DNA supercoiling promotes formation of a bent repression loop in lac DNA

Titration experiments on supercoiled lac DNA show that one repressor tetramer can bind simultaneously to the primary lac operator and to the very weak lac pseudo-operator, located 93 base-pairs apart. The formation of this complex is accompanied by the appearance of an extreme hypersensitive site in a five base-pair sequence located approximately midway between the operators. This remote sequence is hypersensitive to attack by two different chemical probes, dimethyl sulfate and potassium permanganate, the latter of which is a new probe for distorted DNA. We interpret these results in terms of a complex in which lac repressor holds two remote operators together in a DNA loop. The formation of this bent DNA loop requires negative DNA supercoiling. In vivo, both lac operators bind repressor even though the presence of multiple operator copies has forced the two operators to compete for a limited amount of repressor. This suggests that the operator and pseudo-operator have similar affinities for repressor in vivo. Such similar affinities were observed in vitro only when DNA supercoiling forced formation of a repression loop.     

lac repressor forms loops with linear DNA carrying two suitably spaced lac operators.

Tetrameric lac repressor may bind to two lac operators on one DNA fragment and induce the intervening DNA to form a loop. Electron microscopy, non-denaturing polyacrylamide gel electrophoresis, and DNase I protection experiments were used to demonstrate such DNA loops, where the distance between the centres of symmetry of the two lac operators varies between 63 and 535 bp. Formation of a DNA loop is favoured by correct phasing of the two lac operators and a low concentration of both components of the reaction. When a large excess of lac repressor over DNA is used, a 'tandem' structure is observed, in which both lac operators are occupied independently by two repressor tetramers. When the concentrations of both lac repressor and lac operator are high, a 'sandwich' structure is observed, in which two DNA molecules are connected by two lac repressor tetramers in trans.     

Interaction of tight binding repressors with lac operators. An analysis by DNA-footprinting

To increase our understanding of protein-DNA interaction in general, and in particular that of lac repressor with lac operator, we have investigated the interaction of tight binding (Itb) repressors with wild type (WT) operator and Oc operators. Nine Oc and a WT operator were cloned and sequenced. Three different Oc and an O+ were then chosen for the footprint analysis of six Itb repressors and WT repressor. Distinct protection patterns for the various repressor-operator pairs were observed at low repressor concentrations whereas, at high repressor concentrations, a stretch of 24 bases of the lower strand of the four different operators was protected in most cases. This protection pattern at high repressor concentration was almost completely redundant for all repressor-operator pairs, in spite of the fact that the affinities of the various pairs differed by more than three orders of magnitude. Two exceptions to this general observation were the two tight binding repressors R67 and R78a. These had been mapped in a region that codes for amino acid residues involved in subunit interaction. The two repressors showed reduced protection of O+ and of some Oc operators at the 3' (right) end of the lower strand. Dimethylsulfoxide, which is known to increase the affinity of O+ for repressor, did not increase the number of bases protected by WT repressor on the lower strand of O+. The footprinting results presented here clearly demonstrate that lac repressor can maximally protect about 24 bases of the lower strand of the operator and that the number and kind of interactions occurring in this region determine the strength of the repressor-operator interaction.     

Probing co-operative DNA-binding in vivo. The lac O1:O3 interaction

The lac primary (O1) and weak upstream pseudo (O3) operators contained on a plasmid were footprinted in vivo in order to determine whether they act co-operatively in binding lac repressor in the cell. The occupancy at O3 by lac repressor was substantially reduced upon deletion of the lac primary operator, demonstrating co-operativity at a distance. Plots of operator occupancy versus active repressor concentration were obtained for each operator by treating the cells with different amounts of the lac inducer isopropyl-beta-D-thiogalactoside and probing lac repressor binding. This analysis can be used to obtain relative binding constants in vivo and demonstrates that O3 binds repressor only 10.3-fold less tightly than O1 in their co-operative interaction. The removal of DNA torsional tension in vivo by the use of coumermycin leads to the same loss of binding at O3 as does deleting O1. These in-vivo results are analogous to the in-vitro situation, where O3 binds repressor strongly in a DNA repression loop only on supercoiled templates.     

The interaction of the recognition helix of lac repressor with lac operator.

We have constructed a system which allows systematic testing of repressor--operator interactions. The system consists of two plasmids. One of them carries a lac operon in which lac operator has been replaced by a unique restriction site into which synthetic operators can be cloned. The other plasmid carries the gene coding for the repressor, in our case a semisynthetic lacI gene of which parts can be exchanged in a cassette-like manner. A galE host allows us to select for mutants which express repressors with altered specificities. Here we report the change of specificity in the lac system by changing residues 1 and 2 of the recognition helix of lac repressor. The specificity changes are brought about cooperatively by the change of both residues. Exchanges of just one residue broaden the specificity. Our results hint that the recognition helix of lac repressor may possibly have the opposite orientation to those in Lambda cro protein or 434 CI repressor.     

Lac repressor with the helix-turn-helix motif of lambda cro binds to lac operator.

Lac repressor, lambda cro protein and their operator complexes are structurally, biochemically and genetically well analysed. Both proteins contain a helix-turn-helix (HTH) motif which they use to bind specifically to their operators. The DNA sequences 5'-GTGA-3' and 5'-TCAC-3' recognized in palindromic lac operator are the same as in lambda operator but their order is inverted form head to head to tail to tail. Different modes of aggregation of the monomers of the two proteins determine the different arrangements of the HTH motifs. Here we show that the HTH motif of lambda cro protein can replace the HTH motif of Lac repressor without changing its specificity. Such hybrid Lac repressor is unstable. It binds in vitro more weakly than Lac repressor but with the same specificity to ideal lac operator. It does not bind to consensus lambda operator.     

Targeting the Escherichia coli lac repressor to the mammalian cell nucleus

We have previously shown that about 90% of total Escherichia coli lac repressor synthesized in mammalian cells is located in the cytoplasm [Hu and Davidson, Cell 48 (1987) 555-566]. To target a functional lac repressor to the nucleus, we mutated 10 nucleotides at the 3' end of the coding sequence, thus adding the nuclear localization signal of the simian virus 40 large-T antigen to the C terminus of the repressor. The mutant lacI gene and the wild-type (wt) gene, both in standard animal cell expression vectors, driven by the promoter of the Rous sarcoma virus long terminal repeat, were stably transfected into three rodent cell lines. In confirmation of our previous results, only about 10% of the wt repressor, but all of the mutant protein, was localized in the nucleus. DNase I footprint analyses showed that the mutant repressor retained the same operator DNA-binding specificity as wt repressor. Furthermore, both repressor-operator complexes could be dissociated by addition of isopropyl-beta-D-thiogalactopyranoside in vitro. However, the ratio of number of repressor molecules per nucleus that, by in vitro assay, could bind to the operator sequence to the number of monomer repressor polypeptides per nucleus, as determined by Western blotting, was about 1:4 for the wt repressor and about 1:30 for the mutant repressor. This suggests that: (a) the mutant repressor assembles into tetramers inefficiently; and/or (b) it has reduced binding affinity to the operator sequence; and/or (c) it has higher binding affinity to nonspecific DNA.     

Physical properties of DNA in vivo as probed by the length dependence of the lac operator looping process

Plasmid constructs containing a wild-type (O+) lac operator upstream of an operator-constitutive (Oc) lac control element exhibit a length-dependent, oscillatory pattern of repression of expression of the regulated gene as interoperator spacing is varied from 115 to 177 base pairs (bp). Both the length dependence and the periodicity of repression are consistent with a thermodynamic model involving a stable looped complex in which bidentate lac repressor interacts simultaneously with both O+ and Oc operators. The oscillatory pattern of repression with distance occurs with a period approximating the helical repeat of DNA and presumably reflects the necessity for proper alignment of interacting operators along the helical face of the DNA. In the length regime examined, the presence of the upstream operator enhances repression between 6-fold and 50-fold depending upon phasing. This reflects a torsional rigidity of DNA in vivo that is consistent with in vitro measurements. The oscillatory pattern of repression is best fit with a period of either 9.0 or 11.7 bp/cycle but not 10.5 bp/cycle. This periodicity is interpreted as reflecting the average helical repeat of the 40-bp interoperator region of plasmid DNA in vivo, suggesting that the local helical repeat of DNA in vivo may differ significantly from 10.5 bp/turn. The apparent persistence length needed to fit the data (aapp) is only one-fifth the standard in vitro value. This low value of aapp may be due in part to DNA bending induced by catabolite activator protein (CAP) bound to its site between the interacting operators.(ABSTRACT TRUNCATED AT 250 WORDS)     

Plasticity in protein-DNA recognition: lac repressor interacts with its natural operator 01 through alternative conformations of its DNA-binding domain

The lac repressor-operator system is a model system for understanding protein-DNA interactions and allosteric mechanisms in gene regulation. Despite the wealth of biochemical data provided by extensive mutations of both repressor and operator, the specific recognition mechanism of the natural lac operators by lac repressor has remained elusive. Here we present the first high-resolution structure of a dimer of the DNA-binding domain of lac repressor bound to its natural operator 01. The global positioning of the dimer on the operator is dramatically asymmetric, which results in a different pattern of specific contacts between the two sites. Specific recognition is accomplished by a combination of elongation and twist by 48 degrees of the right lac subunit relative to the left one, significant rearrangement of many side chains as well as sequence-dependent deformability of the DNA. The set of recognition mechanisms involved in the lac repressor-operator system is unique among other protein-DNA complexes and presents a nice example of the adaptability that both proteins and DNA exhibit in the context of their mutual interaction.     

Studies on gene control regions X. The effect of specific adenine-thymine transversions on the lac repressor-lac operator interaction.

Chemical and enzymatic methods were used to synthesize a transition (AT to GC) and a transversion (AT to TA) at a lac operator site known to interact with lac repressor through the thymine 5 methyl group. These operators also contained a poly(dA) . poly(dT) tail 8 to 12 base pairs in length at one end. Results suggest that the steric constraints of lac repressor relative to the position of the 5 methyl group are quite critical. For example a seven fold reduction in stability was observed for the transversion. Results also suggest that the operator spans at least 21 base pairs.     

How Lac repressor finds lac operator in vitro.

Filter-binding and gel mobility shift assays were used to analyse the kinetics of the interaction of Lac repressor with lac operator. A comparison of the two techniques reveals that filter-binding assays with tetrameric Lac repressor have often been misinterpreted. It has been assumed that all complexes of Lac repressor and lac operator DNA bind with equal affinity to nitrocellulose filters. This assumption is wrong. Sandwich or loop complexes where two lac operators bind to one tetrameric Lac repressor are not or are only badly retained on nitrocellulose filters under normal conditions. Taking this into account, dimeric and tetrameric Lac repressor do not show any DNA-length dependence of their association and dissociation rate constants when they bind to DNA fragments smaller than 2455 base-pairs carrying a single symmetric ideal lac operator. A ninefold increased association rate to ideal lac operator on lambda DNA is observed for tetrameric but not dimeric Lac repressor. It is presumably due to intersegment transfer involving lac operator-like sequences.     

Quality and position of the three lac operators of E. coli define efficiency of repression.

Repression of the lac promoter may be achieved in two different ways: either by interference with the action of RNA polymerase or by interference with CAP activation. We investigated cooperative repression of the Escherichia coli lac operon by systematic conversion of its three natural operators (O1, O2 and O3) on the chromosome. We find that cooperative repression by tetrameric Lac repressor increases with both quality and proximity of the interacting operators. A short distance of 92 bp allows effective repression by two very weak operators (O3, O3). The cooperativity of lac operators is discussed in terms of a local increase of repressor concentration. This increase in concentration depends on flexible DNA which allows loop formation.     

Mutant lac repressors with new specificities hint at rules for protein--DNA recognition.

Proteins which recognize specific sequences of DNA play a fundamental role in the regulation of protein synthesis in all organisms. A particular helix of the bacterial protein lac repressor recognizes the bases in the major groove of the lac operator. We show that the first two residues of this recognition helix interact independently with two base pairs. This allows us in many cases to predict repression as an indicator of strength of the repressor-operator complex. Rules of recognition can be derived for 16 symmetric operators. They also apply to the gal repressor and possibly to other bacterial repressors.     

The lac repressor

Few proteins have had such a strong impact on a field as the lac repressor has had in Molecular Biology. Over 40 years ago, Jacob and Monod [Genetic regulatory mechanisms in the synthesis of proteins, J. Mol. Biol. 3 (1961) 318] proposed a model for gene regulation, which survives essentially unchanged in contemporary textbooks. It is a cogent depiction of how a set of 'structural' genes may be coordinately transcribed in response to environmental conditions and regulates metabolic events in the cell. In bacteria, the genes required for lactose utilization are negatively regulated when a repressor molecule binds to an upstream cis activated operator. The repressor and its operator together form a genetic switch, the lac operon. The switch functions when inducer molecules alter the conformation of the repressor in a specific manner. In the presence of a particular metabolite, the repressor undergoes a conformational change that reduces its affinity for the operator. The structures of the lac repressor and its complexes with operator DNA and effector molecules have provided a physical platform for visualizing at the molecular level the different conformations the repressor and the molecular basis for the switch. The structures of lac repressor, bound to its operator and inducer, have also been invaluable for interpreting a plethora of biochemical and genetic data.     

lac repressor forms stable loops in vitro with supercoiled wild-type lac DNA containing all three natural lac operators

We have analyzed protein-DNA complexes formed between lac repressor and linear or differently supercoiled lac DNA (802 or 816 base-pairs in length), which carry all three natural lac operators (O1, O2 and O3) in their wild-type sequence context and spacing and compared them with constructs that contain specifically mutated "pseudo-operators" O2 or O3. We used gel retardation assays to identify the nature of the complexes according to their characteristic electrophoretic mobility and dissociation rate measurements to determine their stability. With linear DNA we found only indirect evidence for loop formation between O1 and O2. In covalently closed DNA minicircles the formation of a loop between O1 and O2 could be demonstrated by the observation that O1-O2 containing DNA with low negative supercoiling (sigma = -0.013 and less) is constricted by binding of lac repressor, resulting in an increased electrophoretic mobility. At elevated negative supercoiling (sigma = -0.025, -0.037, -0.05) O1-O2 containing DNA complexed with lac repressor migrates significantly slower than the corresponding O1-DNA, indicating loop formation. The dissociation of lac repressor-operator complexes is decreased with increasing negative supercoiling for all tested operator combinations of O1, O2 and O3. However, in the presence of at least two natural lac operators on the same DNA minicircle the enhancement of stability is particularly large. This indicates that a DNA loop is formed between these two lac operators, O1 and O2 as well as O1 and O3, since negative supercoiling is known specifically to promote the formation of looped structures. Additionally, we observe a dependence of dissociation rate on the spatial alignment of the operators as a result of changing helical periodicity in differently supercoiled DNA and consider this to be further evidence for loop formation between O1 and O2 as well as O1 and O3.