Cooperative tandem binding of met repressor of Escherichia coli

We present biochemical and genetic data to support the hypothesis that the Escherichia coli met repressor, MetJ, binds to synthetic and natural operator sequences in tandem arrays such that repression depends not only on the affinity of the DNA-protein interaction, but also on protein-protein contacts along the tandem array. This represents a novel form of regulatory switch. Furthermore, there seems to be homology between the organization of the met and trp operators.     

Crystal structure of the met repressor-operator complex at 2.8 A resolution reveals DNA recognition by beta-strands.

The crystal structure of the met repressor-operator complex shows two dimeric repressor molecules bound to adjacent sites 8 base pairs apart on an 18-base-pair DNA fragment. Sequence specificity is achieved by insertion of double-stranded antiparallel protein beta-ribbons into the major groove of B-form DNA, with direct hydrogen-bonding between amino-acid side chains and the base pairs. The repressor also recognizes sequence-dependent distortion or flexibility of the operator phosphate backbone, conferring specificity even for inaccessible base pairs.     

Ethylation interference and X-ray crystallography identify similar interactions between 434 repressor and operator

In the crystal structure of a repressor-operator complex (the 434 repressor DNA-binding domain and its 14-base pair (bp) operator), Anderson et al. elsewhere in this issue identify six positions of likely contact between repressor protein and phosphates of the DNA backbone. At each of these positions, electron densities of protein and DNA merge. Experiments presented here indicate that intact 434 repressor approaches these phosphates very closely when it is bound to DNA in solution. Specifically, when any one of these phosphates is ethylated, repressor cannot bind to the modified operator. We also identify another position where ethylation has a significant but less dramatic effect on repressor binding, and note that in the structure, repressor closely approaches this phosphate. Our results strongly support the idea that the interactions between protein and the DNA phosphate backbone in the crystallized complex are the same as those made by intact repressor to operator DNA in solution. In addition, our results suggest that DNA is slightly bent by repressor binding.     

Importance of DNA stiffness in protein-DNA binding specificity

From the first high-resolution structure of a repressor bound specifically to its DNA recognition sequence it has been shown that the phage 434 repressor protein binds as a dimer to the helix. Tight, local interactions are made at the ends of the binding site, causing the central four base pairs (bp) to become bent and overtwisted. The centre of the operator is not in contact with protein but repressor binding affinity can be reduced at least 50-fold in response to a sequence change there. This observation might be explained should the structure of the intervening DNA segment vary with its sequence, or if DNA at the centre of the operator resists the torsional and bending deformation necessary for complex formation in a sequence dependent fashion. We have considered the second hypothesis by demonstrating that DNA stiffness is sequence dependent. A method is formulated for calculating the stiffness of any particular DNA sequence, and we show that this predicted relationship between sequence and stiffness can explain the repressor binding data in a quantitative manner. We propose that the elastic properties of DNA may be of general importance to an understanding of protein-DNA binding specificity.     

A new-specificity mutant of 434 repressor that defines an amino acid-base pair contact

The repressor encoded by bacteriophage 434 binds to its operators by inserting a 'recognition' alpha-helix into the major groove of the DNA. We have identified an amino acid-base pair contact that determines (in part) the DNA-binding specificity of 434 repressor. The identification is based on the properties of a 'new-specificity' mutant, named Repressor [Ala 28], which bears the substitution of Ala for Gln at the first residue of its recognition alpha-helix. Repressor [Ala 28] binds with high affinity to a particular doubly mutant operator bearing the same substitution at position 1 in each half-site, but does not bind to either the wild-type operator or to other mutant operators. We describe molecular models of residue 28-base pair 1 interactions that account for the binding specificities of both the mutant and wild-type proteins.     

DNA twisting and the effects of non-contacted bases on affinity of 434 operator for 434 repressor.

The bacteriophage 434 repressor regulates gene expression by binding with differing affinities to the six operator sites on the phage chromosome. The symmetrically arrayed outer eight base pairs (four in each half-site) of these 14-base-pair operators are highly conserved but the middle four bases are divergent. Although these four base pairs are not in contact with repressor, operators with A.T or T.A base pairs at these positions bind repressor more strongly than those bearing C.G or G.C, suggesting that these bases are important for the repressor's ability to discriminate between operators. There is evidence that the central base pairs influence operator function by constraining the twisting and/or bending of DNA. Here we show that there is a relationship between the intrinsic twist of an operator, as determined by the sequence of its central bases, and its affinity for repressor; an operator with a lower affinity is undertwisted relative to an operator with higher affinity. In complex with repressor, the twist of both high- and low-affinity operators is the same. These results indicate that the intrinsic twist of DNA and its twisting flexibility both affect the affinity of 434 operator for repressor.     

Structure of the cro repressor from bacteriophage lambda and its interaction with DNA

The three-dimensional structure of the 66-amino acid cro repressor protein of bacteriophage lambda suggests how it binds to its operator DNA. We propose that a dimer of cro protein is bound to the B-form of DNA with the 2-fold axis of the dimer coincident with the 2-fold axis of DNA. A pair of 2-fold-related alpha-helices of the repressor, lying within successive major grooves of the DNA, seem to be a major determinant in recognition and binding. In addition, the C-terminal residues of the protein, some of which are disordered in the absence of DNA, appear to contribute to the binding.     

Crystal structure of trp repressor/operator complex at atomic resolution

The crystal structure of the trp repressor/operator complex shows an extensive contact surface, including 24 direct and 6 solvent-mediated hydrogen bonds to the phosphate groups of the DNA. There are no direct hydrogen bonds or non-polar contacts to the bases that can explain the repressor's specificity for the operator sequence. Rather, the sequence seems to be recognized indirectly through its effects on the geometry of the phosphate backbone, which in turn permits the formation of a stable interface. Water-mediated polar contacts to the bases also appear to contribute part of the specificity.     

Structure of the repressor-operator complex of bacteriophage 434

The crystal structure of a specific complex between the DNA-binding domain of phage 434 repressor and a synthetic 434 operator DNA shows interactions that determine sequence-dependent affinity. The repressor recognizes its operators by its complementarity to a particular DNA conformation as well as by direct interaction with base pairs in the major groove.     

Three-dimensional crystal structures of Escherichia coli met repressor with and without corepressor

The three-dimensional crystal structure of met repressor, in the presence or absence of bound corepressor (S-adenosylmethionine), shows a dimer of intertwined monomers, which do not have the helix-turn-helix motif characteristic of other bacterial repressor and activator structures. We propose that the interaction of met repressor with DNA occurs through either a pair of symmetry-related alpha-helices or a pair of beta-strands, and suggest a model for binding of several dimers to met operator regions.     

Functional contacts of a transfer RNA synthetase with 2'-hydroxyl groups in the RNA minor groove.

The functional analysis of determinants on RNA has been largely limited to molecules that contain naturally occurring ribonucleotides, so little is known about the role of 2'-hydroxyl groups in protein-RNA recognition. A single base pair (G3.U70) in the acceptor stem of tRNA(Ala) is the principal element for specific recognition by Escherichia coli alanine-tRNA synthetase. This tRNA synthetase aminoacylates small RNA helices that contain the G3.U70 base pair. Furthermore, removal of the G3 exocyclic 2-amino group that projects into the minor groove eliminates aminoacylation. This 2-amino group is flanked on either side by ribose 2'-hydroxyl groups that line the minor groove. Here we use chemical synthesis to construct 32 helices that make deoxy and O-methyl substitutions of individual and multiple 2'-hydroxyl groups near and beyond the G3.U70 base pair and find that functional 2'-hydroxyl contacts are clustered within a few ?ngstroms of the critical 2-amino group. These contacts are highly specific and make a thermodynamically significant contribution to RNA recognition.     

Dependence of the torsional rigidity of DNA on base composition

The Escherichia coli phage 434 repressor binds as a dimer to the operator of the DNA helix. Although the centre of the operator is not in contact with protein, the repressor binding affinity can be reduced at least 50-fold by changing the sequence there: operators with A.T base pairs near their centre bind the repressor more strongly than do operators with G.C base pairs at the same positions. To explain these observations, it has been proposed that the base composition at the centre of the operator affects the affinity of the operator for repressor by altering the ease with which operator DNA can undergo the torsional deformation necessary for complex formation. In this model, the variation in binding affinity would require the torsion constant to have specific values and to change in a sequence-dependent manner. We have now measured torsion constants for DNAs with widely different base compositions. Our results indicate that the torsion constants depend only slightly on the overall composition, and firmly delimit the range of values for each. Even the upper-limit values are much too small to account for the observed changes in affinity of the 434 repressor. These results rule out simple models that rely on substantial generic differences in torsion constant between A.T-rich sequences and G.C-rich sequences, although they do not rule out the possibility of particular sequences having abnormal torsion constants.     

Crystal structure of the lambda repressor and a model for pairwise cooperative operator binding

Bacteriophage lambda has for many years been a model system for understanding mechanisms of gene regulation. A 'genetic switch' enables the phage to transition from lysogenic growth to lytic development when triggered by specific environmental conditions. The key component of the switch is the cI repressor, which binds to two sets of three operator sites on the lambda chromosome that are separated by about 2,400 base pairs (bp). A hallmark of the lambda system is the pairwise cooperativity of repressor binding. In the absence of detailed structural information, it has been difficult to understand fully how repressor molecules establish the cooperativity complex. Here we present the X-ray crystal structure of the intact lambda cI repressor dimer bound to a DNA operator site. The structure of the repressor, determined by multiple isomorphous replacement methods, reveals an unusual overall architecture that allows it to adopt a conformation that appears to facilitate pairwise cooperative binding to adjacent operator sites.     

A phage repressor-operator complex at 7 A resolution

The crystal structure of a complex between the DNA-binding domain of phage 434 repressor and a synthetic 434 operator shows that the protein, very similar in conformation to gamma repressor, binds to B-form DNA with the second alpha-helix of a helix-turn-helix motif lying in the major groove.     

Structure of a phage 434 Cro/DNA complex

Comparison of the crystal structure of a complex of the phage 434 Cro protein and a synthetic DNA operator with the complex of the same operator and the 434 repressor DNA-binding domain shows different DNA conformations in the two structures. Binding of the protein determines the precise conformation of the DNA in each case.     

Identification of D segments of immunoglobulin heavy-chain genes and their rearrangement in T lymphocytes

The finding that the diversity (D) and joining (JH) but not the variable (VH) DNA segments of mouse immunoglobulin heavy-chain genes are joined in the DNA of some cloned cytolytic T cells, led to identification and sequencing of three different D DNA segments. Two segments identified on the embryo DNA carry on both the 5' and 3' sides two sets of characteristic sequences separated by a 12-base pair spacer, which have been implicated as recognition signals for a recombinase. The third segment, identified in a form joined with a JHDNA segment in a T cell, carries the recognition signal on the 5' side. These results support the 12/23-base pair model for somatic generation of immunoglobulin V genes, and rule out the possibility that the cytolytic T cells use assembled VH, D and JH sequences to encode their antigen receptors.     

Effect of non-contacted bases on the affinity of 434 operator for 434 repressor and Cro

The repressor of phage 434 binds to six operator sites on the phage chromosome. A comparison of the sequences of these 14-base-pair (bp) operator sites reveals a striking pattern: at five of the six sites, the symmetrically arrayed outer eight base pairs (four in each half-site) are identical and the remaining site differs at only one position (Fig. 1b). In contrast, the sequences of the inner four base pairs are highly variable. Crystallographic analysis of the repressor-operator complex shows that at each half-site, the 'recognition alpha-helix' of the repressor is positioned in the major groove such that it could contact the outermost five base pairs, but not the innermost two (Fig. 1a). We show in this paper that the sequence of the central base pairs of the operator (two in each half-site) have a significant role in determining operator affinity for repressor, despite the evidence presented here and in the accompanying paper that these base pairs are not contacted by repressor. We also show that these central base pairs influence operator affinity for Cro, a second gene regulatory protein encoded by phage 434. We discuss the likely structural basis for this evidently indirect, but sequence-dependent, effect of the central base pairs of the operator on its affinity for the two regulatory proteins.     

Crystal structure of the hereditary haemochromatosis protein HFE complexed with transferrin receptor

HFE is related to major histocompatibility complex (MHC) class I proteins and is mutated in the iron-overload disease hereditary haemochromatosis. HFE binds to the transferrin receptor (TfR), a receptor by which cells acquire iron-loaded transferrin. The 2.8 A crystal structure of a complex between the extracellular portions of HFE and TfR shows two HFE molecules which grasp each side of a twofold symmetric TfR dimer. On a cell membrane containing both proteins, HFE would 'lie down' parallel to the membrane, such that the HFE helices that delineate the counterpart of the MHC peptide-binding groove make extensive contacts with helices in the TfR dimerization domain. The structures of TfR alone and complexed with HFE differ in their domain arrangement and dimer interfaces, providing a mechanism for communicating binding events between TfR chains. The HFE-TfR complex suggests a binding site for transferrin on TfR and sheds light upon the function of HFE in regulating iron homeostasis.