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Neuronal nitric oxide synthase: a substrate for SHP-1 involved in sst2 somatostatin receptor growth inhibitory signaling¹

INSERM U 531, IFR 31, CHU Rangueil, 31403 Toulouse Cedex 4, France

³Correspondence: INSERM U 531, IFR 31, CHU Rangueil, 31403 Toulouse Cedex 4, France. E-mail: susinich{at}rangueil.inserm.fr

SPECIFIC AIMS

The sst2 somatostatin receptor is an inhibitory G-protein-coupled receptor that inhibits normal and tumor cell growth by a mechanism involving activation of the tyrosine phosphatase SHP-1. We addressed whether nitric oxide synthase (NOS) is involved in sst2 signaling. We first investigated whether an NOS isoform interacts with SHP-1 and is activated by somatostatin. We further studied NOS role for sst2-mediated negative growth signal regulation and identified the associated molecular mechanism.

PRINCIPAL FINDINGS

1. SHP-1 associates with neuronal NOS (nNOS) and is involved in somatostatin-induced dephosphorylation of nNOS
To investigate whether SHP-1 interacts with NOS, we performed coimmunoprecipitation and immunoblotting studies in CHO cells expressing sst2 (CHO/sst2). nNOS, but not endothelial NOS, was detected within anti-SHP-1 immunoprecipitates in resting cells. SHP-1 was also coprecipitated within anti-nNOS immunoprecipitates. CHO/sst2 cell treatment with RC-160 (1 nM), a sst2 agonist, increased the amount of immunoprecipitated SHP-1/nNOS complexes, with a maximum at 1–3 min of RC-160 treatment. Because RC-160 induced SHP-1 activity in CHO/sst2, the demonstration of nNOS/SHP-1 interaction suggested that nNOS is a substrate for RC-160-activated SHP-1. nNOS was tyrosine phosphorylated in resting cells and cell treatment with RC-160 reduced nNOS tyrosine phosphorylation. This effect was evident within 1 min of RC-160 treatment and reached a maximum at 5 min (Fig. 1A ). To test whether active SHP-1 is critical for somatostatin-mediated decrease of nNOS tyrosine phosphorylation, we used CHO cells stably expressing sst2 and a dominant-negative form of SHP-1, referred to CHO/sst2-SHP-1(C453S) cells. In CHO/sst2-SHP-1(C453S) cells, nNOS was hyperphosphorylated at the basal level (Fig. 1C ) and RC-160 was unable to dephosphorylate nNOS (Fig. 1B ). This result is consistent with a critical role for active SHP-1 to mediate RC-160-induced nNOS tyrosine dephosphorylation.

View larger version (27K): [in this window] [in a new window]   Figure 1. SHP-1 is involved in sst2-mediated nNOS tyrosine dephosphorylation. CHO/sst2 (A, C) and CHO/sst2-SHP-d453S) (B, C) cells were incubated (A, B) or not (C) at 37°C for the indicated times with 1 nM RC-160. nNOS was immunoprecipitated with anti-nNOS antibodies from cell lysates, and immunoprecipitates were fractionated by a 7.5% SDS-PAGE before sequential immunoblotting with anti-phosphotyrosine (pTyr) and nNOS antibodies.

2. SHP-1 is required for somatostatin-induced activation of nNOS in vitro
To determine whether SHP-1-mediated dephosphorylation of nNOS is relevant to nNOS activation, CHO/sst2 cells were incubated in the presence or absence of somatostatin agonist and nNOS activity was examined in nNOS immunoprecipitates. CHO/sst2 cell treatment with RC-160 induced nNOS activity, which reached 172 ± 13% at 5 min. RC-160 had no effect on nNOS activity in CHO/sst2-SHP-1(C453S) cells. Our results indicate that RC-160-activated SHP-1 dephosphorylates nNOS, thereby increasing its activity.

3. SHP-1 is required for somatostatin-induced activation of nNOS in vivo
To ascertain whether the regulation of nNOS phosphorylation and activation by SHP-1 are physiologically relevant in vivo, we used pancreatic acini isolated from normal mice that highly express endogenous sst2 as well as from motheaten viable (me^v) mice carrying mutations in the SHP-1 gene responsible for loss of SHP-1 activity. As observed in CHO/sst2 cells, in acini from normal mice, nNOS was tyrosine phosphorylated at the basal level and treatment with RC-160 resulted in a decrease of nNOS tyrosine phosphorylation, associated with an increase of nNOS activity. By contrast, in acini derived from me^v mice, RC-160 affected neither nNOS tyrosine phosphorylation nor its catalytic activity. These results provide direct evidence for in vivo RC-160-mediated nNOS dephosphorylation and activation, and confirm the critical role of SHP-1 for RC-160-induced nNOS activation.

4. Somatostatin-mediated activation of nNOS stimulates intracellular cGMP production
Under physiological conditions, NO effects are partially mediated by the stimulation of soluble guanylate cyclase, which produces intracellular cGMP. Therefore, we next examined the effect of RC-160 on the intracellular cGMP level. Stimulation of CHO/sst2 cells or normal mouse acini with RC-160 for 5 min increased cGMP production. This RC-160 effect was abrogated in CHO/sst2-SHP-1(C453S) cells and in acini from me^v mice, whereas the NO donor sodium nitroprusside (SNP) still enhanced cGMP production in these cells. These results indicate that blockade of RC-160 induced NO release and that cGMP production in cells expressing an inactive SHP-1 was likely due to an absence of nNOS stimulation.

5. Somatostatin-activated nNOS/NO/cGMP pathway is involved in sst2-mediated antiproliferative signal
To obtain direct evidence for nNOS implication in RC-160-mediated inhibition of cell proliferation, we transiently coexpressed sst2 and the rat nNOS(C415A) mutant in CHO cells. The Cys⁴¹⁵ of nNOS(C415A) was mutated to Ala to prevent binding of the heme and tetrahydrobiopterin cofactors that are critical for nNOS activation; 1 nM RC-160 treatment for 3 min promoted nNOS activation in CHO/sst2-pCMV5 but not in CHO/sst2-nNOS(C415A) cells. In addition, expression of the catalytically inactive nNOS abrogated the somatostatin analog inhibitory effect on cell proliferation. RC-160 indeed inhibited FCS-induced CHO/sst2-pCMV5 cell proliferation whereas proliferation of CHO/sst2-nNOS(C415A) cells remained unaffected. Finally, expression of a dominant-negative form of nNOS prevented RC-160-induced p27 up-regulation observed on CHO/sst2 cells, indicating that nNOS is involved and contributes to sst2-mediated G₁ cell cycle arrest.

We tested a synthetic inhibitors of both and both soluble guanylate cyclase (L-NAME and LY 83583, respectively) on the antiproliferative effect of RC-160. These inhibitors both significantly reduced RC-160-induced inhibition of CHO/sst2 cell proliferation In contrast, RC-160 did not modify CHO/sst2-SHP-1(C453S) cell proliferation, and the addition of LY 83583 or L-NAME had no effect on these cells. Moreover, the NO donor SNP and the cGMP analog 8-Br-cGMP inhibited serum-induced proliferation of both CHO/sst2 and CHO/sst2-SHP-1(C453S) cells. These results not only indicate that the NO/cGMP pathway is functional in both cell types, but also that this pathway is involved downstream of SHP-1 in the RC-160-induced negative growth signal. All together, our data argue in favor of a critical role for the SHP-1/nNOS/NO/cGMP pathway in sst2-initiated negative growth signal.

CONCLUSION

We previously reported that the inhibitory receptor sst2 mediated the antiproliferative effect of somatostatin by stimulating SHP-1 tyrosine phosphatase activity. Here we provide evidence for a direct regulation of nNOS by SHP-1 and demonstrate the role of nNOS in the sst2 growth inhibitory signal transduction pathway.

SHP-1 has been identified as a critical negative regulator of several growth factor, antigen, and cytokine receptor signaling. SHP-1 recruitment to activated receptors or associated proteins indeed results in inhibition of their signaling cascades. In hematopoietic cells, it is well established that inhibitory immunoreceptors (including killer inhibitory receptors) down-regulate signaling by recruiting SHP-1. SHP-1 then dephosphorylates activated receptors and their associated molecules that are involved in early signal transduction and thereby terminates activating signals. Little is known about the signaling effectors with which SHP-1 interacts to transduce inhibitory G-protein-coupled receptor signals. We previously reported that ligand-activated sst2 recruits SHP-1, which results in SHP-1 enzymatic activation and subsequently dephosphorylation of SHP-1 substrates. In this study, we have identified nNOS as a novel substrate for sst2-activated SHP-1 in vitro in CHO cells expressing sst2, and further demonstrated in vivo in the well-characterized sst2-expressing mouse pancreatic acini a functional role of SHP-1 for nNOS regulation after sst2 activation. The observed SHP-1-dependent effects of somatostatin on tyrosine dephosphorylation and activation of nNOS are consistent with results obtained both in vitro in CHO/sst2 cells expressing a catalytically inactive SHP-1 and in vivo in mouse pancreatic acini derived from me^v mice carrying inactivating mutations in the SHP-1 gene. In these cells, nNOS can no longer be tyrosine dephosphorylated and activated in response to somatostatin. Our results demonstrate the importance of SHP-1 for regulating nNOS activity in the sst2-initiated signaling pathway. nNOS enzyme activity is modulated by phosphorylation/dephosphorylation of serine and threonine residues. However, emerging evidence suggests that phosphorylation/dephosphorylation on tyrosine residues influence nNOS enzyme activity. Indeed, lipopolysaccharide plus interferon increase nNOS tyrosine phosphorylation, which is associated with inhibition of nNOS enzyme activity. Conversely, cholecystokinin-induced activation of the tyrosine phosphatase SHP-2 results in tyrosine nNOS dephosphorylation and activation. Taken together, these results argue in favor of the role of specific tyrosine kinases and tyrosine phosphatases in control of both the nNOS tyrosine phosphorylation level and enzymatic activity. nNOS tyrosyl residues and mechanisms involved in such a regulation remain to be identified.

The physiological role for somatostatin-mediated activation of nNOS in pancreatic acini is not yet established. However, because somatostatin was reported to inhibit pancreatic acinar cell growth, it can be suggested that nNOS contributes to pancreatic cell development.

Somatostatin stimulates cGMP production in CHO/sst2 cells and normal mouse pancreatic acini. Somatostatin-induced guanylate cyclase activation, however, was abrogated in cells expressing an inactive SHP-1, whereas the response to the exogenous NO donor SNP was not modified in these cells. These results suggest that SHP-1 is critical for sst2-mediated cGMP production.

The antiproliferative effect of somatostatin on CHO cells is blocked by coexpressing sst2 and a catalytically inactive nNOS or by treating these cells with the NOS competitive inhibitor, L-NAME or the specific guanylate cyclase inhibitor LY 83583. SNP and 8-bromo-cGMP mimic somatostatin’s effect on cell proliferation. Our results provide evidence that the nNOS/NO/cGMP signaling pathway is involved in sst2-mediated inhibitory growth signaling (Fig. 2 ). The downstream effectors of sst2-induced cGMP production remain to be elucidated.

View larger version (23K): [in this window] [in a new window]   Figure 2. Schematic diagram of the NO/cGMP pathway involved in sst2 somatostatin receptor growth inhibitory signaling. After binding to sst2, somatostatin activates the tyrosine phosphatase SHP-1. Activated SHP-1 associated with nNOS and tyrosine dephosphorylates it, leading to nNOS activation and NO production. Endogenously produced NO activates soluble guanylate cyclase, which converts GTP to cyclic GMP. Increased cGMP inhibits cell growth.

There is widespread distribution of sst2 in the central and peripheral nervous systems as well as in peripheral organs. Sst2 is also highly expressed in the majority of human tumors. Sst2 is implicated in the regulation of various functions including inhibition of hormone secretions, cell proliferation and gut motility, and neurotransmission and behavior, and pathological situations such as tumor growth and inflammation. nNOS has been identified in different tissues including brain, skeletal muscle, gut, and pancreas, where sst2 expression occurs. It would be therefore of critical interest to investigate whether sst2 and nNOS colocalize and whether nNOS transduces other sst2 cellular functions in addition to its antiproliferative effect. The present findings that nNOS acts as an important molecule in the sst2-mediated growth inhibitory signaling represent a first step in demonstrating that nNOS participates in sst2-initiated cellular responses.

FOOTNOTES

¹ To read the full text of this article, go to http://www.fasebj.org/cgi/doi/10.1096/fj.00-0867fje; to cite this article, use FASEB J. (August 17, 2001) 10.1096/fj.00-0867fje

² These two authors contribute equally to this work.

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