Richard G. Brennan

The TetR Family of Transcriptional Repressors

SUMMARY We have developed a general profile for the proteins of the TetR family of repressors. The stretch that best defines the profile of this family is made up of 47 amino acid residues that correspond to the helix-turn-helix DNA binding motif and adjacent regions in the three-dimensional structures of TetR, QacR, CprB, and EthR, four family members for which the function and three-dimensional structure are known. We have detected a set of 2,353 nonredundant proteins belonging to this family by screening genome and protein databases with the TetR profile. Proteins of the TetR family have been found in 115 genera of gram-positive, α-, β-, and γ-proteobacteria, cyanobacteria, and archaea. The set of genes they regulate is known for 85 out of the 2,353 members of the family. These proteins are involved in the transcriptional control of multidrug efflux pumps, pathways for the biosynthesis of antibiotics, response to osmotic stress and toxic chemicals, control of catabolic pathways, differentiation processes, and pathogenicity. The regulatory network in which the family member is involved can be simple, as in TetR (i.e., TetR bound to the target operator represses tetA transcription and is released in the presence of tetracycline), or more complex, involving a series of regulatory cascades in which either the expression of the TetR family member is modulated by another regulator or the TetR family member triggers a cell response to react to environmental insults. Based on what has been learned from the cocrystals of TetR and QacR with their target operators and from their three-dimensional structures in the absence and in the presence of ligands, and based on multialignment analyses of the conserved stretch of 47 amino acids in the 2,353 TetR family members, two groups of residues have been identified. One group includes highly conserved positions involved in the proper orientation of the helix-turn-helix motif and hence seems to play a structural role. The other set of less conserved residues are involved in establishing contacts with the phosphate backbone and target bases in the operator. Information related to the TetR family of regulators has been updated in a database that can be accessed at www.bactregulators.org .

Crystal structure of the lactose operon repressor and its complexes with DNA and inducer.

The lac operon of Escherichia coli is the paradigm for gene regulation. Its key component is the lac repressor, a product of the lacI gene. The three-dimensional structures of the intact lac repressor, the lac repressor bound to the gratuitous inducer isopropyl-β-D-1-thiogalactoside (IPTG) and the lac repressor complexed with a 21-base pair symmetric operator DNA have been determined. These three structures show the conformation of the molecule in both the induced and repressed states and provide a framework for understanding a wealth of biochemical and genetic information. The DNA sequence of the lac operon has three lac repressor recognition sites in a stretch of 500 base pairs. The crystallographic structure of the complex with DNA suggests that the tetrameric repressor functions synergistically with catabolite gene activator protein (CAP) and participates in the quaternary formation of repression loops in which one tetrameric repressor interacts simultaneously with two sites on the genomic DNA.

Hfq: A Bacterial Sm-like Protein that Mediates RNA-RNA Interaction

The bacterial Hfq protein modulates the stability or the translation of mRNAs and has recently been shown to interact with small regulatory RNAs in E. coli. Here we show that Hfq belongs to the large family of Sm and Sm-like proteins: it contains a conserved sequence motif, known as the Sm1 motif, forms a doughnut-shaped structure, and has RNA binding specificity very similar to the Sm proteins. Moreover, we provide evidence that Hfq strongly cooperates in intermolecular base pairing between the antisense regulator Spot 42 RNA and its target RNA. We speculate that Sm proteins in general cooperate in bimolecular RNA-RNA interaction and that protein-mediated complex formation permits small RNAs to interact with a broad range of target RNAs.

Structures of the pleiotropic translational regulator Hfq and an Hfq-RNA complex: a bacterial Sm-like protein.

In prokaryotes, Hfq regulates translation by modulating the structure of numerous RNA molecules by binding preferentially to A/U‐rich sequences. To elucidate the mechanisms of target recognition and translation regulation by Hfq, we determined the crystal structures of the Staphylococcus aureus Hfq and an Hfq–RNA complex to 1.55 and 2.71 Å resolution, respectively. The structures reveal that Hfq possesses the Sm‐fold previously observed only in eukaryotes and archaea. However, unlike these heptameric Sm proteins, Hfq forms a homo‐hexameric ring. The Hfq–RNA structure reveals that the single‐stranded hepta‐oligoribonucleotide binds in a circular conformation around a central basic cleft, whereby Tyr42 residues from adjacent subunits stack with six of the bases, and Gln8, outside the Sm motif, provides key protein–base contacts. Such binding suggests a mechanism for Hfq function.

Molecular Mechanisms of HipA-Mediated Multidrug Tolerance and Its Neutralization by HipB

Bacterial multidrug tolerance is largely responsible for the inability of antibiotics to eradicate infections and is caused by a small population of dormant bacteria called persisters. HipA is a critical Escherichia coli persistence factor that is normally neutralized by HipB, a transcription repressor, which also regulates hipBA expression. Here, we report multiple structures of HipA and a HipA-HipB-DNA complex. HipA has a eukaryotic serine/threonine kinase–like fold and can phosphorylate the translation factor EF-Tu, suggesting a persistence mechanism via cell stasis. The HipA-HipB-DNA structure reveals the HipB-operator binding mechanism, ∼70° DNA bending, and unexpected HipA-DNA contacts. Dimeric HipB interacts with two HipA molecules to inhibit its kinase activity through sequestration and conformational inactivation. Combined, these studies suggest mechanisms for HipA-mediated persistence and its neutralization by HipB.

Structure of Escherichia coli Hfq bound to polyriboadenylate RNA

Hfq is a small, highly abundant hexameric protein that is found in many bacteria and plays a critical role in mRNA expression and RNA stability. As an “RNA chaperone,” Hfq binds AU-rich sequences and facilitates the trans annealing of small RNAs (sRNAs) to their target mRNAs, typically resulting in the down-regulation of gene expression. Hfq also plays a key role in bacterial RNA decay by binding tightly to polyadenylate [poly(A)] tracts. The structural mechanism by which Hfq recognizes and binds poly(A) is unknown. Here, we report the crystal structure of Escherichia coli Hfq bound to the poly(A) RNA, A15. The structure reveals a unique RNA binding mechanism. Unlike uridine-containing sequences, which bind to the “proximal” face, the poly(A) tract binds to the “distal” face of Hfq using 6 tripartite binding motifs. Each motif consists of an adenosine specificity site (A site), which is effected by peptide backbone hydrogen bonds, a purine nucleotide selectivity site (R site), and a sequence-nondiscriminating RNA entrance/exit site (E site). The resulting implication that Hfq can bind poly(A-R-N) triplets, where R is a purine nucleotide and N is any nucleotide, was confirmed by binding studies. Indeed, Hfq bound to the oligoribonucleotides (AGG)8, (AGC)8, and the shorter (A-R-N)4 sequence, AACAACAAGAAG, with nanomolar affinities. The abundance of (A-R-N)4 and (A-R-N)5 triplet repeats in the E. coli genome suggests additional RNA targets for Hfq. Further, the structure provides insight into Hfq-mediated sRNA-mRNA annealing and the role of Hfq in RNA decay.

Crystal structure of the transcription activator BmrR bound to DNA and a drug.

The efflux of chemically diverse drugs by multidrug transporters that span the membrane is one mechanism of multidrug resistance in bacteria. The concentrations of many of these transporters are controlled by transcription regulators, such as BmrR in Bacillus subtilis, EmrR in Escherichia coli and QacR in Staphylococcus aureus . These proteins promote transporter gene expression when they bind toxic compounds. BmrR activates transcription of the multidrug transporter gene, bmr, in response to cellular invasion by certain lipophilic cationic compounds (drugs). BmrR belongs to the MerR family, which regulates response to stress such as exposure to toxic compounds or oxygen radicals in bacteria. MerR proteins have homologous amino-terminal DNA-binding domains but different carboxy-terminal domains, which enable them to bind specific ‘coactivator’ molecules. When bound to coactivator, MerR proteins upregulate transcription by reconfiguring the 19-base-pair spacer found between the -35 and -10 promoter elements to allow productive interaction with RNA polymerase. Here we report the 3.0 Å resolution structure of BmrR in complex with the drug tetraphenylphosphonium (TPP) and a 22-base-pair oligodeoxynucleotide encompassing the bmr promoter. The structure reveals an unexpected mechanism for transcription activation that involves localized base-pair breaking, and base sliding and realignment of the -35 and -10 operator elements.

Structural basis for cooperative DNA binding by two dimers of the multidrug-binding protein QacR

The Staphylococcus aureus multidrug‐binding protein QacR represses transcription of the qacA multidrug transporter gene and is induced by multiple structurally dissimilar drugs. QacR is a member of the TetR/CamR family of transcriptional regulators, which share highly homologous N‐terminal DNA‐binding domains connected to seemingly non‐homologous ligand‐binding domains. Unlike other TetR members, which bind ∼15 bp operators, QacR recognizes an unusually long 28 bp operator, IR1, which it appears to bind cooperatively. To elucidate the DNA‐binding mechanism of QacR, we determined the 2.90 Å resolution crystal structure of a QacR–IR1 complex. Strikingly, our data reveal that the DNA recognition mode of QacR is distinct from TetR and involves the binding of a pair of QacR dimers. In this unique binding mode, recognition at each IR1 half‐site is mediated by a complement of DNA contacts made by two helix–turn–helix motifs. The inferred cooperativity does not arise from cross‐dimer protein–protein contacts, but from the global undertwisting and major groove widening elicited by the binding of two QacR dimers.

Structural Basis of Multidrug Recognition by BmrR, a Transcription Activator of a Multidrug Transporter

Multidrug-efflux transporters demonstrate an unusual ability to recognize multiple structurally dissimilar toxins. A comparable ability to bind diverse hydrophobic cationic drugs is characteristic of the Bacillus subtilis transcription regulator BmrR, which upon drug binding activates expression of the multidrug transporter Bmr. Crystal structures of the multidrug-binding domain of BmrR (2.7 A resolution) and of its complex with the drug tetraphenylphosphonium (2.8 A resolution) revealed a drug-induced unfolding and relocation of an alpha helix, which exposes an internal drug-binding pocket. Tetraphenylphosphonium binding is mediated by stacking and van der Waals contacts with multiple hydrophobic residues of the pocket and by an electrostatic interaction between the positively charged drug and a buried glutamate residue, which is the key to cation selectivity. Similar binding principles may be used by other multidrug-binding proteins.

A direct link between carbohydrate utilization and virulence in the major human pathogen group A Streptococcus

Although central to pathogenesis, the molecular mechanisms used by microbes to regulate virulence factor production in specific environments during host–pathogen interaction are poorly defined. Several recent ex vivo and in vivo studies have found that the level of group A Streptococcus (GAS) virulence factor gene transcripts is temporally related to altered expression of genes encoding carbohydrate utilization proteins. These findings stimulated us to analyze the role in pathogenesis of catabolite control protein A (CcpA), a GAS ortholog of a key global regulator of carbohydrate metabolism in Bacillus subtilis. Inasmuch as the genomewide effects of CcpA in a human pathogen are unknown, we analyzed the transcriptome of a ΔccpA isogenic mutant strain grown in nutrient-rich medium. CcpA influences the transcript levels of many carbohydrate utilization genes and several well characterized GAS virulence factors, including the potent cytolysin streptolysin S. Compared with the wild-type parental strain, the ΔccpA isogenic mutant strain was significantly less virulent in a mouse model of invasive infection. Moreover, the isogenic mutant strain was significantly impaired in ability to colonize the mouse oropharynx. When grown in human saliva, a nutrient-limited environment, CcpA influenced production of several key virulence factors not influenced during growth in nutrient-rich medium. Purified recombinant CcpA bound to the promoter region of the gene encoding streptolysin S. Our discovery that GAS virulence and complex carbohydrate utilization are directly linked through CcpA provides enhanced understanding of a mechanism used by a Gram-positive pathogen to modulate virulence factor production in specific environments.