Activity changes in lac repressor with cysteine oxidation.

The effects of prior covalent cysteine modification or nonspecific DNA presence on the reaction of lac repressor protein with N-bromosuccinimide have been investigated. At low excesses, N-bromosuccinimide oxidation causes loss of operator DNA binding activity with simultaneous retention of inducer and nonspecific DNA binding activities. Cysteine and methionine are oxidized under the conditions utilized. Covalent modification of the cysteines of repressor prior to reaction decreased the observed loss of operator DNA binding capacity; the presence of nonspecific DNA partially prevented oxidation of the cysteines by N-bromosuccinimide, and concurrent protection of operator binding ability was observed. Methionine oxidation was observed in the cases where protection of the operator DNA binding capacity of repressor was seen. The region surrounding cysteine 107 was found to be influential in maintaining intact operator DNA binding function in repressor. This observation provides chemical evidence for the contribution of the core region of repressor in determining specificity of the protein in binding the lac operator. The protection from oxidation of cysteine residues in the core region by the presence of nonspecific DNA suggests that this binding influences the core region of the protein.     

Tissue-Specific Distribution of DNA-Binding Nuclear Proteins

Abstract. The DNA-binding capacity of nuclear proteins of mouse cells was examined by the protein-blotting method. Under conditions in which the lac repressor specifically binds to the lac operator, the DNA-binding nuclear proteins from different tissues showed a tissue-specific distribution, suggesting that the species and amounts of nuclear proteins with DNA binding activity differ in different tissues.
When cloned eukaryotic genes were used for binding, eukaryotic DNA showed stronger binding than prokaryotic DNA. Competition experiments suggested that many nuclear proteins have different DNA binding properties from that of the prokaryotic repressor.     

Tissue-specific distribution of DNA-binding nuclear proteins

The DNA-binding capacity of nuclear proteins of mouse cells was examined by the protein-blotting method. Under conditions in which the lac repressor specifically binds to the lac operator, the DNA-binding nuclear proteins from different tissues showed a tissue-specific distribution, suggesting that the species and amounts of nuclear proteins with DNA binding activity differ in different tissues. When cloned eukaryotic genes were used for binding, eukaryotic DNA showed stronger binding than prokaryotic DNA. Competition experiments suggested that many nuclear proteins have different DNA binding properties from that of the prokaryotic repressor.     

Lactose repressor protein modified with dansyl chloride: activity effects and fluorescence properties

Chemical modification using 5-(dimethylamino)naphthalene-1-sulfonyl chloride (dansyl chloride) has been used to explore the importance of lysine residues involved in the binding activities of the lactose repressor and to introduce a fluorescent probe into the protein. Dansyl chloride modification of lac repressor resulted in loss of operator DNA binding at low molar ratios of reagent/monomer. Loss of nonspecific DNA binding was observed only at higher molar ratios, while isopropyl beta-D-thiogalactoside binding was not affected at any of the reagent levels studied. Lysine residues were the only modified amino acids detected. Protection of lysines-33 and -37 from modification by the presence of nonspecific DNA correlated with maintenance of operator DNA binding activity, and reaction of lysine-37 paralleled operator binding activity loss. Energy transfer between dansyl incorporated in the core region of the repressor protein and tryptophan-201 was observed, with an approximate distance of 23 A calculated between these two moieties.     

Repression of the E coli recA gene requires at least two LexA protein monomers

To analyze the DNA binding domain of E coli LexA repressor and to test whether the repressor binds as a dimer to DNA, negative dominant lexA mutations affecting the binding domain have been isolated. A large number of amino acid substitutions between amino acid positions 39 and 46 were introduced using cassette mutagenesis. Mutants defective in DNA binding were identified and then examined for dominance to lexA+. A number of substitutions weakened repressor function partially, whereas other substitutions led to a repressor with no demonstrable activity and a defective dominant phenotype. Since the LexA binding site has dyad symmetry, we infer that this dominance results from interaction of monomers of wild-type LexA protein with mutant monomers and that an oligomeric form of repressor binds to operator. The binding of LexA protein to operator DNA was investigated further using a mutant protein, LexA408, which recognizes a symmetrically altered operator mutant but not wild-type operator. A mixture of mutant LexA408 and LexA+ proteins, but neither individual protein, bound to a hybrid recA operator consisting of mutant and wild-type operator half sites. These results suggest that at least 1 LexA protein monomer interacts with each operator half site. We discuss the role of LexA oligomer formation in binding of LexA to operator DNA.     

The human estrogen receptor has transcriptional activator and repressor functions in the absence of ligand

Most studies on the cloned human estrogen receptor (hER) have been conducted with a mutant receptor in which Gly400 is changed to Val. Here we describe two novel regulatory functions of wild-type hER that are hormone independent: (i) a constitutive activator function and (ii) a repressor activity. Mutations in the hormone-binding domain, including the Val400 mutation, impair both of these functions. In addition, DNA binding is strongly reduced in the mutant receptors. The hormone-binding domain of the hER thus controls DNA binding (and thereby the repressor function) of the hER as well as its constitutive activator function. Moreover, we find that the antiestrogen tamoxifen restores the constitutive activator function, the DNA binding, and the repressor function of the Val400 mutant, but has no effect on the constitutive activator function or DNA binding of the wild-type hER.     

Repression by a differentiation-specific factor of the human cytomegalovirus enhancer.

We detected a novel nuclear protein, MRF, that binds to multiple sites on the modulator which is located upstream of the human cytomegalovirus major immediate early gene enhancer. The expression of MRF is differentiation specific; the DNA binding activity is present in nuclear extracts from undifferentiated Tera-2 and THP-1 cells, but significantly reduced after these cells are induced to differentiate. In undifferentiated cells the enhancer activity is repressed by the modulator and upon differentiation the enhancer becomes active. Competitive binding assays demonstrate that MRF requires the presence of multiple A+T stretches for binding to DNA, rather than binding to a specific DNA sequence. Mutations of these stretches in the modulator reduce the binding activity of MRF, as well as the repressing activity on the enhancer. These results suggest that MRF may act as a repressor of enhancer function. We propose that MRF binds over the entire modulator and exerts repressor activity.     

Deoxyribonucleic acid-binding studies on the hut repressor and mutant forms of the hut repressor of Salmonella typhimurium.

In Salmonella typhimurium the genes coding for the enzymes of histidine utilization (hut) are clustered in two adjacent operons, hutMIGC and hut(P,R,Q)UH. A single repressor, the product of the C gene, regulates both operons by binding at two operator sites, one near M and one in (P,R,Q). The deoxyribonucleic acid (DNA)-binding activity of the repressor was measured using DNA's containing separate operators. The repressor had greater activity when assayed using DNA containing the operator of the (P,R,Q)UH operon than when assayed using DNA containing the operator of the MIGC operon. The binding to either operator was absent in the presence of the inducer, urocanate. The DNA-binding activities were also determined for two super-repressors. The super-repressors had altered DNA-binding properties, although the self-regulated nature of the repressors complicated the analysis of the results. A purfication procedure for the wild-type repressor is presented. The purified repressor was somewhat unstable, and additional experiments using it were not performed.     

Chemical modification of arginine residues in the lactose repressor

The lactose repressor protein was chemically modified with 2,3-butanedione and phenylglyoxal. Arginine reaction was quantitated by either amino acid analysis or incorporation of 14C-labeled phenylglyoxal. Inducer binding activity was unaffected by the modification of arginine residues, while both operator and nonspecific DNA binding activities were diminished, although to differing degrees. The correlation of the decrease in DNA binding activities with the modification of approximately 1-2 equiv of arginine per monomer suggests increased reactivity of a functionally essential residue(s). For both reagents, operator DNA binding activity was protected by the presence of calf thymus DNA, and the extent of reaction with phenylglyoxal was simultaneously diminished. This protection presumably results from steric restriction of reagent access to an arginine(s) that is (are) essential for DNA binding interactions. These experiments suggest that there is (are) an essential reactive arginine(s) critical for repressor binding to DNA.     

DNA-induced conformational changes in bacteriophage 434 repressor

Although bacteriophage 434 repressor binds to its specific DNA sites only as a dimer, formation of the dimers in solution occurs at concentrations three orders of magnitude higher than those needed to bind the 434 operator DNA. Our results suggest that both specific and non-specific DNA induce conformational changes in repressor that lead to formation of repressor dimers. The repressor conformational changes induced by DNA occur at concentrations much lower than those needed for binding of repressor, suggesting that the alternative conformations of repressor persist even if the protein is not in direct contact with DNA. Hence, DNA acts in a "catalytic" fashion to induce a steady-state amount of an alternative repressor conformation that has an enhanced affinity for its specific binding site. These findings suggest that the repressor conformer induced by non-specific DNA is the form of the repressor that is optimized for searching for DNA binding sites along non-specific DNA. Upon finding a binding site, the repressor protein undergoes an additional conformational change that allows it to "lock-on" to its specific site.     

Displacement of a DNA binding protein by Dda helicase

Bacteriophage T4 Dda helicase has recently been shown to be active as a monomer for unwinding of short duplex oligonucleotides and for displacing streptavidin from 3′-biotinylated oligonucleotides. However, its activity for streptavidin displacement and DNA unwinding has been shown to increase as the number of Dda molecules bound to the substrate molecule increases. A substrate was designed to address the ability of Dda to displace DNA binding proteins. A DNA binding site for the Escherichia coli trp repressor was introduced into an oligonucleotide substrate for Dda helicase containing single-stranded overhang. Here we show that a Dda monomer is insufficient to displace the E.coli trp repressor from dsDNA under single turnover conditions, although the substrate is unwound and the repressor displaced when the single-stranded overhang is long enough to accommodate two Dda molecules. The quantity of product formed increases when the substrate is able to accommodate more than two Dda molecules. These results indicate that multiple Dda molecules act to displace DNA binding proteins in a manner that correlates with the DNA unwinding activity and streptavidin displacement activity. We suggest a cooperative inchworm model to describe the activities of Dda helicase.     

Mapping of binding sites for Mu repressor and ner product within the left-end EcoRI. C fragment of the Mu genome

Bacterial cells containing the ner gene of phage Mu inserted into pBR322 express a binding activity with specificity for the left-end EcoRI.C fragment of Mu DNA. Crude extracts containing either Mu repressor or ner protein have been used to localize binding sites on TaqI subfragments of the EcoRI.C fragment. There are at least 3 distinct binding sites for the Mu repressor and 1 binding site for the ner protein on the EcoRI. C fragment. The possible biological function of these binding sites is discussed.     

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.     

Electron microscopic study of the repressor of bacteriophage λ and its interaction with operator DNA

The structure of purified phage λ repressor has been examined by high resolution electron microscopy. The repressor molecule appears predominantly as a tetramer of about 95 Å × 120 Å. We have proposed a model to account for the variety of aspects seen on the electron micrographs. Spreading DNA without protein film and use of uranyl formate staining allowed the simultaneous visualization of the DNA and the structure of the repressor molecule bound to it. Mapping the positions of λ repressor bound to whole λ DNA shows preferential binding to the region containing the operators. At high resolution multiple binding of repressor to the operator can be demonstrated. Depending on the amount of repressor present, rows of one to four repressor tetramers are seen on the DNA, confirming the model of the operator containing four binding sites for repressor. The bound repressor can consequently protect against nuclease digestion of operator pieces of approximately 30, 57, 87 and 111 base-pairs. The isolated operator appears in the electron microscope as short double-stranded DNA fragments which can be shown to rebind repressor.     

Isolation of amino-terminal fragment of lactose repressor necessary for DNA binding.

lac repressor can be dissected by trypsin into a homogenous tetrameric core (accounting for residues 60 to 347), carrying inducer binding activity, and the monomeric amino-terminal peptides ("headpieces") accounting for residues 1 to 59 and 1 to 51, respectively. This restriction of the action of trypsin on lac repressor is obtained in 1 M Tris-HCl (pH 7.5)-30% in glycerol at 25 degrees C since only the peptide bonds at lysine-59 and to a lesser extent after at arginine-51 are cleaved under these conditions. The headpieces can be purified by gel filtration. They have ordered secondary structure as revealed by circular dichroism studies. The monomeric headpieces show the relatively weak binding to nonoperator DNA but not the highly specific and strong binding to operator DNA typical for tetrameric lac repressor.     

Preferential protection of the minor groove of non-operator DNA by lac repressor against methylation by dimethyl sulphate.

The binding of lactose repressor to non-operator DNA was studied by the modification of several DNA's, including glycosylated DNA, with dimethyl sulphate, which affects the minor and major grooves of DNA and single stranded DNA regions. The non-specific binding of the repressor to DNA protected the minor groove but apparently not the major groove of the DNA double helix against methylation and did not increase the content of single stranded DNA regions. This suggests that the repressor on binding to non-operator DNA makes contacts mainly in the minor groove of DNA and does not uncoil the DNA double helix. This is different from the interaction of the repressor with lactose operator DNA which occurs, as shown by Gilbert et al. (1), along both the major and the minor groove.     

Thyroid hormone receptor dimerization function maps to a conserved subregion of the ligand binding domain.

Thyroid hormone receptors (TRs) bind as dimers to specific DNA response elements. We have used a genetic approach to identify amino acid sequences required for dimerization of the TR beta isoform. Bacteria expressing a chimeric repressor composed of the DNA binding domain of the bacteriophage lambda cl repressor fused to the TR beta ligand binding domain are immune to lambda infection as a consequence of homodimerization activity provided by the receptor sequences. The phenotypes of deletions and point mutations of the TR beta sequences map dimerization activity to a subregion of the ligand binding domain that is highly conserved among all members of the nuclear hormone receptor superfamily. These results confirm and extend previous findings indicating that this subregion plays an important role in the dimerization of TR beta and other superfamily members.