Structure of the lambda complex at 2.5 A resolution: details of the repressor-operator interactions

Crystal structure of lambda-Cro bound to a consensus operator at 3.0 A resolution

The structure of the Cro protein from bacteriophage lambda in complex with a 19 base-pair DNA duplex that includes the 17 base-pair consensus operator has been determined at 3.0 A resolution. The structure confirms the large changes in the protein and DNA seen previously in a crystallographically distinct low-resolution structure of the complex and, for the first time, reveals the detailed interactions between the side-chains of the protein and the base-pairs of the operator. Relative to the crystal structure of the free protein, the subunits of Cro rotate 53 degrees with respect to each other on binding DNA. At the same time the DNA is bent by 40 degrees through the 19 base-pairs. The intersubunit connection includes a region within the protein core that is structurally reminiscent of the "ball and socket" motif seen in the immunoglobulins and T-cell receptors. The crystal structure of the Cro complex is consistent with virtually all available biochemical and related data. Some of the interactions between Cro and DNA proposed on the basis of model-building are now seen to be correct, but many are different. Tests of the original model by mutagenesis and biochemical analysis corrected some but not all of the errors. Within the limitations of the crystallographic resolution it appears that operator recognition is achieved almost entirely by direct hydrogen-bonding and van der Waals contacts between the protein and the exposed bases within the major groove of the DNA. The discrimination of Cro between the operators OR3 and OR1, which differ in sequence at just three positions, is inferred to result from a combination of small differences, both favorable and unfavorable. A van der Waals contact at one of the positions is of primary importance, while the other two provide smaller, indirect effects. Direct hydrogen bonding is not utilized in this distinction.

Crystal structure of an engineered Cro monomer bound nonspecifically to DNA: possible implications for nonspecific binding by the wild-type protein

The structure has been determined at 3.0 A resolution of a complex of engineered monomeric Cro repressor with a seven-base pair DNA fragment. Although the sequence of the DNA corresponds to the consensus half-operator that is recognized by each subunit of the wild-type Cro dimer, the complex that is formed in the crystals by the isolated monomer appears to correspond to a sequence-independent mode of association. The overall orientation of the protein relative to the DNA is markedly different from that observed for Cro dimer bound to a consensus operator. The recognition helix is rotated 48 degrees further out of the major groove, while the turn region of the helix-turn-helix remains in contact with the DNA backbone. All of the direct base-specific interactions seen in the wild-type Cro-operator complex are lost. Virtually all of the ionic interactions with the DNA backbone, however, are maintained, as is the subset of contacts between the DNA backbone and a channel on the protein surface. Overall, 25% less surface area is buried at the protein DNA interface than for half of the wild-type Cro-operator complex, and the contacts are more ionic in character due to a reduction of hydrogen bonding and van der Waals interactions. Based on this crystal structure, model building was used to develop a possible model for the sequence-nonspecific interaction of the wild-type Cro dimer with DNA. In the sequence-specific complex, the DNA is bent, the protein dimer undergoes a large hinge-bending motion relative to the uncomplexed form, and the complex is twofold symmetric. In contrast, in the proposed nonspecific complex the DNA is straight, the protein retains a conformation similar to the apo form, and the complex lacks twofold symmetry. The model is consistent with thermodynamic, chemical, and mutagenic studies, and suggests that hinge bending of the Cro dimer may be critical in permitting the transition from the binding of protein at generic sites on the DNA to binding at high affinity operator sites.

DNA-methyltransferase SsoII interaction with own promoter region binding site

The investigation of Sso II DNA-methyltransferase (M.Sso II) interaction with the intergenic region of Sso II restriction-modification system was carried out. Seven guanine residues protected by M. Sso II from methylation with dimethylsulfate and thus probably involved in enzyme-DNA recognition were identified. Six of them are located symmetrically within the 15 bp inverted repeat inside the Sso II promoter region. The crosslinking of Sso II methyltransferase with DNA duplexes containing 5-bromo-2'-deoxyuridine (br5dU) instead of thymidine was performed. The crosslinked products were obtained in all cases, thus proving that tested thymines were in proximity with enzyme. The ability to produce the crosslinked products in one case was 2-5-fold higher than in other ones. This allowed us to imply that thymine residue in this position of the inverted repeat could be in contact with M. Sso II. Based on the experimental data, two symmetrical 4 bp clusters (GGAC), which could be involved in the interaction with M. Sso II in the DNA-protein complex, were identified. The model of M. Sso II interaction with its own promoter region was proposed.

A new DNA-binding motif in the Skn-1 binding domain-DNA complex

The DNA-binding domain of Skn-1, a developmental transcription factor that specifies mesoderm in C. elegans, is shown by X-ray crystallography to have a novel fold in which a compact, monomeric, four-helix unit organizes two DNA-contact elements. At the C-terminus, a helix extends from the domain to occupy the major groove of DNA in a manner similar to bZip proteins. Skn-1, however, lacks the leucine zipper found in all bZips. Additional contacts with the DNA are made by a short basic segment at the N-terminus of the domain, reminiscent of the 'homeodomain arm'.

A map of the biotin repressor-biotin operator interface: binding of a winged helix-turn-helix protein dimer to a forty base-pair site

The Escherichia coli biotin repressor is a member of the "winged helix-turn-helix" class of site-specific DNA binding proteins. The protein binds as a dimer to the 40 bp biotin operator sequence. Although the structure of the aporepressor has been solved by X-ray crystallographic techniques, no structure of the holorepressor-DNA complex is yet available. In order to characterize the structural features of the biotin repressor-biotin operator interface we have applied a number of solution techniques including DNase I, hydroxyl radical and dimethyl sulfate footprinting and the circular permutation or "bending" assay. Results of these combined studies indicate that each repressor monomer forms a bipartite interface with each half-site of the biotin operator sequence. The results imply that, in addition to the helix-turn-helix module of each monomer, a second structural element participates in the protein-DNA interface. The two bipartite protein-DNA interfaces appear, moreover, to primarily involve the two 12 bp termini of the operator site. Results of combined DNase I footprinting and circular permutation analysis indicate, furthermore, that the central 16 bp region that links the two termini becomes distorted concomitant with binding of holoBirA.

The ClpXP and ClpAP proteases degrade proteins with carboxy-terminal peptide tails added by the SsrA-tagging system

Interruption of translation in Escherichia coli can lead to the addition of an 11-residue carboxy-terminal peptide tail to the nascent chain. This modification is mediated by SsrA RNA (also called 10Sa RNA and tmRNA) and marks the tagged polypeptide for proteolysis. Degradation in vivo of lambda repressor amino-terminal domain variants bearing this carboxy-terminal SsrA peptide tag is shown here to depend on the cytoplasmic proteases ClpXP and ClpAP. Degradation in vitro of SsrA-tagged substrates was reproduced with purified components and required a substrate with a wild-type SsrA tail, the presence of both ClpP and either ClpA or ClpX, and ATP. Clp-dependent proteolysis accounts for most degradation of SsrA-tagged amino-domain substrates at 32 degrees C, but additional proteases contribute to the degradation of some of these SsrA-tagged substrates at 39 degrees C. The existence of multiple cytoplasmic proteases that function in SsrA quality-control surveillance suggests that the SsrA tag is designed to serve as a relatively promiscuous signal for proteolysis. Having diverse degradation systems able to recognize this tag may increase degradation capacity, permit degradation of a wide variety of different tagged proteins, or allow SsrA-tagged proteins to be degraded under different growth conditions.

Characterization of a partially folded monomer of the DNA-binding domain of human papillomavirus E2 protein obtained at high pressure

The pressure-induced dissociation of the dimeric DNA binding domain of the E2 protein of human papillomavirus (E2-DBD) is a reversible process with a Kd of 5.6 x 10(-8) M at pH 5.5. The complete exposure of the intersubunit tryptophans to water, together with the concentration dependence of the pressure effect, is indicative of dissociation. Dissociation is accompanied by a decrease in volume of 76 ml/mol, which corresponds to an estimated increase in solvent-exposed area of 2775 A2. There is a decrease in fluorescence polarization of tryptophan overlapping the red shift of fluorescence emission, supporting the idea that dissociation of E2-DBD occurs in parallel with major changes in the tertiary structure. The dimer binds bis(8-anilinonaphthalene-1-sulfonate), and pressure reduces the binding by about 30%, in contrast with the almost complete loss of dye binding in the urea-unfolded state. These results strongly suggest the persistence of substantial residual structure in the high pressure state. Further unfolding of the high pressure state was produced by low concentrations of urea, as evidenced by the complete loss of bis(8-anilinonaphthalene-1-sulfonate) binding with less than 1 M urea. Following pressure dissociation, a partially folded state is also apparent from the distribution of excited state lifetimes of tryptophan. The combined data show that the tryptophans of the protein in the pressure-dissociated state are exposed long enough to undergo solvent relaxation, but the persistence of structure is evident from the observed internal quenching, which is absent in the completely unfolded state. The average rotational relaxation time (derived from polarization and lifetime data) of the pressure-induced monomer is shorter than the urea-denatured state, suggesting that the species obtained under pressure are more compact than that unfolded by urea.

How Cro and lambda-repressor distinguish between operators: the structural basis underlying a genetic switch

Knowledge of the three-dimensional structures of the lambda-Cro and lambda-repressor proteins in complex with DNA has made it possible to evaluate how these proteins discriminate between different operators in phage lambda. As anticipated in previous studies, the helix-turn-helix units of the respective proteins bind in very different alignments. In Cro the recognition helices are 29 A apart and are tilted by 55 degrees with respect to each other, but bind parallel to the major groove of the DNA. In lambda-repressor [Beamer, L. J. & Pabo, C. O. (1992) J. Mol. Biol. 227, 177-196] the helices are 34 A apart and are essentially parallel to each other, but are inclined to the major grooves. The DNA is much more bent when bound by Cro than in the case with lambda-repressor. The first two amino acids of the recognition helices of the two proteins, Gln-27 and Ser-28 in Cro, and Gln-44 and Ser-45 in lambda-repressor, make very similar interactions with the invariant bps 2 and 4. There are also analogous contacts between the thymine of bp 5 and, respectively, the backbone of Ala-29 of Cro and the backbone of Gly-46 of lambda-repressor. Otherwise, however, unrelated parts of the two proteins are used in sequence-specific recognition. It appears that similar contacts to the invariant or almost invariant bps (especially 2 and 4) are used by both Cro and lambda-repressor to differentiate the operator sites as a group from other sites on the DNA. The discrimination of Cro and lambda-repressor between their different operators is more subtle and seems to be achieved primarily through differences in van der Waals contacts at bp 3', together with weaker, less direct effects at bps 5' and 8', all in the nonconsensus half of the operators. The results provide further support for the idea that there is no simple code for DNA-protein recognition.

Subunit rearrangement accompanies sequence-specific DNA binding by the bovine papillomavirus-1 E2 protein

The 2.5 A crystal structures of the DNA-binding domain of the E2 protein from bovine papillomavirus strain 1 and its complex with DNA are presented. E2 is a transcriptional regulatory protein that is also involved in viral DNA replication. It is the structural prototype for a novel class of DNA-binding proteins: dimeric beta-barrels with surface alpha-helices that serve as recognition helices. These helices contain the amino-acid residues involved in sequence-specifying interactions. The E2 proteins from different papillomavirus strains recognize and bind to the same consensus 12 base-pair DNA sequence. However, recent evidence from solution studies points to differences in the mechanisms by which E2 from the related viral strains bovine papillomavirus-1 and human papillomavirus-16 discriminate between DNA targets based on non-contacted nucleotide sequences. This report provides evidence that sequence-specific DNA-binding is accompanied by a rearrangement of protein subunits and deformation of the DNA. These results suggest that, along with DNA sequence-dependent conformational properties, protein subunit orientation plays a significant role in the mechanisms of target selection utilized by E2.

Dimerization of the UmuD' protein in solution and its implications for regulation of SOS mutagenesis

NMR spectroscopy has been used to determine that the dimerization interface of UmuD' in solution is not the homodimer interface originally inferred from crystallographic data. Instead, it resembles an interface that had been hypothesized to be involved in filamentation.

Interaction of the bacteriophage Mu transcriptional activator protein, C, with its target site in the mom promoter

The bacteriophage Mu C gene encodes a 16.5 kDa site-specific DNA binding protein that is a transcriptional activator of the four "late" promoters, Pmom, Plys, PI and PP. A symmetrical consensus C recognition sequence, TTAT[N5-6]ATAA, containing an inverted tetrad repeat separated by a spacer of five to six G+C-rich nucleotides, has been proposed. To investigate this, we used oligonucleotide mutagenesis to introduce random substitutions within and flanking the proposed C-target region; each variant site was tested for C recognition by an in vivo functional transactivation assay. We observed that all single mutations, in either tetrad, reduced C activation. Although two out of ten substitutions within the spacer reduced activation, the spacer region does not appear to make specific contact with C. We also used in vitro chemical-protection and -interference to study C contacts with Pmom. The results indicate that C contacts Pmom DNA on only one face of the helix through interactions within two adjacent major grooves; this conclusion was supported by gel shift analyses using synthetic oligonucleotide duplexes containing I.C or other base-pair substitutions. Evidence is also presented that C-Pmom contacts are asymmetrical, and that they extend two nucleotides 3' to the promoter-proximal tetrad. We also show that C binding induces a deformation, possibly a bend, in Pmom DNA.

Organization and regulation of the D-xylose operons in Escherichia coli K-12: XylR acts as a transcriptional activator

The metabolism of D-xylose in Escherichia coli K-12 is known to be mediated by the xylAB gene. However, the nearby xylFGHR genes were found by genome sequencing and predicted to be responsible for transport and regulation for xylose based on their sequence similarities to other functionally related genes. Here, we investigated transcriptional organization and functions of the xyl genes. An analysis with random transposon insertions revealed that the xyl genes are organized into two major transcriptional units, xylAB and xylFGHR, governed by the promoters PA and PF, respectively. However, there is an additional weak promoter, PR, which is specific for xylR. Sites of transcription initiation were determined by primer extension analysis. When studied with operon fusions to lacZ, the PA and PF promoters were activated by D-xylose and repressed by glucose. In contrast, the PR promoter was not regulated by these sugars. A mutation in xylR completely abolished expression from the PA and PF promoters, causing a defect in both growth and transport. Binding of XylR to the xyl promoter was enhanced by the presence of D-xylose, suggesting that transcription was positively regulated by XylR. In vivo footprinting analysis revealed that XylR binds to at least two DNA regions, IA and IF, each with a direct repeat. It is very likely that XylR interacts with IA and IF as a dimer. The presumed binding sites are located just upstream of the promoter consensus sequences (-35), while IA is additionally flanked by a cyclic AMP receptor protein-binding site on the other side. The proposed structure of xyl promoters is consistent with the regulation of xyl gene expression and with phenotypes of transposon insertions obtained in the promoter regions.

DNA recognition and bending

DNA-binding proteins recognize their DNA targets not only through the formation of specific contacts with the nucleotide bases but also through inherent properties of the DNA sequence, including increased bendability and rigidity. Consideration of the properties of both the protein and the DNA is required before the sequence specificity and the observed DNA bend in DNA-protein complexes can be understood.

Contacts between Bacillus subtilis catabolite regulatory protein CcpA and amyO target site

Catabolite control protein A (CcpA) is a global regulatory protein involved in catabolite repression and glucose activation in Gram-positive bacteria. cis -Acting DNA sequences, catabolite response elements ( cre s), involved in this regulatory system contain a 14 base pair (bp) region of dyad symmetry. CcpA, a repressor of the Lac I family, has been shown to bind specifically to cre s. To better understand cre recognition by CcpA, we have focused on the interaction between CcpA and the amyE cre , called amyO, which is located at the transcription start site of the alpha-amylase gene. DNA-protein complexes were probed with dimethylsulfate (DMS) and N -ethylnitrosourea (EtNU) to identify guanines and phosphates that participate in complex formation. Interaction between amyO and CcpA visualized through methylation protection and interference showed that CcpA contacts guanine residues at the outer bounds of amyO with higher affinity than near the dyad axis. From ethylation interference studies, it was found that CcpA contacts three phosphate groups at each end of amyO, and one or two phosphate groups near the dyad axis. Exonuclease III protection revealed that CcpA protects a 26 bp region centered around the dyad axis of amyO. The isolated N-terminal fragment still specifically bound to the sequence resembling the half sites of the amyO sequence. Considering these findings and the helical structure of B-DNA, our results suggest that each of the two monomers of the CcpA molecule contact the major groove in each half of the region of dyad symmetry and that the contacts are on the same face of the DNA helix, which is typical of bacterial repressor-operator interactions. However, the absence of strong contacts near the dyad axis by CcpA is in contrast to the situation with the gal repressor, another member of the Lac I family of repressors.

NMR chemical shift perturbation mapping of DNA binding by a zinc-finger domain from the yeast transcription factor ADR1

Mutagenesis studies have revealed that the minimal DNA-binding domain of the yeast transcription factor ADR1 consists of two Cys2-His2 zinc fingers plus an additional 20 residues proximal and N-terminal to the fingers. We have assigned NMR 1H, 15N, and 13C chemical shifts for the entire minimal DNA-binding domain of ADR1 both free and bound to specific DNA. 1H chemical shift values suggest little structural difference between the zinc fingers in this construct and in single-finger constructs, and 13C alpha chemical shift index analysis indicates little change in finger structure upon DNA binding. 1H chemical shift perturbations upon DNA binding are observed, however, and these are mapped to define the protein-DNA interface. The two zinc fingers appear to bind DNA with different orientations, as the entire helix of finger 1 is perturbed, while only the extreme N-terminus of the finger 2 helix is affected. Furthermore, residues N-terminal to the first finger undergo large chemical shift changes upon DNA binding suggesting a role at the protein-DNA interface. A striking correspondence is observed between the protein-DNA interface mapped by chemical shift changes and that previously mapped by mutagenesis.

Engrailed (Gln50-->Lys) homeodomain-DNA complex at 1.9 A resolution: structural basis for enhanced affinity and altered specificity

BACKGROUND

The homeodomain is one of the key DNA-binding motifs used in eukaryotic gene regulation, and homeodomain proteins play critical roles in development. The residue at position 50 of many homeodomains appears to determine the differential DNA-binding specificity, helping to distinguish among binding sites of the form TAATNN. However, the precise role(s) of residue 50 in the differential recognition of alternative sites has not been clear. None of the previously determined structures of homeodomain-DNA complexes has shown evidence for a stable hydrogen bond between residue 50 and a base, and there has been much discussion, based in part on NMR studies, about the potential importance of water-mediated contacts. This study was initiated to help clarify some of these issues.

RESULTS

The crystal structure of a complex containing the engrailed Gln50-->Lys variant (QK50) with its optimal binding site TAATCC (versus TAATTA for the wild-type protein) has been determined at 1.9 A resolution. The overall structure of the QK50 variant is very similar to that of the wild-type complex, but the sidechain of Lys50 projects directly into the major groove and makes several hydrogen bonds to the O6 and N7 atoms of the guanines at base pairs 5 and 6. Lys50 also makes an additional water-mediated contact with the guanine at base pair 5 and has an alternative conformation that allows a hydrogen bond with the O4 of the thymine at base pair 4.

CONCLUSIONS

The structural context provided by the folding and docking of the engrailed homeodomain allows Lys50 to make remarkably favorable contacts with the guanines at base pairs 5 and 6 of the binding site. Although many different residues occur at position 50 in different homeodomains, and although numerous position 50 variants have been constructed, the most striking examples of altered specificity usually involve introducing or removing a lysine sidechain from position 50. This high-resolution structure also confirms the critical role of Asn51 in homeodomain-DNA recognition and further clarifies the roles of water molecules near residues 50 and 51.

An aromatic stacking interaction between subunits helps mediate DNA sequence specificity: operator site discrimination by phage lambda cI repressor

Sequence specific DNA binding by regulatory proteins provides the basis for regulation of initiation of transcription. A great deal of progress has been made toward understanding sequence specific recognition by individual protein subunits. An additional level of control that needs to be understood is that due to coupling between the subunits of oligomeric regulatory proteins. An example is the bacteriophage lambda cI repressor, a dimeric protein that regulates the lysogenic to lytic genetic switch of the phage. Two levels of specificity are critical to this regulation. First, like all transcriptional regulators, dimers distinguish operator from nonspecific DNA. Direct readout of the DNA sequence by the recognition helix is considered the well understood mechanism for this. However, differential affinity for O(R)1, O(R)2 and O(R)3 is equally critical to the switch because it mediates opposing regulation of divergent promoters. Site specificity at this second level is less well understood. Conformational adaptation by both the repressor and the different operators appears to be important. To evaluate how subunit-subunit interactions are involved in this process, we investigated the effects on both dimer stability and operator binding of amino acid substitutions at the contacts between the symmetrically related helices-5 in the dimer interface. Substitutions for Tyr88 alter dimer stability and greatly perturb differential operator affinity, but generally do not affect operator versus non-operator specificity. The pattern of these effects suggests that the geometry of the face-to-face aromatic stacking interaction between symmetrically related Tyr88 in each subunit, a group in the dimer interface but far removed from the DNA binding interface, plays a critical role in operator discrimination. Conformational changes in the tertiary structure of the subunits appears to be involved. By contrast, the significant effect of I84S substitution is to greatly decrease affinity for all three operators. Presumably, the altered packing of the dimer interface causes a quarternary structural change that moves the two helix-turn-helix motifs out of register with successive DNA major grooves.

Crystal structure of the DNA-binding domain of Mbp1, a transcription factor important in cell-cycle control of DNA synthesis

BACKGROUND

During the cell cycle, cells progress through four distinct phases, G1, S, G2 and M; transcriptional controls play an important role at the transition between these phases. MCB-binding factor (MBF), a transcription factor from budding yeast, binds to the so-called MCB (MluI cell-cycle box) elements found in the promoters of many DNA synthesis genes, and activates the transcription of those at the G1-->S phase transition. MBF is comprised of two proteins, Mbp1 and Swi6.

RESULTS

The three-dimensional structure of the N-terminal DNA-binding domain of Mbp1 has been determined by multiwavelength anomalous diffraction from crystals of the selenomethionyl variant of the protein. The structure is composed of a six-stranded beta sheet interspersed with two pairs of alpha helices. The most conserved core region among Mbp1-related transcription factors folds into a central helix-turn-helix motif with a short N-terminal beta strand and a C-terminal beta hairpin.

CONCLUSIONS

Despite little sequence similarity, the structure within the core region of the Mbp1 N-terminal domain exhibits a similar fold to that of the DNA-binding domains of other proteins, such as hepatocyte nuclear factor-3gamma and histone H5 from eukaryotes, and the prokaryotic catabolite gene activator. However, the structure outside the core region defines Mbp1 as a larger entity with substructures that stabilize and display the helix-turn-helix motif.

Lac repressor-operator complex

For many years the lac operon of Escherichia coli has been the paradigm for gene regulation. Recently, the structures of the lac repressor core bound to isopropyl-beta-D-1-thiogalactoside (IPTG), the intact apo lac repressor, the intact lac repressor complexes with IPTG and a 21-base-pair symmetric operator, and the refined headpiece of the repressor have been determined. These structures have provided a framework for understanding a wealth of biochemical and genetic information. An analysis of these structures, as well as a description of their function and a comparison to homologous proteins, is now possible.

The activation defect of a lambda cI positive control mutant

"Positive control" mutants of the cI protein of bacteriophage lambda (lambda cI) bind DNA but, unlike the wild-type protein, fail to activate transcription. According to the original interpretation of Ptashne and co-workers, these mutants bear amino acid substitutions that disrupt a stimulatory interaction between lambda cI bound at operator site O(R)2 and RNA polymerase bound at promoter P(RM), an idea supported by kinetic analysis in one case. Genetic analysis has suggested that one residue in particular, glutamate 34 (E34), is critical for the stimulatory effect of wild-type lambda cI. More recently, however, Kolkhof and Muller-Hill have challenged this view, suggesting that mutant E34K fails to activate because it binds at unusually low concentrations to O(R)3, a site that mediates repression of P(RM). To test this hypothesis, we have examined the behaviour of the lambda cI-E34K mutant both in vitro and in vivo by assaying transcription from P(RM) and monitoring operator site occupancy over a range of protein concentrations. Our results are inconsistent with the interpretation of Kolkhof and Muller-Hill, and demonstrate that under conditions where lambda operator O(R)2 is fully occupied and operator O(R)3 is vacant, wild-type lambda cI activates transcription from promoter P(RM) whereas the mutant does not.

The leucine zipper domain controls the orientation of AP-1 in the NFAT.AP-1.DNA complex

BACKGROUND

Heterologous transcription factors bound to adjacent sites in eukaryotic promoters often exhibit cooperative behavior. In most instances, the molecular basis for this cooperativity is poorly understood. Our efforts have been directed toward elucidation of the mechanism of cooperativity between NFAT and AP-1, two proteins that coordinately direct expression of the T-cell growth factor interleukin-2 (IL-2).

RESULTS

We have previously shown that NFAT1 orients the two subunits of AP-1, c-Jun and c-Fos, on DNA through direct protein-protein interactions. In the present study, we have constructed cJun-cFos chimeric proteins and determined their orientation using a novel affinity-cleavage technology based on chemical ligation. We find that, in the presence of NFAT, the chimeric heterodimer binds in such a way as to preserve the orientation of the AP-1 leucine zipper, but not that of the basic region.

CONCLUSIONS

Protein-protein interactions between NFAT and the leucine zipper of AP-1 enable the two proteins to bind DNA cooperatively and coordinately regulate the IL-2 promoter. The chemical ligation technology presented here provides a powerful strategy for affinity cleavage studies, including those using recombinant proteins.

Characterization of the locus responsible for the bacteriocin production in Lactobacillus plantarum C11

Lactobacillus plantarum C11 secretes a small cationic peptide, plantaricin A, that serves as induction signal for bacteriocin production as well as transcription of plnABCD. The plnABCD operon encodes the plantaricin A precursor (PlnA) itself and determinants (PlnBCD) for a signal transducing pathway. By Northern (RNA) and sequencing analyses, four new plantaricin A-induced operons were identified. All were highly activated in concert with plnABCD upon bacteriocin induction. Two of these operons (termed plnEFI and plnJKLR) each encompass a gene pair (plnEF and plnJK, respectively) encoding two small cationic bacteriocin-like peptides with double-glycine-type leaders. The open reading frames (ORFs) encoding the bacteriocin-like peptides are followed by ORFs (plnI and -L, respectively) encoding cationic hydrophobic proteins resembling bacteriocin immunity proteins. On the third operon (termed plnMNOP), a similar bacteriocin-like ORF (plnN) and a putative immunity ORF (either plnM or -P) were identified as well. These findings suggest that two bacteriocins of two-peptide type (mature PlnEF and PlnJK) and a bacteriocin of one-peptide type (mature PlnN) could be responsible for the observed bacteriocin activity. The last operon (termed plnGHSTUV) contains two ORFs (plnGH) apparently encoding an ABC transporter and its accessory protein, respectively, known to be involved in processing and export of peptides with precursor double-glycine-type leaders. Promoter structure was established. A conserved regulatory-like box encompassing two direct repeats was identified in the promoter regions of all five plantaricin A-induced operons. These repeats may serve as regulatory elements for gene expression.

Preparation and properties of pure, full-length IclR protein of Escherichia coli. Use of time-of-flight mass spectrometry to investigate the problems encountered

IclR protein, the repressor of the aceBAK operon of Escherichia coli, has been examined by time-of-flight mass spectrometry, with ionization by matrix assisted laser desorption or by electrospray. The purified protein was found to have a smaller mass than that predicted from the base sequence of the cloned iclR gene. Additional measurements were made on mixtures of peptides derived from IclR by treatment with trypsin and cyanogen bromide. They showed that the amino acid sequence is that predicted from the gene sequence, except that the protein has suffered truncation by removal of the N-terminal eight or, in some cases, nine amino acid residues. The peptide bond whose hydrolysis would remove eight residues is a typical target for the E. coli protease OmpT. We find that, by taking precautions to minimize Omp T proteolysis, or by eliminating it through mutation of the host strain, we can isolate full-length IclR protein (lacking only the N-terminal methionine residue). Full-length IclR is a much better DNA-binding protein than the truncated versions: it binds the aceBAK operator sequence 44-fold more tightly, presumably because of additional contacts that the N-terminal residues make with the DNA. Our experience thus demonstrates the advantages of using mass spectrometry to characterize newly purified proteins produced from cloned genes, especially where proteolysis or other covalent modification is a concern. This technique gives mass spectra from complex peptide mixtures that can be analyzed completely, without any fractionation of the mixtures, by reference to the amino acid sequence inferred from the base sequence of the cloned gene.

The crystal structure of the DNA-binding domain of yeast RAP1 in complex with telomeric DNA

Telomeres, the nucleoprotein complexes at the ends of eukaryotic chromosomes, are essential for chromosome stability. In the yeast S. cerevisiae, telomeric DNA is bound in a sequence-specific manner by RAP1, a multifunctional protein also involved in transcriptional regulation. Here we report the crystal structure of the DNA-binding domain of RAP1 in complex with telomeric DNA site at 2.25 A resolution. The protein contains two similar domains that bind DNA in a tandem orientation, recognizing a tandemly repeated DNA sequence. The domains are structurally related to the homeodomain and the proto-oncogene Myb, but show novel features in their DNA-binding mode. A structured linker between the domains and a long C-terminal tail contribute to the binding specificity. This structure provides insight into the recognition of the conserved telomeric DNA sequences by a protein.

A possible tertiary structure change induced by acrylamide in the DNA-binding domain of the Tn10-encoded Tet repressor. A fluorescence study

A thorough investigation of the acrylamide fluorescence quenching of F75TetR, a mutant of the Tn10-encoded TetR repressor containing a single Trp residue at position 43, was carried out. The Trp-43 residue is located in a helix alpha-turn-helix alpha (H-t-H) motif involved in the specific binding of F75TetR to the operator site in specific DNA. Distinct Ranges of acrylamide concentration have been assumed. At acrylamide concentrations below 0.15-0.2 M (a usual range of values in fluorescence quenching studies) the observed limited tertiary structure change induced by acrylamide is consistent with a noncooperative local unfolding of the DNA-binding domain. It is suggested that penetration of the neutral quencher could cause the deletion of a hydrophobic tertiary structure contact, partly involving TrP-43, responsible for the anchoring of the H-t-H motif inside the three-helix protein bundle, characterizing the N-terminal part. Correspondingly, the affinity of the mutant repressor for the operator was shown to decrease substantially (about five orders of magnitude), seemingly losing its specificity. A subsequent phase, up to 0.8 M acrylamide, was observed in which the involved intermediate protein structure is not further perturbed, nor is DNA binding.

The EcoRV modification methylase causes considerable bending of DNA upon binding to its recognition sequence GATATC

The EcoRV methyltransferase modifies DNA by the introduction of a methyl group at the 6-NH2 position of the first deoxyadenosine in GATATC sequences. The enzyme forms a stable and specific complex with GATATC sequences in the presence of a nonreactive analogue, such as sinefungin, of its natural cofactor S-adenosyl-L-methionine. Using circular permutation band mobility shift analysis (in which the distance between the GATATC sequence and the end of the DNA is varied) of protein-DNA-cofactor complexes we have shown the methylase induces a bend of just over 60 degrees in the bound DNA. This was confirmed by phasing analysis, in which the spacing between the GATATC site and a poly(dA) tract is varied through a helical turn, which showed that the orientation of the induced curve was toward the major groove. There was no significant difference in the bend angle measured using unmethylated GATATC sequences and hemimethylated sequences which contain G6-Me ATATC in one strand only. These are the natural substates for the enzyme. The EcoRV endonuclease, a very well characterized protein, served as a positive control. DNA bending by this protein has been previously determined both by crystallographic and solution methods. The two proteins bend DNA toward the major groove but the bend angle produced by the methylase, slightly greater than 60 degree, is a little larger than that observed with the endonuclease, which is approximately 44 degrees.

Oct-1 POU domain-DNA interactions: cooperative binding of isolated subdomains and effects of covalent linkage

Structural and biochemical studies of Oct-1 POU domain-DNA interactions have raised important questions about cooperativity and the role of the linker connecting the POU-specific domain and the POU homeo domain. To analyze these interactions, we have studied binding of the isolated domains. Surprisingly, we find that two unlinked polypeptides corresponding to the POU-specific domain and the POU homeo domain bind cooperatively to the octamer site and have a coupling energy of 1.6 kcal/mole. We suggest that overlapping DNA contacts near the center of the octamer site may be the source of this cooperativity, as there are no protein-protein contacts between the domains in the crystal structure of the Oct-1 POU domain-DNA complex. These studies also have allowed us to describe the thermodynamic contribution of the linker (present in the intact POU domain) in terms of an effective concentration (3.6 mM). The broader implications for understanding cooperativity in protein-DNA recognition and gene regulation are discussed.

Specific binding of the replication protein of plasmid pPS10 to direct and inverted repeats is mediated by an HTH motif

The initiator protein of the plasmid pPS10, RepA, has a putative helix-turn-helix (HTH) motif at its C-terminal end. RepA dimers bind to an inverted repeat at the repA promoter (repAP) to autoregulate RepA synthesis. [D. García de Viedma, et al. (1996) EMBO J. in press]. RepA monomers bind to four direct repeats at the origin of replication (oriV) to initiate pPS10 replication This report shows that randomly generated mutations in RepA, associated with defficiencies in autoregulation, map either at the putative HTH motif or in its vicinity. These mutant proteins do not promote pPS10 replication and are severely affected in binding to both the repAP and oriV regions in vitro. Revertants of a mutant that map in the vicinity of the HTH motif have been obtained and correspond to a second amino acid substitution far upstream of the motif. However, reversion of mutants that map in the helices of the motif occurs less frequently, at least by an order of magnitude. All these data indicate that the helices of the HTH motif play an essential role in specific RepA-DNA interactions, although additional regions also seem to be involved in DNA binding activity. Some mutations have slightly different effects in replication and autoregulation, suggesting that the role of the HTH motif in the interaction of RepA dimers or monomers with their respective DNA targets (IR or DR) is not the same.

Binding geometry of alpha-helices that recognize DNA

Many transcription factors have an alpha-helix that binds to DNA bases in a specific fashion. The DNA-binding geometry of these recognition helices varies substantially. We define a set of parameters to describe the binding geometry of recognition helices and analyze specific stereochemical elements that determine particular geometries. Because the convex surface of the helix must fit into the concave surface of the DNA major groove, the number of degrees of freedom of the recognition helix is reduced from a possible six to a single angle, which we call alpha. The chemically interacting DNA bases and amino acid residues must lie along a common line and have the same spacing along it. This pairing of base positions with residue positions seems to restrict the binding geometry further to a set of discrete values for alpha.

Structural comparison of the free and DNA-bound forms of the purine repressor DNA-binding domain

BACKGROUND

The purine repressor (PurR) regulates genes that encode enzymes for purine biosynthesis. PurR has a two domain structure with an N-terminal DNA-binding domain (DBD) and a C-terminal corepressor-binding domain (CBD). The three dimensional structure of a ternary complex of PurR bound to both corepressor and a specific DNA sequence has recently been determined by X-ray crystallography.

RESULTS

We have determined the solution structure of the PurR DBD by NMR. It contains three helices, with the first and second helices forming a helix-turn-helix motif. The tertiary structure of the three helices is very similar to that of the corresponding region in the ternary complex. The structure of the hinge helical region, however, which makes specific base contacts in the minor groove of DNA, is disordered in the DNA-free form.

CONCLUSION

The stable formation of PurR hinge helices requires PurR dimerization, which brings the hinge regions proximal to each other. The dimerization of the hinge helices is likely to be controlled by the CBD dimerization interface, but is induced by specific-DNA binding.

sigma E changed to sigma B specificity by amino acid substitutions in its -10 binding region

The association of a sigma factor (sigma) with RNA polymerase in bacteria determines its specificity of promoter utilization. To identify amino acid residues in sigma E from Bacillus subtilis that determine the specificity of its interaction with the nucleotides at the -10 region of its cognate promoters, we tested whether base pair substitutions in the -10 region of a sigma B-dependent promoter could signal its utilization by sigma E-RNA polymerase. We found that a combination of base pair substitutions at positions -15 and -14 of the sigma B-dependent ctc promoter resulted in its utilization by sigma E-RNA polymerase in vivo. We also found that the combination of two amino acid substitutions at positions 119 and 120 in sigma E changed its specificity for promoter utilization, resulting in a sigma factor that directed transcription from the sigma B-dependent ctc promoter, but not from sigma E-dependent promoters. These results suggest that amino acid residues at positions 119 and 120 determine, at least in part, the specificity of interactions between sigma E and the nucleotides in the -10 region of its cognate promoters.

The solution structure of the Mu Ner protein reveals a helix-turn-helix DNA recognition motif

BACKGROUND

The Mu Ner protein is a small (74 amino acids), basic, DNA-binding protein found in phage Mu. It belongs to a class of proteins, the cro and repressor proteins, that regulate the switch from the lysogenic to the lytic state of the phage life cycle. There is no significant sequence identity between Mu Ner and the cro proteins of other phages, despite their functional similarity. In addition, there is no significant sequence identity with any other DNA-binding proteins, with the exception of Ner from the related phage D108 and the Nlp protein of Escherichia coli. As the tertiary structures of Mu Ner and these two related proteins are unknown, it is clear that a three-dimensional (3D) structure of Mu Ner is essential in order to gain insight into its mode of DNA binding.

RESULTS

The 3D solution structure of Mu Ner has been solved by 3D and 4D heteronuclear magnetic resonance spectroscopy. The structure consists of five alpha helices, two of which comprise a helix-turn-helix (HTH) motif. Analysis of line broadening and disappearance of crosspeaks in a 1H-15N correlation spectrum of the Mu Ner-DNA complex suggests that residues in these two helices are most likely to be in contact with the DNA.

CONCLUSIONS

Like the functionally analogous cro proteins from phages lambda and 434, the Mu Ner protein possesses a HTH DNA recognition motif. The Ner protein from phage D108 and the Nlp protein from E. coli are likely to have very similar tertiary structures due to high amino-acid-sequence identity with Mu Ner.

Structures of the apo- and the metal ion-activated forms of the diphtheria tox repressor from Corynebacterium diphtheriae

The diphtheria tox repressor (DtxR) of Corynebacterium diphtheriae plays a critical role in the regulation of diphtheria toxin expression and the control of other iron-sensitive genes. The crystal structures of apo-DtxR and of the metal ion-activated form of the repressor have been solved and used to identify motifs involved in DNA and metal ion binding. Residues involved in binding of the activated repressor to the diphtheria tox operator, glutamine 43, arginine 47, and arginine 50, were located and confirmed by site-directed mutagenesis. Previous biochemical and genetic data can be explained in terms of these structures. Conformational differences between apo- and Ni-DtxR are discussed with regard to the mechanism of action of this repressor.

Classification of multi-helical DNA-binding domains and application to predict the DBD structures of sigma factor, LysR, OmpR/PhoB, CENP-B, Rapl, and Xy1S/Ada/AraC

We have systematically compared structures of multi-helical DNA-binding domains (DBDs) which have been determined by crystallography or NMR spectroscopy. All the known multi-helical DBDs are very similar. The core of these structures consists of two alpha-helices in the helix-turn-helix combination, associated with one or two other helices. The structures can be classified according to either additional structural compositions or the configuration of the helices. Many DBDs, whose structures are currently unknown, have sequences which resemble those of known structures, permitting outlines of the new structures to be predicted.

DNA determinants in sequence-specific recognition by XmaI endonuclease

The XmaI endonuclease recognizes and cleaves the sequence C decreases CCGGG. Magnesium is required for catalysis, however, the enzyme forms stable, specific complexes with DNA in the absence of magnesium. An association constant of 1.2 x 10(9)/M was estimated for the affinity of the enzyme for a specific 195 bp fragment. Competition assays revealed that the site-specific association constant represented an approximately 10(4)-fold increase in affinity over that for non-cognate sites. Missing nucleoside analyses suggested an interaction of the enzyme with each of the cytosines and guanines within the recognition site. Recognition of each of the guanines was also indicated by dimethylsulfate interference footprinting assays. The phosphates 5' to the guanines within the recognition site appeared to be the major sites of interaction of XmaI with the sugar-phosphate backbone. No significant interaction of the protein was observed with phosphates flanking the recognition sequence. Comparison of the footprinting patterns of XmaI with those of the neoschizomer SmaI (CCC decreases GGG) revealed that the two enzymes utilize the same DNA determinants in their specific interaction with the CCCGGG recognition site.

Mutation of the Oct-1 POU-specific recognition helix leads to altered DNA binding and influences enhancement of adenovirus DNA replication

To assess which residues of Oct-1 POU-specific (POUs) are important for DNA recognition and stimulation of adenovirus DNA replication we have mutated 10 residues of the POUs helix-turn-helix motif implicated in DNA contact. Seven of these turned out to have reduced DNA binding affinity. Of these, three alanine substituted proteins were found to have a changed specificity using a binding site selection procedure. Mutation of the first residue in the recognition helix, Gln44, to alanine led to a loss of specificity for the first two bases, TA, of the wild-type recognition site TATGC(A/T)AAT. Instead of the A, a T was selected, suggesting a new contact and a novel specificity. A change in specificity was also observed for the T45A mutant, which could bind to TATAC(A/T)AAT, a site hardly recognized by the wild-type protein. Mutation of residue Arg49 led to a relaxed specificity for three consecutive bases, TGC. This residue, which is critical for high affinity binding, is absent from the structurally homologous lambdoid helix-turn-helix motifs. Employing a reconstituted system all but two mutants could stimulate adenovirus DNA replication upon saturation. Mutation of residues Gln27 and Arg49 impairs the ability of the Oct-1 POU domain protein to enhance replication, with a concomitant loss of DNA contacts. Since the POU domain binds the precursor terminal protein-DNA polymerase complex and guides it to the origin, lack of stimulation may be caused by incorrect targetting of the DNA polymerase due to loss of specificity.

Structure of Bam HI endonuclease bound to DNA: partial folding and unfolding on DNA binding

The crystal structure of restriction endonuclease Bam HI complexed to DNA has been determined at 2.2 angstrom resolution. The DNA binds in the cleft and retains a B-DNA type of conformation. The enzyme, however, undergoes a series of conformational changes, including rotation of subunits and folding of disordered regions. The most striking conformational change is the unraveling of carboxyl-terminal alpha helices to form partially disordered "arms." The arm from one subunit fits into the minor groove while the arm from the symmetry related subunit follows the DNA sugar-phosphate backbone. Recognition of DNA base pairs occurs primarily in the major groove, with a few interactions occurring in the minor groove. Tightly bound water molecules play an equally important role as side chain and main chain atoms in the recognition of base pairs. The complex also provides new insights into the mechanism by which the enzyme catalyzes the hydrolysis of DNA phosphodiester groups.

Salt effects on polyelectrolyte-ligand binding: comparison of Poisson-Boltzmann, and limiting law/counterion binding models

The theory for salt dependence of the free energy, entropy, and enthalpy of a polyelectrolyte in the PB (PB) model is extended to treat the nonspecific salt dependence of polyelectrolyte-ligand binding reactions. The salt dependence of the binding constant (K) is given by the difference in osmotic pressure terms between the reactants and products. For simple 1-1 salts it is shown that this treatment is equivalent to the general preferential interaction model for the salt dependence of binding [C. Anderson and M. Record (1993) Journal of Physical Chemistry, Vol. 97, pp. 7116-7126]. The salt dependence, entropy, and enthalpy are compared for the PB model and one specific form of the preferential interaction coefficient model that uses counterion condensation/limiting law (LL) behavior. The PB and LL models are applied to three ligand-polyelectrolyte systems with the same net ligand charge: a model sphere-cylinder binding reaction, a drug-DNA binding reaction, and a protein-DNA binding reaction. For the small ligands both the PB and limiting law models give (In K vs. In[salt]) slopes close in magnitude to the net ligand charge. However, the enthalpy/entropy breakdown of the salt dependence is quite different. In the PB model there are considerable contributions from electrostatic enthalpy and dielectric (water reorientation) entropy, compared to the predominant ion cratic (release) entropy in the limiting law model. The relative contributions of these three terms in the PB model depends on the ligand: For the protein, ion release entropy is the smallest contribution to the salt dependence of binding. The effect of three approximations made in the LL model is examined: These approximations are (1) the ligand behaves ideally, (2) the preferential interaction coefficient of the polyelectrolyte is unchanged upon ligand binding, and (3) the polyelectrolyte preferential interaction coefficient is given by the limiting law/counterion-condensation value. Analysis of the PB model shows that assumptions 2 and 3 break down at finite salt concentrations. For the small ligands the effects on the slope cancel, however, giving net slopes that are similar in the PB and LL models, but with a different entropy/enthalpy breakdown. For the protein ligand the errors from assumptions 2 and 3 in the LL models do not cancel.

Gene regulatory proteins and their interaction with DNA

The selective expression of a gene is achieved through the interaction of protein transcription factors with characteristic DNA sequences located in the regulatory region of the gene, which is usually distinct from the coding region. These proteins contain domains that bind specifically to the DNA sites (or response elements). Some general principles in the design of these DNA-binding domains are described, followed by examples of the different structural classes discovered so far and how they recognize their binding sites.

Base-pair opening and spermine binding--B-DNA features displayed in the crystal structure of a gal operon fragment: implications for protein-DNA recognition

A sequence that is represented frequently in functionally important sites involving protein-DNA interactions is GTG/CAC, suggesting that the trimer may play a role in regulatory processes. The 2.5 A resolution structure of d(CGGTGG)/d(CCACCG), a part of the interior operator (OI, nucleotides +44 to +49) of the gal operon, co-crystallized with spermine, is described herein. The crystal packing arrangement in this structure is unprecedented in a crystal of B-DNA, revealing a close packing of columns of stacked DNA resembling a 5-stranded twisted wire cable. The final structure contains one hexamer duplex, 17 water molecules and 1.5 spermine molecules per crystallographic asymmetric unit. The hexamer exhibits base-pair opening and shearing at T.A resulting in a novel non-Watson-Crick hydrogen-bonding scheme between adenine and thymine in the GTG region. The ability of this sequence to adopt unusual conformations in its GTG region may be a critical factor conferring sequence selectivity on the binding of Gal repressor. In addition, this is the first conclusive example of a crystal structure of spermine with native B-DNA, providing insight into the mechanics of polyamine-DNA binding, as well as possible explanations for the biological action of spermine.

Synthesis and characterisation of fluorescent oligonucleotides. Effect of internal labelling on protein recognition

Fluorescently labelled 42 base pair DNA duplexes were synthesised to examine the interaction between the TyR repressor protein of Escherichia coli and its DNA recognition sequence. An Fmoc-protected 5-(3-aminoprop-l-yn-l-yl)-2'-deoxyuridine phosphoramidite was synthesised and incorporated into oligonucleotides using standard beta-cyanoethyl phosphoramidite chemistry. Oligonucleotides containing the 3-aminopropynyl nucleotide at internal positions were reacted with fluorescein isothiocyanate to generate fluorescent DNA molecules useful for characterising interactions between DNA and proteins. Short DNA duplexes were investigated with respect to their melting temperatures and their ability to bind TyrR. Oligonucleotides containing a TyrR binding site were labelled in the central region of the recognition sequence or near the 5' edge of the recognition sequence. Fluorescein-labelled oligonucleotides could hybridise to form duplex DNA, and gel retardation experiments showed that the presence of the dye did not alter the binding affinity for the TyrR protein significantly. Fluorescence anisotropy measurements were used to examine the binding equilibrium in low and high salt buffers. A dissociation constant of 200-500 nM was obtained for the interaction of the TyrR dimer with a 42 bp duplex containing a centrally located 22 bp TyrR binding site.

Analysis of local helix bending in crystal structures of DNA oligonucleotides and DNA-protein complexes

Sequence-dependent bending of the helical axes in 112 oligonucleotide duplex crystal structures resident in the Nucleic Acid Database have been analyzed and compared with the use of bending dials, a computer graphics tool. Our analysis includes structures of both A and B forms of DNA and considers both uncomplexed forms of the double helix as well as those bound to drugs and proteins. The patterns in bending preferences in the crystal structures are analyzed by base pair steps, and emerging trends are noted. Analysis of the 66 B-form structures in the Nucleic Acid Database indicates that uniform trends within all pyrimidine-purine and purine-pyrimidine steps are not necessarily observed but are found particularly at CG and GC steps of dodecamers. The results support the idea that AA steps are relatively straight and that larger roll bends occur at or near the junctions of these A-tracts with their flanking sequences. The data on 16 available crystal structures of protein-DNA complexes indicate that the majority of the DNA bends induced via protein binding are sharp localized kinks. The analysis of the 30 available A-form DNA structures indicates that these structures are also bent and show a definitive preference for bending into the deep major groove over the shallow minor groove.

Virus DNA packaging: the strategy used by phage lambda

Phage lambda, like a number of other large DNA bacteriophages and the herpesviruses, produces concatemeric DNA during DNA replication. The concatemeric DNA is processed to produce unit-length, virion DNA by cutting at specific sites along the concatemer. DNA cutting is co-ordinated with DNA packaging, the process of translocation of the cut DNA into the preformed capsid precursor, the prohead. A key player in the lambda DNA packaging process is the phage-encoded enzyme terminase, which is involved in (i) recognition of the concatemeric lambda DNA; (ii) initiation of packaging, which includes the introduction of staggered nicks at cosN to generate the cohesive ends of virion DNA and the binding of the prohead; (iii) DNA packaging, possibly including the ATP-driven DNA translocation; and (iv) following translocation, the cutting of the terminal cosN to complete DNA packaging. To one side of cosN is the site cosB, which plays a role in the initiation of packaging; along with ATP, cosB stimulates the efficiency and adds fidelity to the endonuclease activity of terminase in cutting cosN. cosB is essential for the formation of a post-cleavage complex with terminase, complex I, that binds the prohead, forming a ternary assembly, complex II. Terminase interacts with cosN through its large subunit, gpA, and the small terminase subunit, gpNu1, interacts with cosB. Packaging follows complex II formation. cosN is flanked on the other side by the site cosQ, which is needed for termination, but not initiation, of DNA packaging. cosQ is required for cutting of the second cosN, i.e. the cosN at which termination occurs. DNA packaging in lambda has aspects that differ from other lambda DNA transactions. Unlike the site-specific recombination system of lambda, for DNA packaging the initial site-specific protein assemblage gives way to a mobile, translocating complex, and unlike the DNA replication system of lambda, the same protein machinery is used for both initiation and translocation during lambda DNA packaging.

Architectures of class-defining and specific domains of glutamyl-tRNA synthetase

The crystal structure of a class I aminoacyl-transfer RNA synthetase, glutamyl-tRNA synthetase (GluRS) from Thermus thermophilus, was solved and refined at 2.5 A resolution. The amino-terminal half of GluRS shows a geometrical similarity with that of Escherichia coli glutaminyl-tRNA synthetase (GlnRS) of the same subclass in class I, comprising the class I-specific Rossmann fold domain and the intervening subclass-specific alpha/beta domain. These domains were found to have two GluRS-specific, secondary-structure insertions, which then participated in the specific recognition of the D and acceptor stems of tRNA(Glu) as indicated by mutagenesis analyses based on the docking properties of GluRS and tRNA. In striking contrast to the beta-barrel structure of the GlnRS carboxyl-terminal half, the GluRS carboxyl-terminal half displayed an all-alpha-helix architecture, an alpha-helix cage, and mutagenesis analyses indicated that it had a role in the anticodon recognition.

Structure and stability of monomeric lambda repressor: NMR evidence for two-state folding

The absence of equilibrium intermediates in protein folding reactions (i.e., two-state folding) simplifies thermodynamic and kinetic analyses but is difficult to prove rigorously. We demonstrate a sensitive method for detecting partially folded species based on using proton chemical shifts as local probes of structure. The coincidence of denaturation curves for probes throughout the molecule is a particularly stringent test for two-state folding. In this study we investigate a new form of the N-terminal domain of bacteriophage lambda repressor consisting of residues 6-85 (lambda 6-85) using nuclear magnetic resonance (NMR) and circular dichroism (CD). This truncated version lacks the residues required for dimerization and is monomeric under the conditions used for NMR. Heteronuclear NMR was used to assign the 1H, 15N, and backbone 13C resonances. The secondary and tertiary structure of lambda 6-85 is very similar to that reported for the crystal structure of the DNA-bound 1-92 fragment [Beamer, L. J., and Pabo, C. O. (1992) J. Mol. Biol. 227, 177-196], as judged by analysis of chemical shifts, amide hydrogen exchange, amide-alpha coupling constants, and nuclear Overhauser enhancements. Thermal and urea denaturation studies were conducted using the chemical shifts of the four aromatic side chains as local probes and the CD signal at 222 nm as a global probe. Plots of the fraction denatured versus denaturant concentration obtained from these studies are identical for all probes under all conditions studied. This observation provides strong evidence for two-state folding, indicating that there are no populated intermediates in the folding of lambda 6-85.

Crystal structure of a paired domain-DNA complex at 2.5 A resolution reveals structural basis for Pax developmental mutations

The 2.5 A resolution structure of a cocrystal containing the paired domain from the Drosophila paired (prd) protein and a 15 bp site shows structurally independent N-terminal and C-terminal subdomains. Each of these domains contains a helical region resembling the homeodomain and the Hin recombinase. The N-terminal domain makes extensive DNA contacts, using a novel beta turn motif that binds in the minor groove and a helix-turn-helix unit with a docking arrangement surprisingly similar to that of the lambda repressor. The C-terminal domain is not essential for prd binding and does not contact the optimized site. All known developmental missense mutations in the paired box of mammalian Pax genes map to the N-terminal subdomain, and most of them are found at the protein-DNA interface.

NolR controls expression of the Rhizobium meliloti nodulation genes involved in the core Nod factor synthesis

The synthesis of Rhizobium meliloti Nod signal molecules, encoded by the nod gene products, is finely regulated. A negative control of plasmid-borne nod gene expression is provided by the NolR repressor encoded by the chromosomal nolR gene. NolR was previously shown to downregulate the expression of the activator nodD1 gene and the common nodABC operon by binding to an overlapping region of the two promoters adjacent to the n1 nod-box (Kondorosi et al., 1989). We demonstrate here that NolR also controls the expression of two additional genes, nodD2 and nodM, but does not directly regulate the expression of the host-specific nod genes located downstream of the n2, n3 and n5 nod-boxes. Thus, the nod genes are differentially regulated by NolR and only those providing common nodulation functions, by determining the synthesis of the core Nod factor structure, are subjected to this negative regulation. Furthermore, NolR has a strong negative effect on the production of Nod metabolites, the level of which may serve as a fine-tuning mechanism for optimal nodulation, specific to host-plant genotypes. In addition, it elicits preferential synthesis of Nod factors carrying unsaturated C16 fatty acids. Expression of nolR was high both in the free-living bacterium and in the bacteroid and it was downregulated by its own product and by the nod gene inducer luteolin.