition of 2 M urea to the incubation medium to increase the specificity of the NADPH diaphorase reaction to localise NOS-1 with the use of catalytic histochemistry.

The nitric oxide synthase-1 and nitric oxide synthase-3/nitric oxide signalling systems in the heart of wild type mice and mouse mutants.

Recently, we have shown that nitric oxide synthase-1 (NOS-1) and thus its product NO are present in the sarcolemma region of a subpopulation of atrial cardiomyocytes in the rat heart. In order to find out whether this newly discovered sarcolemma-associated NOS/NO system represents a general signalling mechanism in the murine rodent heart and whether its properties are comparable to those in skeletal muscle fibres, immunohistochemical and catalytic histochemical methods (including image analysis) were applied to the heart and extensor digitorum longus (EDL) and tongue muscles of wild type and mutant mice. In different strains of wild type mice and NOS-3 knockouts, urea-resistant (and therefore specific) NOS NADPH diaphorase histochemistry and NOS-1 immunohistochemistry revealed that NOS-1 activity and protein were present in the sarcolemma region of a subpopulation of atrial and ventricular working cardiomyocytes, but not in those of the impulse conducting system. Using image analysis, NOS-1 showed similar activities in the sarcolemma region of cardiomyocytes and in EDL type I myofibres. In mdx and NOS-1 knockout mice, NOS-1 was absent from the sarcolemma region of atrial and ventricular cardiomyocytes and of EDL and tongue muscle fibres, whereas NOS-1 was present in the hearts of NOS-3 knockouts. Atrial natriuretic peptide immunohistochemistry identified part of the atrial NOS-1-expressing cardiomyocytes as myoendocrine cells. In mdx mice as well as in NOS-1 - and NOS-3-deficient animals, the peptide was found in greater abundance than in wild type mice. These data suggest that NOS-1 is expressed in a subpopulation of working cardiomyocytes in the murine rodent heart, that the myoendocrine cells may be negatively modulated by NOS-1 - and NOS-3-produced NO, and that the anchoring mechanisms for NOS-1 in these cells (i.e. their confinement to the sarcolemma region) are comparable to those in skeletal muscle fibres.