Papain Does Not Cleave Operator-Bound Lambda Repressor: Structural Characterization of the Carboxy Terminal Domain and the Hinge

Abstract

The circular dichroism spectra of three different purified carboxy terminal fragments 93–236, 112–236 and 132–236 of the bacteriophage γ cI repressor have been measured and compared with those of the intact repressor and the amino terminal fragment 1–92. All three carboxy terminal fragments contain mostly β-strands and loops, a minor helix content increasing with the size of the fragment, showing that the 93–131 region previously called a hinge is structured. Fourier transformed infrared spectra also showed that fragment 93–236 contains α-helices, β-sheets and turns but fragment 132–236 contains no detectable α-helix, only β-sheets and turns. Papain is known to cleave the γ repressor, but it is shown here that it cannot cleave the operator-bound repressor dimer. For the 132–236 fragment, both the wt and the SN228 mutant previously shown to be dimerization defective in the intact, gave similar dimerization properties as investigated by HPLC at 2 to 100 µM protein concentration, with a KD of 13.2 µM and 19.1 µM respectively. The papain cleavage for wt and SN228 proceed at equal rates for the first cleavage at 92–93; however, the subsequent cleavages are faster for SN228. The three Cys residues in the 132–236 fragment were found to be unreactive upon incubation with DTNB, indicating the thiol sulfur atoms are buried in the repressor carboxy terminal domain. Denaturation of the 132–236 fragment studied by tryptophan fluorescence shows two transitions centered at 1.5 M and 4.5 M of urea.     

A comparative three-dimensional model of the carboxy-terminal domain of the lambda repressor and its use to build intact repressor tetramer models bound to adjacent operator sites

A model for residues 93-236 of the lambda repressor (1gfx) was predicted, based on the UmuD(') crystal structure, as part of four intact repressor molecules bound to two adjacent operator sites. The structure of region 136-230 in 1gfx was found to be nearly identical to the independently determined crystal structure of the 132-236 fragment, 1f39, released later by the PDB. Later, two more tetrameric models of the lambda repressor tetramer bound to two adjacent operator sites were constructed by us; in one of these, 1j5g, the N-domain and C-domain coordinates and hence monomer-monomer and dimer-dimer interactions are almost the same as in 1gfx, but the structure of the linker region is partly based on the linker region of the LexA dimer in 1jhe; in the other, 1lwq, the crystalline tetramer for region 140-236 has been coopted from the crystal structure deposited in 1kca, the operator DNA and N-domain coordinates of which are same as those in 1gfx and 1j5g, but the linker region is partly based on the LexA dimer structures 1jhe and 1jhh. Monomer-monomer interactions at the same operator site are stabilized by exposed hydrophobic side chains in beta-strands while cooperative interactions are mostly confined to beta(6) and some adjacent residues in both 1gfx and 1j5g. Mutational data, existence of a twofold axis relating two C-domains within a dimer, and minimization of DNA distortion between adjacent operator sites allow us to roughly position the C-domain with respect to the N-domain for both 1gfx and 1j5g. The study correlates these models with functional, biochemical, biophysical, and immunological data on the repressor in the literature. The oligomerization mode observed in the crystal structure of 132-236 may not exist in the intact repressor bound to the operator since it is shown to contradict several published biochemical data on the intact repressor.     

Digestion of the lambda cI repressor with various serine proteases and correlation with its three dimensional structure

Partial proteolysis of the lambda cI repressor has been carried out systematically with trypsin, chymotrypsin, elastase, endoproteinase Glu-C, kallikrein, and thrombin. The cleavage sites have been determined by (i) comparison of fragments produced and observed in SDS-polyacrylamide gel with known fragments and plots of distance migrated versus log (molecular weight of fragment), (ii) partial Edman sequencing of the stable C-terminal fragments to identify cleavage points, and (iii) electrospray mass spectrometry of fragments produced. Most cleavage points are found to occur in the region 86-137, saving some in the N-terminal domain observed for trypsin and Glu-C. Region 86-137 can be further subdivided into three regions 86-91, 114-121, and 128-137 prone to cleavage, with intermediate regions resistant to cleavage to all six proteases. These resistant regions show that much of the region 93-131 previously called a 'linker' is actually part of the C-domain as first proposed in all models from our laboratory. Region 92-114 includes the cleavage site Ala-Gly, which must be buried in the intact repressor. The observed cleavage points in region 114-137 can be used to judge the best among three previously proposed models since they differ from each other in the structure of region 93-131. Model 1j5g is adjudged to be better than model 1lwq (which is based on 1kca, a crystal structure) as susceptible residues are more exposed in the former and lack of cleavages at six sites is better explained. Likewise, the models 1j5g and 1lwq are compared with a recent crystal structure of fragment 101-229 in 2ho0 and another low resolution crystal structure in 3bdn.     

Dimerization of the operator binding domain of phage lambda repressor

Dimerization of lambda repressor is required for its binding to operator DNA. As part of a continuing study of the structural basis of the coupling between dimer formation and operator binding, we have undertaken 1H NMR and gel filtration studies of the dimerization of the N-terminal domain of lambda repressor. Five protein fragments have been studied: three are wild-type fragments of different length (1-102, 1-92, and 1-90), and two are fragments bearing single amino acid substitutions in residues involved in the dimer interface (1-102, Tyr-88----Cys; 1-92, Ile-84----Ser). The tertiary structure of each species is essentially the same, as monitored by the 1H NMR resonances of internal aromatic groups. However, significant differences are observed in their dimerization properties. 1H NMR resonances of aromatic residues that are involved in the dimer contact allow the monomer-dimer equilibrium to be monitored in solution. The structure of the wild-type dimer contact appears to be similar to that deduced from X-ray crystallography and involves the hydrophobic packing of symmetry-related helices (helix 5) from each monomer. Removal of two contact residues, Val-91 and Ser-92, by limited proteolysis disrupts this interaction and also prevents crystallization. The Ile-84----Ser substitution also disrupts this interaction, which accounts for the severely reduced operator affinity of this mutant protein.     

Carboxy terminal fragment of human alpha-1-antitrypsin from hydroxylamine cleavage: homology with antithrombin III.

Human α-1-antitrypsin (AT) was reacted with hydroxylamine at pH 9.0 giving cleavage at an Asn-Gly bond. A fragment of molecular weight 8,500 was released and this was isolated and sequenced. The fragment had the same carboxy terminal amino acid sequence as intact AT. The 80 residue polypeptide contained the Z variant mutation site and a portion of sequence identical to that found by others for the reactive site, inferring the presence in AT of two active sites. This sequence combined with prviously published work gives a continuous sequence of 152 amino acid residues from the carboxy terminal end of the AT molecule, including the mutation site of the S variant. The sequence shows strong homology with human antithrombin III.     

Structure of a hyper-cleavable monomeric fragment of phage lambda repressor containing the cleavage site region

The key event in the switch from lysogenic to lytic growth of phage lambda is the self-cleavage of lambda repressor, which is induced by the formation of a RecA-ssDNA-ATP filament at a site of DNA damage. Lambda repressor cleaves itself at the peptide bond between Ala111 and Gly112, but only when bound as a monomer to the RecA-ssDNA-ATP filament. Here we have designed a hyper-cleavable fragment of lambda repressor containing the hinge and C-terminal domain (residues 101-229), in which the monomer-monomer interface is disrupted by two point mutations and a deletion of seven residues at the C terminus. This fragment crystallizes as a monomer and its structure has been determined to 1.8 A resolution. The hinge region, which bears the cleavage site, is folded over the active site of the C-terminal oligomerization domain (CTD) but with the cleavage site flipped out and exposed to solvent. Thus, the structure represents a non-cleavable conformation of the repressor, but one that is poised for cleavage after modest rearrangements that are presumably stabilized by binding to RecA. The structure provides a unique snapshot of lambda repressor in a conformation that sheds light on how its self-cleavage is tempered in the absence of RecA, as well as a framework for interpreting previous genetic and biochemical data concerning the RecA-mediated cleavage reaction.     

Characterization of glyoxalase I purified from pig erythrocytes by affinity chromatography

The linear order of nine fragments generated by the action of endonuclease AvaI on the DNA of bacteriophage lambda was determined from the altered fragmentation patterns of bacteriophages containing known deletions and of hybrids of bacteriophages lambda and phi80. Digestion of 5'-terminally 32P-labelled bacteriophage-lambda DNA was used to identify the terminal fragments. Measurement of relative fragment lengths permitted rough mapping of the endonuclease-AvaI cleavage sites relative to the ends of the bacteriophage-lambda chromosome. The fragment order was confirmed and the map refined by analysis of the fragmentation of derivative phages containing single cleavage sites for endonuclease EcoRI.     

Lambda repressor inactivation: properties of purified ind- proteins in the autodigestion and RecA-mediated cleavage reactions

Under physiological conditions, lambda repressor can be inactivated in vivo or in vitro by RecA-mediated cleavage of the polypeptide chain. The repressor protein is thought to cleave itself, with RecA acting to stimulate autodigestion. ind- repressor mutants are resistant to RecA-mediated inactivation in vivo. In this paper, we report the purification of 15 ind- repressor proteins and the behaviors of these proteins in the RecA-mediated and autodigestion cleavage reactions. None of these proteins undergoes substantial RecA-dependent cleavage. However, eight mutant proteins autodigest at the same rate as wild-type repressor, six mutants do not autodigest or autodigest slower, and one mutant autodigests faster than wild-type. We discuss these results with respect to repressor structure and RecA-binding, and suggest possible roles for the RecA protein in the cleavage reaction.     

Primary structure of the lambda repressor

The complete covalent structure of the bacteriophage lambda repressor has been determined by sequential Edman degradation, gas chromatographic-mass spectrometric peptide sequencing, and DNA sequencing of the repressor gene cI. The repressor is a single-chain, acidic protein containing 236 amino acids. The amino terminal 40 residues are highly polar and basic. Lysines and arginines in the sequence tend to be clustered.     

Temperature-inducible amber suppressor: construction of plasmids containing the Escherichia coli serU- (supD-) gene under control of the bacteriophage lambda pL promoter.

An Escherichia coli DNA fragment containing the structural gene serU132 for the nonsense suppressor tRNASer2am was identified and purified by being cloned into a plasmid vector. Information obtained from DNA sequence analysis was used to select a serU132 fragment for insertion downstream from the bacteriophage lambda pL promoter in two pBR322-lambda derivatives. In nonsense mutant strains bearing the resulting serU132 hybrid plasmids, the presence of the lambda cI857 repressor gene carried on the same plasmid or in a prophage genome permits thermal regulation of suppressor synthesis.     

Localization of protein-protein interactions between subunits of phytochrome.

We have used a novel assay based on protein fusions with lambda repressor to identify two small regions within phytochrome's carboxy-terminal domain that are capable of mediating dimerization. Using an in vivo assay, fusions between the DNA binding, amino-terminal domain of lambda repressor and fragments from oat PhyA phytochrome have been assayed for increased repressor activity, an indicator of dimerization. In this assay system, regions of oat phytochrome between amino acids V623-S673 and N1049-Q1129 have been shown to increase repressor activity. These short spans are highly conserved between proteins belonging to the phytochrome PhyA family. Embedded within these sequences are four segments that could potentially form amphipathic alpha helices. Two of the segments are well conserved between PhyA phytochrome and phytochromes encoded by the phyB and phyC genes, suggesting that heterodimers might form by way of subunit interaction at these sites.     

A linkage map of three anonymous human DNA fragments and SOD-1 on chromosome 21

Using DNA polymorphisms adjacent to single-copy genomic fragments derived from human chromosome 21, we initiated the construction of a linkage map of human chromosome 21. The probes were genomic EcoRI fragments pW228C, pW236B, pW231C and a portion of the superoxide dismutase gene (SOD-1). DNA polymorphisms adjacent to each of the probes were used as markers in informative families to perform classical linkage analysis. No crossing-over was observed between the polymorphic sites adjacent to genomic fragments pW228C and pW236B in 31 chances for recombination. Therefore, these fragments are closely linked to one another (theta = 0.00, lod score = 6.91, 95% confidence limits = 0-10 cM) and can be treated as one 'locus' with four high-frequency markers. There is a high degree of non-random association of markers adjacent to each of these two probes which suggests that they are physically very close to one another in the genome. The pW228C - pW236B 'locus' was also linked to the SOD-1 gene (theta = 0.07, lod score = 4.33, 95% confidence limits = 1-20 cM). On the other hand, no evidence for linkage was found between the pW228C-pW236B 'locus' and the genomic fragment pW231C (theta = 0.5, lod score = 0.00). Based on the fact that pW231C maps to 21q22.3 and SOD-1 to 21q22.1, we suggest that the pW228C-pW236B 'locus' lies in the proximal long arm of chromosome 21. These data provide the outline of a linkage map for the long arm of chromosome 21, and indicate that the pW228C-pW236B 'locus' is a useful marker system to differentiate various chromosome 21s in a population.     

The adenomatous polyposis coli protein and retinoblastoma protein are cleaved early in apoptosis and are potential substrates for caspases

Apoptosis in human monocytic THP.1 tumour cells, induced by diverse stimuli, was accompanied by proteolytic cleavage of the adenomatous polyposis coli gene product (APC) and by sequential cleavage of the retinoblastoma susceptibility gene product (Rb). Cleavage of poly(ADP-ribose) polymerase (PARP), APC and the initial cleavage of Rb at the carboxy terminal region all occurred at a similar time, early in the apoptotic process. Subsequently, Rb underwent a secondary cleavage to 43 kDa and 30 kDa protein fragments. Two caspase inhibitors, benzyloxycarbonyl-Val-Ala-Asp (OMe) fluoromethyl ketone (Z-VAD.FMK) and acetyl-Tyr-Val-Ala-Asp chloromethyl ketone (YVAD.CMK), had markedly different effects on the induction of apoptosis. Z-VAD.FMK inhibited the primary and secondary cleavage of Rb, cleavage of APC and PARP, and apoptosis assessed by flow cytometry. In marked contrast, YVAD.CMK inhibited cleavage of APC and the secondary cleavage of Rb to the 43 kDa and 30 kDa protein fragments but did not inhibit the primary carboxy terminal cleavage of Rb, PARP proteolysis or apoptosis assessed by flow cytometry. These results suggest that different caspases are responsible for the cleavage of different substrates at different stages during the apoptotic process and that a caspase may either cleave APC directly or may be involved in the pathway leading to APC proteolysis. This is the first report suggesting that a cytoplasmic tumour suppressor gene (APC) may be cleaved by a caspase during apoptosis.     

Proteolysis of factor Va by factor Xa and activated protein C

Bovine Factor Va, produced by selective proteolytic cleavage of Factor V by thrombin, consists of a heavy chain (D chain) of Mr = 94,000 and a light chain (E chain) of Mr = 74,000. These peptides are noncovalently associated in the presence of divalent metal ion(s). Each chain is susceptible to proteolysis by activated protein C and by Factor Xa. Sodium dodecyl sulfate electrophoretic analysis indicates that cleavage of the E chain by either activated protein C or Factor Xa yields two major fragments: Mr = 30,000 and Mr = 48,000. Amino acid sequence analysis indicates that the Mr = 30,000 fragments have identical NH2-terminal sequences and that this sequence corresponds to that of intact E chain. The Mr = 48,000 fragments also have identical NH2-terminal sequences, indicating that activated protein C and Factor Xa cleave the E chain at the same position. Sodium dodecyl sulfate electrophoretic analysis indicates that activated protein C cleavage of the D chain yields two products: Mr = 70,000 and Mr = 24,000. Amino acid sequence analysis indicates that the Mr = 70,000 fragment has the same NH2-terminal sequence as intact D chain, whereas the Mr = 24,000 fragment does not. Factor Xa cleavage of the D chain also yields two products: Mr = 56,000 and Mr = 45,000. The Mr = 56,000 fragment corresponds to the NH2-terminal end of the D chain and Factor V. Functional studies have shown that both chains of Factor Va may be entirely cleaved to products by Factor Xa without loss of activity, whereas activated protein C cleavage results in loss of activity. Since activated protein C and Factor Xa cleave the E chain at the same position, the cleavage of the D chain by activated protein C is responsible for the inactivation of Factor Va.     

Regulation in repressor inactivation by RecA protein

Treatments that damage DNA or inhibit DNA synthesis in E. coli induce the expression of a set of functions called SOS functions that are involved in DNA repair, mutagenesis, arrest of cell division and prophage induction. Induction of SOS functions is triggered by inactivation of the LexA repressor or a phage repressor. Inactivation of these repressors results from their cleavage by the E. coli RecA protein in the presence of single-stranded DNA and a nucleoside triphosphate.We found that these cleavage reactions are controlled by two mechanisms in vitro: one is through the structural change of the RecA protein in the ternary complex, RecA-ssDNA-ATP-γ-S. The active ternary complex is formed by binding of ATP-γ-S to a complex of RecA protein and ssDNA. On the other hand, when the RecA protein binds to ATP-γ-S prior to its binding to ssDNA, the resulting complex has no or only very weak cleavage activity toward the repressor. This structural change is negatively controlled by its C-terminal part. The loss of the 25 amino acid residues from the C-terminal leads the RecA protein to stable binding to dsDNA as well as ssDNA, and the protein takes the activated form for the repressor cleavage constitutively. The other mechanism is through the structural change of the repressor. The cleavage reaction of a ∅80cI repressor is greatly stimulated by the presence of d(G-G), and d(G-G) stimulates the cleavage by binding to the C-terminal half of the ∅80cI repressor. Moreover, the C-terminal fragment of the cleaved products of the 80cI repressor was able to cleave a ∅80cI-λ chimeric repressor. These results strongly suggested that th active site of the repressor cleavage was located in the C-terminal domain of the repressor and that the C-terminal fragment produced by the cleavage could cleave the repressor.     

Construction of a hybrid col E1 plasmid carrying the gene for bacteriophage lambda repressor.

A biologically active hybrid DNA molecule was constructed from plasmid Col E1 and the Eco R1 fragment of lambda DNA containing the gene for lambda repressor. The presence of this gene in the hybrid molecule was demonstrated genetically. The hybrid plasmid contains two closely located targets for restriction endonuclease Hind 111 in the integrated fragment. Thus, the plasmid may be used as a vector not only for Eco R1 fragments but also for Hind 111 fragments.     

A deletion analysis of hybrid phage carrying the US region of Herpes simplex virus type 1 (Patton). I. Isolation of deletion derivatives and identification of chi-likes sequences

The EcoRI-H fragment (15.4 kb) of Herpes simplex virus type 1 (HSV-1) has been cloned in lambda gtWES in both orientations. This fragment contains the entire US region and has about 900 bp of terminal redundant sequences derived from the internal and terminal repeats of the S region. 56 independent plaque-forming deletion derivatives of the lambda gt/WES::EcoRI-H hybrid phage were isolated using either EDTA resistance or ability to grow on Escherichia coli(P2) lysogens as selective methods. The endpoints of these deletions were located using nine restriction enzymes that cleave within the EcoRI-H fragment. All of the deletions have at least one endpoint within the cloned fragment. Several unusual features of the lambda hybrids, including heterogeneity of a particular region in the HSV-1 EcoRI-H fragment and the presence of chi-like sequences in the US region of HSV-1, are discussed.     

Purification and characterization of the repressor for the sn-glycerol 3-phosphate regulon of Escherichia coli K12

The glpR gene encoding the repressor for the sn-glycerol 3-phosphate regulon of Escherichia coli was cloned downstream from the strong pL promoter of bacteriophage lambda. This allowed overproduction of the repressor upon thermal induction of a cryptic lambda lysogen harboring the cI857 gene. The repressor was purified 40-fold to homogeneity from an induced strain. The purification scheme utilized polyethyleneimine and ammonium sulfate fractionation, followed by phosphocellulose and DEAE-Sephadex chromatography. Purification was monitored by measuring the binding of radiolabeled inducer (sn-glycerol 3-phosphate) to the repressor. The purified repressor migrated as a single band exhibiting a subunit molecular weight of 30,000 assessed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The molecular weight of the repressor under nondenaturing conditions was 100,000-130,000 suggesting the repressor is a tetramer under native conditions. Interaction of the repressor with sn-glycerol 3-phosphate was studied using flow dialysis. Scatchard analysis of the data indicated four binding sites/repressor tetramer and a dissociation constant of 31 microM. Interaction of the repressor with DNA was studied using band-shift electrophoresis. The repressor specifically bound DNA fragments containing the control regions for the glpD, glpK, and glpT-A genes. Binding of DNA by the repressor was diminished in the presence of sn-glycerol 3-phosphate.     

Clathrin light chain: importance of the conserved carboxy terminal domain to function in living cells

Clathrin triskelions assemble into coats capable of packaging membrane and receptors for transport to intracellular destinations. A triskelion is formed from three heavy chains bound to three light chains. All clathrin light chains (clc) contain an acidic amino terminal domain, a central coiled segment, and a carboxy terminal domain conserved in amino acid sequence. To assess their functional contribution in vivo, we expressed tagged segments of the Dictyostelium clcA in clc-minus Dictyostelium (clc null) cells. We examined the ability of these clcA fragments to rescue clathrin phenotypic deficiencies, to cluster into punctae on membranes, and to bind to the heavy chain. When expressed in clc null cells, a clcA fragment containing the amino terminal domain and the central coiled domain bound heavy chain but was dispensable for clathrin function. Instead, the carboxy terminal domain of clcA was a critical determinant for association with punctae, for clathrin function and for robust binding to the heavy chain. A 70 amino acid carboxy terminal fragment was necessary and sufficient for full function, and for localization into punctae on intracellular membranes. A shorter 49 amino acid carboxy terminal fragment could distribute into punctae but failed to rescue developmental deficiencies. These results reveal the importance of the carboxy terminal domain of the light chain in vivo.     

Purification of limited tryptic fragments of Ca2+,Mg2+-adenosine triphosphatase of the sarcoplasmic reticulum and identification of conformation-sensitive cleavage sites

Sarcoplasmic reticulum membranes were treated with trypsin, and samples enriched with A1a, A1b, and C fragments (Saito, K. et al. (1984) J. Biochem. 95, 1297-1304), respectively, were prepared. A1b and C fragments were purified to apparent homogeneity, and an approximately equimolar mixture of A1(Met1-Arg198), A1a, and A1b fragments free from other contaminants was also obtained through gel permeation and hydroxylapatite chromatography in the presence of sodium dodecyl sulfate. N- and C-terminal amino acid sequence analyses of these peptides were carried out in order to identify the tryptic cleavage sites responsible for the formation of these fragments. Both A1a and A1b fragments had the same C-terminal sequence as A1 fragment. Single cleavage of A1 at T3a (Lys218-Ala219) yielded A1a, while a cleavage between either Lys234-Ile235 or Arg236-Asp237 (collectively designated as T3b) resulted in A1b fragment. Thus, A1a and A1b fragments differed from A1 fragment only by their loss of short stretches corresponding to the N-terminal region of the latter. On the other hand, C fragment represented the C-terminal half of B fragment (Ala506-Gly994). It had the same C-terminal sequence as B fragment and was produced by cleavage at T4 (Lys728-Thr729). Cleavages at T3a and T3b profoundly affected the catalytic properties of SR-ATPase (Imamura, Y. and Kawakita, M. (1986) J. Biochem. 100, 133-141), and it was suggested that the segment of the ATPase molecule including the region between Ala199 and Arg236 is important in mediating the coupling between ATP splitting and Ca2+-transport.