Generality of peptide cyclization catalyzed by isolated thioesterase domains of nonribosomal peptide synthetases

The C-terminal thioesterase (TE) domains from nonribosomal peptide synthetases (NRPSs) catalyze the final step in the biosynthesis of diverse biologically active molecules. In many systems, the thioesterase domain is involved in macrocyclization of a linear precursor presented as an acyl-S-enzyme intermediate. The excised thioesterase domain from the tyrocidine NRPS has been shown to catalyze the cyclization of a peptide thioester substrate which mimics its natural acyl-S-enzyme substrate. In this work we explore the generality of cyclization catalyzed by isolated TE domains. Using synthetic peptide thioester substrates from 6 to 14 residues in length, we show that the excised TE domain from the tyrocidine NRPS can be used to generate an array of sizes of cyclic peptides with comparable kinetic efficiency. We also studied the excised TE domains from the NRPSs which biosynthesize the symmetric cyclic decapeptide gramicidin S and the cyclic lipoheptapeptide surfactin A. Both TE domains exhibit expected cyclization activity: the TE domain from the gramicidin S NRPS catalyzes head-to-tail cyclization of a decapeptide thioester to form gramicidin S, and the TE domain from the surfactin NRPS catalyzes stereospecific cyclization to form a macrolactone analogue of surfactin. With an eye toward generating libraries of cyclic molecules by TE catalysis, we report the solid-phase synthesis and TE-mediated cyclization of a small pool of linear peptide thioesters. These studies provide evidence for the general utility of TE catalysis as a means to synthesize a wide range of macrocyclic compounds.     

Cyclization of backbone-substituted peptides catalyzed by the thioesterase domain from the tyrocidine nonribosomal peptide synthetase

The excised C-terminal thioesterase (TE) domain from the multidomain tyrocidine nonribosomal peptide synthetase (NRPS) was recently shown to catalyze head-to-tail cyclization of a decapeptide thioester to form the cyclic decapeptide antibiotic tyrocidine A [Trauger, J. W., Kohli, R. M., Mootz, H. D., Marahiel, M. A., and Walsh, C. T. (2000) Nature 407, 215-218]. The peptide thioester substrate was a mimic of the TE domain's natural, synthetase-bound substrate. We report here the synthesis of modified peptide thioester substrates in which parts of the peptide backbone are altered either by the replacement of three amino acid blocks with a flexible spacer or by replacement of individual amide bonds with ester bonds. Rates of TE domain catalyzed cyclization were determined for these substrates and compared with that of the wild-type substrate, revealing that some parts of the peptide backbone are important for cyclization, while other parts can be modified without significantly affecting the cyclization rate. We also report the synthesis of a modified substrate in which the N-terminal amino group of the wild-type substrate, which is the nucleophile in the cyclization reaction, is replaced with a hydroxyl group and show that this compound is cyclized by the TE domain to form a macrolactone at a rate comparable to that of the wild-type substrate. These results demonstrate that the TE domain from the tyrocidine NRPS can catalyze cyclization of depsipeptides and other backbone-substituted peptides and suggest that during the cyclization reaction the peptide substrate is preorganized for cyclization in the enzyme active site in part by intramolecular backbone hydrogen bonds analogous to those in the product tyrocidine A.     

Mutation of the phosphorylatable residue Thr429 in Glu of the human VPAC1 led to a constitutively desensitized receptor

The hVPAC1 receptor is rapidly phosphorylated and internalized by agonists but not re-expressed at the membrane after washing. Mutation of Ser/Thr residues in the C-terminus reduced phosphorylation but not internalization that was abolished only when all the phosphorylatable residues were mutated. Substitution of Thr429 by Glu mimicking a phosphothreonin led to a mutant with unchanged binding properties, decreased coupling to adenylate cyclase consisting in a reduced VIP potency, increased basal and VIP stimulated phosphorylation, preserved internalization followed by a rapid receptor re-expression. These are the expected characteristics of a constitutively desensitized receptor, putting forward the role of Thr429 phosphorylation in that process.     

Protein kinase C inhibits type VI adenylyl cyclase by phosphorylating the regulatory N domain and two catalytic C1 and C2 domains

We previously showed that phosphorylation of Ser(10) of the N terminus domain of the type VI adenylyl cyclase (ACVI) partly mediated protein kinase C (PKC)-induced inhibition of ACVI. We now report that phosphorylation of the other two cytosolic domains (C1 and C2), which form the catalytic core complex of ACVI, also contributes to PKC-mediated inhibition. In vitro phosphorylation by PKC of the recombinant C1a and C2 domains, and of the synthetic peptides representing potential PKC phosphorylation sites, suggests that Ser(568) and Ser(674) of the C1 domain and Thr(931) of the C2 domain might act as substrates for PKC. We next created several full-length ACVI mutants in which one or more of the four likely PKC phosphorylation sites (Ser(10), Ser(568), Ser(674), and Thr(931)) were mutated to alanine. Simultaneous mutation of at least two of the three likely residues located in the N and C1 domains (Ser(10), Ser(568), and Ser(674)) was required to render ACVI variants completely insensitive to PKC treatment. In contrast, a single mutation of Thr(931) was sufficient to create a functional ACVI mutant that exhibited no detectable PKC-mediated inhibition, demonstrating the essentiality of Thr(931) to PKC-mediated regulation. Based on these results, we propose that the three cytosolic domains of ACVI might form a regulatory complex. Phosphorylation of this regulatory complex at different sites might induce a fine-tuning of the catalytic core complex and subsequently lead to alternation in the catalytic activity of ACVI.     

Chemoenzymatic design of acidic lipopeptide hybrids: new insights into the structure-activity relationship of daptomycin and A54145

The acidic lipopeptides, including the clinically approved antibiotic daptomycin, constitute a class of structurally related branched cyclic peptidolactones and peptidolactams synthesized by nonribosomal peptide synthetases (NRPSs). In this study, the excised peptide cyclases from A54145 and daptomycin NRPSs were shown to be able to catalyze the macrocyclization of peptide thioester substrates, which were chemically produced by solid phase peptide synthesis. Applying this chemoenzymatic strategy, we generated derivatives of A54145 and daptomycin as well as hybrid molecules of both compounds. Bioactivity determination of the derived cyclic molecules revealed new insights into the structure-activity relationship of the acidic lipopeptide family. The general importance of several amino acid positions, including two conserved aspartic acid residues, was confirmed to be substantial for antibiotic potency. As a robust macrocyclization catalyst, the peptide cyclase excised from A54145 synthetase is the first cyclase of a branched cyclic lipopeptide, which catalyzes both macrolactonization and macrolactamization. The results presented herein illustrate the advantages of combining organic synthesis with natural product biosynthetic enzymes to explore the interplay between structural features and biological activity.     

Posttranslational heterocyclization of cysteine and serine residues in the antibiotic microcin B17: distributivity and directionality

To produce the antibiotic Microcin B17, four Cys and four Ser residues are converted into four thiazoles and four oxazoles by the three subunit Microcin B17 synthetase. High-resolution mass spectrometry (MS) was used to monitor the kinetics of posttranslational heterocyclic ring formation (-20 Da per ring) and demonstrated the accumulation of all intermediates, from one to seven rings, indicating distributive processing. All of the intermediates could be converted by the enzyme to the eight ring product. Enzymatic chemoselectivity (Cys vs Ser cyclization rates) was assessed using iodoacetamido-salicylate to alkylate unreacted cysteines (+193 Da) in the 8 kDa biosynthetic intermediates; three of the first four rings formed were thiazoles, and by the five ring stage, all four of the cysteines had been heterocyclized while three of the original four serines remained uncyclized. Finally, tandem MS using a 9.4 T Fourier transform instrument with electrospray ionization was used to elaborate the major processing pathway: the first two rings formed are at the most amino proximal sites (Cys(41) then Ser(40)) followed by the remaining three cysteines at positions 48, 51, and 55. The cyclization of serines at positions 56, 62, and 65 then follows, with Ser(62) and Ser(65) the last to heterocyclize and the first of these at a slower rate. Thus, despite free dissociation of intermediates after each of seven ring-forming catalytic cycles, there is an overall directionality of ring formation from N-terminal to C-terminal sites. This remarkable regioselectivity is determined more by the substrate than the enzyme, due to a combination of (1) initial high-affinity binding of the posttranslational catalyst to the N-terminal propeptide of substrate 88mer, and (2) a chemoselectivity for thiazole over oxazole formation. This mechanism is consistent with antibiotic biosynthesis in vivo, yielding microcin with six, seven, and eight rings, all with bioactivity.     

Characterization of a eukaryotic-like tyrosine protein kinase expressed by the Shiga toxin-encoding bacteriophage 933W

The Shiga toxin (Stx)-encoding bacteriophage 933W contains an open reading frame, stk, with amino acid sequence similarity to the catalytic domain of eukaryotic serine/threonine (Ser/Thr) protein kinases (PKs). Eukaryotic PKs are related by a common catalytic domain, consisting of invariant and nearly invariant residues necessary for ATP binding and phosphotransfer. We demonstrate that rather than a Ser/Thr kinase, stk encodes a eukaryotic-like tyrosine (Tyr) kinase. An affinity-purified recombinant Stk (rStk) autophosphorylates and catalyzes the phosphorylation of an artificial substrate on Tyr residues and not on Ser or Thr residues. A change of an invariant lysine within the putative catalytic domain abolishes this kinase activity, indicating that Stk uses a phosphotransfer mechanism similar to the mechanism used by eukaryotic PKs. We provide evidence suggesting that stk is cotranscribed with cI from the phage promoter responsible for maintaining CI expression during lysogeny. The stk gene was identified in prophages obtained from independently isolated Stx-producing Escherichia coli clinical isolates, suggesting that selective pressure has maintained the stk gene in these pathogenic bacteria.     

Synthesis and Cytotoxic Activity of the Products of Addition of Thiophenol to Sesquiterpene Lactones

Russian Journal of Bioorganic Chemistry - Derivatives of sesquiterpene lactones modified at the lactone ring with a thiophenol residue have been synthesized. The resulting conjugates with...     

Protein-splicing reaction via a thiazolidine intermediate: crystal structure of the VMA1-derived endonuclease bearing the N and C-terminal propeptides

Protein splicing excises an internal intein segment from a protein precursor precisely, and concomitantly ligates flanking N and C-extein polypeptides at the respective sides of the precursor. Here, a series of precursor recombinants bearing 11 N-extein and ten C-extein residues is prepared for the intein of the Saccharomyces cerevisiae VMA1-derived homing endonuclease referred to as VDE and as PI-SceI. The recombinant with replacements of C284S, H362N, N737S, and C738S is chosen as a spliceable precursor model and is then subjected to a 2.1A resolution crystallographic analysis. The crystal structure shows that the introduced extein polypeptides are located in the vicinity of the splicing site, and that each of their peptide bonds is in the trans conformation. The S284 O(gamma) atom located at a distance of 3.1A from the G283 C atom in the N-terminal junction suggests that a nucleophilic attack of the C284 S(gamma) atom on the G283 C atom forms a tetrahedral intermediate containing a five-membered thiazolidine ring. The tetrahedral intermediate is supposedly resolved into a thioester acyl group upon the cleavage of the linkage between the G283 C and C284 N atoms, and this thioester acyl formation completes the initial steps of Nright arrowS acyl shift at the junction between the N-extein and intein. The S738 O(gamma) atom in the C-terminal junction is placed in close proximity to the S284 O(gamma) atom at a distance of 3.6A, and is well suited for another nucleophilic attack on the resultant thioester acyl group that is then subjected to the transesterification in the next step. The reaction steps proposed for the acyl shift are driven entirely by protonation and deprotonation, in which proton ingress and egress is balanced within the splicing site.     

Squalene-hopene cyclase (Spterp25) from Streptomyces peucetius: sequence analysis, expression and functional characterization

Squalene-hopene cyclase, which catalyzes the complex cyclization of squalene to the pentacyclic triterpene, hopene, is a key enzyme in the biosynthesis of hopanoids. The deduced amino acid sequence of the Streptomyces peucetius gene (spterp25) had significant similarity to other prokaryotic squalene-hopene cyclases. Like other triterpene cyclases, the S. peucetius squalene-hopene cyclase contains eight so-called QW-motifs with an aspartate-rich domain. The 2,025-bp squalene-hopene cyclase-encoding gene was expressed in Escherichia coli BL21(DE3)pLySs, and the in vitro activity of the recombinant cyclase was demonstrated using purified membrane protein. The cyclization product hopene was identified by gas chromatography/mass spectrometry (GC/MS).     

Purification of hog liver isomerase. Mechanism of isomerization of 3-alkenyl and 3-alkynyl thioesters.

A hog liver enzyme that catalyzes the reversible conversion of 3-acetylenic fatty acyl thioester to (+)-2,3-dienoyl fatty acyl thioester has been purified to homogeneity. The enzyme is not inhibited by the allenic product that it generates. The same homogenous enzyme catalyzes the conversions of 3-cis- or 3-trans-acyl Coenzyme A derivatives to 2-trans-acyl-CoA derivatives. Four forms of the isomerase differing in charge (pI = 6.57, 6.83, 7.01, and 7.27) have been separated by isoelectric focusing. Ultracentrifugation and sodium dodecyl sulfate-gel electrophoresis indicate that each of these enzyme forms is dimeric and composed of two 45,000-dalton subunits. With 3-acetylenic substrates, all enzyme forms exhibit broad specificity for chain length (C6 to C12) and for the thioester moiety (N-acetylcysteamine (NAC), pantetheine, or CoA). The 3-cis and 3-trans olefinic substrates are active only in the form of their coenzyme A derivatives; their NAC thioesters inhibit competitively. Mechanistic studies favor an isomerization pathway by way of carbanion intermediates. The acetylene-allene isomerase described here and the reported crotonase-catalyzed hydration of allenic thioesters (Branchini, B.R., Miesowicz, F.M., and Bloch, K. (1977) Bioorg. Chem. 6, 49-52) may be responsible for the degradation of naturally occurring acetylenic and allenic acids.     

Selective peptide bond hydrolysis of cysteine peptides in the presence of Ni(II) ions

Recently, we described a sequence-specific R1-(Ser/Thr) peptide bond hydrolysis reaction in peptides of a general sequence R1-(Ser/Thr)-Xaa-His-Zaa-R, which occurs in the presence of Ni(II) ions [A. Kr??el, E. Kopera, A. M. Protas, A. Wys?ouch-Cieszyńska, J. Poznański, W. Bal, J. Am. Chem. Soc. 132 (2010) 3355-3366]. In this study we explored the possibility of substituting the Ser/Thr and the His residues, necessary for the reaction to occur according to the Ni(II)-assisted acyl shift reaction mechanism, with Cys residues. We tested this concept by synthesizing three homologous peptides: R1-Ser-Arg-Cys-Trp-R2, R1-Cys-Arg-His-Trp-R2, and R1-Cys-Arg-Cys-Trp-R2, and the R1-Ser-Arg-His-Trp-R2 peptide as comparator (R1 and R2 were CH3CO-Gly-Ala and Lys-Phe-Leu-NH2, respectively). We studied their hydrolysis in the presence of Ni(II) ions, under anaerobic conditions and in the presence of TCEP as a thiol group antioxidant. We measured hydrolysis rates using HPLC and identified products of reaction using electrospray mass spectrometry. Potentiometry and UV-vis spectroscopy were used to assess Ni(II) complexation. We demonstrated that Ni(II) is not compatible with the Cys substitution of the Ser/Thr acyl acceptor residue, but the substitution of the Ni(II) binding His residue with a Cys yields a peptide susceptible to Ni(II)-related hydrolysis. The relatively high activity of the R1-Ser-Arg-Cys-Trp-R2 peptide at pH 7.0 suggests that this peptide and its Cys-containing analogs might be useful in practical applications of Ni(II)-dependent peptide bond hydrolysis.     

Structural studies of intermediates along the cyclization pathway of Aplysia ADP-ribosyl cyclase

Cyclic ADP-ribose (cADPR) is a calcium messenger that can mobilize intracellular Ca²⁺ stores and activate Ca²⁺ influx to regulate a wide range of physiological processes. Aplysia cyclase is the first member of the ADP-ribosyl cyclases identified to catalyze the cyclization of NAD⁺ into cADPR. The catalysis involves a two-step reaction, the elimination of the nicotinamide ring and the cyclization of the intermediate resulting in the covalent attachment of the purine ring to the terminal ribose. Aplysia cyclase exhibits a high degree of leniency towards the purine base of its substrate, and the cyclization reaction takes place at either the N1- or the N7-position of the purine ring. To decipher the mechanism of cyclization in Aplysia cyclase, we used a crystallization setup with multiple Aplysia cyclase molecules present in the asymmetric unit. With the use of natural substrates and analogs, not only were we able to capture multiple snapshots during enzyme catalysis resulting in either N1 or N7 linkage of the purine ring to the terminal ribose, we were also able to observe, for the first time, the cyclized products of both N1 and N7 cyclization bound in the active site of Aplysia cyclase.     

Characterization of the surfactin synthetase C-terminal thioesterase domain as a cyclic depsipeptide synthase

The C-terminal thioesterase domain of the nonribosomal peptide synthetase producing the lipopetide surfactin (Srf TE) retains autonomous ability to generate the cyclic peptidolactone skeleton of surfactin when provided with a soluble beta-hydroxy-butyryl-heptapeptidyl thioester substrate. Utilizing the recently solved crystal structure [Bruner, S. D., et al. (2002) Structure 10, 301-310], the active-site nucleophile, Ser80, was changed to Cys, and the other members of the catalytic triad, Asp107 and His207, were changed to Ala, with the resulting mutants lacking detectable activity. Two cationic side chains in the active site, Lys111 and Arg120, were changed to Ala, causing an increased partitioning of the product to hydrolysis, as did a P26G mutant, mimicking the behavior of lipases. To evaluate recognition elements in substrates used by Srf TE, alterations to the fatty acyl group, the heptapeptide, and the thioester leaving group were made, and the resulting substrates were characterized for kinetic competency and flux of product to cyclization or hydrolysis. Alterations that could be accepted for cyclization were identified in all three parts of the substrate, although tolerance limits for changes varied. In addition, cocrystal structures of Srf TE with dipeptidyl boronate inhibitors were solved, illustrating the critical binding determinants of the substrate. On the basis of the structures and biochemical data, the cyclizing conformation of the surfactin peptide was modeled into the enzyme active site.     

Autophosphorylated residues involved in the regulation of human chk2 in vitro

Human checkpoint kinase 2 is a major actor in checkpoint activation through phosphorylation by ataxia telangiectasia mutated in response to DNA double-strand breaks. In the absence of de novo DNA damage, its autoactivation, reported in the event of increased Cds1/checkpoint kinase 2 (Chk2) expression, has been attributed to oligomerization. Here we report a study performed on autoactivated recombinant Chk2 proteins that aims to correlate kinase activity and phosphorylation status. Using a fluorescence-based technique to assay human checkpoint kinase 2 catalytic activity, slight differences in the ability to phosphorylate Cdc25C were observed, depending on the recombinant system used. Using mass spectrometry, the phosphorylation sites were mapped to identify sites potentially involved in the kinase activity. Five phosphorylated positions, at Ser120, Ser260, Thr225, Ser379 and Ser435, were found to be common to bacteria and insect cells expression systems. They were present in addition to the six known phosphorylation sites induced by ionizing radiation (Thr68, Thr432, Thr387, Ser516, Ser33/35 and Ser19) detected by immunoblotting. After phosphatase treatment, Chk2 regained activity via autorephosphorylation. The determination of the five common sites and ionizing-radiation-inducible positions as rephosphorylated confirms that they are potential positive regulators of Chk2 kinase activity. For Escherichia coli's most highly phosphorylated 6His-Chk2, 13 additional phosphorylation sites were assigned, including 7 novel sites on top of recently reported phosphorylation sites.     

Effects of glycosylation on the conformation and dynamics of O-linked glycoproteins: carbon-13 NMR studies of ovine submaxillary mucin

Carbon-13 NMR spectroscopic studies of native and sequentially deglycosylated ovine submaxillary mucin (OSM) have been performed to examine the effects of glycosylation on the conformation and dynamics of the peptide core of O-linked glycoproteins. OSM is a large nonglobular glycoprotein in which nearly one-third of the amino acid residues are Ser and Thr which are glycosylated by the alpha-Neu-NAc(2-6)alpha-GalNAc- disaccharide. The beta-carbon resonances of glycosylated Ser and Thr residues in intact and asialo mucin display considerable chemical shift heterogeneity which, upon the complete removal of carbohydrate, coalesces to single sharp resonances. This chemical shift heterogeneity is due to peptide sequence variability and is proposed to reflect the presence of sequence-dependent conformations of the peptide core. These different conformations are thought to be determined by steric interactions of the GalNAc residue with adjacent peptide residues. The absence of chemical shift heterogeneity in apo mucin is taken to indicate a loss in the peptide-carbohydrate steric interactions, consistent with a more relaxed random coiled structure. On the basis of the 13C relaxation behavior (T1 and NOE) the dynamics of the alpha-carbons appear to be unique to each amino acid type and glycosylation state, with alpha-carbon mobilities decreasing in the order Gly greater than Ala = Ser greater than Thr much greater than monoglycosylated Ser/Thr approximately greater than disaccharide linked Ser/Thr.(ABSTRACT TRUNCATED AT 250 WORDS)     

Discovery of Unique Lanthionine Synthetases Reveals New Mechanistic and Evolutionary Insights

Lantibiotic synthetases are remarkable biocatalysts generating conformationally constrained peptides with a variety of biological activities by repeatedly utilizing two simple posttranslational modification reactions: dehydration of Ser/Thr residues and intramolecular addition of Cys thiols to the resulting dehydro amino acids. Since previously reported lantibiotic synthetases show no apparent homology with any other known protein families, the molecular mechanisms and evolutionary origin of these enzymes are unknown. In this study, we present a novel class of lanthionine synthetases, termed LanL, that consist of three distinct catalytic domains and demonstrate in vitro enzyme activity of a family member from Streptomyces venezuelae. Analysis of individually expressed and purified domains shows that LanL enzymes install dehydroamino acids via phosphorylation of Ser/Thr residues by a protein kinase domain and subsequent elimination of the phosphate by a phosphoSer/Thr lyase domain. The latter has sequence homology with the phosphothreonine lyases found in various pathogenic bacteria that inactivate host mitogen activated protein kinases. A LanC-like cyclase domain then catalyzes the addition of Cys residues to the dehydro amino acids to form the characteristic thioether rings. We propose that LanL enzymes have evolved from stand-alone protein Ser/Thr kinases, phosphoSer/Thr lyases, and enzymes catalyzing thiol alkylation. We also demonstrate that the genes for all three pathways to lanthionine-containing peptides are widespread in Nature. Given the remarkable efficiency of formation of lanthionine-containing polycyclic peptides and the latter''s high degree of specificity for their cognate cellular targets, it is perhaps not surprising that (at least) three distinct families of polypeptide sequences have evolved to access this structurally and functionally diverse class of compounds.     

Crystal structure of the protein serine/threonine phosphatase 2C at 2.0 A resolution.

Protein phosphatase 2C (PP2C) is a Mn2+- or Mg2+-dependent protein Ser/Thr phosphatase that is essential for regulating cellular stress responses in eukaryotes. The crystal structure of human PP2C reveals a novel protein fold with a catalytic domain composed of a central beta-sandwich that binds two manganese ions, which is surrounded by alpha-helices. Mn2+-bound water molecules at the binuclear metal centre coordinate the phosphate group of the substrate and provide a nucleophile and general acid in the dephosphorylation reaction. Our model presents a framework for understanding not only the classical Mn2+/Mg2+-dependent protein phosphatases but also the sequence-related domains of mitochondrial pyruvate dehydrogenase phosphatase, the Bacillus subtilus phosphatase SpoIIE and a 300-residue domain within yeast adenyl cyclase. The protein architecture and deduced catalytic mechanism are strikingly similar to the PP1, PP2A, PP2B family of protein Ser/Thr phosphatases, with which PP2C shares no sequence similarity, suggestive of convergent evolution of protein Ser/Thr phosphatases.     

Hierarchical phosphorylation of delta-opioid receptor regulates agonist-induced receptor desensitization and internalization

Treatment of HEK293 cells expressing the delta-opioid receptor with agonist [d-Pen(2,5)]enkephalin (DPDPE) resulted in the rapid phosphorylation of the receptor. We constructed several mutants of the potential phosphorylation sites (Ser/Thr) at the carboxyl tail of the receptor in order to delineate the receptor phosphorylation sites and the agonist-induced desensitization and internalization. The Ser and Thr were substituted to alanine, and the corresponding mutants were transiently and stably expressed in HEK293 cells. We found that only two residues, i.e. Thr(358) and Ser(363), were phosphorylated, with Ser(363) being critical for the DPDPE-induced phosphorylation of the receptor. Furthermore, using alanine and aspartic acid substitutions, we found that the phosphorylation of the receptor is hierarchical, with Ser(363) as the primary phosphorylation site. Here, we demonstrated that DPDPE-induced rapid receptor desensitization, as measured by adenylyl cyclase activity, and receptor internalization are intimately related to phosphorylation of Thr(358) and Ser(363), with Thr(358) being involved in the receptor internalization.