We have previously shown that somatostatin promotes the stimulation of a membrane tyrosine phosphatase activity in pancreatic cells. To gain insight into the mechanism of somatostatin action, we purified somatostatin-receptor complexes from somatostatin 28-prelabelled rat pancreatic plasma membranes by immunoaffinity chromatography using immobilized antibodies raised against the N-terminal part of somatostatin 28, somatostatin 28 (1-14), which is not involved in receptor-binding-site recognition. After SDS gel electrophoresis a band with a molecular mass of 87 kDa was identified in the affinity-purified material as the somatostatin receptor. The 87 kDa protein was not observed when the membrane receptors were solubilized in a free unoccupied or somatostatin 14-occupied form, or when nonimmune serum replaced the anti-[somatostatin 28 (1-14)] anti-serum. Somatostatin 14 inhibited the appearance of the 87 kDa protein in the same range of concentrations that inhibit radioligand binding on pancreatic membranes. After somatostatin 28 treatment of membranes, purified somatostatin receptor preparations exhibited an elevated tyrosine phosphatase activity that dephosphorylated phosphorylated epidermal growth factor receptor and poly(Glu,Tyr). This activity was related to the presence of somatostatin receptors in purified material. It was increased by dithiothreitol and inhibited by orthovanadate. In purified material containing somatostatin receptors, anti-[Src homology 2 domains (SH2)]-containing tyrosine phosphatase SHPTP1 polyclonal antibodies identified a protein of 66 kDa which was not detected in the absence of somatostatin receptor. Furthermore, the anti-SHPTP1 antibodies immunoprecipitated specific somatostatin receptors from somatostatin-prelabelled pancreatic membranes and from untreated membranes. These results indicate that a 66 kDa tyrosine phosphatase related to SHPTP1 co-purifies with the pancreatic somatostatin receptors, and suggest that this protein is associated with somatostatin receptors at the membrane level.
Interactions between growth factor receptor systems may be important in the regulation of cell growth. The proliferation of pancreatic tumor AR42J cells has been shown to be stimulated by Epidermal growth factor (EGF) and gastrin and inhibited by somatostatin. To analyze the interaction between these different peptides, we explored the influence of EGF and gastrin on the somatostatin receptors. Treatment of AR42J cells with 10 nM EGF or gastrin for 24 hr increased specific binding of [125I] Tyr3SMS to 131 and 147% of that in control cells, respectively. The effect of peptides on [125I]Tyr3SMS binding was time- and dose-dependent, with half-maximal effect at 0.2 +/- 0.03 nM EGF and 0.3 +/- 0.15 nM gastrin. Scatchard plots revealed an increase in somatostatin receptor number of 27 and 80% after 48 hr of treatment with EGF and gastrin, respectively, without any change in receptor affinity. The increase in somatostatin receptor density was accompanied by the enhancement of biological responses to somatostatin. In cells pretreated with EGF or gastrin, the potency of somatostatin for inhibiting vasoactive intestinal peptide-stimulated cAMP content was increased 2-fold as that of somatostatin analog, SMS, for inhibiting cell proliferation. Furthermore, the efficiency of SMS as antiproliferative agent was greatly increased. Vasoactive intestinal peptide or forskolin did not modify [125I]Tyr3SMS binding of control or treated cells. The phorbol ester 12-O-tetradecanoyl phorbol 13-acetate (TPA) did not affect [125I]Tyr3SMS binding. On the other hand, cycloheximide completely blocked the increase in [125I]Tyr3SMS binding induced by EGF and gastrin.(ABSTRACT TRUNCATED AT 250 WORDS)
Regulation of tyrosine phosphorylation is thought to be an essential step in signal transduction mechanisms that mediate cellular responses. In pancreatic tumour cells we demonstrated that somatostatin analogues inhibited cell proliferation and stimulated a membrane protein tyrosine phosphatase (PTP) activity at concentrations at which they bind to the somatostatin receptor. To elucidate the role of PTP in the signal transduction pathway activated by somatostatin receptors we first studied the interaction of PTP with the somatostatin receptor at the membrane. We purified somatostatin receptors by immunoaffinity from pancreatic membranes that strongly expressed the type 2 somatostatin receptor sstr2. We identified the receptor as an 87 kDa protein. We demonstrated that a PTP activity co-purified with somatostatin receptors. The PTP was identified as a 66 kDa protein immunoreactive to antibodies against SHPTP1. These antibodies immunoprecipitated somatostatin receptors either occupied or unoccupied by ligand indicating that SHPTP1 is associated with somatostatin receptors. We then expressed sstr2A in monkey kidney COS-7 cells and mouse NIH/3T3 fibroblasts and demonstrated that somatostatin analogues (RC 160, octreotide and BIM 23014) which exhibited high affinity for sstr2 stimulated a PTP activity and inhibited cell proliferation in proportion to their affinities for sstr2. Under the same conditions these analogues have no effect on the growth of cells expressing sstr1. All these results suggest that a PTP related to SHPTP1 is associated with somatostatin receptors and may be involved in the negative growth signal promoted by sstr2.
A phosphoryl protein tyrosine phosphatase (PTPase) activity has been characterized in rat pancreatic acinar membranes using 32 P‐labeled poly(Glu,Tyr) as substrate. Acinar membranes exhibited a high affinity for the substrate, with an apparent K m of 0.46 μM and an apparent V max of 0.9 nmol · mg protein −1 · min −1 . Acinar membrane PTPase activity displayed specific characteristics of other PTPases; it was inhibited by the inhibitors Zn 2+ , orthovanadate and by the divalent cations Mn 2+ and Mg 2+ , and was stimulated by the reducing‐agent dithiothreitol. It was also inhibited by soybean trypsin inhibitor and stimulated by trypsin. Gel permeation of pancreatic acinar membranes gave a single peak of enzyme activity with an apparent molecular mass of 70 000 Da. Further purification by HPLC on DEAE revealed two peaks of PTPase activity at 120 mM and 180 mM NaCl. These two peaks reacted in a Western‐blot procedure with anti‐(peptide) serum directed towards conserved domain of PTPase as a common 67‐kDa form associated with lower‐molecular‐mass proteolytic fragments (31–56 kDa). Incubation of pancreatic acini with somatostatin analgoues, SMS 201–995 or BIM 23014, resulted in a stimulation of membrane PTPase activity. The stimulation was rapid and transient, with a maximal level reached within 15 min of addition. The two analogs stimulated PTPase activity in a dose‐dependent manner with half‐maximal activation occurring at 7 pM and 37 pM and maximal activation at 0.1 nM and 0.1–1 nM for SMS 201–995 and BIM 23014, respectively. The stimulated‐membrane PTPase activity also eluted at an apparent molecular mass of 70 kDa in gel‐permeation chromatography. The two analogs inhibited the binding of [ 125 I‐Tyr 3 ]SMS 201–995 to pancreatic acinar membranes with similar relative potencies to that observed on stimulation of PTPase activity. We conclude that pancreatic acinar membranes possess a low‐molecular‐mass PTPase which is stimulated by somatostatin analogs at concentrations involving activation of membrane somatostatin receptors.
