Probing the H-protein-induced conformational change and the function of the N-terminal region of Escherichia coli T-protein of the glycine cleavage system by limited proteolysis

T-protein, a component of the glycine cleavage system, catalyzes a tetrahydrofolate-dependent reaction. Previously, we reported a conformational change of Escherichia coli T-protein upon interacting with E. coli H-protein (EH), showing an important role for the N-terminal region of the T-protein in the interaction. To further investigate the T-protein catalysis, the wild type (ET) and mutants were subjected to limited proteolysis. ET was favorably cleaved at Lys(81), Lys(154), Lys(288), and Lys(360) by lysylendopeptidase and the cleavages at Lys(81) and Lys(288) were strongly prevented by EH. Although ET was highly resistant to trypsinolysis, the mutant with an N-terminal 7-residue deletion (ETDelta7) was quite susceptible and instantly cleaved at Arg(16) accompanied by the rapid degradation of the resulting C-terminal fragment, indicating that the cleavage at Arg(16) is the trigger for the C-terminal fragmentation. EH showed no protection from the N-terminal cleavage, although substantial protection from the C-terminal fragmentation was observed. The replacement of Leu(6) of ET with alanine resulted in a similar sensitivity to trypsin as ETDelta7. These results suggest that the N-terminal region of ET functions as a molecular "hasp" to hold ET in the compact form required for the proper association with EH. Leu(6) seems to play a central role in the hasp function. Interestingly, Lys(360) of ET was susceptible to proteolysis even after the stabilization of the entire molecule of ET by EH, indicating its location at the surface of the ET-EH complex. Together with the buried position of Lys(81) in the complex and previous results on folate binding sites, these results suggest the formation of a folate-binding cavity via the interaction of ET with EH. The polyglutamyl tail of the folate substrate may be inserted into the bosom of the cavity leaving the pteridine ring near the entrance of the cavity in the context of the catalytic reaction.     

Characterization of the Raptor/4E-BP1 Interaction by Chemical Cross-linking Coupled with Mass Spectrometry Analysis

mTORC1 plays critical roles in the regulation of protein synthesis, growth, and proliferation in response to nutrients, growth factors, and energy conditions. One of the substrates of mTORC1 is 4E-BP1, whose phosphorylation by mTORC1 reverses its inhibitory action on eIF4E, resulting in the promotion of protein synthesis. Raptor in mTOR complex 1 is believed to recruit 4E-BP1, facilitating phosphorylation of 4E-BP1 by the kinase mTOR. We applied chemical cross-linking coupled with mass spectrometry analysis to gain insight into interactions between mTORC1 and 4E-BP1. Using the cross-linking reagent bis[sulfosuccinimidyl] suberate, we showed that Raptor can be cross-linked with 4E-BP1. Mass spectrometric analysis of cross-linked Raptor-4E-BP1 led to the identification of several cross-linked peptide pairs. Compilation of these peptides revealed that the most N-terminal Raptor N-terminal conserved domain (in particular residues from 89 to 180) of Raptor is the major site of interaction with 4E-BP1. On 4E-BP1, we found that cross-links with Raptor were clustered in the central region (amino acid residues 56–72) we call RCR (Raptor cross-linking region). Intramolecular cross-links of Raptor suggest the presence of two structured regions of Raptor: one in the N-terminal region and the other in the C-terminal region. In support of the idea that the Raptor N-terminal conserved domain and the 4E-BP1 central region are closely located, we found that peptides that encompass the RCR of 4E-BP1 inhibit cross-linking and interaction of 4E-BP1 with Raptor. Furthermore, mutations of residues in the RCR decrease the ability of 4E-BP1 to serve as a substrate for mTORC1 in vitro and in vivo.     

Mutational and biochemical analyses of the endolysin Lys(gaY) encoded by the Lactobacillus gasseri JCM 1131T phage phi gaY

The Lys(gaY) of Lactobacillus gasseri JCM 1131(T) phage phigaY endolysin was purified to homogeneity using the Escherichia coli/His.Tag system. Zymographic and spectrophotometric assays showed that Lys(gaY) lysed over 20 heated Gram-positive bacterial species as the substrates, including lactobacilli, lactococci, enterococci, micrococci, and staphylococci. The enzymatic activity had the pH and temperature optima of about 6.5 and 37 degrees C, respectively. Amino-acid substitution analysis revealed that 13 residues of Lys(gaY) were involved in cell-lytic activity: in the beta/alpha(gaY) domain, G10, D12, E33, D36, H60, Y61, D96, E98, V124, L132, and D198; in the SH3b(gaY) domain, Y272 and W284. In addition, deletion analysis demonstrated that the beta/alpha(gaY) domain of N-terminal 216 residues is the core enzyme portion, although the cell-lytic ability is lower than that of Lys(gaY). These mutational experiments suggested that beta/alpha(gaY) (in which two acidic residues of D12 and E98 likely act as catalytic residues) is responsible for cell-lytic activity, and SH3b(gaY) promotes beta/alpha(gaY) possibly through cell-wall binding function. The purified His-tagged SH3b(gaY) domain containing 94 residues from S217 to K310 (i) bound to Gram-positive bacteria susceptible to Lys(gaY), (ii) induced aggregation of exponentially growing cells of L. gasseri JCM 1131(T), L. casei IAM 1045, Lactococcus lactis C2, L. lactis MG 1363, and Enterococcus hirae IAM 1262 by forming thread-like chained cells, (iii) inhibited lytic activity of Lys(gaY), and (iv) impeded autolysis of L. gasseri JCM 1131(T) in buffer systems. A truncated protein HDeltaSH3b(gaY) lacking in N-terminal 21 residues (from S217 to E237) of SH3b(gaY) and an amino-acid substituted protein HSH3b(gaY)G (W284G) lost the activities of HSH3b(gaY), showing that the N-terminal region and W284 probably play important roles in the SH3b(gaY) function(s).     

Identification of the folate binding sites on the Escherichia coli T-protein of the glycine cleavage system.

T-protein is a component of the glycine cleavage system and catalyzes the tetrahydrofolate-dependent reaction. To determine the folate-binding site on the enzyme, 14C-labeled methylenetetrahydropteroyltetraglutamate (5,10-CH2-H4PteGlu4) was enzymatically synthesized from methylenetetrahydrofolate (5, 10-CH2-H4folate) and [U-14C]glutamic acid and subjected to cross-linking with the recombinant Escherichia coli T-protein using 1-ethyl-3-(3-dimethylaminopropyl)carbodiimide, a zero-length cross-linker between amino and carboxyl groups. The cross-linked product was digested with lysylendopeptidase, and the resulting peptides were separated by reversed-phase high performance liquid chromatography. Amino acid sequencing of the labeled peptides revealed that three lysine residues at positions 78, 81, and 352 were involved in the cross-linking with polyglutamate moiety of 5, 10-CH2-H4PteGlu4. The comparable experiment with 5,10-CH2-H4folate revealed that Lys-81 and Lys-352 were also involved in cross-linking with the monoglutamate form. Mutants with single or multiple replacement(s) of these lysine residues to glutamic acid were constructed by site-directed mutagenesis and subjected to kinetic analysis. The single mutation of Lys-352 caused similar increase (2-fold) in Km values for both folate substrates, but that of Lys-81 affected greatly the Km value for 5,10-CH2-H4PteGlu4 rather than for 5,10-CH2-H4folate. It is postulated that Lys-352 may serve as the primary binding site to alpha-carboxyl group of the first glutamate residue nearest the p-aminobenzoic acid ring of 5,10-CH2-H4folate and 5,10-CH2-H4PteGlu4, whereas Lys-81 may play a key role to hold the second glutamate residue through binding to alpha-carboxyl group of the second glutamate residue.     

Influence of an extrinsic cross-link on the folding pathway of ribonuclease A. Kinetics of folding-unfolding

The kinetics of folding/unfolding of cross-linked Lys7-dinitrophenylene-Lys41-ribonuclease A were studied and compared to those of unmodified ribonuclease A (RNase A) at various concentrations of guanidine hydrochloride. The folding of the denatured cross-linked protein involved one fast-folding species (22 +/- 4%) and two slow-folding species, as observed in unmodified ribonuclease A. Also, a nativelike intermediate, analogous to that reported previously for unmodified ribonuclease A [Cook, K. H., Schmid, F. X., & Baldwin, R. L. (1979) Proc. Natl. Acad. Sci. U.S.A. 76, 6157], has been detected on the folding pathway of cross-linked ribonuclease A. The extrinsic cross-link between Lys7 and Lys41 did not affect the rate constants for the folding kinetics of these three species. The cross-link did, however, significantly affect the rate constant for unfolding of the native protein. The conformation of the protein in the transition state of the unfolding pathway was deduced from an analysis of the kinetic data. It appears that the 41 N-terminal residues are unfolded in the transition state of the unfolding pathway. Thus, the unfolding pathway of RNase A is sequential in that further unfolding (after the transition state) follows the unfolding of the 41 N-terminal residues. Also, the conformation of the 41 N-terminal residues does not play a role in the folding pathway. Presumably, if the cross-link were introduced instead between two other residues that are in the segment(s) involved in the rate-limiting step(s), it could increase the refolding rate constants and possibly the concentration of fast-folding species.     

Molecular analysis of the lysis protein Lys encoded by Lactobacillus plantarum phage phig1e

The putative cell-lysis gene lys of Lactobacillus plantarum G1e phage phig1e encodes for a 442 amino-acids protein Lys. The N-terminal region (about 80 amino acids) of Lys consists of two discrete regions (the signal-peptide-like domain and the DE domain containing putative active sites of endolysin). To elucidate functions of the regions of Lys, mutational (random, site-directed, and/or fusion) analysis was performed. The plasmid pNdEHL, expressing the wild type Lys protein under promoter of lacZ' gene in Escherichia coli, was constructed. Two molecular species (44 kDa; referred to as pre-Lys, and 42 kDa; mature-Lys) from the protein extract of XL1-Blue/pNdEHL were detected on a sodium dodecyl sulfate gel and zymogram with L. plantarum G1e cells. Based on the N-terminal amino acid sequences, the two molecules were determined as; pre-Lys (the amino acid position deduced from lys gene, 1-7) MKLKNKL, mature-Lys (27-33) QTLSSQS. The mature Lys was hardly detected in the cells treated with sodium azide.These results suggested that the N-terminal 26 amino acids region of Lys precursor form is possibly processed posttranslationally, by a SecA-dependent manner at least in E. coli.Analysis of the point mutants (pLD36A, pLE39A, pLE55A, pLE67A and pLD71A), indicated that the acidic residues (aspartic acids at position 36, 71 and glutamic acids at position 39, 55) of N-terminal region and the serine at the position 48 of phig1e Lys are essential for the lytic activity.     

Improved method for mapping the binding site of an actin-binding protein in the actin sequence. Use of a site-directed antibody against the N-terminal region of actin as a probe of its N-terminus

An antibody was raised against the N-terminal 18 residues of rabbit skeletal muscle actin. By the use of this antibody as the N-terminal probe of actin and the fluorescent label at Cys-374 as its C-terminal probe, binding sites of depactin (an actin-depolymerizing protein from starfish oocytes) were identified in the actin sequence according to the method of Sutoh [Sutoh, K. (1982) Biochemistry 21, 3654-3661]. Cross-linking of the one-to-one complex of actin and depactin with 1-ethyl-3-[3-(dimethylamino)propyl]-carbodiimide (EDC) generated two types of cross-linked products with slightly different apparent molecular weights, denoted as 60KU and 60KL. By the use of the N-terminal probe, it was unequivocally revealed that the C-terminal actin segment of residues 357-375 participated in cross-linking with depactin to form 60KL. On the other hand, by the use of the C-terminal probe it was revealed that the N-terminal actin segment of residues 1-12 participated in cross-linking with depactin to form 60KU. Since EDC cross-links Lys residue with Asp or Glu residue only when they are in direct contact, the result indicates that some of the N-terminal residues 1-12 and the C-terminal residues 357-375 of actin participate in binding depactin. The introduction of the N-terminal probe (the antibody recognizing the actin N-terminus) has increased the flexibility of the mapping method for locating binding sites of actin-binding proteins in the actin sequence.     

Amino acid sequence of the N-terminal aggregation and cross-linking region (7S domain) of the alpha 1 (IV) chain of human basement membrane collagen

The amino acid sequence of the 216-residue-long N-terminal aggregation and cross-linking 7S domain of the alpha 1 (IV) chain of human placental basement membrane collagen is presented. The N terminus of the alpha 1 (IV) chain starts with a non-triple-helical region, which is at least 15 residues long and contains four cysteine and two lysine residues as putative cross-linking sites. This segment is followed by a 120-residue-long triple helical region, which contains the unusual occurrence of a cysteine residue in the Xaa position of a Gly-Xaa-Yaa triplet. Since individual molecules in the 7S domain are associated in an antiparallel manner, this cysteine probably aligns with one of the four cysteines in the amino-terminal end of an adjacent molecule, forming an intermolecular disulfide bridge. The length of the overlap of two adjacent molecules is estimated to be about 110 residues. The triple helix adjacent to the overlap zone is interrupted by a 10-residue-long non-helical area, which is probably responsible for the flexible region of the molecules in the neighbourhood of the overlap zone observed in the electron microscope. The mode of aggregation of the 7S domain, the formation of intermolecular cross-links as well as the relatively high stability of this region against proteolytic attack are discussed in the light of the elucidated amino acid sequence.     

Sauvagine cross-links to the second extracellular loop of the corticotropin-releasing factor type 1 receptor

Contact sites between the corticotropin-releasing factor receptor type 1 (CRFR1), the sauvagine (SVG) radioligands [Tyr(0),Gln(1)]SVG ((125)I-YQS) and [Tyr(0),Gln(1), Leu(17)]SVG ((125)I-YQLS) were examined. (125)I-YQLS or (125)I-YQS was cross-linked to CRFR1 using the chemical cross-linker, disuccinimidyl suberate (DSS), which cross-links the epsilon amino groups of lysine residues that have a molecular distance of 11.4 A. DSS specifically and efficiently cross-linked (125)I-YQLS and (125)I-YQS to CRFR1. CRFR1 contains 5 putative extracellular lysine residues (Lys(110), Lys(111), Lys(113), Lys(257), and Lys(262)) that can cross-link to the 4 lysine residues (Lys(16), Lys(22), Lys(25), and Lys(27)) of the radioligands. Identification of the CNBr-cleaved fragments of CRFR1 cross-linked to (125)I-YQLS or (125)I-YQS established that the second extracellular loop of CRFR1 cross-links to Lys(16) of YQS. Additionally, site-directed mutagenesis (changing Lys to Arg in CRFR1 individually and in combination) revealed that Lys(257) in the second extracellular loop of CRFR1 is an important cross-linking site. In conclusion, it was shown that in SVG-bound CRFR1, Lys(257) of CRFR1 lies in close proximity (11.4 A) to Lys(16) of SVG.     

Molecular structure of a novel membrane protease specific for a stomatin homolog from the hyperthermophilic archaeon Pyrococcus horikoshii

Membrane-bound proteases are involved in various regulatory functions. Our previous study indicated that the N-terminal region of an open reading frame, PH1510 (residues 16-236, designated as 1510-N) from the hyperthermophilic archaeon Pyrococcus horikoshii, is a serine protease with a catalytic Ser-Lys dyad that specifically cleaves the C-terminal hydrophobic residues of a membrane protein, the stomatin-homolog PH1511. In humans, an absence of stomatin is associated with a form of hemolytic anemia known as hereditary stomatocytosis, but the function of stomatin is not fully understood. Here, we report the crystal structure of 1510-N in dimeric form. Each active site of 1510-N is rich in hydrophobic residues, which accounts for the substrate-specificity. The monomer of 1510-N shows structural similarity to one monomer of Escherichia coli ClpP, an ATP-dependent tetradecameric protease. But, their oligomeric forms are different. Major contributors to dimeric interaction in 1510-N are the alpha7 helix and beta9 strand, both of which are missing from ClpP. While the long handle region of ClpP contributes to the stacking of two heptameric rings, the corresponding L2 loop of 1510-N is disordered because the region has little interaction with other residues of the same molecule. The catalytic Ser97 of 1510-N is in almost the same location as the catalytic Ser97 of E.coli ClpP, whereas another residue, Lys138, presumably forming the catalytic dyad, is located in the disordered L2 region of 1510-N. These findings suggest that the binding of the substrate to the catalytic site of 1510-N induces conformational changes in a region that includes loop L2 so that Lys138 approaches the catalytic Ser97.     

Introduction of the most common cystic fibrosis mutation (Delta F508) into human P-glycoprotein disrupts packing of the transmembrane segments

The most common mutation in cystic fibrosis (deletion of phenylalanine 508 (DeltaF508) in the cystic fibrosis conductance transmembrane regulator (CFTR) gene) causes defective synthesis of CFTR protein. To understand how this deletion interferes with protein folding, we made the equivalent deletion (DeltaY490) in P-glycoprotein (P-gp). A Cys-less P-gp with cysteines in transmembrane (TM) 4 or TM5 can be cross-linked with a cysteine in TM12. Deleting Tyr(490) in P-gp resulted in an inactive and defectively processed mutant in which no cross-linking between TM4 or TM5 and TM12 was detected. Expression of the DeltaY490 mutant in the presence of a chemical chaperone corrected the processing defect and yielded active P-gp mutants that could be cross-linked between TM4 or TM5 and TM12. Cross-linking between TM4 or TM5 and TM12 was also detected when residues (483)TIAENIRYG(491) in P-gp were replaced with residues (501)TIKENIIFG(509) from CFTR (P-gp/CFTR). Deleting Phe(508) in the P-gp/CFTR chimera, however, caused defective processing of the mutant protein and no detectable cross-linking between TM4 or TM5 and TM12. The processing defect was corrected with a chemical chaperone and yielded active P-gp/CFTR mutant proteins that could be cross-linked. These results show that deletion at residue 490 disrupts packing of the TM segments possibly by affecting interaction between the first nucleotide-binding domain (Tyr(490)) and the first cytoplasmic loop (Glu(184)).     

Localization of epsilon-lysyl-gamma-glutamyl cross-links in five human alpha 2-macroglobulin-proteinase complexes. Nature of the high molecular weight cross-linked products.

Covalent binding of proteinases by human alpha 2-macroglobulin (alpha 2M) results primarily from the formation of stable epsilon-Lys-gamma-Glu isopeptide bonds. Cross-linking engages 12, 13, and 10 of the 14, 14, and 11 Lys residues in chymotrypsin, trypsin, and subtilisin, respectively, and reaction with the alpha-amino group of the C-chain of chymotrypsin and the B-chain of beta-trypsin is also seen. In contrast, cross-linking engages only 6 of the 11 Lys residues in thermolysin. In each of these proteinases, a few residues react to the greatest extent: Lys36, Lys79, Lys87, and Lys93 in chymotrypsin; Lys87, Lys109, Lys222, and Lys239 in trypsin; Lys12, Lys43, and Lys141 in subtilisin; and Lys210 and Lys219 in thermolysin. In elastase, 1 of the 3 Lys residues (Lys87) is tentatively identified as being cross-linked. Formation of unstable bonds judged to be mainly p-tyrosyl-gamma-glutamyl esters can also be significant for some proteinases. In each of the proteinases, several of the strongly reacting Lys residues are located relatively close to each other, presumably reflecting steric constraints within the alpha 2M-proteinase complexes as they form. Proteinases are covalently bound to alpha 2M to one or two of its COOH-terminal bait region-cleaved half-subunits. The sodium dodecyl sulfate-polyacrylamide gel electrophoresis pattern of the high molecular weight cross-linked species indicates that binding of a proteinase through two cross-links occurs not only within the 360-kDa disulfide-bridged alpha 2M dimer but also between the two dimers in the alpha 2M tetramer.     

Roles of N-terminal region residues Lys11, Arg13, and Arg24 of antithrombin in heparin recognition and in promotion and stabilization of the heparin-induced conformational change

The N-terminal region residues, Lys11, Arg13, and Arg24, of the plasma coagulation inhibitor, antithrombin, have been implicated in binding of the anticoagulant polysaccharide, heparin, from the identification of natural mutants with impaired heparin binding or by the X-ray structure of a complex of the inhibitor with a high-affinity heparin pentasaccharide. Mutations of Lys11 or Arg24 to Ala in this work each reduced the affinity for the pentasaccharide approximately 40-fold, whereas mutation of Arg13 to Ala led to a decrease of only approximately 7-fold. All three substitutions resulted in the loss of one ionic interaction with the pentasaccharide and those of Lys11 or Arg24 also in 3-5-fold losses in affinity of nonionic interactions. Only the mutation of Lys11 affected the initial, weak interaction step of pentasaccharide binding, decreasing the affinity of this step approximately 2-fold. The mutations of Lys11 and Arg13 moderately, 2-7-fold, altered both rate constants of the second, conformational change step, whereas the substitution of Arg24 appreciably, approximately 25-fold, reduced the reverse rate constant of this step. The N-terminal region of antithrombin is thus critical for high-affinity heparin binding, Lys11 and Arg24 being responsible for maintaining appreciable and comparable binding energy, whereas Arg13 is less important. Lys11 is the only one of the three residues that is involved in the initial recognition step, whereas all three residues participate in the conformational change step. Lys11 and Arg13 presumably bind directly to the heparin pentasaccharide by ionic, and in the case of Lys11, also nonionic interactions. However, the role of Arg24 most likely is indirect, to stabilize the heparin-induced P-helix by interacting intramolecularly with Glu113 and Asp117, thereby positioning the crucial Lys114 residue for optimal ionic and nonionic interactions with the pentasaccharide. Together, these findings show that N-terminal residues of antithrombin make markedly different contributions to the energetics and dynamics of binding of the pentasaccharide ligand to the native and activated conformational states of the inhibitor that could not have been predicted from the X-ray structure.     

Use of proteinase K nonspecific digestion for selective and comprehensive identification of interpeptide cross-links: application to prion proteins

Chemical cross-linking combined with mass spectrometry is a rapidly developing technique for structural proteomics. Cross-linked proteins are usually digested with trypsin to generate cross-linked peptides, which are then analyzed by mass spectrometry. The most informative cross-links, the interpeptide cross-links, are often large in size, because they consist of two peptides that are connected by a cross-linker. In addition, trypsin targets the same residues as amino-reactive cross-linkers, and cleavage will not occur at these cross-linker-modified residues. This produces high molecular weight cross-linked peptides, which complicates their mass spectrometric analysis and identification. In this paper, we examine a nonspecific protease, proteinase K, as an alternative to trypsin for cross-linking studies. Initial tests on a model peptide that was digested by proteinase K resulted in a "family" of related cross-linked peptides, all of which contained the same cross-linking sites, thus providing additional verification of the cross-linking results, as was previously noted for other post-translational modification studies. The procedure was next applied to the native (PrP(C)) and oligomeric form of prion protein (PrPβ). Using proteinase K, the affinity-purifiable CID-cleavable and isotopically coded cross-linker cyanurbiotindipropionylsuccinimide and MALDI-MS cross-links were found for all of the possible cross-linking sites. After digestion with proteinase K, we obtained a mass distribution of the cross-linked peptides that is very suitable for MALDI-MS analysis. Using this new method, we were able to detect over 60 interpeptide cross-links in the native PrP(C) and PrPβ prion protein. The set of cross-links for the native form was used as distance constraints in developing a model of the native prion protein structure, which includes the 90-124-amino acid N-terminal portion of the protein. Several cross-links were unique to each form of the prion protein, including a Lys(185)-Lys(220) cross-link, which is unique to the PrPβ and thus may be indicative of the conformational change involved in the formation of prion protein oligomers.     

Site-Directed Mutagenesis of Cytochrome P450scc (CYP11A1). Effect of Lysine Residue Substitution on Its Structural and Functional Properties

Our previous chemical modification and cross-linking studies identified some positively charged amino acid residues of cytochrome P450scc that may be important for its interaction with adrenodoxin and for its functional activity. The present study was undertaken to further evaluate the role of these residues in the interaction of cytochrome P450scc with adrenodoxin using site-directed mutagenesis. Six cytochrome P450scc mutants containing replacements of the surface-exposed positively charged residues (Lys103Gln, Lys110Gln, Lys145Gln, Lys394Gln, Lys403Gln, and Lys405Gln) were expressed in E. coli cells, purified as a substrate-bound high-spin form, and characterized as compared to the wild-type protein. The replacement of the surface Lys residues does not dramatically change the protein folding or the heme pocket environment as judged from limited proteolysis and spectral studies of the cytochrome P450 mutants. The replacement of Lys in the N-terminal sequence of P450scc does not dramatically affect the activity of the heme protein. However, mutant Lys405Gln revealed rather dramatic loss of cholesterol side-chain cleavage activity, efficiency of enzymatic reduction in a reconstituted system, and apparent dissociation constant for adrenodoxin binding. The present results, together with previous findings, suggest that the changes in functional activity of mutant Lys405Gln may reflect the direct participation of this amino acid residue in the electrostatic interaction of cytochrome P450scc with its physiological partner, adrenodoxin.     

Mapping of the 5'-2-deoxyribose-5-phosphate lyase active site in DNA polymerase beta by mass spectrometry

The mechanism of the 5'-2-deoxyribose-5-phosphate lyase reaction catalyzed by mammalian DNA beta-polymerase (beta-pol) was investigated using a cross-linking methodology in combination with mass spectrometric analyses. The approach included proteolysis of the covalently cross-linked protein-DNA complex with trypsin, followed by isolation, peptide mapping, and mass spectrometric and tandem mass spectrometric analyses. The 8-kDa domain of beta-pol was covalently cross-linked to a 5'-2-deoxyribose-5-phosphate-containing DNA substrate by sodium borohydride reduction. Using tandem mass spectrometry, the location of the DNA adduct on the 8-kDa domain was unequivocally determined to be at the Lys(72) residue. No additional amino acid residues were found as minor cross-linked species. These data allow assignment of Lys(72) as the sole Schiff base nucleophile in the 8-kDa domain of beta-pol. These results provide the first direct evidence in support of a catalytic mechanism involving nucleophilic attack by Lys(72) at the abasic site.     

The early interaction of the outer membrane protein phoe with the periplasmic chaperone Skp occurs at the cytoplasmic membrane

Spheroplasts were used to study the early interactions of newly synthesized outer membrane protein PhoE with periplasmic proteins employing a protein cross-linking approach. Newly translocated PhoE protein could be cross-linked to the periplasmic chaperone Skp at the periplasmic side of the inner membrane. To study the timing of this interaction, a PhoE-dihydrofolate reductase hybrid protein was constructed that formed translocation intermediates, which had the PhoE moiety present in the periplasm and the dihydrofolate reductase moiety tightly folded in the cytoplasm. The hybrid protein was found to cross-link to Skp, indicating that PhoE closely interacts with the chaperone when the protein is still in a transmembrane orientation in the translocase. Removal of N-terminal parts of PhoE protein affected Skp binding in a cumulative manner, consistent with the presence of two Skp-binding sites in that region. In contrast, deletion of C-terminal parts resulted in variable interactions with Skp, suggesting that interaction of Skp with the N-terminal region is influenced by parts of the C terminus of PhoE protein. Both the soluble as well as the membrane-associated Skp protein were found to interact with PhoE. The latter form is proposed to be involved in the initial interaction with the N-terminal regions of the outer membrane protein.