Synthesis of peptide with multiple cysteic acids

Abstract:

We have synthesized and purified a 19-amino acid peptide whose sequence is derived from the carboxyl-terminal region of bovine rhodopsin, in which the seven serines and threonines that would normally become phosphorylated have been substituted with cysteic acid. The peptide was synthesized by the Fmoc (DCC/HOBl)' procedure using Fmoc-(S-4-methoxytrityl) Cys {Fmoc-Cys(Mmt)-OH}. The Mmt group was removed and the resin-bound peptide was oxidized with performic acid, which also removed other blocking grou_psand cleaved the peptide from the resin.

Cloning and functional characterization of salamander rod and cone arrestins

PURPOSE

To clone, localize, and determine functional binding characteristics of rod and cone arrestins from the retina of the tiger salamander (Ambystoma tigrinum).

METHODS

Two arrestins from salamander retina were cloned on the basis of their homology to known arrestins from other species. The expression pattern of these arrestins (SalArr1 and SalArr2) in the retina was determined by immunocytochemistry and in situ hybridization. SalArr1 and SalArr2 were expressed and functionally characterized.

RESULTS

Both immunocytochemistry and in situ hybridization show that SalArr1 and SalArr2 localized specifically to rod and cone photoreceptors, respectively. SalArr1 demonstrated a characteristic high selectivity for light-activated phosphorylated rhodopsin (P-Rh*) and significant species selectivity, binding preferentially to amphibian rhodopsin over bovine rhodopsin. Mutant constitutively active forms of SalArr1 demonstrated a 2- to 4-fold increase in P-Rh* binding (compared with wild-type protein) and an even more dramatic (up to 25-fold) increase in binding to unphosphorylated Rh* and dark P-Rh. Constitutively active SalArr1 mutants also showed a reduced specificity for amphibian rhodopsin. The ability of Escherichia coli-expressed SalArr1, SalArr2, and an SalArr1-3A (L369A,V370A,F371A) mutant to bind to frog Rh* and P-Rh* and to compete with tritiated SalArr1 for amphibian P-Rh* was compared. SalArr1 and its mutant form bound to amphibian P-Rh* with high affinity (Ki = 179 and 74 nM, respectively), whereas the affinity of SalArr2 for P-Rh* was substantially lower (Ki = 9.1 microM).

CONCLUSIONS

SalArr1 and SalArr2 are salamander rod and cone arrestins, respectively. Crucial regulatory elements in SalArr1 are conserved and play functional roles similar to those of their counterparts in bovine rod arrestin. Rod and cone arrestins are relatively specific for their respective receptors.

Sulfhydryl reactivity demonstrates different conformational states for arrestin, arrestin activated by a synthetic phosphopeptide, and constitutively active arrestin

The sulfhydryl groups of the three cysteines in bovine arrestin react with DTNB very slowly (over a period of several hours). In the presence of the synthetic phosphopeptide comprising the fully phosphorylated carboxyl-terminal 19 amino acids of bovine rhodopsin, the reactivity of one of the sulfhydryls was enhanced while that of another was greatly reduced. Since this synthetic peptide was shown to activate arrestin with respect to its binding to unphosphorylated, light-activated rhodopsin, the reactivity of the sulfhydryl groups of a constitutively active R175Q arrestin mutant was examined. All three of the sulfhydryl groups of the mutant arrestin R175Q reacted rapidly with DTNB, but not as rapidly as with SDS-denatured arrestin. The arrestin mutant R175Q bound to light-activated, unphosphorylated rhodopsin in ROS disk membranes. The arrestin mutant R175Q also inhibited the light-activated PDE activity with an IC50 of 1.3 microM under the experimental conditions that were used. These data indicate that each of these forms of arrestin is a different conformation. The activated conformation of arrestin that binds to phosphorylated rhodopsin in vivo may be yet another conformation. We conclude that arrestin is a flexible molecule that is able to attain several different conformations, all of which are able to attain the activated functional state of arrestin.

Identification of regions of arrestin that bind to rhodopsin

Arrestin facilitates phototransduction inactivation through binding to photoactivated and phosphorylated rhodopsin (RP). However, the specific portions of arrestin that bind to RP are not known. In this study, two different approaches were used to determine the regions of arrestin that bind to rhodopsin: panning of phage-displayed arrestin fragments against RP and cGMP phosphodiesterase (PDE) activity inhibition using synthetic arrestin peptides spanning the entire arrestin protein. Phage display indicated the predominant region of binding was contained within amino acids 90-140. A portion of this region (residues 95-140) expressed as a fusion protein with glutathione S-transferase is capable of binding to rhodopsin regardless of the activation or phosphorylation state of the receptor. Within this region, the synthetic peptide of residues 109-130 was shown to completely inhibit the binding of arrestin to rhodopsin with an IC50 of 1.1 mM. The relatively high IC50 of this competition suggests that this portion of the molecule may be only one of several regions of binding between arrestin and RP. A survey of synthetic arrestin peptides in the PDE assay indicated that the two most effective inhibitors of PDE activity were peptides of residues 111-130 and 101-120. These results indicate that at least one of the principal regions of binding between arrestin and RP is contained within the region of residues 109-130.

Effects of phosphorylation on the structure of the G-protein receptor rhodopsin

Upon activation by light, rhodopsin is subject to phosphorylation by rhodopsin kinase at serine and threonine residues in the carboxyl terminal region of the protein. A 19 amino acid peptide that corresponds to the carboxyl terminal end of rhodopsin (residues 330-348) and contains these phosphorylation sites was synthesized. The structure of this peptide was determined using two-dimensional proton NMR. The structure of this peptide was similar to that determined for this region in peptides corresponding to the carboxyl 33 and 43 amino acids of rhodopsin. The effect of phosphorylation on the structure of the carboxyl terminal domain of rhodopsin was determined by solving the solution structures of the peptide containing residues 330-348 with phosphorylation at one (residue 343), three (residues 343, 338, and 334) and seven residues (residues 334, 335, 336, 338, 340, 342, 343). These data indicate that the major structural change occurs upon phosphorylation of the first residue, and that an additional structural change occurs with seven phosphates.

Organ recovery from a donor with presumed viral encephalitis: a case report and review

This article reviews the pathophysiology of viral encephalitis, which is specifically infectious to transplant recipients, and discusses the potential infectivity of donors who had this virus. In addition, the case report demonstrates one center's experience in placing organs from a donor who was presumed--but not confirmed--to have viral encephalitis. When a patient with viral encephalitis is considered for organ donation, it is recommended that a brain biopsy be obtained prior to organ placement to identify the suspected virus or confirm the absence of any viral entity.

Regulation of sorting and post-Golgi trafficking of rhodopsin by its C-terminal sequence QVS(A)PA

Several mutations that cause severe forms of the human disease autosomal dominant retinitis pigmentosa cluster in the C-terminal region of rhodopsin. Recent studies have implicated the C-terminal domain of rhodopsin in its trafficking on specialized post-Golgi membranes to the rod outer segment of the photoreceptor cell. Here we used synthetic peptides as competitive inhibitors of rhodopsin trafficking in the frog retinal cell-free system to delineate the potential regulatory sequence within the C terminus of rhodopsin and model the effects of severe retinitis pigmentosa alleles on rhodopsin sorting. The rhodopsin C-terminal sequence QVS(A)PA is highly conserved among different species. Peptides that correspond to the C terminus of bovine (amino acids 324-348) and frog (amino acids 330-354) rhodopsin inhibited post-Golgi trafficking by 50% and 60%, respectively, and arrested newly synthesized rhodopsin in the trans-Golgi network. Peptides corresponding to the cytoplasmic loops of rhodopsin and other control peptides had no effect. When three naturally occurring mutations: Q344ter (lacking the last five amino acids QVAPA), V345M, and P347S were introduced into the frog C-terminal peptide, the inhibitory activity of the peptides was no longer detectable. These observations suggest that the amino acids QVS(A)PA comprise a signal that is recognized by specific factors in the trans-Golgi network. A lack of recognition of this sequence, because of mutations in the last five amino acids causing autosomal dominant retinitis pigmentosa, most likely results in abnormal post-Golgi membrane formation and in an aberrant subcellular localization of rhodopsin.

Rhodopsins from three frog and toad species: sequences and functional comparisons

The frequency of thermal 'dark events' in the membrane current of rhodopsin rods of the bullfrog, Rana catesbeiana, is considerably lower than observed in rods of two toad species, even though all three rhodopsins have approximately the same absorbance characteristics. In order to map amino acid substitutions possibly associated with thermal stability in the genus Rana, the cDNA's coding for the rhodopsins of Bufo bufo, B. marinus and R. temporaria were sequenced and the conceptually translated protein sequences aligned to the previously sequenced rhodopsins of R. catesbeiana, R. pipiens and Xenopus laevis. Across the six anuran species studied, there are sixteen non-conserved substitutions and six changes that include gain or loss of a hydroxyl group. Serine or threonine at position 220 is unique to the three Rana species, phenylalanine at position 270 is unique to all three Ranas and to X. laevis, and phenylalanine at position 274 is unique to both species of the genus Bufo. This investigation produces a list of substitutions that are candidates for future studies of thermal stability. In addition, a number of amino acids are identified that apparently do not influence absorbance characteristics, at least not cumulatively.

Rhodopsins with Similar Absorbance Characteristics but Different Rates of Thermal Activation: Amino Acid Sequences

Thermal activation of the visual pigment is thought to be an important factor that in many cases limits the absolute sensitivity of vision in darkness. It has been suggested that pigments with high \lambdamax (ie with good absorbance at long wavelengths, allowing ‘red-sensitive’ vision) are associated with a cost in terms of high thermal activation rates, degrading signal/noise and hence visual sensitivity [Barlow, 1957 Nature (London)179 255 – 256]. While rhodopsins in different species do show a general correlation between red-sensitivity and high thermal activation rates as measured electrophysiologically in whole rods (Firsov and Govardovskii, 1990 Sensornye Sistemy4 25 – 34), a comparison of the toads Bufo marinus and B. bufo with the bull-frog Rana catesbeiana has suggested that the two properties are not tightly coupled. Toad and bull-frog rhodopsins have almost the same \lambdamax, yet the thermal activation rate in bull-frog rods is lower by almost one order of magnitude [Donner et al, 1990 Journal of Physiology (London)428 673 – 692]. We have sequenced the cDNA coding for the rhodopsins of the two toad species and that of the common frog R. temporaria and aligned them to previously sequenced rhodopsins of R. catesbeiana, R. pipiens and Xenopus laevis in an attempt to identify substitutions that could underlie the greater thermal stability of bull-frog rhodopsin compared with toad rhodopsins.

The open reading frame predicted proteins of 354 amino acids. There was 96% identity between species of the same genus and 90% identity between genera. Across the six species studied, there is a total of 22 non-conserved substitutions and changes that include gain or loss of hydroxyl groups. Our study produced a list of substitutions that apparently do not significantly affect absorbance characteristics. We could not, however, unequivocally identify substitutions important for thermal stability.

Synthesis of Multiphosphorylated Peptide From a C-Terminal Bovine Rhodopsin Sequence

Abstract:

We have synthesized and purified a 19-amino acid peptide, containing 4 phosphothreonines and 3 phosphoserines, of sequence derived from the C-terminal region of bovine rhodopsin. The peptide has been synthesized on Pamt resin using Boc-0-(diphenylphosphono)-serine and -threonine. Cleavage and deblocking have been performed in a single step using catalytic hydrogenolysis in the presence of palladium {II) and platinum (IV) with anhydrous trifluoroacetic acid as solvent.

Alligator rhodopsin: sequence and biochemical properties

We sequenced selected peptides of alligator rhodopsin that accounted for about half of the total protein. These sequences were confirmed when the total primary structure of alligator rhodopsin was deduced from the cDNA sequence. Differences in the amino-terminal region, compared to that of bovine rhodopsin, account for failure of cross-reactivity of several anti-bovine rhodopsin monoclonal antibodies. Differences in the carboxyl-terminal region give rise to limited antibody cross-reactivity and may also account for a slightly reduced ability of alligator rhodopsin to be phosphorylated by bovine rhodopsin kinase. Alligator rhodopsin regenerates much faster than bovine rhodopsin. The pseudo-first-order rate constant for alligator rhodopsin regeneration is approximately 25 times that of bovine. Phylogenetic analysis of 17 rhodopsin sequences indicates that the alligator is more closely related to the chicken than to the other species examined.

The deduced amino-acid sequence of opsin from rabbit rod photoreceptors

The amino acid (aa) sequence of rabbit opsin from rod photoreceptor cells was determined by direct aa sequencing and conceptual translation from the cDNA. The cDNA (1198 bp) containing the complete coding region encodes a 348-aa opsin protein. Of the 16 rod cell opsins that are known, rabbit opsin is most similar to human opsin (96.3% identity at the aa level).

Synthetic phosphopeptide from rhodopsin sequence induces retinal arrestin binding to photoactivated unphosphorylated rhodopsin

A synthetic heptaphosphopeptide comprising the fully phosphorylated carboxyl terminal phosphorylation region of bovine rhodopsin, residues 330-348, was found to induce a conformational change in bovine arrestin. This caused an alteration of the pattern of limited proteolysis of arrestin similar to that induced by binding phosphorylated rhodopsin or heparin. Unlike heparin, the phosphopeptide also induced light-activated binding of arrestin to both unphosphorylated rhodopsin in disk membranes as well as to endoproteinase Asp-N-treated rhodopsin (des 330-348). These findings suggest that one function of phosphorylation of rhodopsin is to activate arrestin which can then bind to other regions of the surface of the photoactivated rhodopsin.

Use of cryotherapy for orthopaedic patients

Effective pain management and prevention of edema are goals for orthopaedic patients after injury and after surgery. Cryotherapy is the use of cold to decrease swelling and pain when tissue is damaged secondary to trauma or surgery. Although cryotherapy has been used for years by some practitioners to achieve these goals, it is gaining wider acceptance in sports medicine for acute and postoperative care. Newer techniques of application have broadened its use for postoperative care. This article reviews the physiology of cold, basic principles of cryotherapy, various techniques of cold application, nursing assessment and care, and patient teaching for a patient with cryotherapy.

Optimization of peptide synthesis on polyethylene rods

Multipin solid-phase peptide synthesis is widely used for epitope mapping of monoclonal and polyclonal antibodies. However, neither the chemical yield nor the homogeneity of products currently match those of solid-phase synthesis of peptides on resins. In order to improve synthesis parameters, we have repeated the standard procedure and introduced modifications during synthesis of model heptapeptides and peptides from the sequence of rhodopsin and other proteins. Good incorporation of amino acids using the multipin peptide synthesis system can now be obtained in less synthesis time and with less costly reagents.

Phosphorylation sites in bovine rhodopsin

Bovine rhodopsin has been phosphorylated in rod outer segments by ATP and endogenous rhodopsin kinase. Mono-, di-, and triphosphorylated rhodopsins have been prepared by chromatofocusing. Nearly all of the phosphate is found in peptide 330-348, formed by digestion of phosphorhodopsins with endoproteinase Asp-N. Sequence analysis of the phosphopeptides shows that monophosphorylated rhodopsin consists of a mixture containing rhodopsins phosphorylated at 338Ser and 343Ser. Diphosphorylated rhodopsin is phosphorylated at both 338Ser and 343Ser. When rhodopsin becomes triphosphorylated it does not become phosphorylated on 334Ser but appears to become phosphorylated on one or more of the four threonine residues: 335Thr, 336Thr, 340Thr, and 342Thr.

Rhodopsin and phototransduction: a model system for G protein-linked receptors

Rhodopsin is the photoreceptor protein in rod cells of the vertebrate retina and the first member of the class of G protein-coupled receptors for which the amino acid sequence was determined. Rhodopsin is available in greater quantities than any other receptor of its class and therefore has been studied biochemically and biophysically by methods difficult or impossible to apply to its fellow receptors. Such studies support a model in which rhodopsin consists of seven transmembrane helices that form a binding pocket for its ligand, 11-cis retinal. Insights into the structure and function of rhodopsin serve as a model for understanding the structure and function of other members of the receptor class. Rhodopsin undergoes a change in conformation upon photoexcitation and activates a G protein, transducin, and is phosphorylated by a receptor-specific kinase, rhodopsin kinase. The phosphorylated photoactivated rhodopsin is bound by arrestin, thereby terminating activity of the receptor in the signal transduction process. These auxiliary proteins that function with rhodopsin on rod cells serve as models for understanding how other members of the receptor family may function in conjunction with other G proteins, kinases, and arrestin-like proteins.

Differential scanning calorimetry of bovine rhodopsin in rod-outer-segment disk membranes

Rhodopsin-containing retinal rod disk membranes from cattle have been examined by differential scanning calorimetry. Under conditions of 67 mM phosphate pH 7.0, unbleached rod outer segment disk membranes gave a single major endotherm with a temperature of denaturation (Tm) of 71.9 +/- 0.4 degrees C and a thermal unfolding calorimetric enthalpy change (delta Hcal) of 700 +/- 17 kJ/mol rhodopsin. Bleached rod outer segment disk membranes (membranes that had lost their absorbance at 498 nm after exposure to orange light) gave a single major endotherm with a Tm of 55.9 +/- 0.3 degrees C and a delta Hcal of 520 +/- 17 kJ/mol opsin. Neither bleached nor unbleached rod outer segment disk membranes gave endotherms upon thermal rescans. When thermal stability is examined over the pH range of 4-9, the major endotherms of both bleached and unbleached rod outer segment disk membranes were found to show maximum stability at pH 6.1. The observed delta Hcal values for bleached and unbleached rod outer segment disk membranes exhibit membrane concentration dependences which plateau at protein concentrations beyond 1.5 mg/mL. For partially bleached samples of rod outer segment disk membranes, the calorimetric enthalpy change for opsin appears to be somewhat dependent on the degree of bleaching, indicating intramembrane nearest neighbor interactions which affect the unfolding of opsin. Delta Hcal and Tm are particularly useful for assessing stability and testing for completeness of regeneration of rhodopsin from opsin. Other factors such as sample preparation and the presence of low concentrations of ethanol also affect the delta Hcal values while the Tm values remain fairly constant. This shows that the delta Hcal is a sensitive parameter for monitoring environmental changes of rhodopsin and opsin.

Role of the carboxyl-terminal region of arrestin in binding to phosphorylated rhodopsin

The structural and functional properties of arrestin were studied by subjecting the protein to limited proteolysis. Limited proteolysis by trypsin cleaves arrestin (48 kDa), producing 20-25-kDa fragments. Prior to this stage of proteolysis, trypsin produced 46.6-, 45.4-, and 42-kDa fragments. Structural analysis of the proteolytic fragments demonstrated major cleavage at the carboxyl terminus, indicating that the carboxyl terminus is highly exposed. We found that forms of arrestin truncated at their carboxyl terminus maintained their functional properties and bound to phosphorylated rhodopsin. Native arrestin binds only to photoexcited phosphorylated rhodopsin, whereas the truncated arrestin binds to phosphorylated rhodopsin independent of its exposure to light. The truncated forms of arrestin were separated from native arrestin by a chromatographic procedure and subsequently characterized in functional studies. The binding of the truncated forms of arrestin to phosphorylated photoexcited rhodopsin is more tight than the binding of native arrestin as determined by a direct binding assay and the phosphodiesterase assay. We suggest that the acidic carboxyl-terminal region of arrestin may act as a regulator for light-dependent binding to phosphorylated rhodopsin.

Anti-rhodopsin monoclonal antibodies of defined specificity: characterization and application

A panel of anti-bovine rhodopsin monoclonal antibodies (MAbs) of defined site-specificity has been prepared and used for functional and topographic studies of rhodopsins. In order to select these antibodies, hybridoma supernatants that contained anti-rhodopsin antibodies have been screened by enzyme-linked immunosorbent assay (ELISA) in the presence of synthetic peptides from rhodopsin's cytoplasmic regions. We selected for antibodies against predominantly linear determinants (as distinct from complex assembled determinants) and have isolated antibodies that recognize rhodopsin's amino terminus, its carboxyl terminus, as well as the hydrophilic helix-connecting regions 61-75, 96-115, 118-203, 230-252 and 310-321. Detailed specificities have been further determined by using a series of overlapping peptides and chemically modified rhodopsins as competitors. A group of seven antibodies with epitopes clustered within the amino terminal region of rhodopsin and a group of 15 antibodies with epitopes within the carboxyl terminal region are described. These MAbs have high affinities for rhodopsin with Kas in the range of 10(8)-10(10) M-1. Some MAbs specific for the carboxyl and amino terminal regions were used to compare these bovine rhodopsin sequences to those of different vertebrates. The MAbs cross-reacted with the different species tested to different extents indicating that there is some similarity in the sequences of these regions. However, some differences in the sequences were indicated by a reduced or absent cross-reactivity with some MAbs. In membrane topographic studies the MAbs showed both the presence and the accessibility of rhodopsin sequences 330-348, 310-321 and 230-252 on the cytoplasmic surface of the disk membrane. Similarly, sequences 1-20 and 188-203 were shown to reside on the lumenal surface of the disk and to be accessible to a macromolecular (antibody) probe. Antibodies directed against rhodopsin's carboxyl terminal sequence did not bind well to highly phosphorylated rhodopsin. Similarly, these antibodies as well as those against the V-VI loop inhibited phosphorylation of rhodopsin. Antibody A11-82P, specific for phosphorylated rhodopsin, recognized rhodopsin containing two or more phosphates and inhibited its further phosphorylation.

Phosphorylation of iodopsin, chicken red-sensitive cone visual pigment

The amino acid sequence has been determined for the carboxyl-terminal 41 amino acids of chicken red-sensitive cone pigment, iodopsin. This sequence is distinct from but structurally homologous to that of other visual pigments. It contains a region rich in the hydroxy amino acids serine and threonine. In the related rod cell visual pigment, rhodopsin, such serines and threonines have previously been identified as sites for phosphorylation by rhodopsin kinase. Phosphorylation of photolyzed rhodopsin serves to terminate its ability to function in visual transduction as an activator of G-protein. We have purified and reconstituted both chicken rhodopsin and chicken iodopsin and shown them to be phosphorylated by bovine rhodopsin kinase. Chicken iodopsin has a Km and Vmax similar to but distinguishably different from that for bovine rhodopsin. These results, in conjunction with other data, suggest that visual pigments in cone cells, upon absorption of light, undergo functional processes similar to those of the visual pigments in rod cells.