Dynamics of the chaperonin ATPase cycle: implications for facilitated protein folding.

The Escherichia coli chaperonins GroEL and GroES facilitate protein folding in an adenosine triphosphate (ATP)-dependent manner. After a single cycle of ATP hydrolysis by the adenosine triphosphatase (ATPase) activity of GroEL, the bi-toroidal GroEL formed a stable asymmetric ternary complex with GroES and nucleotide (bulletlike structures). With each subsequent turnover, ATP was hydrolyzed by one ring of GroEL in a quantized manner, completely releasing the adenosine diphosphate and GroES that were tightly bound to the other ring as a result of the previous turnover. The catalytic cycle involved formation of a symmetric complex (football-like structures) as an intermediate that accumulated before the rate-determining hydrolytic step. After one to two cycles, most of the substrate protein dissociated still in a nonnative state, which is consistent with intermolecular transfer of the substrate protein between toroids of high and low affinity. A unifying model for chaperonin-facilitated protein folding based on successive rounds of binding and release, and partitioning between committed and kinetically trapped intermediates, is proposed.

Symmetric complexes of GroE chaperonins as part of the functional cycle.

The particular structural arrangement of chaperonins probably contributes to their ability to assist in the folding of proteins. The interaction of the oligomeric bacterial chaperonin GroEL and its cochaperonin, GroES, in the presence of adenosine diphosphate (ADP) forms an asymmetric complex. However, in the presence of adenosine triphosphate (ATP) or its nonhydrolyzable analogs, symmetric complexes were found by electron microscopy and image analysis. The existence of symmetric chaperonin complexes is not predicted by current models of the functional cycle for GroE-mediated protein folding. Because complete folding of a nonnative substrate protein in the presence of GroEL and GroES only occurs in the presence of ATP, but not with ADP, the symmetric chaperonin complexes formed during the GroE cycle are proposed to be functionally significant.

Crystal structure of 3,4-dihydroxy-2-butanone 4-phosphate synthase of riboflavin biosynthesis.

BACKGROUND: 3,4-Dihydroxy-2-butanone-4-phosphate synthase catalyzes a commitment step in the biosynthesis of riboflavin. On the enzyme, ribulose 5-phosphate is converted to 3,4-dihydroxy-2-butanone 4-phosphate and formate in steps involving enolization, ketonization, dehydration, skeleton rearrangement, and formate elimination. The enzyme is absent in humans and an attractive target for the discovery of antimicrobials for pathogens incapable of acquiring sufficient riboflavin from their hosts. The homodimer of 23 kDa subunits requires Mg(2+) for activity. RESULTS: The first three-dimensional structure of the enzyme was determined at 1.4 A resolution using the multiwavelength anomalous diffraction (MAD) method on Escherichia coli protein crystals containing gold. The protein consists of an alpha + beta fold having a complex linkage of beta strands. Intersubunit contacts are mediated by numerous hydrophobic interactions and three hydrogen bond networks. CONCLUSIONS: A proposed active site was identified on the basis of amino acid residues that are conserved among the enzyme from 19 species. There are two well-separated active sites per dimer, each of which comprise residues from both subunits. In addition to three arginines and two threonines, which may be used for recognizing the phosphate group of the substrate, the active site consists of three glutamates, two aspartates, two histidines, and a cysteine which may provide the means for general acid and base catalysis and for coordinating the Mg(2+) cofactor within the active site.

Crystal structure of riboflavin synthase.

BACKGROUND: Riboflavin synthase catalyzes the dismutation of two molecules of 6,7-dimethyl-8-(1'-D-ribityl)-lumazine to yield riboflavin and 4-ribitylamino-5-amino-2,6-dihydroxypyrimidine. The homotrimer of 23 kDa subunits has no cofactor requirements for catalysis. The enzyme is nonexistent in humans and is an attractive target for antimicrobial agents of organisms whose pathogenicity depends on their ability to biosynthesize riboflavin. RESULTS: The first three-dimensional structure of the enzyme was determined at 2.0 A resolution using the multiwavelength anomalous diffraction (MAD) method on the Escherichia coli protein containing selenomethionine residues. The homotrimer consists of an asymmetric assembly of monomers, each of which comprises two similar beta barrels and a C-terminal alpha helix. The similar beta barrels within the monomer confirm a prediction of pseudo two-fold symmetry that is inferred from the sequence similarity between the two halves of the protein. The beta barrels closely resemble folds found in phthalate dioxygenase reductase and other flavoproteins. CONCLUSIONS: The three active sites of the trimer are proposed to lie between pairs of monomers in which residues conserved among species reside, including two Asp-His-Ser triads and dyads of Cys-Ser and His-Thr. The proposed active sites are located where FMN (an analog of riboflavin) is modeled from an overlay of the beta barrels of phthalate dioxygenase reductase and riboflavin synthase. In the trimer, one active site is formed, and the other two active sites are wide open and exposed to solvent. The nature of the trimer configuration suggests that only one active site can be formed and be catalytically competent at a time.

Chaperonin assisted polypeptide folding and assembly: implications for the production of functional proteins in bacteria.

Production of biologically active foreign proteins with correct three-dimensional structures is often difficult in bacteria. Recent advances demonstrate that, for some proteins at least, their correct folding and assembly is facilitated by a class of proteins known as molecular chaperones. An understanding of the function of molecular chaperones may assist in the synthesis in bacteria of functional foreign proteins produced by recombinant techniques.

Purified chaperonin 60 (groEL) interacts with the nonnative states of a multitude of Escherichia coli proteins.

In vitro experiments employing the soluble proteins from Escherichia coli reveal that about half of them, in their unfolded or partially folded states, but not in their native states, can form stable binary complexes with chaperonin 60 (groEL). These complexes can be isolated by gel filtration chromatography and are efficiently discharged upon the addition of Mg.ATP. Binary complex formation is substantially reduced if chaperonin 60 is presaturated with Rubisco-I, the folding intermediate of Rubisco, but not with native Rubisco. Binary complex formation is also reduced if the transient species that interact with chaperonin 60 are permitted to progress to more stable states. This implies that the structural elements or motifs that are recognized by chaperonin 60 and that are responsible for binary complex formation are only present or accessible in the unfolded states of proteins or in certain intermediates along their respective folding pathways. Given the high-affinity binding that we have observed in the present study and the normal cellular abundance of chaperonin 60, we suspect that the folding of most proteins in E. coli does not occur in free solution spontaneously, but instead takes place while they are associated with molecular chaperones.

Crystal structure analysis of a pentameric fungal and an icosahedral plant lumazine synthase reveals the structural basis for differences in assembly.

Lumazine synthase catalyzes the penultimate step in the synthesis of riboflavin in plants, fungi, and microorganisms. The enzyme displays two quaternary structures, the pentameric forms in yeast and fungi and the 60-meric icosahedral capsids in plants and bacteria. To elucidate the structural features that might be responsible for differences in assembly, we have determined the crystal structures of lumazine synthase, complexed with the inhibitor 5-nitroso-6-ribitylamino-2,4-pyrimidinedione, from spinach and the fungus Magnaporthe grisea to 3.3 and 3.1 A resolution, respectively. The overall structure of the subunit and the mode of inhibitor binding are very similar in these enzyme species. The core of the subunit consists of a four-stranded parallel beta-sheet sandwiched between two helices on one side and three helices on the other. The packing of the five subunits in the pentameric M. grisea lumazine synthase is very similar to the packing in the pentameric substructures in the icosahedral capsid of the plant enzyme. Two structural features can be correlated to the differences in assembly. In the plant enzyme, the N-terminal beta-strand interacts with the beta-sheet of the adjacent subunit, thus extending the sheet from four to five strands. In fungal lumazine synthase, an insertion of two residues after strand beta1 results in a completely different orientation of this part of the polypeptide chain and this conformational difference prevents proper packing of the subunits at the trimer interface in the icosahedron. In the spinach enzyme, the beta-hairpin connecting helices alpha4 and alpha5 participates in the packing at the trimer interface of the icosahedron. Another insertion of two residues at this position of the polypeptide chain in the fungal enzyme disrupts the hydrogen bonding in the hairpin, and the resulting change in conformation of this loop also interferes with proper intrasubunit contacts at the trimer interface.

Cleavage of HIV-1 gag polyprotein synthesized in vitro: sequential cleavage by the viral protease.

The virally encoded protease of human immunodeficiency virus is responsible for the processing of the gag and gag-pol polyprotein precursors to their mature polypeptides. Since correct processing of the viral polypeptides is essential for the production of infectious virus, HIV protease represents a potential target for therapeutic agents that may prove beneficial in the treatment of AIDS. In this study, full-length gag polyprotein has been synthesized in vitro to serve as a substrate for bacterially expressed HIV-1 protease. Expression of the protease in E. coli from the lac promoter was enhanced approximately five-fold by deletion of a potential hairpin loop upstream from the codon determining the amino terminus of mature protease. Extracts of induced cultures of E. coli harboring a protease-containing plasmid served as the source of protease activity. The gag polyprotein synthesized in vitro was cleaved by such lysates, producing fragments corresponding in size to p17 plus p24 and mature p24. Immunoprecipitations with monoclonal antibodies to p17 and p24 polypeptides suggest that initial cleavage of gag polyprotein occurs near the p24-p15 junction. The proteolysis was inhibited by pepstatin with an IC50 of 0.15 mM for cleavage at the p24-p15 junction and 0.02 mM for cleavage at the p17-p24 junction.

Activation and detection of (pro)mutagenic chemicals using recombinant strains of Streptomyces griseus.

Two recombinant strains of Streptomyces griseus have been developed to report on the activation of promutagenic chemicals. This activation is monitored by reversion of the bacterial test strains to a kanamycin-resistant phenotype. Strain H69 detects point mutations and was reverted at an increased frequency by acetonitrile, 2-aminoanthracene, 1,2-benzanthracene, benzidine, benzo(a)pyrene, 9,10-dimethyl-1,2-benzanthracene, and glycine. The second strain, FS2, detects frame shift mutations and was reverted at an increased frequency by 1,2-benzanthracene, benzidine, and glycine. Compounds such as butylated hydroxytoluene, catechol, chlorobenzene, hydroquinone, potassium chloride, phenol, cis-stilbene, trans-stilbene, and toluene did not elicit positive responses in either strain. In addition, these strains are capable of detecting direct-acting mutagens such as N-methyl-N'-nitrosoguanidine and ICR-191, providing further evidence of their promise for detecting a wider range of mutagens. To our knowledge, this is the first report of bacterial strains capable of activating promutagenic compounds and detecting their mutagenic metabolites without the benefit of an exogenous activation system such as the rodent liver homogenate (S9).

Hepatitis A, B, C and HIV infections among Finnish female prisoners--young females a risk group.

OBJECTIVES: Previous prison studies have shown that the female gender is associated with higher hepatitis C prevalence. However, there are few prison studies of gender differences concerning the risk factors of hepatitis C infections. We studied the prevalence of hepatitis and HIV infections and the risk factors among Finnish female prisoners. METHODS: The material consisted of 88 females and 300 male prisoners as controls. RESULTS: The prevalence of hepatitis C virus antibodies was 52%, hepatitis B surface antigen 0%, hepatitis A virus antibodies 38% and HIV antibodies 1% among women, and 44%, 0.7%, 4% and 0.7% respectively among men. Among women, 71% of the age group 16-24 had HCV. There was no significant association between gender and HCV. Women were more commonly sharing syringes/needles and had unsafe sexual habits. Among women, HCV was associated only with IDU and syringe/needle sharing whereas among men also with tattoos, cumulative years in prison and age. CONCLUSIONS: Especially young females had a high prevalence of HCV. The study showed that the risk factors are differentiated by gender. This should be taken into account when assessing earlier studies which mainly concentrate on men.

Hydrolysis of adenosine 5'-triphosphate by Escherichia coli GroEL: effects of GroES and potassium ion.

The potassium-ion activation constant (Kact) for the ATPase activity of Escherichia coli chaperonin groEL is inversely dependent upon the ATP concentration over at least 3 orders of magnitude. The ATPase activity shows positively cooperative kinetics with respect to ATP and K+. Both the K0.5 for ATP and cooperativity (as measured by the Hill coefficient) decrease as the K+ concentration increases. Equilibrium binding studies under conditions where hydrolysis does not occur indicate that MgATP binds weakly to groEL in the absence of K+. In the absence of groES, the K(+)-dependent hydrolysis of ATP by groEL continues to completion. In the presence of groES, the time course for the hydrolysis of ATP by groEL becomes more complex. Three distinct kinetic phases can be discerned. Initially, both heptameric toroids turn over once at the same rate that they do in the absence of groES. This leads to the formation of an asymmetric binary complex, groEL14-MgADP7-groES7, in which 7 mol of ADP is trapped in a form that does not readily exchange with free ADP. In the second phase, the remaining seven sites (containing readily exchangeable ADP) turn over, or have the potential to turn over, at the same rate as they do in the absence of groES, so that the overall rate of hydrolysis is maximally 50%. These remaining sites of the asymmetric binary complex do not hydrolyze all of the available ATP. Instead, the second phase of hydrolysis gives way to a third, completely inhibited state, the onset of which is dependent upon the relative affinities of the remaining sites for MgATP and MgADP.(ABSTRACT TRUNCATED AT 250 WORDS)

Chaperonins and protein folding: unity and disunity of mechanisms.

Chaperonin-facilitated folding of proteins involves two partial reactions. The first partial reaction, the formation of stable binary complexes between chaperonin-60 and non-native states of the target protein, is common to the chaperonin-facilitated folding of all target proteins investigated to date. The structural basis for this interaction is not presently understood. The second partial reaction, the dissociation of the target protein in a form committed to the native state, appears to proceed by a variety of mechanisms, dependent upon the nature of the target protein in question. Those target proteins (e.g. rubisco, rhodanese, citrate synthase) which require the presence of chaperonin-10, also appear to require the hydrolysis of ATP to bring about the dissociation of the target protein from chaperonin-60. With one exception (pre-beta-lactamase) those target proteins which do not require the presence of chaperonin-10 to be released from chaperonin-60, also do not require the hydrolysis of ATP, since non-hydrolysable analogues of ATP support the release of the target protein in a state committed to the native state. The question of whether or not chaperonin-facilitated folding constitutes a catalysed event is addressed.

Identification, characterization, and DNA sequence of a functional "double" groES-like chaperonin from chloroplasts of higher plants.

Chloroplasts of higher plants contain a nuclear-encoded protein that is a functional homolog of the Escherichia coli chaperonin 10 (cpn10; also known as groES). In pea (Pisum sativum), chloroplast cpn10 was identified by its ability to (i) assist bacterial chaperonin 60 (cpn60; also known as groEL) in the ATP-dependent refolding of chemically denatured ribulose-1,5-bisphosphate carboxylase and (ii) form a stable complex with bacterial cpn60 in the presence of Mg.ATP. The subunit size of the pea protein is approximately 24 kDa--about twice the size of bacterial cpn10. A cDNA encoding a spinach (Spinacea oleracea) chloroplast cpn10 was isolated, sequenced, and expressed in vitro. The spinach protein is synthesized as a higher molecular mass precursor and has a typical chloroplast transit peptide. Surprisingly, however, attached to the transit peptide is a single protein, comprised of two distinct cpn10 molecules in tandem. Moreover, both halves of this "double" cpn10 are highly conserved at a number of residues that are present in all cpn10s that have been examined. Upon import into chloroplasts the spinach cpn10 precursor is processed to its mature form of approximately 24 kDa. N-terminal amino acid sequence analysis reveals that the mature pea and spinach cpn10 are identical at 13 of 21 residues.

What is the role of the transit peptide in thylakoid integration of the light-harvesting chlorophyll a/b protein?

Whereas it is widely accepted that the transit peptide of the precursor for the light-harvesting chlorophyll a/b protein (preLHCP) is responsible for targeting this polypeptide to chloroplasts, the signals which govern its intraorganellar targeting appears to be transit peptide-mediated for plastocyanin (Smeekins, S., Bauerle, C., Hageman, J., Keegstra, K., and Weisbeek, P. (1986) Cell 46, 365-375) and several other nuclear-encoded, thylakoid luminal proteins. To determine whether a similar mechanism operates for LHCP (an integral thylakoid protein), we have used oligonucleotide-directed mutagenesis to delete the proposed transit sequence from a petunia precursor of this polypeptide. Intact preLHCP and the deletion mutant product have been expressed in vitro, and their abilities to integrate into purified thylakoids have been compared. We have found that both polypeptides insert into thylakoids correctly, provided the latter are supplemented with a membrane-free stromal extract and Mg.ATP. Our results clearly demonstrate that whereas the transit peptide is required for transport into chloroplasts, thylakoid integration of preLHCP is determined by mature portions of the polypeptide. In addition, we note that transit peptide removal has little effect on the apparent solubility of the in vitro translation products.

An imported thylakoid protein accumulates in the stroma when insertion into thylakoids is inhibited.

The light-harvesting chlorophyll a/b protein (LHCP) is synthesized in the cytosol as a precursor (pLHCP) that is imported into chloroplasts and assembled into thylakoid membranes. Under appropriate conditions, either pLHCP or LHCP will integrate into isolated thylakoids. We have identified two situations that inhibit integration in this assay. Ionophores and uncouplers inhibited integration up to 70%. Carboxyl-terminal truncations of pLHCP also interfered with integration. A 22-residue truncation reduced integration to about 25% of control, whereas a 93 residue truncation completely abolished it. When pLHCP was imported into chloroplasts in the presence of uncouplers or when truncated forms of pLHCP were used, significant amounts of the imported proteins failed to insert into thylakoids and instead accumulated in the aqueous stroma. Accumulation of stromal LHCP occurred at uncoupler concentrations required to dissipate the trans-thylakoid proton electrochemical gradient and was enhanced at reduced levels of ATP. The latter effect may be a secondary consequence of a reduction in ATP-dependent degradation within the stroma. These results indicate that the stroma is an intermediate location in the LHCP assembly pathway and provide the first evidence for a soluble intermediate during biogenesis of a chloroplast membrane protein.