The uncoupling protein dimer can form a disulfide cross-link between the mobile C-terminal SH groups

Isolated uncoupling protein (UCP) can be cross-linked, by various disulfide-forming reagents, to dimers. The best cross-linking is achieved with Cu2+-phenanthroline oxidation. Because cross-linking is independent of UCP concentration and prevented by SDS addition, a disulfide bridge must be formed between the two subunits of the native dimer. Cross-linking is prevented by SH reagent and reversed by SH-reducing reagents. In mitochondria, cross-linking of UCP with disulfide-forming agents is even more efficient than in isolated state. It proves that UCP is a dimer in mitochondria, before isolation. Disulfide-bridge formation does not inhibit GTP-binding to UCP. Cross-linked UCP re-incorporated in proteoliposomes either before or after cross-linking fully retains the H1-transport function. Rapid cross-linking by membrane impermeant reagents indicates a surface localization of the C-terminus in soluble UCP and projection to the outer surface in mitochondria. Intermolecular disulfide-bridge formation in a dimer requires juxtaposition of identical cysteines at the twofold symmetry axis. A rigid juxtaposition of cysteines is unlikely, unless intended for a native disulfide bridge. The absence of such a bridge in UCP suggests that juxtaposition of cysteines is generated by high mobility. In order to localize the cysteine involved, cross-linked UCP was cleaved by BrCN. The CB-7 C-terminal peptide, which contains cysteines at positions 287 and 304, disappears. Limited trypsinolytic cleavage, previously shown to occur at Lys-292, removed cross-linking in UCP both in the solubilized and mitochondrially bound state. The cleaved C-terminal peptide of 11 residues contains only cystein-304 which, thus, should be the only one (out of 7 cysteines in UCP) involved in the S-S bridge formation. Obviously, the C-terminal location of the cysteine, because of its high mobility, permits juxtapositioning for cross-linking. This agrees with predictions from hydrophobicity analysis that the last 14 residues in UCP protrude from the membrane.     

Labeling of two different regions of the nucleotide binding site of the uncoupling protein from brown adipose tissue mitochondria with two ATP analogs.

The nucleotide binding site of the uncoupling protein (UCP) from brown adipose tissue was mapped by photoaffinity labeling with 2-azidoadenosine 5'-triphosphate (2-azido-ATP) and by affinity labeling with 3'-O-(5-fluoro-2,4-dinitrophenyl)adenosine 5'-triphosphate (FDNP-ATP). Both analogs bind with high affinity and specificity to the UCP in intact mitochondria, as well as to the isolated solubilized protein. Reversible binding at 4 degrees C in the dark is competitively blocked by GTP. Like the natural ligands ATP and GTP, both analogs are capable of inhibiting the H+/OH- conductance of the UCP as measured in proteoliposomes with reconstituted UCP. 2-azido-ATP was incorporated into UCP in mitochondria in the presence of carboxyatractylate, while FDNP-ATP was inserted into isolated UCP by prolonged incubation at room temperature under pH variation. Both reactions can be blocked by GTP. The incorporation of 2-azido-ATP could be localized between residues 258 and 283 by cleavage with CNBr. Solid-phase sequencing of the homoserine-linked radioactive peptide indicated that the 2-azido-ATP was linked to threonine-263. The incorporation of FDNP-ATP could be assigned by cleavage with CNBr and alternatively with trypsin at a locus of covalent attachment between residues 238 and 255. On the basis of published data that no tyrosine participates in nucleotide binding of the UCP, the probable residue reacting with FDNP-ATP is cysteine-253.(ABSTRACT TRUNCATED AT 250 WORDS)     

Sequence analysis of peptide fragments from the intrinsic membrane protein of calf lens fibers MP26 and its natural maturation product MP22

Calf lens fiber plasma membranes, containing only the intrinsic membrane protein MP26 and its maturation product MP22 were treated with proteolytic enzymes such as trypsin, protease V8 from S. aureus or with chemical agents as CNBr in formic acid. The cleavage products, purified by electrophoresis, were analysed for their amino acid composition and N-terminal sequences. Proteolysis gave rise to peptides which were mainly shortened at the C-terminal end of the molecules. While the V8 protease produced a fragment with a similar N-terminal sequence as the maturation product MP22, trypsin yielded another cleavage product. Chemical hydrolysis yielded large fragments (11-15 kDa) with hydrophobic N-terminal sequences. Our results suggest that MP26 is characterised by an N-terminal signal sequence and possesses other hydrophobic domains which could function as untranslocated insertion sequences.     

NMR studies of the C-terminal secretion signal of the haem-binding protein, HasA.

HasA is a haem-binding protein which is secreted under iron-deficiency conditions by the gram-negative bacterium Serratia marcescens. It is a monomer of 19 kDa (187 residues) able to bind free haem as well as to capture it from haemoglobin. HasA delivers haem to a specific outer-membrane receptor HasR and allows the bacteria to grow in the absence of any other source of iron. It is secreted by a signal peptide-independent pathway which involves a C-terminal secretion signal and an ABC (ATP-binding cassette) transporter. The C-terminal region of the secretion signal containing the essential secretion motif is cleaved during or after the secretion process by proteases secreted by the bacteria. In this work, we study by 1H NMR the conformation of the C-terminal extremity of HasA in the whole protein and that of the isolated secretion signal peptide in a zwitterionic micelle complex that mimicks the membrane environment. We identify a helical region followed by a random-coil C-terminus in the peptide-micelle complex and we show that in both the whole protein and the complex, the last 15 residues containing the motif essential for secretion are highly flexible and unstructured. This flexibility may be a prerequisite to the recognition of HasA by its ABC transporter. We determine the cleavage site of the C-terminal extremity of the protein and analyse the effect of the cleavage on the haem acquisition process.     

Photoaffinity labeling of the nucleotide-binding site of the uncoupling protein from hamster brown adipose tissue.

The nucleotide binding center of the uncoupling protein from brown adipose tissue (UCP) was probed by photoaffinity labeling with 8-azido-ATP. The isolated dimeric UCP in non-ionic detergent was used. 8-azido-ATP binds to UCP with a Kd = 3 microM, i.e. with an only threefold lower affinity than ATP and a maximum number of binding sites of about 12 mumol/g protein corresponding to about 1 mol/mol dimer UCP. UCP is rapidly degraded by ultraviolet radiation, and therefore only near ultraviolet and visible light can be used for photoaffinity labeling. The total covalent incorporation is shown to be dependent on the concentration of azido-ATP and on competing phospholipids. The specific, i.e. ATP-sensitive incorporation only to the binding site depends on the presence of cysteine. With CNBr cleavage the 8-azido-[gamma-32P]ATP insertion within the primary structure was located by identifying ATP-sensitive labeled peptides in SDS/PAGE. A major specific 8-azido-ATP incorporation was found by autoradiography in the smallest CNBr fragments. Identification of the radioactive peptides was difficult since 8-azido-ATP insertion causes a distinct shift in the gels from the stained peptides. Identification was possible by specific disulfide formation at the C-terminal within the UCP dimer which only removed the CB7 (CB, CNBr fragment) portion of the low-molecular-mass peptides but did not move the radioactive band. This excludes the C-terminal CB7 and identifies the labeled peptide as CB6. Also, limited tryptic cleavage of intact UCP at Lys293 did not remove the radioactivity. Cleavage of tryptophanes support localization of 8-azido-ATP between residues 173-280 which includes CB6. Solid-phase sequencing of the labeled CB6 both after serine lactone and carboxyl coupling suggest incorporation into Thr260. These results indicate that the adenine-binding site is within the third domain of the tripartite UCP structure at a putative hydrophilic channel which can be assessed both from the cytosol and matrix of mitochondria.     

A novel interaction partner for the C-terminus of Arabidopsis thaliana plasma membrane H+-ATPase (AHA1 isoform): site and mechanism of action on H+-ATPase activity differ from those of 14-3-3 proteins

Using the two-hybrid technique we identified a novel protein whose N-terminal 88 amino acids (aa) interact with the C-terminal regulatory domain of the plasma membrane (PM) H+-ATPase from Arabidopsis thaliana (aa 847-949 of isoform AHA1). The corresponding gene has been named Ppi1 for Proton pump interactor 1. The encoded protein is 612 aa long and rich in charged and polar residues, except for the extreme C-terminus, where it presents a hydrophobic stretch of 24 aa. Several genes in the A. thaliana genome and many ESTs from different plant species share significant similarity (50-70% at the aa level over stretches of 200-600 aa) to Ppi1. The PPI1 N-terminus, expressed in bacteria as a fusion protein with either GST or a His-tag, binds the PM H+-ATPase in overlay experiments. The same fusion proteins and the entire coding region fused to GST stimulate H+-ATPase activity. The effect of the His-tagged peptide is synergistic with that of fusicoccin (FC) and of tryptic removal of a C-terminal 10 kDa fragment. The His-tagged peptide binds also the trypsinised H+-ATPase. Altogether these results indicate that PPI1 N-terminus is able to modulate the PM H+-ATPase activity by binding to a site different from the 14-3-3 binding site and is located upstream of the trypsin cleavage site.     

Antibodies to synthetic peptides as probes of acetylcholine receptor structure

Peptides containing the C-terminus of the alpha-chain of the nicotinic acetylcholine receptor (nAChR), as deduced from cDNA data, were synthesised and shown to bind to antibodies to denatured nAChR. Conversely, peptide-specific antibodies bound both to native and to denatured nAChR. Binding was exclusively to the alpha-chain. Trypsinization experiments and the use of the unique C-terminal hexapeptide of the alpha-chain demonstrated that the proposed C-terminus does exist on the mature alpha-chain, and that post-translational cleavage can be discounted as an explanation of the discrepancy of the molecular masses of the alpha-chain deduced from SDS gel electrophoresis (40 kDa) and from the DNA sequencing (50 kDa). Cleavage of the alpha-chain in the membrane occurs at two closely linked sites, resulting in the formation of a large fragment (approximately 35 kDa) and the remainder of the chain (approximately 9-10 kDa). No signs of experimental myasthenia gravis were observed in rabbits immunised with C-terminal peptide coupled to carrier protein.     

Characterization of a self-splicing mini-intein and its conversion into autocatalytic N- and C-terminal cleavage elements: facile production of protein building blocks for protein ligation

The determinants governing the self-catalyzed splicing and cleavage events by a mini-intein of 154 amino acids, derived from the dnaB gene of Synechocystis sp. were investigated. The residues at the splice junctions have a profound effect on splicing and peptide bond cleavage at either the N- or C-terminus of the intein. Mutation of the native Gly residue preceding the intein blocked splicing and cleavage at the N-terminal splice junction, while substitution of the intein C-terminal Asn154 resulted in the modulation of N-terminal cleavage activity. Controlled cleavage at the C-terminal splice junction involving cyclization of Asn154 was achieved by substitution of the intein N-terminal cysteine residue with alanine and mutation of the native C-extein residues. The C-terminal cleavage reaction was found to be pH-dependent, with an optimum between pH6.0 and 7.5. These findings allowed the development of single junction cleavage vectors for the facile production of proteins as well as protein building blocks with complementary reactive groups. A protein sequence was fused to either the N-terminus or C-terminus of the intein, which was fused to a chitin binding domain. The N-terminal cleavage reaction was induced by 2-mercaptoethanesulfonic acid and released the 43kDa maltose binding protein with an active C-terminal thioester. The 58kDa T4 DNA ligase possessing an N-terminal cysteine was generated by a C-terminal cleavage reaction induced by pH and temperature shifts. The intein-generated proteins were joined together through a native peptide bond. This intein-mediated protein ligation approach opens up novel routes in protein engineering.     

Topology of subunits of the mammalian cytochrome c oxidase: relationship to the assembly of the enzyme complex.

The arrangement of three subunits of beef heart cytochrome c oxidase, subunits Va, VIa, and VIII, has been explored by chemical labeling and protease digestion studies. Subunit Va is an extrinsic protein located on the C side of the mitochondrial inner membrane. This subunit was found to label with N-(4-azido-2-nitrophenyl)-2-aminoethane[35S]sulfonate and sodium methyl 4-[3H]formylphenyl phosphate in reconstituted vesicles in which 90% of cytochrome c oxidase complexes were oriented with the C domain outermost. Subunit VIa was cleaved by trypsin both in these reconstituted vesicles and in submitochondrial particles, indicating a transmembrane orientation. The epitope for a monoclonal antibody (mAb) to subunit VIa was lost or destroyed when cleavage occurred in reconstituted vesicles. This epitope was localized to the C-terminal part of the subunit by antibody binding to a fusion protein consisting of glutathione S-transferase (G-ST) and the C-terminal amino acids 55-85 of subunit VIa. No antibody binding was obtained with a fusion protein containing G-ST and the N-terminal amino acids 1-55. The mAb reaction orients subunit VIa with its C-terminus in the C domain. Subunit VIII was cleaved by trypsin in submitochondrial particles but not in reconstituted vesicles. N-Terminal sequencing of the subunit VIII cleavage product from submitochondrial particles gave the same sequence as the untreated subunit, i.e., ITA, indicating that it is the C-terminus which is cleaved from the M side. Subunits Va and VIII each contain N-terminal extensions or leader sequences in the precursor polypeptides; subunit VIa is made without an N-terminal extension.     

Conformational changes of yeast plasma membrane H(+)-ATPase during activation by glucose: role of threonine-912 in the carboxy-terminal tail

Yeast Pma1 H(+)-ATPase, which belongs to the P-type family of cation-transporting ATPases, is activated up to 10-fold by growth on glucose, and indirect evidence has linked the activation to Ser/Thr phosphorylation within the C-terminal tail. We have now used limited trypsinolysis to map glucose-induced conformational changes throughout the 100 kDa ATPase. In the wild-type enzyme, trypsin cleaves first at Lys-28 and Arg-73 in the extended N-terminal segment (sites T1 and T2); subsequent cleavages occur at Arg-271 between the A domain and M3 (site T3) and at Lys-749 or Lys-754 in the M6-M7 cytoplasmic loop (site T4). Activation by glucose leads to a striking increase in trypsin sensitivity. At the C-terminal end of the protein, the Arg- and Lys-rich tail is shielded from trypsin in membranes from glucose-starved cells (GS) but becomes accessible in membranes from glucose-metabolizing cells (GM). In the presence of orthovanadate, Lys-174 at the boundary between M2 and the A domain also becomes open to cleavage in GM but not GS samples (site T5). Significantly, this global conformational change can be suppressed by mutations at Thr-912, a consensus phosphorylation site near the C-terminus. Substitution by Ala at position 912 leads to a GS-like (trypsin-resistant) state, while substitution by Asp leads to a GM-like (trypsin-sensitive) state. Thus, the present results help to dissect the intramolecular movements that result in glucose activation.     

Functional and structural membrane topology of rat liver microsomal glutathione transferase

The membrane topology of rat liver microsomal glutathione transferase was investigated by comparing the tryptic cleavage products from intact and permeabilized microsomes. It was shown that lysine-4 of microsomal glutathione transferase is accessible at the luminal surface of the endoplasmic reticulum, whereas lysine-41 faces the cytosol. These positions are separated by a hydrophobic stretch of 25 amino acids (positions 11–35) which comprises the likely membrane-spanning region. Reaction of cysteine-49 of the microsomal glutathione transferase with the charged sulfhydryl reagent DTNB (2,2′-dithiobis(5-nitrobenzoic acid))) in intact microsomes further supports the cytosolic localization of this portion of the polypeptide chain. The role of two other potential membrane-spanning/associated segments in the C-terminal half of the polypeptide chain was examined by investigating the association of the protein to the membrane after trypsin cleavage at lysine-41. Activity measurements and Western blot analysis after washing with high concentrations of salt, as well as after phase separation in Triton X-114, indicate that this portion of the protein also binds to the membrane. It is also shown that cleavage of the purified protein at Lys-41 and subsequent separation of the fragments obtained yields a functional C-terminal polypeptide with the expected length for the product encompassing positions 42–154. The location of the active site of microsomal glutathione transferase was investigated using radiolabelled glutathione together with a second substrate. Since isolated rat liver microsomes do not take up glutathione or release the glutathione conjugate into the lumen, it can be concluded that the active site of rat liver microsomal glutathione transferase faces the cytosolic side of the endoplasmic reticulum.     

A role for ubiquitinylation and the cytosolic proteasome in turnover of mitochondrial uncoupling protein 1 (UCP1)

In this study we show that mitochondrial uncoupling protein 1 (UCP1) in brown adipose tissue (BAT) and thymus mitochondria can be ubiquitinylated and degraded by the cytosolic proteasome. Using a ubiquitin conjugating system, we show that UCP1 can be ubiquitinylated in vitro. We demonstrate that UCP1 is ubiquitinylated in vivo using isolated mitochondria from brown adipose tissue, thymus and whole brown adipocytes. Using an in vitro ubiquitin conjugating-proteasome degradation system, we show that the cytosolic proteasome can degrade UCP1 at a rate commensurate with the half-life of UCP1 (i.e. 30-72h in brown adipocytes and ~3h, in thymocytes). In addition, we demonstrate that the cytoplasmic proteasome is required for UCP1 degradation from mitochondria that the process is inhibited by the proteasome inhibitor MG132 and that dissipation of the mitochondrial membrane potential inhibits degradation of UCP1. There also appears to be a greater amount of ubiquitinylated UCP1 associated with BAT mitochondria from cold-acclimated animals. We have also identified (using immunoprecipitation coupled with mass spectrometry) ubiquitinylated proteins with molecular masses greater than 32kDa, as being UCP1. We conclude that there is a role for ubiquitinylation and the cytosolic proteasome in turnover of mitochondrial UCP1. This article is part of a Special Issue entitled: 17th European Bioenergetics Conference (EBEC 2012).     

Topology of the anion exchange protein AE1: the controversial sidedness of lysine 743

The topology of the band 3 (AE1) polypeptide of the erythrocyte membrane is not fully established despite extensive study. Residues near lysine 743 (K743) have been reported to be extracellular in some studies and cytoplasmic in others. In the work presented here, we have attempted to establish the sidedness of K743 using in situ proteolysis. Trypsin, papain, and proteinase K do not cleave band 3 at or near K743 in intact red cells, even under conditions that cause cleavage on the C-terminal side of the glycosylation site (N642) in extracellular loop 4. In contrast, trypsin sealed inside red cell ghosts cleaves at K743, as does trypsin treatment of inside-out vesicles (IOVs). The transport inhibitor 4,4'-diisothiocyanatodihydrostilbene-2,2'-disulfonate (H(2)DIDS), acting from the extracellular side, blocks trypsin cleavage at K743 in unsealed membranes by inducing a protease-resistant conformation. H(2)DIDS added to IOVs does not prevent cleavage at K743; therefore, trypsin cleavage at K743 in IOVs is not a consequence of cleavage of right-side-out or leaky vesicles. Finally, microsomes were prepared from HEK293 cells expressing the membrane domain of AE1 lacking the normal glycosylation site. This polypeptide does not traffic to the surface membrane; trypsin treatment of microsomes containing this polypeptide produces the 20 kDa fragment, providing further evidence that K743 is exposed at the cytoplasmic surface. Therefore, the actions of trypsin on intact cells, resealed ghosts, unsealed ghosts, inside-out vesicles, and microsomes from HEK293 cells all indicate that K743 is cytoplasmic and not extracellular.     

Limited proteolysis and active-site labeling studies of soybean lipoxygenase.

Soybean lipoxygenase 1 was studied using limited proteolysis and active-site labeling to begin the structural characterization of the enzyme in solution. The serine proteases trypsin and chymotrypsin cleaved the large monomeric protein (95 kDa) into two large polypeptides, a C-terminal fragment of about 30 kDa and an N-terminal fragment of about 60 kDa. Under conditions that led to complete cleavage of the protein as judged by SDS-polyacrylamide gel electrophoresis, the catalytic activity of the protein was either reduced slightly (chymotrypsin) or enhanced (trypsin). The characteristics of the cleaved enzymes were the same as for native lipoxygenase 1 in all aspects examined: insensitivity to cyanide, fluoride, and EDTA, regiochemical and stereochemical consequences of catalysis, and EPR spectroscopy upon oxidation by product. The two fragments apparently were tightly associated as they could not be resolved under conditions which preserved the catalytic activity. Both native and protease-cleaved lipoxygenase 1 formed covalent adducts when treated with either 14C-phenylhydrazine or 4-nitrophenylhydrazine. The label was found only in the 60-kDa fragment and following complete trypsin digestion was associated with a peptide beginning after Lys-482 in the primary sequence. Therefore labeling occurred in the vicinity of the conserved histidine cluster which has been postulated as the iron-binding site. From these observations it appears that lipoxygenase 1 exists as a pair of tightly associated domains with the iron-binding site located in the larger of the two.     

Cell-surface display of a Pseudomonas aeruginosa strain K pilin peptide within the paracrystalline S-layer of Caulobacter crescentus

The paracrystalline surface (S)-layer of Caulobacter crescentus is composed of a single secreted protein (RsaA) that interlocks in a hexagonal pattern to completely envelop the bacterium. Using a genetic approach, we inserted a 12 amino acid peptide from Pseudomonas aeruginosa strain K pilin at numerous semirandom positions in RsaA. We then used an immunological screen to identify those sites that presented the inserted pilin peptide on the C. crescentus cell surface as a part of the S-layer. Eleven such sites (widely separated in the primary sequence) were identified, demonstrating for the first time that S-layers can be readily exploited as carrier proteins to display ‘epitope-size’ heterologous peptides on bacterial cell surfaces. Whereas intact RsaA molecules carrying a pilin peptide could always be found on the surface of C. crescentus regardless of the particular insertion site, introduction of the pilin peptide at 9 of the 11 sites resulted in some proteolytic cleavage of RsaA. Two types of proteolytic phenomena were observed. The first was characterized by a single cleavage within the pilin peptide insert with both fragments of the S-layer protein remaining anchored to the outer membrane. The other proteolytic phenomenon was characterized by cleavage of the S-layer protein at a point distant from the site of the pilin peptide insertion. This cleavage always occurred at the same location in RsaA regardless of the particular insertion site, yielding a surface-anchored 26 kDa proteolytic fragment bearing the RsaA N-terminus; the C-terminal cleavage product carrying the pilin peptide was released into the growth medium. When the results of this work were combined with the results of a previous study, the RsaA primary sequence could be divided into three regions with respect to the location of a peptide insertion and its effect on S-layer biogenesis: (i) insertions in the extreme N-terminus of RsaA either produce no apparent effect on S-layer biogenesis or disrupt surface-anchoring of the protein; (ii) insertions in the extreme C-terminus either produce no apparent effect on S-layer biogenesis or disrupt protein secretion; and (iii) insertions more centrally located in the protein either have no apparent effect on S-layer biogenesis or result in proteolytic cleavage of RsaA. These data are discussed in relation to our previous assignment of the RsaA N- and C-terminus as regions that are important for surface anchoring and secretion respectively.     

The structural basis of proteolytic activation of bovine glutamate dehydrogenase

In this work, we re-examine the previously reported phenomenon of the creation of a superactive glutamate dehydrogenase by proteolytic modification by chymotrypsin and explore the various discrepancies that came to light during those studies. We find that superactivation is caused by cleavage at the N terminus of the protein and not the C-terminal allosteric site, as has previously been suggested. N-terminal sequencing reveals that TLCK-treated chymotrypsin cleaves bovine glutamate dehydrogenase at phenylalanine 10. We suggest that trypsin contamination in nontreated chymotrypsin may have led to the production of the larger 4–5 kDa digestion product, previously misinterpreted as having caused the activation. In line with some previous studies, we can confirm that GTP inhibition is attenuated to some extent by the proteolysis, while ADP activation is almost abolished. Utilizing the recently solved structures of bovine glutamate dehydrogenase, we illustrate the cleavage points.     

Interaction of the C-terminal region of p105 with the nuclear localisation signal of p50 is required for inhibition of NF-kappa B DNA binding activity.

DNA binding of the homodimeric p50 subunit of NF-kappa B was inhibited by a bacterially expressed protein containing the ankyrin repeats present in the C-terminus of the p105 precursor but not by the I kappa B protein MAD-3. However p50 was retained on protein affinity matrices containing either the C-terminal ankyrin repeats of p105 or MAD-3. To investigate the interaction between p50 and proteins containing ankyrin repeats we have used a number of approaches to probe the accessibility of the p50 nuclear localisation signal in the protein complex. A monoclonal antibody recognising a linear epitope either very close to, or including, the nuclear localisation signal of the p50 protein could immunoprecipitate p50 homodimers but was unable to precipitate the protein when it was bound to the C-terminal region of p105. A close association between the nuclear localisation signal of p50 and the C-terminal region of p105 was also suggested by protease accessibility experiments. While the nuclear localisation signal of free p50 is extremely susceptible to cleavage with trypsin the same site is masked in the presence of the C-terminal ankyrin repeats of p105 and, to a lesser extent MAD-3. Removal of the nuclear localisation signal by trypsin digestion generates a protein that is fully competent for DNA binding but is refractile to inhibition by the C-terminal ankyrin repeats of p105. Addition of DNA destabilises complexes between p50 and ankyrin repeat containing proteins, increasing the susceptibility of the nuclear localisation signal to trypsin cleavage. The data suggest that there is a rapid exchange of p50 between complexes containing DNA or I kappa B proteins via a metastable complex containing DNA, p50 and I kappa B.     

Active site of α1-antitrypsin: Homologous site in antithrombin-III

Examination of peptides resulting from reaction of bovine trypsin and human α₁-antitrypsin in near-equimolar amounts showed anomalous cleavage of antitrypsin at a Met-Ser bond 37 residues from the C-terminus, giving evidence that this is the active site for trypsin inhibition. Alignment of the C-terminal 141 residues of α₁-antitrypsin with the C-terminal 147 residues of human antithrombin-III showed homology with 30% identity and allowed the identification of a homologous active site in antithrombin.     

A polyglycine stretch is necessary for proper targeting of the protein translocation channel precursor to the outer envelope membrane of chloroplasts

Toc75 is a protein translocation channel in the outer envelope membrane of chloroplasts and its presence is essential for the biogenesis of the organelles. Toc75 is the only protein identified so far in the outer membrane of chloroplasts or mitochondria that is synthesized as a larger precursor, preToc75, with a bipartite transit peptide. Its N-terminus targets the protein to the stroma and is removed by the stromal processing peptidase, whereas its C-terminus mediates envelope targeting and is removed by a yet unknown peptidase. Several conserved domains have been identified in the C-terminal portion of the preToc75 transit peptide from six plant species. We evaluated their importance in the biogenesis of Toc75 by means of deletion or site-directed mutagenesis, followed by import experiments using isolated chlroplasts. Among the conserved domains, a polyglycine stretch was found to be necessary for envelope targeting. Substitution of this domain with other stretches of a single amino acid such as alanine caused mistargeting of the protein into the stroma, indicating an important role for this domain. Furthermore, a glutamate at +2 and two alanine residues at -3 and -1 to the second cleavage site were found to be important for processing. A potential mechanism for the biogenesis of Toc75 is discussed.     

Role of the major capsid protein of phage T4 in DNA packaging from structure-function and site-directed mutagenesis studies

Heat cleavage of asp-pro peptide bonds was used to probe the primary structures of the Phage T4 major capsid protein precursor, gp23, its mature capsid form gp23*, and a DNA-dependent ATPase, called capsizyme. This analysis suggests that capsizyme is a gp23** resulting from the N-terminal processing found in gp23* as well as shortening at the C-terminus. Photoaffinity labeling with Azido-ATP and BrU-DNA, followed by heat cleavage, suggests binding sites for these compounds toward the C-terminus of gp23**, suggesting localization of functions within the gp23 primary sequence. Site-directed mutagenesis experiments were targeted therefore to the C-terminal end of g23 as well as to its processing sites. N-terminal processing site modification supports the consensus gp21 proteinase cleavage rule, whereas mutagenesis at the C-terminus suggests that the C-terminal alteration is unlikely to result from a gp21-morphogenesis proteinase cleavage. Amino acid replacements in gp23 at newly introduced amber sites reveal a new g23 mutant phenotype, defective partially DNA-filled heads, in support of the hypothesis that gp23 and its products function directly in the DNA packaging mechanism.