Production and characterization of monoclonal antibodies to the N-terminal domain of lambda repressor

Monoclonal antibodies reactive with distinct regions of the N-terminal domain of the lambda repressor protein have been isolated. By comparing the affinities of these antibodies for mutant repressors with increased and decreased thermal stabilities, each of the antibodies can be shown to bind to epitopes accessible in the native conformation of the N-terminal domain. Experiments probing antibody binding to protein fragments, mutant variants, and peptides have also been used to define likely regions of contact between the antibodies and the N-terminal domain.     

Identification of C-terminal extensions that protect proteins from intracellular proteolysis

Revertants of defective mutants in the Arc repressor of bacteriophage P22 were isolated. Five of the six reverting mutations were frameshifts near the end of the coding sequence which resulted in proteins with C-terminal extensions. Each of the reverting mutations prolong the half-lives in vivo of the proteins in which they reside, yet they do not alter the thermodynamic stability, structure, oligomeric form, or DNA-binding properties of these proteins. Fusion of one of these tails to the C-terminal end of a mutant form of the N-terminal domain of lambda repressor also prevented proteolysis of this protein. These C-terminal sequences may prevent degradation by blocking the recognition of unstable proteins by the proteolytic machinery in the cell.     

Thermodynamic analysis of the structural stability of phage 434 Cro protein

Thermodynamic parameters describing the phage 434 Cro protein have been determined by calorimetry and, independently, by far-UV circular dichroism (CD) measurements of isothermal urea denaturations and thermal denaturations at fixed urea concentrations. These equilibrium unfolding transitions are adequately described by the two-state model. The far-UV CD denaturation data yield average temperature-independent values of 0.99 +/- 0.10 kcal mol(-)(1) M(-)(1) for m and 0.98 +/- 0.05 kcal mol(-)(1) K(-)(1) for DeltaC(p)()(,U), the heat capacity change accompanying unfolding. Calorimetric data yield a temperature-independent DeltaC(p)()(,U) of 0.95 +/- 0.30 kcal mol(-)(1) K(-)(1) or a temperature-dependent value of 1.00 +/- 0.10 kcal mol(-)(1) K(-)(1) at 25 degrees C. DeltaC(p)()(,U) and m determined for 434 Cro are in accord with values predicted using known empirical correlations with structure. The free energy of unfolding is pH-dependent, and the protein is completely unfolded at pH 2.0 and 25 degrees C as judged by calorimetry or CD. The stability of 434 Cro is lower than those observed for the structurally similar N-terminal domain of the repressor of phage 434 (R1-69) or of phage lambda (lambda(6)(-)(85)), but is close to the value reported for the putative monomeric lambda Cro. Since a protein's structural stability is important in determining its intracellular stability and turnover, the stability of Cro relative to the repressor could be a key component of the regulatory circuit controlling the levels and, consequently, the functions of the two proteins in vivo.     

Crystallography and mutagenesis point to an essential role for the N-terminus of human mitochondrial ClpP

We have determined a 2.1 A crystal structure for human mitochondrial ClpP (hClpP), the proteolytic component of the ATP-dependent ClpXP protease. HClpP has a structure similar to that of the bacterial enzyme, with the proteolytic active sites sequestered within an aqueous chamber formed by face-to-face assembly of the two heptameric rings. The hydrophobic N-terminal peptides of the subunits are bound within the narrow (12 A) axial channel, positioned to interact with unfolded substrates translocated there by the associated ClpX chaperone. Mutation or deletion of these residues causes a drastic decrease in ClpX-mediated protein and peptide degradation. Residues 8-16 form a mobile loop that extends above the ring surface and is also required for activity. The 28 amino acid C-terminal domain, a unique feature of mammalian ClpP proteins, lies on the periphery of the ring, with its proximal portion forming a loop that extends out from the ring surface. Residues at the start of the C-terminal domain impinge on subunit interfaces within the ring and affect heptamer assembly and stability. We propose that the N-terminal peptide of ClpP is a structural component of the substrate translocation channel and may play an important functional role as well.     

A thermodynamic study of the 434-repressor N-terminal domain and of its covalently linked dimers.

The isolated N-terminal 1-69 domain of the 434-phage repressor, R69, and its covalently linked (head-to-tail and tail-to-tail) dimers have been studied by differential scanning microcalorimetry (DSC) and CD. At neutral solvent conditions the R69 domain maintains its native structure, both in isolated form and within the dimers. The stability of the domain depends highly upon pH within the acidic range, thus at pH 2 and low ionic strength R69 is already partially unfolded at room temperature. The thermodynamic parameters of unfolding calculated from the DSC data are typical for small globular proteins. At neutral pH and moderate ionic strength, the domains of the dimers behave as two independent units with unfolding parameters similar to those of the isolated domain, which means that linking two R69 domains, either by a long peptide linker or by a designed C-terminal disulfide bridge, does not induce any cooperation between them.     

Critical and functional regulation of CHOP (C/EBP homologous protein) through the N-terminal portion

C/EBP homologous protein (CHOP) is an endoplasmic reticulum stress-inducible protein that plays a critical role in the regulation of programmed cell death; however, the regulation of its function has not been well characterized. We have previously demonstrated that CHOP is regulated by the ubiquitin-proteasome system. In this study, during the process of clarifying the mechanism of the degradation of CHOP, we identified a novel regulation domain of CHOP in its N-terminal portion that is involved in various regulations and functions. The CHOP N-terminal domain is necessary not only for protein degradation but also for its transactivity and interaction with p300. In addition, trichostatin A, a histone deacetylase inhibitor, repressed the degradation of CHOP protein via the N-terminal domain. TRB3, a mammalian tribbles homolog that functions as a repressor of CHOP, also interacted with CHOP via the N-terminal portion and significantly blocked the association of p300 with CHOP. These results suggest that the N-terminal portion of CHOP plays a crucial role in its functional regulation and enable us to identify a novel function of TRB3 as an intracellular antagonist of the p300-binding domain of CHOP.     

Quaternary structure and function in phage lambda repressor: 1H-NMR studies of genetically altered proteins

The quaternary structure and dynamics of phage lambda repressor are investigated in solution by 1H-NMR methods. lambda repressor contains two domains separable by proteolysis: an N-terminal domain that mediates sequence-specific DNA-A binding, and a C-terminal domain that contains strong dimer and higher-order contacts. The active species in operator recognition is a dimer. Although the crystal structure of an N-terminal fragment has been determined, the intact protein has not been crystallized, and there is little evidence concerning its structure. 1H-NMR data indicate that the N-terminal domain is only loosely tethered to the C-terminal domain, and that its tertiary structure is unperturbed by proteolysis of the "linker" polypeptide. It is further shown that in the intact repressor structure a quaternary interaction occurs between N-terminal domains. This domain-domain interaction is similar to the dimer contact observed in the crystal structure of the N-terminal fragment and involves the hydrophobic packing of symmetry-related helices (helix 5). In the intact structure this interaction is disrupted by the single amino-acid substitution, Ile84----Ser, which reduces operator affinity at least 100-fold. We conclude that quaternary interactions between N-terminal domains function to appropriately orient the DNA-binding surface with respect to successive major grooves of B-DNA.     

The role of internal packing interactions in determining the structure and stability of a protein

Cassette mutagenesis has been used to investigate how internal packing interactions help to specify a protein's three-dimensional structure and stability. Three interacting residues in the hydrophobic core of the N-terminal domain of lambda repressor were randomized combinatorially. The randomization was restricted to the five amino acids Val, Leu, Ile, Met and Phe, thereby generating a sterically diverse set of core sequences composed solely of hydrophobic residues. We have isolated 78 of the 125 possible sequences generated by this randomization. Approximately 70% of the isolated sequences show some level of biological activity, and thus still carry sufficient information to encode the basic structure of lambda repressor. An assay based on the temperature dependence of activity in vivo has been used to estimate the relative activities and thermal stabilities of the set of mutants. In addition, nine mutants have been purified and their stabilities and DNA binding activities characterized in vitro. Of the 56 active sequences, only two, in addition to the wild-type, maintain the wild-type level of stability and activity. All three of these proteins satisfy stringent requirements for specifically shaped residues at each position. All of the remaining active sequences have reduced stabilities and/or reduced DNA binding affinities. These and previous results suggest that there are two levels of structural information encoded in core residues. At the first level, the basic structural information appears to reside largely in the hydrophobic character of these residues. The majority of sequences that simply maintain hydrophobicity at core positions are able to adopt the overall lambda repressor fold and maintain moderate stability. At the second, more detailed level, specific steric features of these residues and their packing interactions clearly act as important determinants of the protein's precise structure and stability. These results imply that many of the basic structural features of a protein could be predicted from relatively simple, degenerate sequence patterns.     

Mutational analysis of the fine specificity of binding of monoclonal antibody 51F to lambda repressor

Monoclonal antibody 51F recognizes determinants in the helix 4 region of the native form of the N-terminal domain of lambda repressor. A cassette mutagenesis method was used to introduce changes within this region, and antibody-reactive candidates were isolated and sequenced. The resulting data allow the identification of repressor side chains that are critical determinants of antibody binding. Four of these side chains are on the surface of the N-terminal domain and probably contact the antibody directly. These contact positions were then mutagenized individually, and the antibody binding phenotypes of a large number of singly mutant repressors were determined. Taken together, the mutational data allow a functional map of the recognition surface to be constructed and the physical nature of some of the specific interactions that stabilize the antibody-antigen complex to be surmised.     

Domains in lambda Cro repressor. A calorimetric study.

Thermodynamic properties of a mutant lambda Cro repressor with Cys replacing Val55 were studied calorimetrically. Formation of the S-S cross-link between neighboring Cys55 residues in this dimeric molecule leads to stabilization of a structure formed by the C-terminal parts of the two polypeptide chains, which behave as a single cooperative domain upon protein denaturation by heating. This composite domain is very stable at neutral pH and disrupts at 110 degrees C. The S-S-cross-linked tryptic fragment (residues 22-66), which includes this C-terminal domain, has similar stability. The N-terminal parts of the polypeptide chains do not form any stable structure when isolated, but in S-S-cross-linked dimer, they form a single cooperative block which melts in an all-or-none way 9 degrees C higher than the un-cross-linked protein. The observed cooperation of the distant N-terminal parts in dimer raises questions regarding lambda Cro repressor structure in solution.     

An engineered intersubunit disulfide enhances the stability and DNA binding of the N-terminal domain of lambda repressor

Site-directed mutagenesis has been used to replace Tyr-88 at the dimer interface of the N-terminal domain of lambda repressor with cysteine. Computer model building had suggested that this substitution would allow formation of an intersubunit disulfide without disruption of the dimer structure [Pabo, C. O., & Suchanek, E. G. (1986) Biochemistry (preceding paper in this issue)]. We find that the Cys-88 protein forms a disulfide-bonded dimer that is very stable to reduction by dithiothreitol and has increased operator DNA binding activity. The covalent Cys88-Cys88' dimer is also considerably more stable than the wild-type protein to thermal denaturation or urea denaturation. As a control, Tyr-85 was replaced with cysteine. A Cys85-Cys85' disulfide cannot form without disrupting the wild-type structure, and we find that this disulfide bond reduces the DNA binding activity and stability of the N-terminal domain.     

Structural characteristics of an abnormal protein influencing its proteolytic susceptibility.

Structural properties of two similar beta-galactosidase fragments were investigated to determine how they influence the fragments' degradation rate in Escherichia coli. Both fragments resulting from a C-terminal nonsense mutation in lacZ, the CSH11 polypeptide and its 90 kDa degradative intermediate, exist predominantly as monomer subunits instead of in the tetrameric form characteristic of the native enzyme. However, both fragments appear to produce trace amounts of dimers and tetramers. The tetramer and higher molecular weight aggregates formed by the wild-type subunit confer greater protection for the enzyme's N-terminal auto-alpha polypeptide than does the monomer state of the beta-galactosidase fragments. The thermally induced aggregation of both beta-galactosidase fragments correlates with their sensitivity to alpha-chymotrypsin. The relatively low thermal stability of the 90 kDa degradative intermediate appears to be the cause of the significant increase in its proteolytic susceptibility at moderately high temperatures.     

The intracellular domain of Jagged-1 interacts with Notch1 intracellular domain and promotes its degradation through Fbw7 E3 ligase

Notch signaling involves the proteolytic cleavage of the transmembrane Notch receptor after binding to its transmembrane ligands. Jagged-1 also undergoes proteolytic cleavage by gamma-secretase and releases an intracellular fragment. In this study, we have demonstrated that the Jagged-1 intracellular domain (JICD) inhibits Notch1 signaling via a reduction in the protein stability of the Notch1 intracellular domain (Notch1-IC). The formation of the Notch1-IC-RBP-Jk-Mastermind complex is prevented in the presence of JICD, via a physical interaction. Furthermore, JICD accelerates the protein degradation of Notch1-IC via Fbw7-dependent proteasomal pathway. These results indicate that JICD functions as a negative regulator in Notch1 signaling via the promotion of Notch1-IC degradation.     

The extreme C terminus of rat liver carnitine palmitoyltransferase I is not involved in malonyl-CoA sensitivity but in initial protein folding

We previously reported that the N-terminal domain (1-147 residues) of rat liver carnitine palmitoyltransferase I (L-CPTI) was essential for import into the outer mitochondrial membrane and for maintenance of a malonyl-CoA-sensitive conformation. Malonyl-CoA binding experiments using mitochondria of Saccharomyces cerevisiae strains expressing wild-type L-CPTI or previously constructed chimeric CPTs (Cohen, I., Kohl, C., McGarry, J.D., Girard, J., and Prip-Buus, C. (1998) J. Biol. Chem. 273, 29896-29904) indicated that the N-terminal domain was unable, independently of the C-terminal domain, to bind malonyl-CoA with a high affinity, suggesting that the modulation of malonyl-CoA sensitivity occurred through N/C intramolecular interactions. To assess the role of the C terminus in malonyl-CoA sensitivity, a series of C-terminal deletion mutants was generated. The kinetic properties of Delta772-773 and Delta767-773 deletion mutants were similar to those of L-CPTI, indicating that the last two highly conserved Lys residues in all known L-CPTI species were not functionally essential. By contrast, Delta743-773 deletion mutant was totally inactive and unfolded, as shown by its sensitivity to trypsin proteolysis. Because the C terminus of the native folded L-CPTI could be cleaved by trypsin without inducing protein unfolding, we concluded that the last 31 C-terminal residues constitute a secondary structural determinant essential for the initial protein folding of L-CPTI.     

Globular protein stability: aspects of interest in protein turnover

The conformational stability of globular proteins is remarkably low. Under physiological conditions, the native globular conformation is only from 5 to 15 kcal/mole more stable than unfolded conformations. In addition, small changes in the structure of a protein such as removing one terminal residue or cleaving a single peptide bond frequently lead to a substantial decrease in the stability. Likewise, single substitutions in the amino acid sequence can increase or decrease the stability by several kilocalories per mole. The low conformational stability of globular proteins and the sensitivity to small changes in structure suggest a possible role for conformational stability in the intracellular degradation of proteins. Several lines of evidence from in vivo studies of protein degradation are consistent with this idea.     

Multiphasic denaturation of the lambda repressor by urea and its implications for the repressor structure.

Urea denaturation of the lambda repressor has been studied by fluorescence and circular dichroic spectroscopies. Three phases of denaturation could be detected which we have assigned to part of the C-terminal domain, N-terminal domain and subunit dissociation coupled with further denaturation of the rest of the C-terminal domain at increasing urea concentrations. Acrylamide quenching suggests that at least one of the three tryptophan residues of the lambda repressor is in a different environment and its emission maximum is considerably blue-shifted. The transition in low urea concentration (midpoint approximately 2 M) affects the environment of this tryptophan residue, which is located in the C-terminal domain. Removal of the hinge and the N-terminal domain shifts this transition towards even lower urea concentrations, indicating the presence of interaction between hinge on N-terminal and C-terminal domains in the intact repressor.     

Toxin-antitoxin modules as bacterial metabolic stress managers

Bacterial genomes frequently contain operons that encode a toxin and its antidote. These 'toxin-antitoxin (TA) modules' have an important role in bacterial stress physiology and might form the basis of multidrug resistance. The toxins in TA modules act as gyrase poisons or stall the ribosome by mediating the cleavage of mRNA. The antidotes contain an N-terminal DNA-binding region of variable fold and a C-terminal toxin-inhibiting domain. When bound to toxin, the C-terminal domain adopts an extended conformation. In the absence of toxin, by contrast, this domain (and sometimes the whole antidote protein) remains unstructured, allowing its fast degradation by proteolysis. Under silent conditions the antidote inhibits the toxin and the toxin-antidote complex acts as a repressor for the TA operon, whereas under conditions of activation proteolytic degradation of the antidote outpaces its synthesis.     

Comparison of the structures of operator DNA free and in complex with lambda repressor

The structures of operator DNA unbound and in complex with lambda repressor protein are compared. The conformation of the left 10 base pairs of a lambda right regulatory operator DNA sequence has been previously determined in solution using nuclear magnetic resonance techniques and the structure of a homologous left regulatory operator DNA bound to lambda repressor N-terminal domain had been previously solved using X-ray crystallography. The DNA adopts an overall linear B-form DNA both in the absence and presence of lambda repressor. Superimpositioning of the DNA structures reveals small differences between them that are due to the binding of protein and not to the different techniques used for their determination.     

The transmembrane domain of the DnaJ-like protein DjlA is a dimerisation domain

DjlA is a bitopic inner membrane protein, which belongs to the DnaJ co-chaperone family in Escherichia coli. Overproduction of DjlA leads to the synthesis of colanic acid, resulting in mucoidy, via the activation of the two-component regulatory system RcsC/B that controls the cps (capsular polysaccharide) operon. This induction requires both the co-chaperone activity of DjlA, in cooperation with DnaK and GrpE, and its unique transmembrane (TM) domain. Here, we show that the TM segment of DjlA acts as a dimerisation domain: when fused to the N-terminal DNA-binding domain of the lambda cI repressor protein, it can substitute for the native C-terminal dimerisation domain of cI, thus generating an active cI repressor. Replacing the TM domain of DjlA by other TM domains, with or without dimerising capacity, revealed that dimerisation is not sufficient for the induction of cps expression, indicating an additional sequence- or structurally specific role for the TM domain. Finally, the conserved glycines present in the TM domain of DjlA are essential for the induction of mucoidy, but not for dimerisation.