A low-affinity Ca2+-dependent association of calmodulin with the Rab3A effector domain inversely correlates with insulin exocytosis.

The stimulus-response coupling pathway for glucose-regulated insulin secretion has implicated a rise in cytosolic [Ca2+]i as a key factor to induce insulin exocytosis. However, it is unclear how elevated [Ca2+]i communicates with the pancreatic beta-cell's exocytotic apparatus. As Rab3A is a model protein involved in regulated exocytosis, we have focused on its role in regulating insulin exocytosis. By using a photoactivatable cross-linking synthetic peptide that mimics the effector domain of Rab3A and microsequence analysis, we found calmodulin to be a major Rab3A target effector protein in pancreatic beta-cells. Coimmunoprecipitation analysis from pancreatic islets confirmed a Rab3A-calmodulin interaction in vivo, and that it inversely correlated with insulin exocytosis. Calmodulin affected neither GTPase nor guanine nucleotide exchange activity of Rab3A. The calmodulin-Rab3A interaction was pH- and Ca2+-dependent, and it was preferential for GTP-bound Rab3A. However, Rab3A affinity for calmodulin was relatively low (Kd = 18-22 micromol/l at 10(-5) mol/l [Ca2+]) and competed by other calmodulin-binding proteins that had higher affinity (e.g., Ca2+/calmodulin-dependent protein kinase-2 [CaMK-2] [Kd = 300-400 nmol/l at 10(-5) mol/l [Ca2+]]). Moreover, the Ca2+ dependence of the calmodulin-Rab3A interaction (K0.5 = 15-18 micromol/l [Ca2+], maximal at 100 micromol/l [Ca2+]) was significantly lower compared with that of the calmodulin-CaMK-2 association (K0.5 = 40 micromol/l [Ca2+], maximal at 1 mmol/l [Ca2+]). The data suggested that a transient Rab3A-calmodulin interaction might represent a means of directing calmodulin to the cytoplasmic face of a beta-granule, where it can be subsequently transferred for activation of other beta-granule-associated calmodulin-binding proteins as local [Ca2+]i rises to promote insulin exocytosis.

Chemical and biochemical issues related to X-ray crystallography of the ligand-binding domain of estrogen receptor alpha.

Careful attention to technical issues preceded successful crystallography of the ligand-binding domain of estrogen receptor alpha (ERalpha) complexed with CP-336156, a nonsteroidal estrogen agonist/antagonist. An affinity column based on immobilized estradiol was prepared according to the scheme of Greene et al. (Greene, G. L., Nolan, C., Engler, J. P., and Jensen, E. V. (1980) Proc. Natl. Acad. Sci. U.S.A. 77, 5115-5119). It was shown by X-ray crystallography that the major and less polar isomer of the affinity column precursor was 17alpha-((S)-2',3'-epoxyprop-1'-yl)estra-1,3,5(10)-triene-3,17beta-diol. This diastereomer was coupled to Thiopropyl Sepharose, with coupling monitored by observing loss of the phenolic absorption band of estradiol from the reaction supernatant, and gave an affinity matrix containing about 9 micromol of estradiol per milliliter of wet gel. Recombinant ERalpha ligand binding domain was selectively removed from E. coli cell lysate by binding to the column and was partly S-carboxymethylated by treatment with iodoacetic acid while bound to the column as described by previous workers. After being eluted from the column as a complex with drug, the receptor fragment was shown by mass spectrometry to be a mixture of differently modified forms. It was further S-carboxymethylated in solution, after which anion-exchange chromatography was used to isolate protein in which two of the four cysteine residues were S-carboxymethylated. This material, which afforded diffraction-quality crystals, was subjected to digestion with trypsin and peptide mapping analysis by HPLC coupled with mass spectrometry. For this experiment, the two previously unmodified cysteines were alkylated with 4-vinylpyridine to allow definitive identification. It was shown that Cys-417 and Cys-530 were S-carboxymethylated in the crystallized protein, while Cys-381 and Cys-447 remained unmodified. Close attention to such technical issues may be important in structural studies of other nuclear receptors, a very important class of potential drug targets.

Modification of amino groups.

This unit describes group-specific modifications of amino groups. These reactions remain valid tools for early-stage evaluation of structure-function relationships, but are now valued even more for their applications in the preparation of bioconjugates, affinity columns, biosensors, and tagged macromolecules. Protocols are provided here for reaction of amino groups with succinimidyl esters and isothiocyanates. These methods are broadly useful for the stable coupling to proteins of groups with useful, non-native functional properties. These include biotin for detection or recovery, fluorescent groups for biophysics or cytochemistry, cross-linking reagents for making bioconjugates, or metal-chelators that permit proteins to be loaded with radioisotopes for medical imaging or antitumor therapy. These applications require accurate product characterization, which preferably is performed by mass spectrometry, as described in this unit as a support procedure. A protocol employing succinic or acetic anhydrides to change the charge state of protein amino groups is provided here, as is a procedure for reductive alkylation that leaves their charge unaltered but converts primary amines to secondary or tertiary amines.

Identification, characterization, and crystal structure of the Omega class glutathione transferases.

A new class of glutathione transferases has been discovered by analysis of the expressed sequence tag data base and sequence alignment. Glutathione S-transferases (GSTs) of the new class, named Omega, exist in several mammalian species and Caenorhabditis elegans. In humans, GSTO 1-1 is expressed in most tissues and exhibits glutathione-dependent thiol transferase and dehydroascorbate reductase activities characteristic of the glutaredoxins. The structure of GSTO 1-1 has been determined at 2.0-A resolution and has a characteristic GST fold (Protein Data Bank entry code ). The Omega class GSTs exhibit an unusual N-terminal extension that abuts the C terminus to form a novel structural unit. Unlike other mammalian GSTs, GSTO 1-1 appears to have an active site cysteine that can form a disulfide bond with glutathione.

Dye-pair reporter systems for protein-peptide molecular interactions.

Modifying a linear peptide near each terminus with a fluorescent dye can make it able to signal its own binding to a protein. As originally described, the dye pair is composed of fluorescein and tetramethylrhodamine [Wei, A.-P., Blumenthal, D. K., and Herron, J. N. (1994) Anal. Chem. 66, 1500-1506]. This paper shows that it may also be two molecules of tetramethylrhodamine. In aqueous solution, mutual affinity of the dyes causes fluorescence-quenching contact between them. When the peptide is bound by an antibody or cleaved by a proteinase, or when acetonitrile is added, dye-to-dye contact decreases and fluorescence increases 3-15-fold. When five peptides of 4-20 amino acid residues were doubly modified with tetramethylrhodamine, each product had the absorption spectrum of a tetramethylrhodamine dimer. As the peptides were not known to have special conformational features, self-affinity of the dye appeared to be the main cause of dimerization. Disruption of the dye dimers by acetonitrile suggested that dimerization of the dye(s) in aqueous solution was largely an effect of hydrophobicity. Dye-tagged peptides were used in fluorometric assays for two peptide-protein interactions. First, a peptide from type II collagen recognized by a monoclonal antibody was derivatized with two different dye pairs. The monoclonal bound each modified peptide, disrupting dye-to-dye contact and increasing fluorescence up to 4-fold. Second, a phosphopeptide recognized by an SH2 domain was tagged with fluorescein and tetramethylrhodamine, and its binding to the SH2 domain was detected through fluorescence. Doubly dye-tagged peptides offer a direct, solution-phase assay for protein-peptide binding.

Spontaneous alpha-N-6-phosphogluconoylation of a "His tag" in Escherichia coli: the cause of extra mass of 258 or 178 Da in fusion proteins.

Several proteins expressed in Escherichia coli with the N-terminus Gly-Ser-Ser-[His]6- consisted partly (up to 20%) of material with 178 Da of excess mass, sometimes accompanied by a smaller fraction with an excess 258 Da. The preponderance of unmodified material excluded mutation, and the extra masses were attributed to posttranslational modifications. As both types of modified protein were N-terminally blocked, the alpha-amino group was modified in each case. Phosphatase treatment converted +258-Da protein into +178-Da protein. The modified His tags were isolated, and the mass of the +178-Da modification estimated as 178.06 +/- 0.02 Da by tandem mass spectrometry. As the main modification remained at +178 Da in 15N-substituted protein, it was deemed nitrogen-free and possibly carbohydrate-like. Limited periodate oxidations suggested that the +258-Da modification was acylation with a 6-phosphohexonic acid, and that the +178-Da modification resulted from its dephosphorylation. NMR spectra of cell-derived +178-Da His tag and synthetic alpha-N-d-gluconoyl-His tag were identical. Together, these results suggested that the +258-Da modification was addition of a 6-phosphogluconoyl group. A plausible mechanism was acylation by 6-phosphoglucono-1,5-lactone, produced from glucose 6-phosphate by glucose-6-phosphate dehydrogenase (EC 1.1.1.49). Supporting this, treating a His-tagged protein with excess d-glucono-1,5-lactone gave only N-terminal gluconoylation.

Mutation of a protease-sensitive region in firefly luciferase alters light emission properties.

Luciferase (EC 1.13.12.7) from the North American firefly, Photinus pyralis, is widely used as a reporter enzyme in cell biology. One of its distinctive properties is a pronounced susceptibility to proteolytic degradation that causes luciferase to have a very short intracellular half-life. To define the structural basis for this behavior and possibly facilitate the design of more stable forms of luciferase, limited proteolysis studies were undertaken using trypsin and chymotrypsin to identify regions of the protein whose accessible and flexible character rendered them especially sensitive to cleavage. Regions of amino acid sequence 206-220 and 329-341 were found to be sensitive, and because the region around 206-220 had high homology with other luciferases, CoA ligases, and peptidyl synthetases, this region was selected for mutagenesis experiments intended to determine which of its amino acids were essential for activity. Surprisingly, many highly conserved residues including Ser198, Ser201, Thr202, and Gly203 could be mutated with little effect on the luminescent activity of P. pyralis luciferase. One mutation, however, S198T, caused several alterations in enzymatic properties including shifting the pH optimum from 8.1 to 8.7, lowering the Km for Mg-ATP by a factor of 4 and increasing the half-time for light emission decay by a factor of up to 150. While the S198T luciferase was less active than wild type, activity could be restored by the introduction of the additional L194F and N197Y mutations. In addition to indicating the involvement of this region in ATP binding, these results provide a new form of the enzyme that affords a more versatile reporter system.

Cleavage efficiency by adenovirus protease is site-dependent.

The adenovirus protease cleaves consensus sequences (M/I/L)XGX-G and (M/I/L)XGG-X. Using purified recombinant protease, we showed that a peptide bearing the GX-G site was hydrolyzed more rapidly than a peptide bearing the GG-X site. The GX-G site was also preferentially cleaved on viral protein pVI which bears both sites of cleavage. Evidence is presented that suggests a biological role for this differential cleavage efficiency.

Improved method for converting an unmodified peptide to an energy-transfer substrate for a proteinase.

This paper describes refinements to a method for generating energy-transfer-based fluorogenic substrates for proteinases [Geoghegan, K. F., et al. (1993) Bioconjugate Chem. 4, 537-544]. An unprotected peptide is taken as starting material and coupled by three steps of chemistry to two dyes that form an energy donor-energy acceptor pair. The donor group is Lucifer Yellow CH (lambda cx 420-430 nm, lambda em 530 nm), and the acceptor is 5-carboxytetramethylrhodamine, a strong chromophore that effectively quenches Lucifer Yellow fluorescence in intact substrates. Periodate oxidation of N-terminal Ser gives the peptide an alpha-N-glyoxylyl moiety, OHC-CO-peptide, which is allowed to react with Lucifer Yellow CH (a carbohydrazide derivative) to attach the dye through an adequately stable hydrazone bond. Derivatization is completed by allowing the succinimidyl ester of 5-carboxytetramethylrhodamine to react with the epsilon-amino group of a single Lys placed near the C terminus. In the revised method, the first two steps of chemistry are completed sequentially in a single vessel to eliminate the labor and losses associated with isolating the alpha-N-glyoxylyl intermediate. In addition, peptides taken as starting material for this method are now designed according to the scheme (Ser)-(cleavable sequence)-(Lys-Arg). The addition of Arg at the C terminus promotes aqueous solubility of the final substrate without complicating the chemistry; multiple Arg might also be used, through this has not been tried here. It has also been found that relative reversed-phase HPLC retention of Lucifer Yellow/5-carboxytetramethylrhodamine substrates is predictable on the basis of the hydrophobicity of the original peptide. Substrates prepared from peptides with Bull and Breese indices of > 200 cal/ mol are readily separated from residual dye in the second and final chromatographic step of the synthesis, simplifying the only moderately difficult step in the preparation. As with all fluorogenic substrates, assays using these substrates are subject to internal filtering effects that can lead to serious error. This problem becomes significant at a range of substrate concentration that is predictable when the size and geometry of the fluorescence cell are taken into account. The reasoning applied in determining this range is applicable to substrates constructed with any donor-acceptor pair.

Cloning, expression, and type II collagenolytic activity of matrix metalloproteinase-13 from human osteoarthritic cartilage.

Proteolysis of triple-helical collagen is an important step in the progression toward irreversible tissue damage in osteoarthritis. Earlier work on the expression of enzymes in cartilage suggested that collagenase-1 (MMP-1) contributes to the process. Degenerate reverse transcription polymerase chain reaction experiments, Northern blot analysis, and direct immunodetection have now provided evidence that collagenase-3 (MMP-13), an enzyme recently cloned from human breast carcinoma, is expressed by chondrocytes in human osteoarthritic cartilage. Variable levels of MMP-13 and MMP-1 in cartilage was significantly induced at both the message and protein levels by interleukin-1 alpha. Recombinant MMP-13 cleaved type II collagen to give characteristic 3/4 and 1/4 fragments; however, MMP-13 turned over type II collagen at least 10 times faster than MMP-1. Experiments with intact type II collagen as well as a synthetic peptide suggested that MMP-13 cleaved type II collagen at the same bond as MMP-1, but this was then followed by a secondary cleavage that removed three amino acids from the 1/4 fragment amino terminus. The expression of MMP-13 in osteoarthritic cartilage and its activity against type II collagen suggest that the enzyme plays a significant role in cartilage collagen degradation, and must consequently form part of a complex target for proposed therapeutic interventions based on collagenase inhibition.

Site-directed double fluorescent tagging of human renin and collagenase (MMP-1) substrate peptides using the periodate oxidation of N-terminal serine. An apparently general strategy for provision of energy-transfer substrates for proteases.

Periodate in neutral aqueous solution rapidly converts N-terminal Ser or Thr to an alpha-N-glyoxylyl moiety that can serve as the locus for incorporation of a modifying group [Geoghegan, K. F., and Stroh, J. G. (1992) Bioconjugate Chem. 3, 138-146. Gaertner, H. F. et al. (1992) Bioconjugate Chem. 3, 262-268]. The usefulness of this procedure has been further illuminated in a route to "energy-transfer" substrates for endoproteases. Each such substrate is an oligopeptide cleavable by a proteinase, but modified (usually at its termini) with two chromophores that form an energy donor-acceptor pair. Production of these substrates is an exercise in double site-directed peptide modification. The new route is composed of three steps, beginning from an unprotected peptide in which a sequence recognized by the pertinent enzyme is placed between N-terminal Ser and C-terminal Lys. Lys may not occur elsewhere in the peptide. Periodate oxidation converts the N-terminal Ser to an alpha-N-glyoxylyl group, which is then allowed to form a hydrazone with the carbohydrazide derivative Lucifer Yellow CH, a hydrophilic fluor with a large Stokes shift (excitation maximum, 425 nm; emission maximum, 525 nm). Finally, the modified peptide is allowed to react with 5-carboxytetramethylrhodamine succinimidyl ester. This reaction selectively modifies the epsilon-amino group of C-terminal Lys, the only amino group remaining in the peptide. 5-Carboxytetramethylrhodamine strongly (> 90%) quenches Lucifer Yellow fluorescence by resonance energy transfer in the intact substrate, but enzyme-catalyzed cleavage eliminates the quenching. The resulting increase in fluorescence may be used to follow the hydrolytic reaction.(ABSTRACT TRUNCATED AT 250 WORDS)

IL-1 beta maturation: evidence that mature cytokine formation can be induced specifically by nigericin.

Mouse peritoneal macrophages stimulated with LPS produce large amounts of pro-IL-1 beta. When these cells were pulse-labeled with [35S]methionine, however, little labeled cytokine appeared in the medium after a chase, and that which was externalized was not processed to its mature biologically active form. In an effort to promote proteolytic maturation of IL-1 beta, macrophages were treated with agents that were expected to compromise their viability. The calcium ionophore A23187 and the detergent saponin caused complete release of nonprocessed 35-kDa pro-IL-1 beta and liberation into the extracellular medium of the cytoplasmic marker enzyme LDH and the lysosomal enzyme beta-N-acetylglucosaminidase. Hypotonic lysis resulted in the release of a 20-kDa IL-1 beta species that was distinct from the 17-kDa mature species. Importantly, incubation of the murine macrophages with the potassium/proton ionophore nigericin led to a quantitative conversion of pro-IL-1 beta to a 17-kDa species. The N-terminus of this nigericin-derived product possessed the amino acid sequence expected for mature biologically active IL-1 beta. Monensin, an ionophore similar to nigericin, did not induce release or proteolysis of IL-1 beta. Complete release of mature IL-1 beta required concentrations of nigericin in excess of 2 microM and a minimum of 10 min of treatment. Mature 17-kDa IL-1 beta was observed within the nigericin-treated cells before their lysis. Nigericin's effect was not limited to mouse peritoneal macrophages, inasmuch as the ionophore also induced release and proteolytic maturation of IL-1 beta produced by LPS-stimulated human peripheral blood monocytes. Treatment of macrophages with LPS and nigericin, therefore, results in a unique series of intracellular events that promote formation of mature 17-kDa IL-1 beta.

Site-directed conjugation of nonpeptide groups to peptides and proteins via periodate oxidation of a 2-amino alcohol. Application to modification at N-terminal serine.

The 2-amino alcohol structure -CH(NH2)CH(OH)- exists in proteins and peptides in N-terminal Ser or Thr and in hydroxylysine. Its very rapid oxidation by periodate at pH 7 generates an aldehyde in the peptide and is the first step in a method for site-directed labeling with biotin or a fluorescent reporter. The modifying group is a hydrazide, RCONHNH2, which reacts with the new aldehyde to form a hydrazone-peptide conjugate, RCONHN = CH-peptide. Experiments with two synthetic peptides, Ser-Ile-Gly-Ser-Leu-Ala-Lys and Ser-Tyr-Ser-Met-Glu-His-Phe-Arg-Trp-Gly, and with recombinant murine interleukin-1 alpha (an 18-kDa cytokine with N-terminal Ser) demonstrated this method of peptide tagging. The use of a low molar ratio of periodate to peptide minimized the potential for side reactions during the oxidation, and the desired oxidation was rapid and highly specific. The hydrazones formed were stable at pH 6-8 for at least 12 h at 22 degrees C, but were labile at more acidic pH values. Potential uses of this method include the attachment of biotin, reporter groups, metal chelating groups, imaging agents, and cytotoxic drugs to peptides.

Structural basis of latency in plasminogen activator inhibitor-1.

Human plasminogen activator inhibitor-1 (PAI-1) is the fast-acting inhibitor of tissue plasminogen activator and urokinase and is a member of the serpin family of protease inhibitors. Serpins normally form complexes with their target proteases that dissociate very slowly as cleaved species and then fold into a highly stable inactive state in which the residues that flank the scissile bond (P1 and P1';) are separated by about 70 A. PAI-1 also spontaneously folds into a stable inactive state without cleavage; this state is termed 'latent' because inhibitory activity can be restored through denaturation and renaturation. Here we report the structure of intact latent PAI-1 determined by single-crystal X-ray diffraction to 2.6 A resolution. The three-dimensional structure reveals that residues on the N-terminal side of the primary recognition site are inserted as a central strand of the largest beta sheet, in positions similar to the corresponding residues in the cleaved form of the serpin alpha 1-proteinase inhibitor (alpha 1-PI). Residues C-terminal to the recognition site occupy positions on the surface of the molecule distinct from those of the corresponding residues in cleaved serpins or in the intact inactive serpin homologue, ovalbumin, and its cleavage product, plakalbumin. The structure of latent PAI-1 is similar to one formed after cleavage in other serpins, and the stability of both latent PAI-1 and cleaved serpins may be derived from the same structural features.

Characterization of a novel 14 kDa bile acid-binding protein from rat ileal cytosol.

A 14 kDa polypeptide in rat ileal cytosol has been identified as the major intestinal cytosolic bile acid-binding protein (I-BABP) by photoaffinity labeling with the radiolabeled 7,7-azo derivative of taurocholate (7,7-azo-TC). To further characterize I-BABP, the protein was purified by lysylglycocholate Sepharose 4B affinity and DE-52 anion-exchange chromatography. The purified I-BABP contained a single 14 kDa band on SDS-PAGE. The 14 kDa protein showed a 26-fold increase in binding affinity for [3H]7,7-azo-TC compared to cytosolic protein. Immunoblotting of protein fractions separated by affinity chromatography showed that neither liver fatty acid binding protein (L-FABP) nor intestinal fatty acid binding protein (I-FABP) bind to the affinity column and that the 14 kDa protein which bound to the column and was subsequently eluted with detergent did not cross-react with anti-L-FABP or anti-I-FABP. The 14 kDa protein labeled with [3H]7,7-azo-TC was radioimmunoprecipitated from cytosol by rabbit antiserum raised against purified I-BABP. I-BABP was shown to have a blocked N-terminus; however, its mixed internal sequence generated from cyanogen bromide-cleaved protein and amino acid composition indicated that it was related to (although clearly distinct from) both I-FABP and L-FABP. These studies have isolated a 14 kDa bile acid-binding protein from rat ileal cytosol which is immunologically and biochemically distinct from I-FABP and L-FABP.

Identification of the 14 kDa bile acid transport protein of rat ileal cytosol as gastrotropin.

The 14 kDa bile acid binding protein of rat ileal cytosol (I-BABP), previously shown to be the major intracellular transporter of bile acids in enterocytes, was purified by affinity chromatography and gel electrophoresis. Enzymatic digestion of I-BABP which had been electroblotted to nitrocellulose led to the recovery and sequence analysis of four peptides representing 47 residues of sequence (approximately 35% of the full sequence). All the peptide sequences displayed high levels of identity (greater than 60%) and homology (greater than 80%) to the sequences of porcine and canine gastrotropin. This high level of homology together with other features of I-BABP identify it as rat gastrotropin, establishing gastrotropin as the major intracellular bile acid carrier of rat enterocytes.

Reduction of biological activity of murine recombinant interleukin-1 beta by selective deamidation at asparagine-149.

A biologically active preparation of murine recombinant interleukin-1 beta (mIL-1 beta) from Escherichia coli cell lysates contained tow forms of mIL-1 beta with pI 8.7 and pI 8.1, respectively. Treatment with 0.1 M Tris, pH 8.5, at 37 degrees C for 35 h converted the pI 8.7 form to the pI 8.1 form by the selective deamidation of an asparagine residue (Asn149) in the mIL-1 beta molecule. Deamidated mIL-1 beta had 3- to 5-fold lower co-mitogenic activity and receptor affinity than the unmodified form.

Preliminary X-ray analysis of crystals of plasminogen activator inhibitor-1.

Crystals of bacterially expressed plasminogen activator inhibitor (PAI-1) suitable for X-ray diffraction analysis have been obtained from 8% (w/v) PEG 1500, pH 8.25. The space group is P1, and the lattice constants are a = 82.17 A, b = 47.82 A, c = 62.89 A, alpha = 90.00 degrees, beta = 106.90 degrees, gamma = 106.84 degrees. The diffraction limit is 2.3 A, and the unit cell contains two molecules of PAI-1. The crystals contain latent PAI-1 which can be partly reactivated by exposure to denaturants.