Crystal structure of transcription factor MalT domain III: a novel helix repeat fold implicated in regulated oligomerization.

BACKGROUND: MalT from Escherichia coli, the best-studied member of the MalT family of ATP-dependent transcriptional activators, regulates the genes for malto-oligosaccharide utilization. The active form of this 4 domain protein is a homooligomer, and its multimerization is induced by the binding of maltotriose. Domains II and III of MalT were suggested to mediate the oligomerization process, but its molecular mechanism and the specific functions of these domains remain to be identified. RESULTS: We solved the crystal structure of MalT domain III at 1.45 A resolution by multiple isomorphous replacement phasing. The structure reveals eight copies of a two-helix bundle motif arranged in a novel, right-handed superhelix fold with closed walls, followed by a small C-terminal subdomain. The MalT superhelix contains a potential maltotriose binding site and forms a large hydrophobic protein-protein interaction interface that mediates the contact between two MalT domain III molecules. Structure-based analysis of the two-helix bundle motifs revealed a novel degenerated sequence pattern, and repeats of this pattern could be identified in other regulator proteins. CONCLUSIONS: MalT domain III contains a novel superhelix fold. Its protein-protein interaction interface, however, resembles protein binding sites of other superhelical proteins, suggesting a model with domain III mediating MalT oligomerization. Maltotriose seems to modulate the interaction interface and MalT oligomerization by occupying the ligand binding site inside the superhelix. Similar structural and mechanistic features in other MalT protein-family members and unrelated regulator proteins are indicated by the reappearance of a novel sequence motif derived from the MalT domain III structure.

A complex signaling module governs the activity of MalT, the prototype of an emerging transactivator family.

MalT, the specific activator of the maltose regulon, is the prototype of a family of high-molecular-mass ATP-binding bacterial transcription activators. On binding of its two positive effectors, the inducer maltotriose and ATP, MalT oligomerizes to an active state competent for promoter binding and transcription activation. In addition to its previously known DNA-binding domain, limited proteolysis showed that MalT contains three other domains, the boundaries of which were accurately delimited by N-terminal microsequencing. The N-terminal domain alone binds ATP. Maltotriose binding involves an extended region corresponding to domains 2 and 3, although weak binding to domain 3 alone was also observed. Moreover, maltotriose binding induces a conformational shift involving a movement of both domains 1 and 3 with respect to domain 2, leading to the active form of the protein. Sequence examination of the MalT homologues suggests that these three domains might constitute a signaling module.

Two amino acid residues from the DNA-binding domain of MalT play a crucial role in transcriptional activation.

MalT is the transcriptional activator of the Escherichia coli maltose regulon. Several lines of evidence suggest that MalT might act by interacting with RNA polymerase. Here, we show that 'MalT, the DNA-binding domain of MalT, activates transcription. In order to identify amino acids of 'MalT playing a specific role in activation, and therefore possibly involved in the putative contact(s) with RNA polymerase, we developed a double screen to isolate mutations of the 'malT gene affecting activation by 'MalT without impairing its DNA-binding affinity. The effect of the mutations thus obtained on activation was assessed in vivo. This strategy essentially pointed to serine 834 and glutamine 876 of the MalT amino acid sequence as specifically involved in activation. Various 'MalT derivatives substituted at positions 834 or 876 were purified and tested in vitro for their DNA-binding affinity, as well as for their activation ability. Together, the results obtained clearly show that serine 834 and glutamine 876 are important for activation by 'MalT but not for DNA-binding. We argue that these amino acid residues are possibly solvent-exposed and propose that they act by contacting RNA polymerase.

Multiple protein-DNA and protein-protein interactions are involved in transcriptional activation by MalT.

The promoters of the Escherichia coli maltose regulon are positively regulated by the MalT protein, which recognizes a short asymmetric nucleotide sequence that is present as several copies in each promoter of the regulon. We report a detailed biochemical characterization of the interaction of MalT with the promoter of the malPQ operon. The MalT sites in malPp were precisely located and their occupation as a function of MalT concentration was quantified using DNase I and dimethyl sulphate footprinting experiments. The contribution of each site to malPp activity was assessed by introducing mutations that destroy them and measuring the residual in vivo and in vitro activity. Two main results were obtained. First, although the proximal MalT site is centred at -37.5, RNA polymerase is likely to establish a contact required for malPp activity with at least one base pair of the promoter -35 region; this close proximity between RNA polymerase and MalT bound to site 1 suggests that the two proteins interact. Second, even if the interaction of MalT with the three functional sites in malPp is a co-operative process, the MalT molecules bound to the two distal sites play a more subtle role than simply increasing the occupancy of the proximal site and may also contact RNA polymerase. We suggest that, in the nucleoprotein structure responsible for the initiation of transcription, MalT, RNA polymerase and malPp are held together by several weak interactions.

Which nucleotides in the "-10" region are crucial to obtain a fully active MalT-dependent promoter?

We have replaced the hexanucleotide corresponding to the "-10" region of malPp, a positively regulated promoter from Escherichia coli, by random nucleotide sequences and isolated 48 different variants that were as active as the wild-type promoter. Analysis of the nucleotide sequence of their "-10" region strongly suggests that the nature of the nucleotide present at three positions plays a crucial role: 46 of the 48 malPp variants contained C or T at position -12, A at position -11 and T at position -7. The nucleotide composition at the three other positions seems to be much more flexible. The features of these "-10" regions are similar to those of the constitutive promoters, but some significant differences are noticeable and will be discussed. In contrast to other positively regulated promoters, none of the various "-10" regions, including the consensus sequence TATAAT, led to a constitutive promoter.

On the puzzling arrangement of the asymmetric MalT-binding sites in the MalT-dependent promoters.

The MalT-dependent promoters of the enterobacteria belong to a small family of positively regulated prokaryotic promoters in which the activator protein recognizes short asymmetric nucleotide sequences present in several locations and orientations. We demonstrate that active MalT-dependent semisynthetic promoters can be constructed by using a synthetic decanucleotide as the MalT site and random nucleotide sequences as connecting sequences, provided that the location and orientation of the sites are the same as in natural MalT-dependent promoters. Strikingly, the induced level of promoter activity and the induction factor of each semisynthetic promoter are identical to those of its natural counterpart, in spite of considerable differences in their nucleotide sequences. The study of these semisynthetic promoters confirms the importance of the structural motif formed by two MalT sites in a direct repeat. This motif is involved in promoter activation either alone or in conjunction with a third MalT site, proximal with respect to the transcription start site. In this latter configuration, the promoters are active irrespective of the orientation of the repeat, and they retain at least some activity when the distance between the repeat and the proximal site is increased, provided that the alignment along the axis of the helix is conserved.

A small C-terminal region of the Escherichia coli MalT protein contains the DNA-binding domain.

MalT, the transcriptional activator of the Escherichia coli maltose regulon, is a 901-amino acid-long protein that specifically binds to short, asymmetric nucleotide sequences present in several copies in the promoters of the regulon. We report that the protein structure involved in this specific binding is carried by a small C-terminal part of MalT encompassing the last 95 amino acid residues. This was demonstrated by fusing the last 95 codons of malT to the gene that encodes glutathione S-transferase, purifying the hybrid protein by affinity chromatography, and comparing the DNase I and dimethyl sulfate footprints of the hybrid and of wild-type MalT on different MalT-binding sites. MalT belongs to a large family of prokaryotic transcriptional activators, which share significant homology in their approximately 60-amino acid C-terminal regions. Our result strongly supports the suggestion that the region of homology corresponds to the DNA-binding domain of the proteins in this family.