Autodigestion and RecA-dependent cleavage of Ind- mutant LexA proteins

The LexA repressor of Escherichia coli undergoes a specific cleavage reaction in vivo, an event that leads to derepression of the SOS regulon and requires an activated form of RecA protein. In vitro, cleavage requires RecA at neutral pH; at alkaline pH, a spontaneous cleavage reaction termed autodigestion takes place. Both autodigestion and RecA-mediated cleavage cut the same bond, and are observed for the same set of substrates, suggesting that RecA acts indirectly to stimulate LexA self-cleavage at neutral pH, perhaps binding to LexA and acting as an allosteric effector. We previously isolated a set of lexA(Ind-) mutants that are deficient in in vivo RecA-mediated cleavage but retain significant repressor function. Here, we describe the in vitro cleavage of purified mutant proteins. All of those tested were deficient in both cleavage reactions. Although most of them were equally deficient in both reactions, some were more deficient in one reaction than the other. Several mutant proteins appeared to have defects in binding to RecA. Autodigestion of all but one of the poorly cleavable mutant proteins reached a maximum rate at pH around 10, as does wild-type LexA. The exception was KR156, which changed Lys156, a residue previously implicated in the mechanism of cleavage, to Arg, another basic residue: for this protein, the rate of autodigestion increased with pH at values above 11. RecA-mediated cleavage of KR156 was 1% the wild-type rate at pH 7, but increased with increasing pH to a plateau at pH 9.5, where the rate was 40% the wild-type rate. In contrast, an essentially constant rate was observed for wild-type LexA over the pH range 6 to 11. We suggest, first, that deprotonation of Arg156 and, by inference, Lys156 in the wild-type protein, is required for both autodigestion and RecA-mediated cleavage: and second, that RecA acts to reduce the pKa of Lys156, allowing efficient cleavage of wild-type repressor under physiological conditions.     

Genetic analysis of the LexA repressor: Isolation and characterization of LexA(Def) mutant proteins

Summary We report the isolation of LexA mutant proteins with impaired repressor function. These mutant proteins were obtained by transforming a LexA-deficient recA-lacZ indicator strain with a randomly mutagenized plasmid harbouring the lexA gene and subsequent selection on MacConkey-lactose indicator plates. A total of 24 different lexA(Def) missense mutations were identified. All except three mutant proteins are produced in near-normal amounts suggesting that they are fairly resistant to intracellular proteases. All lexA(Def) missense mutations are situated within the first 67 amino acids of the amino-terminal DNA binding domain. The properties of an intragenic deletion mutant suggest that the part of the amino-terminal domain important for DNA recognition or domain folding should extent at least to amino acids 69 or 70. A recent 2D-NMR study (Lamerichs et al. 1989) has identified three a helices in the DNA binding domain of LexA. The relative orientation of two of them (helices 2 and 3) is reminiscent of, but not identical to, the canonical helix-turn-helix motif suggesting nevertheless that helix 3 might be involved in DNA recognition. The distribution of the lexA(Def) missense mutations along the first 67 amino-terminal amino acids indeed shows some clustering within helix 3, since 8 out of the 24 different missense mutations are found in this helix. However one mutation in front of helix 1 and five mutations between amino acids 61 and 67 suggest that elements other than helices 2 and 3 may be important for DNA binding.     

RecA protein and SOS. Correlation of mutagenesis phenotype with binding of mutant RecA proteins to duplex DNA and LexA cleavage

The RecA protein of Escherichia coli is required for SOS-induced mutagenesis in addition to its recombinational and regulatory roles. We have suggested that RecA might participate directly in targeted mutagenesis by binding preferentially to the site of the DNA damage (e.g. pyrimidine dimer) because of its partially unwound nature; DNA polymerase III will then encounter RecA-coated DNA at the lesion and might replicate across the damaged site more often but with reduced fidelity. In support of this proposal, we have found that the phenotype of wild-type and mutant RecA for mutagenesis correlates with capacity to bind to double-stranded DNA. Wild-type RecA binds more efficiently to ultraviolet (u.v.)-irradiated, duplex DNA than to non-irradiated DNA. The RecA441 (Tif) protein that is constitutive for mutagenesis binds extremely well to double-stranded DNA with no lesions, whereas the RecA430 protein that is defective in mutagenesis binds poorly even to u.v.-irradiated DNA. The RecA phenotype also correlates with capacity to use duplex DNA as a cofactor for cleavage of the LexA repressor protein for SOS-controlled operons. Wild-type RecA provides efficient cleavage of LexA only with u.v.-irradiated duplex DNA; RecA441 cleaves well with non-irradiated DNA; RecA430 gives very poor cleavage even with u.v.-irradiated DNA. We conclude that the interaction of RecA with damaged double-stranded DNA is likely to be a critical component of SOS mutagenesis and to define a pathway for the LexA cleavage reaction as well.     

Mechanism of specific LexA cleavage: autodigestion and the role of RecA coprotease

Specific LexA cleavage can occur under two different conditions: RecA-mediated cleavage requires an activated form of RecA, while an intramolecular self-cleavage termed autodigestion proceeds spontaneously at high pH and does not involve RecA. The two cleavage reactions are closely related. We postulate that RecA stimulates autodigestion rather than acting as a typical protease, and it is proposed to term this activity 'RecA coprotease' to emphasize this indirect role. The mechanism of autodigestion is similar to that of a serine protease, and RecA appears to act by reducing the pKa of a critical lysine residue LexA. A new class of mutants, termed lexA (IndS), is described; these mutations increase the rate of LexA cleavage.     

SOS induction in Escherichia coli by single-stranded DNA of mutant filamentous phage: monitoring by cleavage of LexA repressor.

Infection of Escherichia coli in the presence of chloramphenicol with mutant filamentous phage that are defective in the initiation of minus-strand DNA synthesis induces the SOS response as monitored by cellular LexA levels. This observation demonstrates that single-stranded DNA serves as a primary signal for SOS induction in vivo.     

Isolation and characterization of LexA mutant repressors with enhanced DNA binding affinity.

The LexA repressor from Escherichia coli is a sequence-specific DNA binding protein that shows no pronounced sequence homology with any of the known structural motifs involved in DNA binding. Since little is known about how this protein interacts with DNA, we have selected and characterized a great number of intragenic, second-site mutations which restored at least partially the activity of LexA mutant repressors deficient in DNA binding. In 47 cases, the suppressor effect of these mutations was due to an Ind- phenotype leading presumably to a stabilization of the mutant protein. With one exception, these second-site mutations are all found in a small cluster (amino acid residues 80 to 85) including the LexA cleavage site between amino acid residues 84 and 85 and include both already known Ind- mutations as well as new variants like GN80, GS80, VL82 and AV84. The remaining 26 independently isolated second-site suppressor mutations all mapped within the amino-terminal DNA binding domain of LexA, at positions 22 (situated in the turn between helix 1 and helix 2) and positions 57, 59, 62, 71 and 73. These latter amino acid residues are all found beyond helix 3, in a region where we have previously identified a cluster of LexA (Def) mutant repressors. In several cases the parental LexA (Def) mutation has been removed by subcloning or site-directed mutagenesis. With one exception, these LexA variants show tighter in vivo repression than the LexA wild-type repressor. The most strongly improved variant (LexA EK71, i.e. Glu71----Lys) that shows an about threefold increased repression rate in vivo, was purified and its binding to a short consensus operator DNA fragment studied using a modified nitrocellulose filter binding assay. As expected from the in vivo data, LexA EK71 interacts more tightly with both operator and (more dramatically) with non-operator DNA. A determination of the equilibrium association constants of LexA EK71 and LexA wild-type as a function of monovalent salt concentration suggests that LexA EK71 might form an additional ionic interaction with operator DNA as compared to the LexA wild-type repressor. A comparison of the binding of LexA to a non-operator DNA fragment further shows that LexA interacts with the consensus operator very selectively with a specificity factor of Ks/Kns of 1.4 x 10(6) under near-physiological salt conditions.     

In vitro cleavage of double- and single-stranded DNA by plasmid RSF1010-encoded mobilization proteins.

We have used purified RSF1010 mobilization proteins to reproduce in vitro a strand-specific nicking at the plasmid origin of transfer, oriT. In the presence of Mg2+, the proteins MobA (78-kDa form of RSF1010 DNA primase), MobB, and MobC and supercoiled or linear duplex oriT DNA form large amounts of a cleavage complex, which is characterized by its sensitivity to protein-denaturant treatment. Upon addition of SDS to such a complex, a single strand break is generated in the DNA, and MobA is found linked to the 5' nick terminus, presumably covalently. The double-strand nicking activity of MobA requires, in addition to Mg2+, the presence of MobC and is stimulated by the presence of MobB. The nick site has been shown by DNA sequencing to lie at the position cleaved in vivo during transfer, between nucleotides 3138/3139 in the r strand of RSF1010. We have found that MobA will also cleave DNA at sites other than oriT if the DNA is present in single-stranded form. Breakage in this case occurs in the absence of denaturing conditions, and after prolonged incubation, reclosure can be demonstrated.     

P. mirabilis RecA protein catalyses cleavage of E. coli LexA protein and the lambda repressor in vitro

Summary The cloned recA ⁺ gene of Proteus mirabilis substitutes for a defective RecA protein in Escherichia coli recA ^– mutants, and restores recombination, repair and phage induction functions to near normal levels. In a previous report, we described the purification and charactrisation of the recombination activities of the P. mirabilis RecA protein (West et al. 1983b). In this paper, we show that the purified protein catalyses the cleavage of both the Escherichia coli LexA protein and the bacteriophage lambda repressor in vitro. These results provide a direct biochemical basis for the interspecies complementation observed in vivo and suggest that P. mirabilis has an SOS regulatory network similar to that of E. coli.     

Activation of recA protein. The open helix model for LexA cleavage.

RecA protein is induced by the binding of DNA and ATP to become active in the hydrolysis of ATP and the cleavage of repressors. These reactions appear to depend on the structural state of the protein polymerized along the DNA, i.e. a helical coat of six RecA per turn of 95 to 100 A pitch. In support of this model of the active conformation, it was shown that high concentrations of salt also induce this helical polymerized state as well as the enzymatic activities. Here, we describe that, in vitro and with the non-hydrolyzable analogue ATP gamma S, RNA and heparin can also induce both the structural transition and the enzymatic activation of RecA to LexA cleavage in accordance with the model. RNA and heparin do not support the reaction in the presence of ATP, and they do not induce the hydrolysis of ATP either, suggesting that, in contrast to ATP gamma S, the nucleotide is not bound stably enough, and that the combined affinities of polynucleotide and ATP actually modulate the discrimination of RecA for the various possible inducers in vivo.     

Proteolytic cleavage of beta-catenin by caspases: an in vitro analysis.

Cleavage of structural proteins by caspases has been associated with the severe morphological changes occurring during the apoptotic process. One of the proteins regulating the connection of the actin filament with cadherins in a cell-cell adhesion complex is beta-catenin. During apoptosis, both an N-terminal and a small C-terminal part are removed from beta-catenin. Removal of the N-terminal part may result in a disconnection of the actin filament from a cadherin cell-cell adhesion complex. We demonstrate that caspase-8, -3 and -6 directly proteolyse beta-catenin in vitro. However, the beta-catenin cleavage products generated by caspase-8 were different from those generated by caspase-3 or caspase-6. Caspase-1, -2, -4/11 and -7 did not or only very inefficiently cleave beta-catenin. These data suggest that activation of procaspase-3, -6 or -8 by different stimuli in the cell might result in a differential proteolysis of beta-catenin.     

In vitro selection of RNAs with increased tertiary structure stability.

An in vitro selection system was devised to select RNAs based on their tertiary structural stability, independent of RNA activity. Selection studies were conducted on the P4-P6 domain from the Tetrahymena thermophila group I intron, an autonomous self-folding unit that contains several important tertiary folding motifs including the tetraloop receptor and the A-rich bulge. Partially randomized P4-P6 molecules were selected based on their ability to fold into compact structures using native gel electrophoresis in the presence of decreasing concentrations of MgCl2. After 10 rounds of the selection process, a number of sequence alterations were identified that stabilized the P4-P6 RNA. One of these, a single base deletion of C209 within the P4 helix, significantly stabilized the P4-P6 molecule and would not have been identified by an activity-based selection because of its essential role for ribozyme function. Additionally, the sequence analysis provided evidence that stabilization of secondary structure may contribute to overall tertiary stability for RNAs. This system for probing RNA structure irrespective of RNA activity allows analysis of RNA structure/function relationships by identifying nucleotides or motifs important for folding and then comparing them with RNA sequences required for function.     

In vitro selection of DNAs with an increased propensity to form small circles

A protocol was devised to select for DNA molecules that efficiently form circles from a library of 126 base pair DNAs containing 90 randomized base pairs. After six rounds of selection, individual molecules from the library showed 20‐ to 100‐fold greater j‐factors compared with the starting library, validating the selection protocol. High‐throughput sequencing revealed a sinusoidal pattern of enrichment and de‐enrichment of A/T dinucleotides in the random region with a 10.4 base pair period associated with the helicity of DNA. A similar, but more moderate pattern of C/G dinucleotides was offset by precisely half a helical turn. While C/G dinucleotide enrichments were evenly distributed, A/T dinucleotide enrichments displayed a preference to cluster in individual DNA molecules. The most highly enriched 10 base pair sequences in the random region contained adjacent blocks of A/T and C/G trinucleotides present in some, but not all, rapidly cyclizing molecules. The phased dinucleotide enrichments closely match those present in accurately mapped yeast nucleosomes, confirming the importance of DNA bending in nucleosome formation. However, at certain sites the nucleosomal DNAs show dinucleotide enrichments that differ substantially from the cyclization data. These discrepancies can often be correlated with sequence specific contacts that form between histones and DNA. © 2015 Wiley Periodicals, Inc. Biopolymers 103: 303–320, 2015.