Interdomain hydrolysis of a truncated Pseudomonas exotoxin by the human immunodeficiency virus-1 protease

The specificity of HIV-1 (human immunodeficiency virus-1) protease has been evaluated relative to its ability to cleave the three-domain Pseudomonas exotoxin (PE66) and related proteins in which the first domain has been deleted or replaced by a segment of CD4. Native PE66 is not hydrolyzed by the HIV-1 protease. However, removal of its first domain produces a molecule which is an excellent substrate for the enzyme. The major site of cleavage in this truncated exotoxin, called LysPE40, occurs in a segment that connects its two major domains, the translocation domain (II), and the ADP-ribosyltransferase (III). This interdomain region contains the sequence ...Asn-Tyr-Pro-Thr... which is similar to that surrounding the scissile Tyr-Pro bond in the gag precursor polyprotein, a natural substrate of the HIV-1 protease. Nevertheless, it is not this sequence that is recognized and cleaved by the enzyme, but one 6 residues away, ...Ala-Leu-Leu-Glu... in which the Leu-Leu peptide bond is hydrolyzed. A second, slower cleavage takes place at the Leu-Ala bond 3 residues in from the NH2 terminus of LysPE40. When domain I of PE66 is replaced by a segment comprising the first two domains of CD4, the resulting chimeric protein is hydrolyzed at the same Leu-Leu bond by HIV-1 protease. Enzyme activities toward synthetic peptides modeled after the sequences defined above in LysPE40 are in complete accord, relative to specificity, kinetics, and pH optimum, with results obtained in the hydrolysis of the parent protein. These findings demonstrate that ideas concerning the specificity of the HIV-1 protease that are based solely upon its processing of natural viral polyproteins can be expanded by evaluation of other multidomain proteins as substrates. Moreover, it would appear that it is not a particular conformation, but sequence and accessibility that play the dominant role in defining sites in a protein substrate that are susceptible to hydrolysis by the enzyme.     

Structure-function relation of the NH2-terminal domain of the Semliki Forest virus capsid protein.

The capsid (C) protein of alphaviruses consists of two protein domains: a serine protease at the COOH terminus and an NH2-terminal domain which is thought to interact with RNA in the virus nucleocapsid (NC). The latter domain is very rich in positively charged amino acid residues. In this work, we have introduced large deletions into the corresponding region of a full-length cDNA clone of Semliki Forest virus, expressed the transcribed RNA in BHK-21 cells, and monitored the autoprotease activity of C, the formation of intracellular NCs, and the release of infectious virus. Our results show that if the gene region encoding the whole NH2-terminal domain is removed, the expressed C protein fragment cannot assemble into NCs and virus particles but it is still able to function as an autoprotease. Thus, these results underline the general importance of the NH2-terminal domain in the virus assembly process and furthermore show that the serine protease domain can function independently of the NH2 terminus. Surprisingly, analysis of additional C protein deletion variants showed that not all of the NH2-terminal domain is required for virus assembly, but large deletions involving up to one-third of its positively charged residues are still compatible with NC and virus formation. The fact that so much flexibility is allowed in the structure of the NH2-terminal domain of C suggests that most of this region is involved in nonspecific interactions with the encapsidated RNA, probably through its positively charged amino acid residues.     

Chemical synthesis of a biotinylated derivative of the simian immunodeficiency virus protease. Purification by avidin affinity chromatography and autocatalytic activation.

The protease from simian immunodeficiency virus (SIV) was chemically synthesized by automated solid-phase technology as an NH2-terminally extended derivative, capped with biotin. Biotin-linker-(SIV protease (1-99)): the linker segment, Gly-Gly-Asp-Arg-Gly-Phe-Ala-Ala, corresponds to the amino acid sequence preceding that of the protease in the SIV gag/pol precursor polyprotein. Accordingly, the Ala-Pro bond joining the octapeptide linker to the protease constitutes a site naturally cleaved by the protease during viral maturation. This strategy for synthesis was designed to facilitate purification of the biotinylated protein derivative from a complex mixture of reaction products by avidin/agarose-affinity chromatography and to provide the means for autocatalytic removal of the biotin-linker segment. As anticipated, folding of the full-length construct leads to activation of the enzyme and excision of the desired 99-residue SIV protease (overall yield, approximately). The specificity of the synthetic SIV protease toward a number of well characterized protein substrates was the same as observed for the nearly identical enzyme from human immunodeficiency virus type 2 (HIV-2 protease) and distinct from that of the more disparate HIV-1 protease. The same functional ordering with respect to the human retroviral proteases was reflected in Ki values observed with a number of protease inhibitors. Thus, the folded synthetic SIV protease shows patterns of specificity and susceptibility to inhibition that are in accord with what would be expected based upon its degree of structural similarity to proteases from HIV-1 and HIV-2.     

Constraints imposed by protease accessibility on the trans-membrane and surface topography of the colicin E1 ion channel.

The surface topography of a 190-residue COOH-terminal colicin E1 channel peptide (NH2-Met 333-Ile 522-COOH) bound to uniformly sized 0.2-micron liposomes was probed by accessibility of the peptide to proteases in order (1) to determine whether the channel structure contains trans-membrane segments in addition to the four alpha-helices previously identified and (2) to discriminate between different topographical possibilities for the surface-bound state. An unfolded surface-bound state is indicated by increased trypsin susceptibility of the bound peptide relative to that of the peptide in aqueous solution. The peptide is bound tightly to the membrane surface with Kd < 10(-7) M. The NH2-terminal 50 residues of the membrane-bound peptide are unbound or loosely bound as indicated by their accessibility to proteases, in contrast with the COOH-terminal 140 residues, which are almost protease inaccessible. The general protease accessibility of the NH2-terminal segment Ala 336-Lys 382 excludes any model for the closed channel state that would include trans-membrane helices on the NH2-terminal side of Lys 382. Lys 381-Lys 382 is a major site for protease cleavage of the surface-bound channel peptide. A site for proteinase K cleavage just upstream of the amphiphilic gating hairpin (K420-K461) implies the presence of a surface-exposed segment in this region. These protease accessibility data indicate that it is unlikely that there are any alpha-helices on the NH2-terminal side of the gating hairpin K420-K461 that are inserted into the membrane in the absence of a membrane potential. A model for the topography of an unfolded monomeric surface-bound intermediate of the colicin channel domain, including a trans-membrane hydrophobic helical hairpin and two or three long surface-bound helices, is proposed.     

alpha 2-Macroglobulin is cleaved by HIV-1 protease in the bait region but not in the C-terminal inter-domain region.

alpha 2-Macroglobulin is cleaved by human immunodeficiency virus-1 protease. The cleavage site is the Phe684-Tyr685 bond in the "bait region", an exposed part of alpha 2-macroglobulin, creating the "F-form". The methylamine derivative of alpha 2-macroglobulin is also cleaved at the same bond. The homologous chicken ovomacroglobulin does not form an F-form structure with the protease, although, F-form generation by other enzymes is known. This is possibly due to the lack of a suitable cleavage sequence in the corresponding region of ovomacroglobulin. In human alpha 2-macroglobulin, the interdomain segment between the main part of the molecule and the receptor-binding C-terminal domain is not cleaved by the HIV protease although typical cleavage sequences occur. In AIDS, therefore, HIV protease from infected cells in unlikely to interfere with receptor-binding of alpha 2-macroglobulin.     

Actin, troponin C, Alzheimer amyloid precursor protein and pro-interleukin 1 beta as substrates of the protease from human immunodeficiency virus

We show here for the first time that actin, troponin C, Alzheimer amyloid precursor protein (AAP), and pro-interleukin 1 beta (pro-IL-1 beta), are substrates of the protease encoded by the human immunodeficiency virus (HIV) type-1. As has been seen in other non-viral protein substrates of the HIV protease, the presence of Glu residues in the P2' position appears to play an important role in substrate recognition. Three of the four bonds cleaved in actin, two of the three in troponin C, and all of the bonds hydrolyzed in AAP and pro-IL-1 beta have a P2' Glu residue. In fact, Glu residues are accommodated in all positions from P4 to P4' surrounding the scissile bond in substrates of the HIV proteases, and as many as 4 adjacent Glu residues were seen in one of the bonds cleaved in AAP. This study of non-viral protein substrates has also revealed unexpected amino acids such as Gly, Arg, and Glu in the scissile bond itself rather than the more conventional hydrophobic amino acids. The HIV-2 protease hydrolyzed actin in a manner similar to that of the HIV-1 enzyme, but its cleavage of troponin C was distinct in that it split a bond adjacent to a triplet of Glu residues in P2, P3, and P4 that was refractory to the HIV-1 enzyme. Documentation of cleavage sites in the several important cellular proteins noted above has extended our understanding of the features in a substrate that are recognized by these multi sub-site proteases of retroviral maturation. Moreover, the present work adds to an accumulating body of evidence which demonstrates that these enzymes can damage crucial structural and regulatory cellular proteins if ever their activity is expressed outside the viral particle itself.     

Molecular and enzymatic characterization of the porcine endogenous retrovirus protease

The protease of the porcine endogenous retrovirus (PERV) subtypes A/B and C was recombinantly expressed in Escherichia coli as proteolytically active enzyme and characterized. The PERV Gag precursor was also recombinantly produced and used as the substrate in an in vitro enzyme assay in parallel with synthetic nonapeptide substrates designed according to cleavage site sequences identified in the PERV Gag precursor. The proteases of all PERV subtypes consist of 127 amino acid residues with an M(r) of 14,000 as revealed by determining the protease N and C termini. The PERV proteases have a high specificity for PERV substrates and do not cleave human immunodeficiency virus (HIV)-specific substrates, nor are they inhibited by specific HIV protease inhibitors. Among the known retroviral proteases, the PERV proteases resemble most closely the protease of the murine leukemia retrovirus.     

Purification and characterization of a keratinolytic serine proteinase from Streptomyces albidoflavus.

Streptomyces strain K1-02, which was identified as a strain of Streptomyces albidoflavus, secreted at least six extracellular proteases when it was cultured on feather meal-based medium. The major keratinolytic serine proteinase was purified to homogeneity by a two-step procedure. This enzyme had a molecular weight of 18,000 and was optimally active at pH values ranging from 6 to 9.5 and at temperatures ranging from 40 to 70 degrees C. Its sensitivity to protease inhibitors, its specificity on synthetic substrates, and its remarkably high level of NH2-terminal sequence homology with Streptomyces griseus protease B (SGPB) showed that the new enzyme, designated SAKase, was homologous to SGPB. We tested the activity of SAKase with soluble and fibrous substrates (elastin, keratin, and type I collagen) and found that it was very specific for keratinous substrates compared to SGPB and proteinase K.     

A non-canonical lon proteinase lacking the ATPase domain employs the ser-Lys catalytic dyad to exercise broad control over the life cycle of a double-stranded RNA virus

We have identified a region related to the protease domain of bacterial and organelle ATP-dependent Lon proteases in virus protein 4 (VP4) of infectious bursal disease virus strain P2 (IBDVP2), a two-segmented double-stranded RNA virus. Unlike canonical Lons, IBDVP2 VP4 possesses a proteinase activity though it lacks an ATPase domain. Ser652 and Lys692 of IBDVP2 VP4 are conserved across the Lon/VP4 family and are essential for catalysis. Lys692 has the properties of a general base, increasing the nucleophilicity of Ser652; a similar catalytic dyad may function in the other Lons. VP4 can cleave in trans and is responsible for the interdomain proteolytic autoprocessing of the pVP2- VP4-VP3 polyprotein encoded by RNA segment A. VP2, which is later derived from pVP2, and VP3 are major capsid proteins of birnaviruses. Results of the characterization of a range of the IBDVP2 VP4 mutants in cell cultures implicate VP4 in trans-activation of the synthesis of VP1, putative RNA-dependent RNA polymerase encoded by RNA segment B, and in cleavage rate-dependent control of process(es) crucial for the generation of the infectious virus progeny.     

Specificity and inhibition of proteases from human immunodeficiency viruses 1 and 2

Highly purified, recombinant preparations of the virally encoded proteases from human immunodeficiency viruses (HIV) 1 and 2 have been compared relative to 1) their specificities toward non-viral protein and synthetic peptide substrates, and 2) their inhibition by several P1-P1' pseudodipeptidyl-modified substrate analogs. Hydrolysis of the Leu-Leu and Leu-Ala bonds in the Pseudomonas exotoxin derivative, Lys-PE40, is qualitatively the same for HIV-2 protease as published earlier for the HIV-1 enzyme (Tomasselli, A. G., Hui, J. O., Sawyer, T. K., Staples, D. J., FitzGerald, D. J., Chaudhary, V. K., Pastan, I., and Heinrikson, R. L. (1990) J. Biol. Chem. 265, 408-413). However, the rates of cleavage at these two sites are reversed for the HIV-2 protease which prefers the Leu-Ala bond. The kinetics of hydrolysis of this protein substrate by both enzymes are mirrored by those obtained from cleavage of model peptides. Hydrolysis by the two proteases of other synthetic peptides modeled after processing sites in HIV-1 and HIV-2 gag polyproteins and selected analogs thereof demonstrated differences, as well as similarities, in selectivity. For example, while the two proteases were nearly identical in their rates of cleavage of the Tyr-Pro bond in the HIV-1 gag fragment, Val-Ser-Gln-Asn-Tyr-Pro-Ile-Val, the HIV-1 protease showed a 64-fold enhancement over the HIV-2 enzyme in hydrolysis of a Tyr-Val bond in the same template. Accordingly, the HIV-2 protease appears to have a different specificity than the HIV-1 enzyme; it is better able to hydrolyze substrates with small amino acids in P1 and P1', but is variable in its rate of hydrolysis of peptides with bulky substituents in these positions. In addition to these comparisons of the two proteases with respect to substrate specificity, we present inhibitor structure-activity data for the HIV-2 protease. Relative to P1-P1' statine or Phe psi [CH2N]Pro-modified pseudopeptidyl inhibitors, compounds having Xaa psi[CH(OH)CH2]Yaa inserts were found to show significantly higher affinities to both enzymes, generally binding from 10 to 100 times stronger to HIV-1 protease than to the HIV-2 enzyme. Molecular modeling comparisons based upon the sequence homology of the two enzymes and x-ray crystal structures of HIV-1 protease suggest that most of the nonconservative amino acid replacements occur in regions well outside the catalytic cleft, while only subtle structural differences exist within the active site.(ABSTRACT TRUNCATED AT 400 WORDS)     

The alpha-lytic protease gene of Lysobacter enzymogenes. The nucleotide sequence predicts a large prepro-peptide with homology to pro-peptides of other chymotrypsin-like enzymes

alpha-Lytic protease is a 19.8-kDa protein secreted from the Gram-negative bacterium Lysobacter enzymogenes. We have cloned and sequenced the gene for this serine protease. The nucleotide sequence contains an open reading frame which codes for the 198-residue mature enzyme and a potential prepro-peptide, also of 198 residues. The COOH-terminal 49 residues of the pro-peptide are significantly homologous to the propeptides of Streptomyces griseus proteases A and B. We suggest that this pro-peptide region facilitates formation of the active enzyme. A region bridging the NH2-terminal pre- and pro-peptides is homologous to a maize inhibitor of serine proteases. We speculate that this region inhibits enzymatic activity of the prepro-enzyme.     

Domain structure of 3-hydroxy-3-methylglutaryl coenzyme A reductase, a glycoprotein of the endoplasmic reticulum

We present and evaluate a model for the secondary structure and membrane orientation of 3-hydroxy-3-methylglutaryl coenzyme A reductase, the glycoprotein of the endoplasmic reticulum that controls the rate of cholesterol biosynthesis. This model is derived from proteolysis experiments that separate the 97-kilodalton enzyme into two domains, an NH2-terminal membrane-bound domain of 339 residues and a COOH-terminal water-soluble domain of 548 residues that projects into the cytoplasm and contains the catalytic site. These domains were identified by reaction with antibodies against synthetic peptides corresponding to specific regions in the molecule. Computer modeling of the reductase structure, based on the amino acid sequence as determined by molecular cloning, predicts that the NH2-terminal domain contains 7 membrane-spanning regions. Analysis of the gene structure reveals that each proposed membrane-spanning region is encoded in a separate exon and is separated from the adjacent membrane-spanning region by an intron. The COOH-terminal domain of the reductase is predicted to contain two beta-structures flanked by a series of amphipathic helices, which together may constitute the active site. The NH2-terminal membrane-bound domain of the reductase bears some resemblance to rhodopsin, the photoreceptor protein of retinal rod disks and the only other intracellular glycoprotein whose amino acid sequence is known.     

Detection and localization of a cytoplasmic domain on the beta-subunit of Na+,K+-ATPase. A monoclonal antibody study

A monoclonal antibody directed against the beta-subunit of dog kidney Na+,K+-ATPase was generated. Immunoblots demonstrate that monoclonal antibody III 18A binds exclusively to the denaturated beta-subunit. Binding experiments with membranes and whole cells reveal that III 18A binds to membranes but not to whole cells, indicating that the antibody binds to a cytoplasmic domain on the native beta-subunit. To localize the antibody-binding epitope, purified membrane-bound enzyme was fragmented by protease treatment. Tryptic digestion yields a 30-kDa fragment of the beta-subunit, which still retains the binding capacity for the antibody. Thus III 18A probably does not bind to the NH2-terminal segment of the protein. On the other hand, fragmentation of the beta-subunit with low concentrations of papain, which is known to yield a 40-kDa NH2-terminal and a 16-kDa COOH-terminal fragment, results in a complete loss of III 18A binding. These results suggest that the antibody-binding epitope is localized at or near a papain cleavage site on the COOH-terminal part of the beta-subunit. This is inconsistent with a structure model of the beta-subunit containing only a single transmembrane hydrophobic segment with a cytoplasmic NH2-terminal portion, but agrees quite well with a hypothetical structure with four intramembrane segments.     

Selective proteolysis of cytosolic aspartate aminotransferase by a new microbial protease

A protease from Streptomyces violaceochromogenes (Murao, S., Nishino, Y., & Maeda, Y. (1984) Agric. Biol. Chem. 48, 2163-2166) is known to inactivate pig heart aspartate aminotransferase [EC 2.6.1.1]. Chemical analysis of the core proteins and peptide fragments produced upon proteolysis of the aminotransferase revealed that peptide bond cleavage occurred specifically at Leu 20 with concomitant inactivation. Neither inactivation nor peptide bond cleavage was observed with the mitochondrial isoenzyme. The proteolytically produced derivative 21-412 of the cytosolic isoenzyme retained approximately 0.1% enzymic activity for transamination with natural dicarboxylic substrates. The pyridoxal form of the derivative 21-412 was fully converted by cysteinesulfinate or alanine to the pyridoxamine form and conversely the pyridoxamine form of the derivative was also fully converted by 2-oxoglutarate or pyruvate into the pyridoxal form, indicating that the derivative was still catalytically competent. However, the rates of reaction with dicarboxylic substrates were much reduced whereas the rates with monocarboxylic substrates remained at an order of magnitude similar to that observed with the native enzyme. Thus the NH2-terminal segment appears to be an import structural component which determines the substrate specificity of aspartate aminotransferase for dicarboxylic keto and amino acids. A substantial alteration in the molecular structure accompanying the loss of the NH2-terminal 20 residues was also reflected by the decrease in heat stability and in the lowering of the pKa value for His 68, which is involved in the intersubunit interaction of this dimeric enzyme.     

The Ulp1 SUMO isopeptidase: distinct domains required for viability,nuclear envelope localization,and substrate specificity

Protein modification by the ubiquitin-like SUMO protein contributes to many cellular regulatory mechanisms. In Saccharomyces cerevisiae, both sumoylating and desumoylating activities are essential for viability. Of its two known desumoylating enzymes, Ubl-specific protease (Ulp)1 and Ulp2/Smt4, Ulp1 is specifically required for cell cycle progression. A approximately 200-residue segment, the Ulp domain (UD), is conserved among Ulps and includes a core cysteine protease domain that is even more widespread. Here we demonstrate that the Ulp1 UD by itself can support wild-type growth rates and in vitro can cleave SUMO from substrates. However, in cells expressing only the UD of Ulp1, many SUMO conjugates accumulate to high levels, indicating that the nonessential Ulp1 NH2-terminal domain is important for activity against a substantial fraction of sumoylated targets. The NH2-terminal domain also includes sequences necessary and sufficient to concentrate Ulp1 at nuclear envelope sites. Remarkably, NH2-terminally deleted Ulp1 variants are able, unlike full-length Ulp1, to suppress defects of cells lacking the divergent Ulp2 isopeptidase. Thus, the NH2-terminal regulatory domain of Ulp1 restricts Ulp1 activity toward certain sumoylated proteins while enabling the cleavage of others. These data define key functional elements of Ulp1 and strongly suggest that subcellular localization is a physiologically significant constraint on SUMO isopeptidase specificity.     

A pre-aspartate-specific protease from human leukocytes that cleaves pro-interleukin-1 beta

Interleukin-1 beta is a 17.4-kilodalton hormone derived from a 33-kilodalton inactive precursor produced by monocytes. We used the precursor as a substrate to detect proteolytic activities in peripheral blood mono-nuclear cell-conditioned medium that might be involved in interleukin-1 beta processing. We found that the conditioned medium, following passage through DEAE-Sephacel, generates a biologically active fragment from the precursor that runs slightly higher than the mature hormone in sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The responsible activity behaved as a single protein in ion exchange chromatography. It was completely inhibited by metal ion chelators and not by inhibitors of serine, cysteine, or aspartate proteases, and it was dependent on both calcium (or magnesium) and zinc. The enzyme was not inhibited by three substrate-based metalloprotease inhibitors, phosphoramidon, benzyloxycarbonyl-Gly-Leu-NH2, and N-(2-carboxy-3-phenylpropionyl)-Leu. NH2-terminal sequence analysis showed that cleavage of the precursor occurred between a histidine and an aspartate residue, and digestion of synthetic peptides indicated that the protease is specific for pre-aspartate cleavages.     

Structural basis of the unusual stability and substrate specificity of ervatamin C, a plant cysteine protease from Ervatamia coronaria

Ervatamin C is an unusually stable cysteine protease from the medicinal plant Ervatamia coronaria belonging to the papain family. Though it cleaves denatured natural proteins with high specific activity, its activity toward some small synthetic substrates is found to be insignificant. The three-dimensional structure and amino acid sequence of the protein have been determined from X-ray diffraction data at 1.9 A (R = 17.7% and R(free) = 19.0%). The overall structure of ervatamin C is similar to those of other homologous cysteine proteases of the family, folding into two distinct left and right domains separated by an active site cleft. However, substitution of a few amino acid residues, which are conserved in the other members of the family, has been observed in both the domains and also at the region of the interdomain cleft. Consequently, the number of intra- and interdomain hydrogen-bonding interactions is enhanced in the structure of ervatamin C. Moreover, a unique disulfide bond has been identified in the right domain of the structure, in addition to the three conserved disulfide bridges present in the papain family. All these factors contribute to an increase in the stability of ervatamin C. In this enzyme, the nature of the S2 subsite, which is the primary determinant of specificity of these proteases, is similar to that of papain, but at the S3 subsite, Ala67 replaces an aromatic residue, and has the effect of eliminating sufficient hydrophobic interactions required for S3-P3 stabilization. This provides the possible explanation for the lower activity of ervatamin C toward the small substrate/inhibitor. This substitution, however, does not affect the binding of denatured natural protein substrates to the enzyme significantly, as there exist a number of additional interactions at the enzyme-substrate interface outside the active site cleft.     

Interdomain and membrane interactions of CTP:phosphocholine cytidylyltransferase revealed via limited proteolysis and mass spectrometry

CTP:phosphocholine cytidylyltransferase (CCT) is a multi-domain enzyme that regulates phosphatidylcholine synthesis. It converts to an active form upon binding cell membranes, and interdomain dissociations have been hypothesized to accompany this process. To identify these interdomain and membrane interactions, the tertiary structures of three forms of CCTalpha were probed by monitoring accessibility to proteases. Time-limited digestion with chymotrypsin or arginine C of soluble CCTalpha (CCT(sol)), phospholipid vesicle-bound CCT (CCT(mem)), and a soluble constitutively active CCT truncated at amino acid 236 generated complex mixtures of peptides that were resolved and identified by gel electrophoresis/immunoblotting and by matrix-assisted laser desorption/ionization-mass spectrometry, with or without coupling to capillary liquid chromatography. Identification of cleavage sites enabled assembly of peptide bond accessibility maps for each CCT form. Our results reveal a approximately 80-residue core within the catalytic domain (domain C) as the most inaccessible region in all three forms and the C-terminal phosphorylation domain as the most accessible. Membrane binding has little effect on the protease accessibility of these domains. To map the protease sites onto the catalytic domain, its three-dimensional structure was modeled from the atomic coordinates of glycerol-phosphate cytidylyltransferase (Protein Data Bank code 1COZ). The protease inaccessibility of most sites in domain C could be explained by burial or location within secondary structural elements. The accessibility of the N-terminal domain (domain N) was enhanced upon membrane binding. Residues Phe(234)-Leu(303) were inaccessible in CCT(mem), suggesting burial in the membrane. Surprisingly, residues Leu(274)-Leu(303) of this domain were also inaccessible in CCT(sol). We propose that this region is buried by interdomain contacts with domain N in CCT(sol). Membrane binding and burial of domain M in the lipid bilayer may disrupt this interaction, leading to increased exposure of sites in domain N.     

Structure of the whole cytosolic region of ATP-dependent protease FtsH

An ATP-dependent protease, FtsH, digests misassembled membrane proteins in order to maintain membrane integrity and digests short-lived soluble proteins in order to control their cellular regulation. This enzyme has an N-terminal transmembrane segment and a C-terminal cytosolic region consisting of an AAA+ ATPase domain and a protease domain. Here we present two crystal structures: the protease domain and the whole cytosolic region. The cytosolic region fully retains an ATP-dependent protease activity and adopts a three-fold-symmetric hexameric structure. The protease domains displayed a six-fold symmetry, while the AAA+ domains, each containing ADP, alternate two orientations relative to the protease domain, making "open" and "closed" interdomain contacts. Apparently, ATPase is active only in the closed form, and protease operates in the open form. The protease catalytic sites are accessible only through a tunnel following from the AAA+ domain of the adjacent subunit, raising a possibility of translocation of polypeptide substrate to the protease sites through this tunnel.     

Localization of the deoxyribose phosphate lyase active site in human DNA polymerase iota by controlled proteolysis

Human DNA polymerase iota (pol iota) is a member of the Y-family of low fidelity lesion bypass DNA polymerases. In addition to a probable role in DNA lesion bypass, this enzyme has recently been shown to be required for somatic hypermutation in human B-cells. We found earlier that human pol iota has deoxyribose phosphate (dRP) lyase activity and unusual specificity for activity during DNA synthesis, suggesting involvement in specialized forms of base excision repair (BER). Here, mapping of the domain structure of human pol iota by controlled proteolysis revealed that the enzyme has a 48-kDa NH2-terminal domain and a protease resistant 40-kDa "core domain" spanning residues Met79 to approximately Met445. A covalently cross-linked pol iota-DNA complex, representing a trapped intermediate in the dRP lyase reaction, was subjected to controlled proteolysis. Cross-linking was mapped to the 40-kDa core domain, indicating that the dRP lyase active site is in this region. To further evaluate the BER capacity of the enzyme, the dRP lyase and DNA polymerase activities were characterized on DNA substrates representing BER intermediates, and we found that pol iota was able to complement the in vitro single-nucleotide BER deficiency of a DNA polymerase beta null cell extract.