Faculty Bibliography

Matrix-assisted laser desorption/ionization time-of-flight mass spectrometry (MALDI-TOF MS), in conjunction with enzymatic digestion of proteins and molecular weight search of peptide-mass database is a powerful technique for peptide/protein identification. Ideally, peptide mixtures should be compatible with both MALDI-TOF and microsequencing. In our laboratory, enzymatic digestion and extraction of peptides from polyvinylidene difluoride (PVDF)-bound proteins is performed in the presence of nonionic detergents. However, nonionic detergents have been shown to cause signal suppression in MALDI-TOF analysis. This study demonstrates that by using a modified matrix solution, peptide-mass fingerprinting of PVDF-bound proteins by MALDI-TOF can be obtained in the presence of nonionic detergents such as hydrogenated Triton X-100 (RTX-100), octylglucopyranoside, and Tween 20

An improved and simplified procedure for enzymatic digestion of proteins bound to polyvinylidene difluoride (PVDF) membranes for obtaining internal protein sequence data is presented. This improved procedure is compatible with various enzymes (trypsin, endoproteinase Lys-C, endoproteinase Glu-C, and clostripain) and is performed in the presence of 1% hydrogenated Triton X-100 (RTX-100)/10% acetonitrile/100 mM Tris, pH 8.0, followed by microbore HPLC purification of the recovered peptides. Previously published techniques required treatment of the PVDF-bound protein with polyvinylpyrrolidine M(r) 40,000 (PVP-40) prior to digestion, in order to prevent adsorption of the enzyme to the membrane. Unfortunately, contaminants produced from residual PVP-40 interfere with subsequent peptide mapping. We have found that when RTX-100 is used in the digestion buffer, no pretreatment of the PVDF-bound protein with PVP-40 is necessary. Advantages of this improved (one-step) procedure over the two-step PVP-40 procedure are (a) the elimination of undesirable contaminants associated with PVP-40, (b) a decrease in the time required for the technique, and (c) a reduction in sample manipulation. Peptide maps and recoveries from PVDF-bound standard proteins (4 micrograms each) enzymatically digested with this one-step method are compared with those obtained from the standard PVP-40 method. In addition, peptide maps and internal sequence data from low-level quantities of unknown proteins enzymatically digested with the improved procedure are presented. To date, this improved, one-step procedure has been successfully applied to 52 PVDF-bound unknown proteins (0.7-10 micrograms) of varying molecular weight (19-300 kDa) for which internal sequence data were obtained

A procedure is described for the in situ carboxamidomethylation of cystine/cysteine residues in protein samples of as little as 10 pmol, prior to automated protein sequence analysis. Previous in situ methods for the modification of cysteines are limited to proteins available in quantities greater than 100 pmol due to contaminants which interfere with HPLC identification of phenylthiohydantoin amino acids, and cannot be performed on polyvinylidenedifluoride (PVDF)-bound samples. In our procedure, protein samples, immobilized on either PVDF- or polybrene-treated glass filters, are reduced with tributylphosphine followed by alkylation with iodoacetamide prior to automated sequence analysis. Carboxamidomethylcysteine is formed in high yield with no discernable side reactions in standard proteins (insulin, human transferrin, lysozyme) or experimental samples. Both initial and repetitive yields of carboxamidomethylated proteins were either comparable to or better than nonalkylated proteins. No apparent increase in background nor any sequence preview due to partial amino-terminal alkylation was observed. The carboxamidomethylation procedure described here successfully overcomes the limitations of available methods for reduction and alkylation of less than 100 pmol of protein directly on sequencer membrane supports

A procedure for the generation and isolation of internal peptide fragments for less than 10 micrograms of protein bound to either polyvinylidene difluoride (PVDF) or nitrocellulose membranes after electrophoretic transfer from sodium dodecyl sulfate-polyacrylamide gels (SDS-PAGE) is presented. This technique has produced internal sequence data for 120 peptides, with an average initial yield of 20 pmol. Membrane-bound proteins were enzymatically digested with either trypsin or endoproteinase Lys-C in the presence of 1% hydrogenated Triton X-100/10% acetonitrile/100 mM Tris-HCl, pH 8.0, for 24 h at 37 degrees C. The eluted peptides were then directly isolated by microbore HPLC for subsequent sequence analysis. One percent hydrogenated Triton X-100 did not inhibit enzymatic activity, distort HPLC resolution of peptides, or contain uv-absorbing contaminants that could interfere with peptide identification. Reproducible peptide maps and consistent recoveries are presented for standard proteins (3.5-8.0 micrograms) bound to either membrane, with higher recoveries for PVDF-bound proteins. Ninety percent of the proteins analyzed by this technique have produced results; representative peptide maps and sequence data are presented. This technique has a wide range of applications, particularly for proteins with blocked amino termini or those that can only be purified by SDS-PAGE or 2D isoelectric focusing SDS-PAGE

Adducin is an erythrocyte membrane skeletal phosphoprotein comprised of two related subunits of 105,000 and 100,000 Mr. These peptides form a functional heterodimer, and the smaller of the two binds calmodulin in a calcium-dependent fashion. Although this protein has been physicochemically characterized, its function remains unknown. We have examined the interaction of human adducin with actin and with human erythrocyte spectrin using sedimentation, electrophoretic, and morphologic techniques. Purified adducin binds actin at physiologic ionic strength and bundles it into arrays of laterally arranged filaments, the adducin forming cross-bridges between the filaments at 35.2 /- 3.8 (2 SD) nm intervals. The stoichiometry of high affinity adducin binding to actin at saturation is 1:7, corresponding to a dimer of adducin for every actin helical unit. Adducin also promotes the binding of spectrin to actin independently of protein 4.1. At saturation, each adducin promotes the association of one spectrin heterodimer. The formation of this ternary spectrin-actin-adducin complex is independent of the assembly path, and the complex exists in a readily reversible equilibrium with the free components. The binding of adducin to actin and its ability to stimulate spectrin-actin binding is down-regulated by calmodulin in a calcium-dependent fashion. These results thus identify a putative role for adducin, and define a calcium- and calmodulin-dependent mechanism whereby higher states of actin association and its interaction with spectrin in the erythrocyte may be controlled

The ability of protein 4.1 to stimulate the binding of spectrin to F-actin has been compared by cosedimentation analysis for three avian (erythrocyte, brain, and brush border) and two mammalian (erythrocyte and brain) spectrin isoforms. Human erythroid protein 4.1 stimulated actin binding of all spectrins except the brush border isoform (TW 260/240). These results suggested that the beta subunit determined the protein 4.1 sensitivity of the heterodimer, since all avian alpha subunits are encoded by a single gene. Tissue-specific posttranslational modification of the alpha subunit was excluded by examining the properties of hybrid spectrins composed of the purified alpha subunit from avian erythrocyte or brush border spectrin and the beta subunit of human erythrocyte spectrin. A hybrid composed of avian brush border alpha and human erythroid beta spectrin ran on nondenaturing gels as a discrete band, migrating near human erythroid spectrin tetramers. The actin-binding activity of this hybrid was stimulated by protein 4.1, while either chain alone was devoid of activity. Therefore, although both subunits were required for actin binding, the sensitivity of the spectrin-actin interaction to protein 4.1 is a property uniquely bestowed on the heterodimer by the beta subunit. The singular insensitivity of brush border spectrin to stimulation by erythroid protein 4.1 was also consistent with the absence of proteins in avian intestinal epithelial cells which were immunoreactive with polyclonal antisera sensitive to all of the known avian and human erythroid 4.1 isoforms

Partial sequences of group A streptococcal M proteins exhibit up to 50% sequence identity with segments of rabbit skeletal tropomyosin. It is well recognized that rheumatic fever and rheumatic heart disease in humans are sequelae of group A streptococcal infection. To examine whether the human cardiac tropomyosin would exhibit greater homology with the streptococcal M proteins, we have now determined its complete amino acid sequence. The amino acid sequence of human cardiac tropomyosin was established from sequence analyses of its peptides derived by enzymic and chemical cleavages, and comparison of these sequences to the reported sequence of rabbit skeletal tropomyosin. These studies have revealed that the amino acid sequence of human cardiac alpha tropomyosin is identical to that of the rabbit skeletal alpha tropomyosin, but for a single conservative substitution of Arg/Lys at position 220. This observation increases the significance of the previously observed sequence homology between streptococcal M protein and rabbit skeletal tropomyosin and may have relevance to the pathogenesis of rheumatic fever. Furthermore, these results rank tropomyosin as one of the most highly conserved contractile proteins between vertebrate species reported thus far

The complete amino acid sequence of a peptic fragment (Pep M5) of the group A streptococcal type 5 M protein, the antiphagocytic cell surface molecule of the bacteria, is described. This fragment, comprising nearly half of the native M molecule, is biologically active in that it has the ability to interact with opsonic antibodies as well as to evoke such an antibody response in rabbits. The sequence of Pep M5 was determined by automated Edman degradations of the uncleaved molecule and its enzymatically derived peptides. The primary peptides for Edman degradation were the arginine peptides obtained by tryptic digestion. The tryptic cleavage of Pep M5 was limited to the arginyl peptide bonds by derivatizing the epsilon-amino groups of lysine residues by reductive dihydroxypropylation. The overlapping peptides were generated by digestion of the unmodified Pep M5 with chymotrypsin, V8 protease, and subtilisin. The sequence thus established for the Pep M5 molecule consists of a total of 197 residues (Mr = 22,705). The Pep M5 protein contains some identical, or nearly so, repeating sequences: four 7-residue segments and two 10-residue segments. However, extensive sequence repeats of the kind previously reported within the partial sequence of another M protein serotype, namely Pep M24, were absent. The Pep M5 sequence is distinct from, but exhibits some homology with, the partial sequences of two other M protein serotypes, namely, Pep M6 and Pep M24. Furthermore, the 7-residue periodicity of the nonpolar and charged residues, an alpha-helical coiled-coil structural characteristic that was previously observed within the partial sequences of M proteins, was found to extend over a significant part of the Pep M5 sequence. The implication of these results to the function and immunological diversity in M proteins is discussed