The application of Tet repressor in prokaryotic gene regulation and expression

Inducible gene expression based upon Tet repressor (tet regulation) is a broadly applied tool in molecular genetics. In its original environment, Tet repressor (TetR) negatively controls tetracycline (tc) resistance in bacteria. In the presence of tc, TetR is induced and detaches from its cognate DNA sequence tetO, so that a tc antiporter protein is expressed. In this article, we provide a comprehensive overview about tet regulation in bacteria and illustrate the parameters of different regulatory architectures. While some of these set‐ups rely on natural tet‐control regions like those found on transposon Tn10, highly efficient variations of this system have recently been adapted to different Gram‐negative and Gram‐positive bacteria. Novel tet‐controllable artificial or hybrid promoters were employed for target gene expression. They are controlled by regulators expressed at different levels either in a constitutive or in an autoregulated manner. The resulting tet systems have been used for various purposes. We discuss integrative elements vested with tc‐sensitive promoters, as well as tet regulation in Gram‐negative and Gram‐positive bacteria for analytical purposes and for protein overproduction. Also the use of TetR as an in vivo biosensor for tetracyclines or as a regulatory device in synthetic biology constructs is outlined. Technical specifications underlying different regulatory set‐ups are highlighted, and finally recent developments concerning variations of TetR are presented, which may expand the use of prokaryotic tet systems in the future.     

Teaching TetR to recognize a new inducer

Tet Repressor (TetR) recognizes the inducer tetracycline (tc) with high affinity. The tc analog 4-de(dimethylamino)-6-deoxy-6-demethyl-tetracycline (cmt3) is not an inducer for TetR. Induction specificity for cmt3 was generated by employing a directed evolution approach to screen appropriate TetR mutants in four successive steps. The specificity of the best TetR mutant is more than 20,000-fold increased for cmt3 over tc as judged by the ratio of their respective binding constants. Two rounds of directed evolution via DNA shuffling revealed His64 as a key residue for inducer specificity. The best TetR mutant with cmt3 specificity contains the H64K exchange, leading to a 300-fold decreased tc and a 20-fold increased cmt3 affinity. Another round of directed evolution made use of randomized oligonucleotides to mutate selected residues close to the tc-binding pocket of TetR and yielded TetR S135L with a 250-fold increased cmt3 affinity. The double mutant TetR H64K S135L was constructed and again subjected to directed evolution using randomized oligonucleotides to alter residues in the "secondary shell" of the tc-binding pocket. The resulting best mutants TetR H64K E114Q S135L, TetR A61V H64K Q109E Q116E S135L and TetR H64K T112K S135L are fully inducible by cmt3 and not by tc. Thus, their inducer specificity has been redesigned. The molecular mechanism of changed inducer recognition is discussed, based on binding constants with several tc analogs and in light of the TetR crystal structure.     

Structure-based design of Tet repressor to optimize a new inducer specificity

We constructed a mutant of the tetracycline-inducible repressor protein TetR with specificity for the tc analogue 4-de(dimethylamino)anhydrotetracycline (4-ddma-atc), which is neither an antibiotic nor an inducer for the wild-type protein. The previously published relaxed specificity mutant TetR H64K S135L displays reduced induction by tc but full induction by doxycycline (dox), anhydrotetracycline (atc), and 4-de(dimethylamino)-6-demethyl-6-deoxytetracycline (cmt3). To create induction specificity for tc derivatives lacking the 4-dimethylamino grouping such as cmt3 and 4-ddma-atc, the residues at positions 82 and 138, which are located close to that moiety in the crystal structure of the TetR-[tc-Mg](+)(2) complex, were randomized. We anticipated that a residue with increased size may lead to sterical hindrance, and screening for 4-ddma-atc-specific induction indeed revealed the mutant TetR H64K S135L S138I. Out of 24 exchanges only the addition of S138I to TetR H64K S135L yielded a mutant with a pronounced reduction of affinity for atc and dox, while the one for 4-ddma-atc is not affected. The ratio of binding constants revealed a 200-fold specificity increase for 4-ddma-atc over atc. The contributions of each single mutant to specificity indicate that the tc variants bind slightly different positions in the TetR tc binding pocket.     

Structural basis of gene regulation by the tetracycline inducible Tet repressor-operator system

The tetracycline repressor (TetR) regulates the most abundant resistance mechanism against the antibiotic tetracycline in grain-negative bacteria. The TetR protein and its mutants are commonly used as control elements to regulate gene expression in higher eukaryotes. We present the crystal structure of the TetR homodimer in complex with its palindromic DNA operator at 2.5 A resolution. Comparison to the structure of TetR in complex with the inducer tetracycline-Mg2+ allows the mechanism of induction to be deduced. Inducer binding in the repressor core initiates conformational changes starting with C-terminal unwinding and shifting of the short helix a6 in each monomer. This forces a pendulum-like motion of helix a4, which increases the separation of the attached DNA binding domains by 3 A, abolishing the affinity of TetR for its operator DNA.     

Tet repressor-tetracycline interaction

Previous studies [Wasylewskiet al. (1996),J. Protein Chem. 15, 45–58] have shown that the W43 residue localized within the helix-turn-helix structure domain of Tet repressor can exist in the ground state in two conformational states. In this paper we investigate the fluorescence properties of W43 of TetR upon binding of tetracycline inducer and its chemical analogs such as anhydro- and epitetracycline. Binding of the drug inducer to the protein indicates that the W43 residue still exists in two conformational states; however, its environment changes drastically, as can be judged by the changes in fluorescence parameters. The FQRS (fluorescence-quenching-resolved spectra) method was used to decompose the total emission spectrum. The resolved spectra exhibit maxima of fluorescence at 346 and 332 nm and the component quenchable by KI (346 nm) is shifted 9 nm toward the blue side of the spectrum upon inducer binding. The observed shift does not result from the changes in the exposure of W43, since the bimolecular quenching rate constant remains the same and is equal to about 2.7×10⁹M^–1sec^–1. The binding of tetracycline leads to drastic decrease of the W43 fluorescence intensity and increase of the tetracycline intensity as well as the decrease of fluorescence lifetime, especially of the W43 component characterized by the emission at 332 nm. The observed energy transfer from W43 to tetracycline is more efficient for the state characterized by the fluorescence emission at 332 nm (88%) than for the component quenchable by iodide (53%) Tetracycline and several of its derivatives were also used to observe how chemical modifications of the hydrophilic groups in tetracycline influence the mechanism of binding of the antibiotic to Tet repressor. By use of pulsed-laser photoacoustic spectroscopy it is shown that the binding of tetracyclines to Tet repressor leads to significant increase of tetracycline fluorescence quantum yields. Steady-state fluorescence quenching of tetracycline analogs in complexes with Tet repressor using potassium iodide as a quencher allowed us to determine the dependence of the exposure of bound antibiotic on the modifications of hydrophilic substituents of tetracycline. Circular dichroism studies of the TetR-[Mg · tc]⁺ complex do not indicate dramatic changes in the secondary structure of the protein; however, the observed small decrease in the TetR helicity may occur due to partial unfolding of the DNA recognition helix of the protein. The observed changes may play an important role in the process of induction in which tetracycline binding results in the loss of specific DNA binding.Abbreviations FQRS fluorescence-quenching-resolved spectra - HTH helix-turn-helix motif - tc tetracycline - TetR tetracycline repressor from Escherichia coli - TetR WT wild-type TetR - TetR W43 single point mutant with phenylalanine substituted for tryptophan at position 75 in both subunits     

Functionally important residues of the Tet repressor inducing peptide TIP determined by a complete mutational analysis

Tet repressor (TetR) is widely used to control gene expression in pro- and eukaryotes. The mechanism of induction by its natural inducer tetracycline is well characterized. A 16-mer oligopeptide, called TIP, fused to thioredoxin A (TrxA) of Escherichia coli is an artificial inducer of TetR. We analyzed the sequence requirements of TIP by directed and random single amino acid substitutions and identified residues important for TetR induction. An alanine scanning analysis of the first twelve residues showed that all except the ones at position eleven and twelve are important for induction. A randomization of residues at positions one to twelve of TIP revealed the properties of each residue necessary for induction. These further insights into the specificity of TIP-TetR interaction are discussed in the light of the X-ray structure of the [TetR-TIP] complex. The last four residues of TIP contribute indirectly to TetR induction by increasing the steady-state level of the fusion protein. TIP mutants fused N-terminally or C-terminally to TrxA in E. coli induce with the same efficiency indicating identical binding and induction mechanisms, and the lack of contribution from TrxA.     

Single-chain Tet transregulators

We demonstrate here that the Tet repressor (TetR), a dimeric allosterical regulatory protein, can be converted to a fully functional monomer when connected by a 29 amino acid linker. TetR-based transregulators are widely used to regulate gene expression in eukaryotes. They can be fused to form single-chain (sc) Tet transregulators with two TetR moieties and one eukaryotic regulatory domain. Sc variants of transactivator and transsilencer exhibit the same regulatory properties as their respective dimeric counterparts in human cell lines. In particular, the reverse ‘tet-on’ phenotype of rtTA variants is also present in the sc variants. Coexpression of a reverse transactivator and sc transsilencer leads to reduced background expression and shows full activation upon induction. The data demonstrate that sc Tet transregulators exhibit the phenotype of their respective dimers and lack functional interference when coexpressed in the same cell.     

Pip, a novel activator of phenazine biosynthesis in Pseudomonas chlororaphis PCL1391

Secondary metabolites are important factors for interactions between bacteria and other organisms. Pseudomonas chlororaphis PCL1391 produces the antifungal secondary metabolite phenazine-1-carboxamide (PCN) that inhibits growth of Fusarium oxysporum f. sp. radius lycopersici the causative agent of tomato foot and root rot. Our previous work unraveled a cascade of genes regulating the PCN biosynthesis operon, phzABCDEFGH. Via a genetic screen, we identify in this study a novel TetR/AcrR regulator, named Pip (phenazine inducing protein), which is essential for PCN biosynthesis. A combination of a phenotypical characterization of a pip mutant, in trans complementation assays of various mutant strains, and electrophoretic mobility shift assays identified Pip as the fifth DNA-binding protein so far involved in regulation of PCN biosynthesis. In this regulatory pathway, Pip is positioned downstream of PsrA (Pseudomonas sigma factor regulator) and the stationary-phase sigma factor RpoS, while it is upstream of the quorum-sensing system PhzI/PhzR. These findings provide further evidence that the path leading to the expression of secondary metabolism gene clusters in Pseudomonas species is highly complex.     

Quorum-sensing regulation of gene expression: Fundamental and applied aspects and the role in bacterial communication

Quorum sensing (QS) is a specific type of regulation of gene expression in bacteria; it is dependent on the population density. QS systems include two obligate components: a low-molecular-weight regulator (autoinducer), readily diffusible through the cytoplasmic membrane, and a regulatory receptor protein, which interacts with the regulator. As the bacterial population reaches a critical level of density, autoinducers accumulate to a necessary threshold value and abrupt activation (induction) of certain genes and operons occurs. By means of low-molecular-weight regulators, bacteria accomplish communication between cells belonging to the same or different species, genera, and even families. QS systems have been shown to play a key role in the regulation of various metabolic processes in bacteria and to function as global regulators of the expression of bacterial genes. Data are presented on different types of QS systems present in bacteria of various taxonomic groups, on the species specificity of these systems, and on communication of bacteria by means of QS systems. The possibility is considered of using QS regulation systems as targets while combating bacterial infections; other applied aspects of QS investigation are discussed.     

Quorum-sensing regulation of gene expression: fundamental and applied aspects and the role in bacterial communication

Quorum sensing (QS) is a specific type of regulation of gene expression in bacteria; it is dependent on the population density. QS systems include two obligate components: a low-molecular-weight regulator (autoinducer), readily diffusible through the cytoplasmic membrane, and a regulatory receptor protein, which interacts with the regulator. As the bacterial population reaches a critical level of density, autoinducers accumulate to a necessary threshold value and abrupt activation (induction) of certain genes and operons occurs. By means of low-molecular-weight regulators, bacteria accomplish communication between cells belonging to the same or different species, genera, and even families. QS systems have been shown to play a key role in the regulation of various metabolic processes in bacteria and to function as global regulators of the expression of bacterial genes. Data are presented on different types of QS systems present in bacteria of various taxonomic groups, on the species specificity of these systems, and on communication of bacteria by means of QS systems. The possibility is considered of using QS regulation systems as targets while combating bacterial infections; other applied aspects of QS investigation are discussed.     

Homologous Protein Domains in Superkingdoms Archaea,Bacteria, and Eukaryota and the Problem of the Origin of Eukaryotes

The distribution of protein domains was analyzed in superkingdoms Archaea, Bacteria, and Eukaryota. About a half of eukaryotic domains have prokaryotic origin. Many domains related to information processing in the nucleocytoplasm were inherited from archaea. Sets of domains associated with metabolism and regulatory and signaling systems were inherited from bacteria. Many signaling and regulatory domains common for bacteria and eukaryotes were responsible for the cellular interaction of bacteria with other components of the microbial community but were involved in coordination of the activity of eukaryotic organelles and cells in multicellular organisms. Many eukaryotic domains of bacterial origin could not originate from ancestral mitochondria and plastids but rather were adopted from other bacteria. An archaeon with the induced incorporation of alien genetic material could be the ancestor of the eukaryotic nucleocytoplasm.__________Translated from Izvestiya Akademii Nauk, Seriya Biologicheskaya, No. 4, 2005, pp. 389–400.Original Russian Text Copyright © 2005 by Markov, Kulikov.     

Direct and specific chemical control of eukaryotic translation with a synthetic RNA-protein interaction

Sequence-specific RNA-protein interactions, though commonly used in biological systems to regulate translation, are challenging to selectively modulate. Here, we demonstrate the use of a chemically-inducible RNA-protein interaction to regulate eukaryotic translation. By genetically encoding Tet Repressor protein (TetR)-binding RNA elements into the 5'-untranslated region (5'-UTR) of an mRNA, translation of a downstream coding sequence is directly controlled by TetR and tetracycline analogs. In endogenous and synthetic 5'-UTR contexts, this system efficiently regulates the expression of multiple target genes, and is sufficiently stringent to distinguish functional from non-functional RNA-TetR interactions. Using a reverse TetR variant, we illustrate the potential for expanding the regulatory properties of the system through protein engineering strategies.     

染色质构象调控真核基因的表达

真核基因的表达受到各种顺式调控元件、反式作用因子、染色质DNA以及组蛋白表观遗传修饰等多因素、多层次的调控。染色质三维空间结构的变化在调控真核基因表达方面也发挥了至关重要的作用。染色质构象的变化一方面可以使增强子等调控元件与靶基因相互靠近,从而促进基因表达;同时也可能通过形成空间位阻结构阻碍调控元件作用于靶基因,抑制基因表达。虽然染色质结构变化调控真核基因表达的机制仍缺乏较为精确的分子模型,但在组蛋白修饰、核小体定位、染色体领域以及染色质间相互作用等表观遗传学研究中,已经发现有诸多证据支持染色质构象在真核基因表达调控中的重要地位。文章主要综述了染色质结构及其构象的变化等对真核基因表达调控的影响。