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1.
J Clin Pharmacol ; 53(12): 1334-40, 2013 Dec.
Article in English | MEDLINE | ID: mdl-24030903

ABSTRACT

Global introspection is considered an unreliable method for attribution of causality of serious adverse events (SAEs), yet remains widely used for cancer drug clinical trials. Here, we compare structured case abstraction (SCA) to the routine method for detecting, evaluating, and reporting ADEs during cancer drug clinical trials to an Institutional Review Board (IRB). We obtained all SAE reports (2001-2008) received by one IRB for six clinical trials involving bevacizumab or oxaliplatin for treatment of gastrointestinal cancers. We compared the routine IRB SAE method to SCA for adverse event detection and causality attribution. Of 205 adverse events, 182 events (75%) were not reported; of these, 6 (20%) of 30 SAEs requiring an IRB report were unreported. For the 10 item Naranjo score, the amount of information useful for causality attribution was higher with SCA than the routine method (6.0 vs. 2.4 items, P < .0001). One-fifth of SAEs requiring an IRB report were unreported to the IRB via the routine method. SCA provided more useful information as to whether an SAE was caused by a cancer drug exposure. Our results suggest that SCA may improve SAE detection and the accuracy of attribution of causality during cancer drug clinical trials.


Subject(s)
Adverse Drug Reaction Reporting Systems , Antibodies, Monoclonal, Humanized/adverse effects , Antineoplastic Agents/adverse effects , Colorectal Neoplasms/drug therapy , Organoplatinum Compounds/adverse effects , Pancreatic Neoplasms/drug therapy , Bevacizumab , Clinical Trials as Topic , Ethics Committees, Research , Humans , Oxaliplatin , United States
2.
Clin Pharmacol Ther ; 88(2): 231-6, 2010 Aug.
Article in English | MEDLINE | ID: mdl-20571489

ABSTRACT

The validity of information regarding drug toxicity in humans depends on the quality of the methods and instruments used to assess adverse drug events (ADEs). This study evaluates the quality of instruments used to assess and report ADEs to institutional review boards (IRBs) at US cancer centers. Forms from all 49 National Cancer Institute (NCI)-designated centers were assessed for utility in abstracting event type, severity, and causality; patient demographics; safety monitoring; and consequent changes in the conduct of the relevant study. Of the 55 items considered essential for ADE reporting, one item (event description) was present on all the forms. Seventy-eight percent of the instruments prompted for global introspection of the investigator, a method known to be unreliable. Of the 34 items that our panel of experts considered essential for event description, the median number of items present was four (domain = 1-11). The use of a validated tool to describe and assess event type, severity, and causality may lead to more timely, accurate identification of safety signals in cancer treatment.


Subject(s)
Adverse Drug Reaction Reporting Systems/statistics & numerical data , Antineoplastic Agents/adverse effects , Causality , Clinical Trials as Topic , Data Interpretation, Statistical , Humans , National Cancer Institute (U.S.) , Patients , Research Design , Socioeconomic Factors , United States
3.
Genetika ; 41(4): 455-65, 2005 Apr.
Article in Russian | MEDLINE | ID: mdl-15909907

ABSTRACT

Bacteriophages of the family Myoviridae represent one of the most widespread domains of the biosphere substantially affecting the ecological balance of microorganisms. Interestingly, sequence analysis of genomic DNAs of large bacteriophages revealed many genes coding for proteins with unknown functions. A new approach is proposed to improve the functional identification of genes. This approach is based on comparing the genome sequence for phylogenetically and morphologically related phages showing no considerable homology at the level of genomic DNA. It is assumed that gene functions essential for the development of phages of a given family are conserved and that the corresponding genes code for similar orthologous proteins even when lacking sequence homology. The genome was sequenced and compared for two Pseudomonas aeruginosa giant bacteriophages, phiKZ and EL, which belong to a group of (phiKZ-related phages. A substantial difference in genome organization was observed, suggesting specific features of phage evolution. In addition, the problem of the minimal genome of the superfamily is discussed on the basis of the difference in size and structure between the phiKZ and EL genomes.


Subject(s)
Evolution, Molecular , Genome, Viral , Pseudomonas Phages/genetics , Viral Proteins/genetics , Base Sequence , Molecular Sequence Data , Pseudomonas aeruginosa , Sequence Analysis, DNA
4.
J Bacteriol ; 183(19): 5747-50, 2001 Oct.
Article in English | MEDLINE | ID: mdl-11544239

ABSTRACT

The DnaK chaperone of Escherichia coli is known to interact with the J domains of DnaJ, CbpA, and DjlA. By constructing multiple mutants, we found that the djlA gene was essential for bacterial growth above 37 degrees C in the absence of dnaJ. This essentiality depended upon the J domain of DjlA but not upon the normal membrane location of DjlA.


Subject(s)
Escherichia coli Proteins , Escherichia coli/growth & development , Heat-Shock Proteins/genetics , Heat-Shock Proteins/metabolism , DNA-Binding Proteins/genetics , DNA-Binding Proteins/metabolism , Escherichia coli/genetics , Escherichia coli/metabolism , HSP40 Heat-Shock Proteins , Hot Temperature , Mutation
5.
Genetics ; 158(2): 507-17, 2001 Jun.
Article in English | MEDLINE | ID: mdl-11404317

ABSTRACT

Genetic experiments have shown that the GroEL/GroES chaperone machine of Escherichia coli is absolutely essential, not only for bacterial growth but also for the propagation of many bacteriophages including lambda. The virulent bacteriophages T4 and RB49 are independent of the host GroES function, because they encode their own cochaperone proteins, Gp31 and CocO, respectively. E. coli groEL44 mutant bacteria do not form colonies above 42 degrees nor do they propagate bacteriophages lambda, T4, or RB49. We found that the vast majority (40/46) of spontaneous groEL44 temperature-resistant colonies at 43 degrees were due to the presence of an intragenic suppressor mutation. These suppressors define 21 different amino acid substitutions in GroEL, each affecting one of 13 different amino acid residues. All of these amino acid residues are located at or near the hinge, which regulates the large en bloc movements of the GroEL apical domain. All of these intragenic suppressors support bacteriophages lambda, T4, and RB49 growth to various extents in the presence of the groEL44 allele. Since it is known that the GroEL44 mutant protein does not interact effectively with Gp31, the suppressor mutations should enhance cochaperone binding. Analogous intragenic suppressor studies were conducted with the groEL673 temperature-sensitive allele.


Subject(s)
Chaperonin 60/chemistry , Chaperonin 60/genetics , Escherichia coli/genetics , Escherichia coli/metabolism , Alleles , Codon , Models, Molecular , Molecular Chaperones , Mutation , Plasmids/metabolism , Protein Conformation , Protein Structure, Tertiary , Sequence Analysis, DNA , Suppression, Genetic , Temperature
6.
J Biol Chem ; 276(22): 18843-8, 2001 Jun 01.
Article in English | MEDLINE | ID: mdl-11278349

ABSTRACT

The ClpX heat shock protein of Escherichia coli is a member of the universally conserved Hsp100 family of proteins, and possesses a putative zinc finger motif of the C(4) type. The ClpX is an ATPase which functions both as a substrate specificity component of the ClpXP protease and as a molecular chaperone. Using an improved purification procedure we show that the ClpX protein is a metalloprotein complexed with Zn(II) cations. Contrary to other Hsp100 family members, ClpXZn(II) exists in an oligomeric form even in the absence of ATP. We show that the single ATP-binding site of ClpX is required for a variety of tasks, namely, the stabilization of the ClpXZn(II) oligomeric structure, binding to ClpP, and the ClpXP-dependent proteolysis of the lambdaO replication protein. Release of Zn(II) from ClpX protein affects the ability of ClpX to bind ATP. ClpX, free of Zn(II), cannot oligomerize, bind to ClpP, or participate in ClpXP-dependent proteolysis. We also show that ClpXDeltaCys, a mutant protein whose four cysteine residues at the putative zinc finger motif have been replaced by serine, behaves in similar fashion as wild type ClpX protein whose Zn(II) has been released either by denaturation and renaturation, or chemically by p-hydroxymercuriphenylsulfonic acid.


Subject(s)
Adenosine Triphosphatases/metabolism , Zinc/metabolism , ATPases Associated with Diverse Cellular Activities , Adenosine Triphosphate/metabolism , Binding Sites , Cations , Chromatography , Circular Dichroism , Cloning, Molecular , Cysteine/chemistry , Dose-Response Relationship, Drug , Endopeptidase Clp , Enzyme-Linked Immunosorbent Assay , Escherichia coli/metabolism , Escherichia coli Proteins , Hydrolysis , Kinetics , Molecular Chaperones , Mutagenesis, Site-Directed , Plasmids/metabolism , Protein Binding , Protein Denaturation , Serine/chemistry , Spectrophotometry , Spectrophotometry, Infrared , Structure-Activity Relationship , Zinc Fingers
7.
J Biol Chem ; 276(7): 4981-7, 2001 Feb 16.
Article in English | MEDLINE | ID: mdl-11050098

ABSTRACT

Chaperonins are universally conserved proteins that nonspecifically facilitate the folding of a wide spectrum of proteins. While bacterial GroEL is functionally promiscuous with various co-chaperonin partners, its human homologue, Hsp60 functions specifically with its co-chaperonin partner, Hsp10, and not with other co-chaperonins, such as the bacterial GroES or bacteriophage T4-encoded Gp31. Co-chaperonin interaction with chaperonin is mediated by the co-chaperonin mobile loop that folds into a beta-hairpin conformation upon binding to the chaperonin. A delicate balance of flexibility and conformational preferences of the mobile loop determines co-chaperonin affinity for chaperonin. Here, we show that the ability of Hsp10, but not GroES, to interact specifically with Hsp60 lies within the mobile loop sequence. Using mutational analysis, we show that three substitutions in the GroES mobile loop are necessary and sufficient to acquire Hsp10-like specificity. Two of these substitutions are predicted to preorganize the beta-hairpin turn and one to increase the hydrophobicity of the GroEL-binding site. Together, they result in a GroES that binds chaperonins with higher affinity. It seems likely that the single ring mitochondrial Hsp60 exhibits intrinsically lower affinity for the co-chaperonin that can be compensated for by a higher affinity mobile loop.


Subject(s)
Chaperonin 10/chemistry , Chaperonin 10/metabolism , Chaperonin 60/metabolism , Amino Acid Sequence , Amino Acid Substitution , Bacteriophage lambda/growth & development , Chaperonin 10/genetics , Chaperonin 60/genetics , Citrate (si)-Synthase/metabolism , Escherichia coli/growth & development , Escherichia coli/metabolism , Humans , Molecular Sequence Data , Protein Folding , Protein Structure, Tertiary , Sequence Homology, Amino Acid
8.
J Biol Chem ; 276(12): 8720-6, 2001 Mar 23.
Article in English | MEDLINE | ID: mdl-11104767

ABSTRACT

Bacteriophage T4-encoded Gp31 is a functional ortholog of the Escherichia coli GroES cochaperonin protein. Both of these proteins form transient, productive complexes with the GroEL chaperonin, required for protein folding and other related functions in the cell. However, Gp31 is specifically required, in conjunction with GroEL, for the correct folding of Gp23, the major capsid protein of T4. To better understand the interaction between GroEL and its cochaperonin cognates, we determined whether the so-called "pseudo-T-even bacteriophages" are dependent on host GroEL function and whether they also encode their own cochaperonin. Here, we report the isolation of an allele-specific mutation of bacteriophage RB49, called epsilon22, which permits growth on the E. coli groEL44 mutant but not on the isogenic wild type host. RB49 epsilon22 was used in marker rescue experiments to identify the corresponding wild type gene, which we have named cocO (cochaperonin cognate). CocO has extremely limited identity to GroES but is 34% identical and 55% similar at the protein sequence level to T4 Gp31, sharing all of the structural features of Gp31 that distinguish it from GroES. CocO can substitute for Gp31 in T4 growth and also suppresses the temperature-sensitive phenotype of the E. coli groES42 mutant. CocO's predicted mobile loop is one residue longer than that of Gp31, with the epsilon22 mutation resulting in a Q36R substitution in this extra residue. Both the CocO wild type and epsilon22 proteins have been purified and shown in vitro to assist GroEL in the refolding of denatured citrate synthase.


Subject(s)
Bacteriophages/genetics , Chaperonin 10/metabolism , Chaperonin 60/metabolism , Chaperonins/metabolism , Viral Proteins/metabolism , Amino Acid Sequence , Base Sequence , Chaperonin 10/chemistry , Chaperonin 60/chemistry , Chaperonins/chemistry , Chaperonins/genetics , Chaperonins/isolation & purification , DNA Primers , Molecular Sequence Data , Mutation , Sequence Homology, Amino Acid , Viral Proteins/chemistry , Viral Proteins/genetics , Viral Proteins/isolation & purification
9.
J Biol Chem ; 276(11): 7906-12, 2001 Mar 16.
Article in English | MEDLINE | ID: mdl-11106641

ABSTRACT

DjlA is a 30-kDa type III membrane protein of Escherichia coli with the majority, including an extreme C-terminal putative J-domain, oriented toward the cytoplasm. No other regions of sequence similarity aside from the J-domain exist between DjlA and the known DnaK (Hsp70) co-chaperones DnaJ (Hsp40) and CbpA. In this study, we explored whether and to what extent DjlA possesses DnaK co-chaperone activity and under what conditions a DjlA-DnaK interaction could be important to the cell. We found that the DjlA J-domain can substitute fully for the J-domain of DnaJ using various in vivo functional complementation assays. In addition, the purified cytoplasmic fragment of DjlA was shown to be capable of stimulating DnaK ATPase in a manner indistinguishable from DnaJ, and, furthermore, DjlA could act as a DnaK co-chaperone in the reactivation of chemically denatured luciferase in vitro. DjlA expression in the cell is tightly controlled, and even its mild overexpression leads to induction of mucoid capsule. Previous analysis showed that DjlA-mediated induction of the wca capsule operon required the RcsC/RcsB two-component signaling system and that wca induction by DjlA was lost when cells contained mutations in either the dnaK or grpE gene. We now show using allele-specific genetic suppression analysis that DjlA must interact with DnaK for DjlA-mediated stimulation of capsule synthesis. Collectively, these results demonstrate that DjlA is a co-chaperone for DnaK and that this chaperone-co-chaperone pair is implicated directly, or indirectly, in the regulation of colanic acid capsule.


Subject(s)
Escherichia coli Proteins , HSP70 Heat-Shock Proteins/physiology , Heat-Shock Proteins/physiology , Molecular Chaperones/physiology , Polysaccharides/biosynthesis , Amino Acid Sequence , HSP40 Heat-Shock Proteins , HSP70 Heat-Shock Proteins/chemistry , Heat-Shock Proteins/chemistry , Molecular Sequence Data , Transcriptional Activation
10.
Annu Rev Genet ; 34: 439-456, 2000.
Article in English | MEDLINE | ID: mdl-11092834

ABSTRACT

Early genetic studies identified the Escherichia coli groES and groEL genes because mutations in them blocked the growth of bacteriophages lambda and T4. Subsequent genetic and biochemical analyses have shown that GroES and GroEL constitute a chaperonin machine, absolutely essential for E. coli growth, because it is needed for the correct folding of many of its proteins. In spite of very little sequence identity to GroES, the bacteriophage T4-encoded Gp31 protein and the bacteriophage RB49-encoded CocO protein are bona fide GroEL cochaperonins, even capable of substituting for GroES in E. coli growth. A major functional distinction is that only Gp31 and CocO can assist GroEL in the correct folding of Gp23, the major bacteriophage capsid protein. Conserved structural features between CocO and Gp31, which are absent from GroES, highlight their potential importance in specific cochaperonin function.


Subject(s)
Bacteriophage T4/genetics , Chaperonins/genetics , Bacterial Proteins/genetics , Escherichia coli/genetics , Escherichia coli Proteins , Heat-Shock Proteins/genetics , Viral Proteins/genetics
11.
Acta Neurochir (Wien) ; 141(11): 1233-5, 1999.
Article in English | MEDLINE | ID: mdl-10592126

ABSTRACT

We present a 32-year-old woman with intracranial haemorrhage due to rupture of a saccular aneurysm arising from the trunk of an accessory middle cerebral artery. This is the first report of an aneurysm arising distally to the anomalous vessel's origin from the A1 segment of the anterior cerebral artery.


Subject(s)
Aneurysm, Ruptured/surgery , Intracranial Aneurysm/surgery , Middle Cerebral Artery/abnormalities , Adult , Aneurysm, Ruptured/diagnostic imaging , Angiography, Digital Subtraction , Cerebral Angiography , Female , Humans , Intracranial Aneurysm/diagnostic imaging , Middle Cerebral Artery/diagnostic imaging , Subarachnoid Hemorrhage/diagnostic imaging , Subarachnoid Hemorrhage/surgery
12.
Genetics ; 152(4): 1449-57, 1999 Aug.
Article in English | MEDLINE | ID: mdl-10430575

ABSTRACT

Previous genetic and biochemical analyses have established that the bacteriophage T4-encoded Gp31 is a cochaperonin that interacts with Escherichia coli's GroEL to ensure the timely and accurate folding of Gp23, the bacteriophage-encoded major capsid protein. The heptameric Gp31 cochaperonin, like the E. coli GroES cochaperonin, interacts with GroEL primarily through its unstructured mobile loop segment. Upon binding to GroEL, the mobile loop adopts a structured, beta-hairpin turn. In this article, we present extensive genetic data that strongly substantiate and extend these biochemical studies. These studies begin with the isolation of mutations in gene 31 based on the ability to plaque on groEL44 mutant bacteria, whose mutant product interacts weakly with Gp31. Our genetic system is unique because it also allows for the direct selection of revertants of such gene 31 mutations, based on their ability to plaque on groEL515 mutant bacteria. Interestingly, all of these revertants are pseudorevertants because the original 31 mutation is maintained. In addition, we show that the classical tsA70 mutation in gene 31 changes a conserved hydrophobic residue in the mobile loop to a hydrophilic one. Pseudorevertants of tsA70, which enable growth at the restrictive temperatures, acquire the same mutation previously shown to allow plaque formation on groEL44 mutant bacteria. Our genetic analyses highlight the crucial importance of all three highly conserved hydrophobic residues of the mobile loop of Gp31 in the productive interaction with GroEL.


Subject(s)
Bacteriophage T4/genetics , Capsid Proteins , Chaperonins/genetics , Viral Proteins/genetics , Amino Acid Sequence , Capsid/biosynthesis , Capsid/chemistry , Chaperonin 60/genetics , Chaperonin 60/physiology , Chaperonins/chemistry , Chaperonins/physiology , Models, Molecular , Molecular Sequence Data , Mutagenesis, Site-Directed , Phenotype , Polymerase Chain Reaction , Protein Conformation , Protein Folding , Sequence Alignment , Sequence Homology, Amino Acid , Viral Proteins/chemistry , Viral Proteins/physiology
13.
Cell ; 97(6): 755-65, 1999 Jun 11.
Article in English | MEDLINE | ID: mdl-10380927

ABSTRACT

A role for DnaK, the major E. coli Hsp70, in chaperoning de novo protein folding has remained elusive. Here we show that under nonstress conditions DnaK transiently associates with a wide variety of nascent and newly synthesized polypeptides, with a preference for chains larger than 30 kDa. Deletion of the nonessential gene encoding trigger factor, a ribosome-associated chaperone, results in a doubling of the fraction of nascent polypeptides interacting with DnaK. Combined deletion of the trigger factor and DnaK genes is lethal under normal growth conditions. These findings indicate important, partially overlapping functions of DnaK and trigger factor in de novo protein folding and explain why the loss of either chaperone can be tolerated by E. coli.


Subject(s)
Bacterial Proteins/metabolism , Cyclophilins , Escherichia coli Proteins , HSP70 Heat-Shock Proteins/metabolism , Peptides/metabolism , Peptidylprolyl Isomerase/metabolism , Bacterial Proteins/genetics , Chaperonin 60/metabolism , Escherichia coli/genetics , Escherichia coli/metabolism , Genes, Bacterial , HSP70 Heat-Shock Proteins/genetics , Peptidylprolyl Isomerase/genetics , Protein Folding , Ribosomes/metabolism
14.
J Biol Chem ; 274(20): 13999-4005, 1999 May 14.
Article in English | MEDLINE | ID: mdl-10318812

ABSTRACT

It has previously been established that sequences at the C termini of polypeptide substrates are critical for efficient hydrolysis by the ClpP/ClpX ATP-dependent protease. We report for the bacteriophage lambda O replication protein, however, that N-terminal sequences play the most critical role in facilitating proteolysis by ClpP/ClpX. The N-terminal portion of lambda O is degraded at a rate comparable with that of wild type O protein, whereas the C-terminal domain of O is hydrolyzed at least 10-fold more slowly. Consistent with these results, deletion of the first 18 amino acids of lambda O blocks degradation of the N-terminal domain, whereas proteolysis of the O C-terminal domain is only slightly diminished as a result of deletion of the C-terminal 15 amino acids. We demonstrate that ClpX retains its capacity to bind to the N-terminal domain following removal of the first 18 amino acids of O. However, ClpX cannot efficiently promote the ATP-dependent binding of this truncated O polypeptide to ClpP, the catalytic subunit of the ClpP/ClpX protease. Based on our results with lambda O protein, we suggest that two distinct structural elements may be required in substrate polypeptides to enable efficient hydrolysis by the ClpP/ClpX protease: (i) a ClpX-binding site, which may be located remotely from substrate termini, and (ii) a proper N- or C-terminal sequence, whose exposure on the substrate surface may be induced by the binding of ClpX.


Subject(s)
Adenosine Triphosphatases/metabolism , Bacteriophage lambda/physiology , Serine Endopeptidases/metabolism , Viral Proteins/metabolism , Virus Replication , Amino Acid Sequence , Bacteriophage lambda/metabolism , Binding Sites , Endopeptidase Clp , Enzyme-Linked Immunosorbent Assay , Hydrolysis , Kinetics , Molecular Sequence Data , Mutagenesis, Site-Directed , Protein Binding , Viral Proteins/genetics
15.
Mol Microbiol ; 31(1): 157-66, 1999 Jan.
Article in English | MEDLINE | ID: mdl-9987118

ABSTRACT

The Escherichia coli sigma 32 transcriptional regulator has been shown to be degraded both in vivo and in vitro by the FtsH (HflB) protease, a member of the AAA protein family. In our attempts to study this process in detail, we found that two sigma 32 mutants lacking 15-20 C-terminal amino acids had substantially increased half-lives in vivo or in vitro, compared with wild-type sigma 32. A truncated version of sigma 32, sigma 32 C delta, was purified to homogeneity and shown to be resistant to FtsH-dependent degradation in vitro, suggesting that FtsH initiates sigma 32 degradation from its extreme C-terminal region. Purified sigma 32 C delta interacted with the DnaK and DnaJ chaperone proteins in a fashion similar to that of wild-type sigma 32. However, in contrast to wild-type sigma 32, sigma 32 C delta was largely deficient in its in vivo and in vitro interaction with core RNA polymerase. As a consequence, the truncated sigma 32 protein was completely non-functional in vivo, even when overproduced. Furthermore, it is shown that wild-type sigma 32 is protected from degradation by FtsH when complexed to the RNA polymerase core, but sensitive to proteolysis when in complex with the DnaK chaperone machine. Our results are in agreement with the proposal that the capacity of the DnaK chaperone machine to autoregulate its own synthesis negatively is simply the result of its ability to sequester sigma 32 from RNA polymerase, thus making it accessible to degradation by the FtsH protease.


Subject(s)
Bacterial Proteins/metabolism , Escherichia coli Proteins , Escherichia coli/metabolism , HSP70 Heat-Shock Proteins/physiology , Heat-Shock Proteins/metabolism , Membrane Proteins/metabolism , Molecular Chaperones/physiology , Sigma Factor/metabolism , Transcription Factors/metabolism , ATP-Dependent Proteases , DNA-Directed RNA Polymerases/metabolism , Escherichia coli/genetics , HSP40 Heat-Shock Proteins , HSP70 Heat-Shock Proteins/metabolism , Heat-Shock Proteins/genetics , Molecular Chaperones/metabolism , Sigma Factor/genetics , Transcription Factors/genetics
16.
J Biol Chem ; 274(1): 52-8, 1999 Jan 01.
Article in English | MEDLINE | ID: mdl-9867810

ABSTRACT

Previous work has shown that the GroEL-GroES interaction is primarily mediated by the GroES mobile loop. In bacteriophage T4 infection, GroES is substituted by the gene 31-encoded cochaperonin, Gp31. Using a genetic selection scheme, we have identified a new set of mutations in gene 31 that affect interaction with GroEL; all mutations result in changes in the mobile loop of Gp31. Biochemical analyses reveal that the mobile loop mutations alter the affinity between Gp31 and GroEL, most likely by modulating the stability of the GroEL-bound hairpin conformation of the mobile loop. Surprisingly, mutations in groEL that display allele-specific interactions with mutations in gene 31 alter residues in the GroEL intermediate domain, distantly located from the mobile loop binding site. The observed patterns of genetic and biochemical interaction between GroES or Gp31 and GroEL point to a mechanism of genetic allele specificity based on compensatory changes in affinity of the protein-protein interaction. Mutations studied in this work indirectly alter affinity by modulating a folding transition in the Gp31 mobile loop or by modulating a hinged conformational change in GroEL.


Subject(s)
Alleles , Chaperonin 60/metabolism , Viral Proteins/metabolism , Amino Acid Sequence , Bacteriophage T4/genetics , Chaperonin 60/chemistry , Chaperonins/metabolism , Citrate (si)-Synthase/metabolism , Magnetic Resonance Spectroscopy , Molecular Sequence Data , Mutation , Protein Binding , Protein Conformation , Protein Folding , Spectrometry, Fluorescence , Viral Proteins/chemistry
17.
Proc Natl Acad Sci U S A ; 95(26): 15259-63, 1998 Dec 22.
Article in English | MEDLINE | ID: mdl-9860956

ABSTRACT

Using the bacteriophage lambda DNA replication system, composed entirely of purified proteins, we have tested the accessibility of the short-lived lambda O protein to the ClpP/ClpX protease during the various stages of lambda DNA replication. We find that binding of lambda O protein to its orilambda DNA sequence, leading to the so-called "O-some" formation, largely inhibits its degradation. On the contrary, under conditions permissive for transcription, the lambda O protein bound to the orilambda sequence becomes largely accessible to ClpP/ClpX-mediated proteolysis. However, when the lambda O protein is part of the larger orilambda:O.P.DnaB preprimosomal complex, transcription does not significantly increase ClpP/ClpX-dependent lambda O degradation. These results show that transcription can stimulate proteolysis of a protein that is required for the initiation of DNA replication.


Subject(s)
Adenosine Triphosphatases/metabolism , Bacterial Proteins , Bacteriophage lambda/genetics , Serine Endopeptidases/metabolism , Transcription, Genetic , Viral Proteins/metabolism , Virus Replication , Bacteriophage lambda/physiology , DNA Helicases/metabolism , DNA Replication , DNA, Viral/genetics , DNA, Viral/metabolism , DNA-Directed RNA Polymerases/metabolism , DnaB Helicases , Endopeptidase Clp , Escherichia coli/genetics , Escherichia coli/metabolism , Escherichia coli/virology , Kinetics , Models, Genetic , Replication Origin
18.
Nat Struct Biol ; 5(11): 977-85, 1998 Nov.
Article in English | MEDLINE | ID: mdl-9808043

ABSTRACT

Two models are being considered for the mechanism of chaperonin-assisted protein folding in E. coli: (i) GroEL/GroES act primarily by enclosing substrate polypeptide in a folding cage in which aggregation is prevented during folding. (ii) GroEL mediates the repetitive unfolding of misfolded polypeptides, returning them onto a productive folding track. Both models are not mutually exclusive, but studies with the polypeptide-binding domain of GroEL have suggested that unfolding is the primary mechanism, enclosure being unnecessary. Here we investigate the capacity of the isolated apical polypeptide-binding domain to functionally replace the complete GroEL/GroES system. We show that the apical domain binds aggregation-sensitive polypeptides but cannot significantly assist their refolding in vitro and fails to replace the groEL gene or to complement defects of groEL mutants in vivo. A single-ring version of GroEL cannot substitute for GroEL. These results strongly support the view that sequestration of aggregation-prone intermediates in a folding cage is an important element of the chaperonin mechanism.


Subject(s)
Chaperonin 10/chemistry , Chaperonin 60/chemistry , Protein Folding , Animals , Cattle , Chaperonin 10/physiology , Chaperonin 60/genetics , Chaperonin 60/physiology , Circular Dichroism , Citrate (si)-Synthase/chemistry , Escherichia coli/chemistry , Genetic Complementation Test , Malate Dehydrogenase/chemistry , Models, Molecular , Protein Conformation , Recombinant Fusion Proteins , Sequence Deletion , Tetrahydrofolate Dehydrogenase/chemistry , Thiosulfate Sulfurtransferase/chemistry
19.
Mol Microbiol ; 30(2): 329-40, 1998 Oct.
Article in English | MEDLINE | ID: mdl-9791178

ABSTRACT

DnaJ is a universally conserved heat shock protein involved in protein folding. DnaJ contains four conserved domains. The N-terminal 'J-domain' has been shown to be responsible for the recruitment of its specific DnaK partner protein. The 'Gly/Phe'- and 'Cys-rich' domains have been implicated in stabilizing interactions with DnaK. DnaJ is also able to interact independently with unfolded or native polypeptides. Very little is known regarding such binding/chaperone abilities, but it has been suggested that the least conserved carboxy-terminal domain could contribute to these properties. To gain insight into the biological activity of this fourth domain, we deleted two relatively conserved patches of amino acid residues, a 'G-rich' cluster and a 'G-D-L-Y-V' motif, resulting in the DnaJDelta[230-238] and DnaJDelta[242-246] mutant proteins respectively. Both mutant proteins are partially defective in stimulating the ATPase activity of DnaK and in preventing aggregation of firefly luciferase in vitro. Both mutants have lost the ability to regulate the sigma32-dependent heat shock response, as shown in vivo using a heat shock transcriptional fusion. Furthermore, and unlike wild-type DnaJ, DnaJDelta[242-246] is unable to assist the DnaK-dependent refolding of denatured luciferase. In agreement with these results, we found that DnaJDelta[242-246] is unable to restore either the temperature-sensitive phenotype or the motility defect of a dnaJ null mutation. Substitution of amino acids [242-246] by five alanines leads to similar phenotypic defects, suggesting that altering the 'G-D-L-Y-V' motif leads to partial loss of DnaJ activity. Our data clearly support a role in the intrinsic chaperone/substrate binding ability of the carboxy-terminal domain of DnaJ.


Subject(s)
Escherichia coli Proteins , Escherichia coli/genetics , Heat-Shock Proteins/genetics , Heat-Shock Proteins/metabolism , Mutation , Sigma Factor , Amino Acid Sequence , Bacteriophage lambda/pathogenicity , Cell Division/genetics , Conserved Sequence , Down-Regulation , Escherichia coli/physiology , Escherichia coli/virology , HSP40 Heat-Shock Proteins , HSP70 Heat-Shock Proteins/metabolism , Heat-Shock Response , Luciferases/metabolism , Molecular Sequence Data , Sequence Deletion , Transcription Factors/metabolism
20.
J Biol Chem ; 273(20): 12466-75, 1998 May 15.
Article in English | MEDLINE | ID: mdl-9575204

ABSTRACT

The Escherichia coli msbA gene, first identified as a multicopy suppressor of htrB mutations, has been proposed to transport nascent core-lipid A molecules across the inner membrane (Polissi, A., and Georgopoulos, C. (1996) Mol. Microbiol. 20, 1221-1233). msbA is an essential E. coli gene with high sequence similarity to mammalian Mdr proteins and certain types of bacterial ABC transporters. htrB is required for growth above 32 degreesC and encodes the lauroyltransferase that acts after Kdo addition during lipid A biosynthesis (Clementz, T., Bednarski, J., and Raetz, C. R. H. (1996) J. Biol. Chem. 271, 12095-12102). By using a quantitative new 32Pi labeling technique, we demonstrate that hexa-acylated species of lipid A predominate in the outer membranes of wild type E. coli labeled for several generations at 42 degreesC. In contrast, in htrB mutants shifted to 42 degreesC for 3 h, tetra-acylated lipid A species and glycerophospholipids accumulate in the inner membrane. Extra copies of the cloned msbA gene restore the ability of htrB mutants to grow at 42 degreesC, but they do not increase the extent of lipid A acylation. However, a significant fraction of the tetra-acylated lipid A species that accumulate in htrB mutants are transported to the outer membrane in the presence of extra copies of msbA. E. coli strains in which msbA synthesis is selectively shut off at 42 degreesC accumulate hexa-acylated lipid A and glycerophospholipids in their inner membranes. Our results support the view that MsbA plays a role in lipid A and possibly glycerophospholipid transport. The tetra-acylated lipid A precursors that accumulate in htrB mutants may not be transported as efficiently by MsbA as are penta- or hexa-acylated lipid A species.


Subject(s)
ATP-Binding Cassette Transporters/metabolism , Bacterial Proteins/metabolism , Lipid A/biosynthesis , Phospholipids/biosynthesis , ATP-Binding Cassette Transporters/genetics , Acylation , Bacterial Proteins/genetics , Biological Transport , Cell Membrane/metabolism , Genes, Bacterial , Hot Temperature , Lipid A/metabolism , Membrane Proteins/genetics , Membrane Proteins/metabolism , Phenotype , Phospholipids/metabolism
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