Regulated expression of nuclear genes by T3 RNA polymerase and lac repressor, using recombinant vaccinia virus vectors.

Recombinant vaccinia viruses that express the bacteriophage T3 RNA polymerase (VV-T3pol) or the Escherichia coli lac repressor (VV-lacI) under control of the early-late vaccinia promoter P7.5 were constructed. To determine whether phage polymerase and lac repressor can function in the nucleus of mammalian cells, the bacterial chloramphenicol acetyltransferase (CAT) gene was cloned downstream of a T3 promoter (PT3-CAT) or downstream of a T3 promoter-lac operator fusion element (PT3Olac-CAT), and these reporter gene cassettes were introduced stably into NIH 3T3 or Ltk- cells. Infection of 3T3/PT3-CAT or Ltk-/PT3-CAT cells by VV-T3pol led to rapid expression of CAT (greater than 20 ng of CAT protein per 10(6) cells). The presence of hydroxyurea (which blocks virus DNA replication) did not prevent CAT production. When 3T3/PT3Olac-CAT cells were infected with both VV-T3pol and VV-lacI (multiplicities of infection of 2.5 and 10, respectively), greater than 30-fold repression of CAT gene activity by lac repressor was observed. This could be reversed to unrepressed levels by the presence of 10 mM o-nitrophenyl-beta-D-galactoside (IPTG) in the medium. Regulated expression of the target gene was observed with cell lines that had been maintained for over 1 year (greater than 50 passages in culture), and Southern blot analysis revealed the presence of the CAT gene only in the nuclear fraction in these cells, demonstrating the stability of the target gene. These results indicate that vaccinia virus-encoded proteins can function in the mammalian nucleus and provide the basis for a genetic system in which essential vaccinia virus genes, placed in the chromosome of a cell, can be used to complement defective virus particles. This approach may prove useful for other virus systems.     

Synthetic lac operator mediates repression through lac repressor when introduced upstream and downstream from lac promoter.

Plasmids were constructed which carry a synthetic lac operator at various distances from the lac promoter. They were tested in vivo for function in the presence and absence of lac repressor. We found significant repression when the lac operator is situated at the 3' end of the lac I gene or at the 5' end of the lac Z gene. When lac operators are inserted at both sites, we found a greater than 150-fold repression. The complex between lac repressor and DNA carrying these two lac operators is exceedingly stable in vitro suggesting that one tetrameric lac repressor may bind to both lac operators.     

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

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

Inducible transformation of cells from transgenic mice expressing SV40 under lac operon control.

If it were possible to clone in vitro cells of any type, at any stage of differentiation, from an extensively characterized animal such as the mouse, many areas of cell biology would benefit. Indeed, it would be even more helpful if these cells could subsequently be restored to their normal in vivo phenotype whenever required. Here, we describe a step on the pathway to such an idealized "clonable" mouse. In principle, it seeks to link a "universal" transforming agent to a regulatory system that is relatively simple, yet quite foreign to the mouse. A plasmid containing the bacterial lac operator/promoter region linked to the SV40 large T antigen and a vector containing the lac repressor that can be expressed in mammalian cells were coinjected into fertilized mouse oocytes utilizing the standard techniques for generating transgenic mice. Two progeny were obtained that express large T antigen in the presence, but not the absence, of the nonmetabolizable lac inducer, isopropyl-beta-thio-D-galactoside. This report characterizes fibroblast cell lines established from these transgenics that are readily transformed in vitro with isopropyl-beta-thio-D-galactoside. A significant proportion of the cells are restored to their "normal" (nontransformed phenotype) when isopropyl-beta-thio-D-galactoside is removed.     

Effects of dominant-negative lac repressor mutations on operator specificity and protein stability

The specific binding of dominant-negative (I-d) lactose (lac) repressors to wild-type (wt) as well as mutant (Oc) lac operators has been examined to explore the sequence-specific interaction of the lac repressor with its target. Mutant lacI genes encoding substitutions in the N-terminal 60 amino acids (aa) were cloned in a derivative of plasmid pBR322. Twelve of these lacI-d missense mutations were transferred from F'lac episomes using general genetic recombination and molecular cloning, and nine lacI missense mutations were recloned from M13-lacI phages [Mott et al., Nucl. Acids Res. 12 (1984) 4139-4152]. The mutant repressors were examined for polypeptide size and stability, for binding the inducer isopropyl-beta-D-thiogalactoside (IPTG), as well as binding to wt operator. The mutant repressors' affinities for wt operator ranged from undetectable to about 1% that of wt repressor, and the mutant repressors varied in transdominance against repressor expressed from a chromosomal lacIq gene. Six of the I-d repressors were partially degraded in vivo. All repressors bound IPTG with approximately the affinity of wt repressor. Repressors having significant affinity for wt operator or with substitutions in the presumed operator recognition helix (aa 17-25) were examined in vivo for their affinities for a series of single site Oc operators. Whereas the Gly-18-, Ser-18- and Leu-18-substituted repressors showed altered specificity for position 7 of the operator [Ebright, Proc. Natl. Acad. Sci. USA 83 (1986) 303-307], the His-18 repressor did not affect specificity. This result may be related to the greater side-chain length of histidine compared to the other amino acid substitutions.     

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

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

The lac repressor

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

Modifications of the E.coli Lac repressor for expression in eukaryotic cells: effects of nuclear signal sequences on protein activity and nuclear accumulation.

Eukaryotic expression vectors designed to produce E. coli Lac repressor protein targeted to the nucleus of mammalian cells were constructed. These constructions carry the lac repressor gene (lacI) fused at different positions to a nuclear localization sequence (NLS) from either the SV40 large T antigen or the adenovirus E1a. When the NLS's were fused to the lacI gene at the 5' end, the protein produced exhibited tighter repression of beta-galactosidase expression than the unmodified LacI protein. Localization sequences at the extreme 3' end of the gene generally diminished induction by IPTG, while introduction of the SV40 NLS nine base pairs upstream of the 3' end eliminated repressor activity. When either NLS was placed at the 3' end behind a random nine base pair linker, the activity of the LacI protein depended on the sequence of the linker, and in 9 of 10 linkers tested, activity of the protein was adversely affected. The one exception was the fusion protein from p3'ss, which had the NLS at the 3' end of lacI behind the nine base pair linker, AGC AGC CTG (ser-ser-leu). This protein exhibited efficient nuclear accumulation, strong repressor activity and greater sensitivity to IPTG induction. The functional linker from the p3'ss fusion protein extends the leucine zipper heptad repeat located at the C-terminus of the protein. These data support the role of the leucine zipper in tetramer formation and predict that extension of this zipper will further stabilize the protein. This modified lacI gene should be valuable for improved adaptation of the prokaryotic regulatory system to eukaryotic cells.     

Targeting the Escherichia coli lac repressor to the mammalian cell nucleus

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

Analysis of inducers of the E.coli lac repressor system in mammalian cells and whole animals.

Although the inducible prokaryotic lac repressor system has been successfully adapted for control of gene expression in mammalian cells, little information is available on the pharmacokinetics of beta-galactoside inducers in mammalian cells for optimizing this system. These studies directly measure the cell uptake and clearance in cultured cells and animal tissue cells of lac inducers. In these cells, the beta-galactosides, isopropyl beta-D-thiogalactoside (IPTG) and methyl beta-D-thiogalactoside (MTG), are rapidly taken up, exceeding extracellular levels in less than 2 hours. Greater than 5% of this inducer is found in the nuclear fraction, slightly exceeding the cytoplasmic concentration. Although similar in uptake, IPTG is cleared from the cultured cells significantly faster than MTG. In the mouse, the half-life of both inducers in the blood ranges from 15-30 minutes. HPLC analysis of tissue extracts from inducer-injected mice indicates that the inducer is metabolically stable and functionally able to bind to lac repressor. These results should permit improvement in the adaptation of the lac repressor system to mammalian cells and aid in the development of an adaptable system for gene control in transgenic animals.     

Regulated expression of plant tRNA genes by the prokaryotic tet and lac repressors

The prokaryotic tet operator (tetO) sequence was inserted at positions upstream and downstream of sequences encoding the Arabidopsis thaliana tRNA _AUC ^Lys or tRNA _AUC ^Trp suppressor tRNAs, and tRNA expression in carrot protoplasts was measured by translational suppression of a nonsense codon in a luciferase reporter gene. Regulation of tRNA expression by the tetracycline repressor (tetR) occurred from genes with the tetO inserted at position –1 (for the tRNA _AUC ^Trp gene), or at positions –2, –6 and –10 (for the tRNA _AUC ^Lys gene), and repression reached 90%. The inducer tetracycline (Tc) restored tRNA expression. Similarly, carrot protoplasts transfected with human tRNA _AUC ^Ser genes containing the lac operator (lacO) in their 5-flanking sequence with or without the lac repressor (lacI) gene, conditionally expressed tRNAs which suppressed the luciferase reporter. Up to 30-fold repression occured by the lactose repressor when lacO was located at position –1 of the tRNA _AUC ^Ser coding sequence. In the presence of the inducer isopropyl--thiogalactoside (IPTG), repression was relieved. These results demonstrate that sequences flanking tRNA genes can strongly influence tRNA expression in plants, and in a conditional fashion when bound by inducible proteins.