Inducible and neuron-specific gene expression in the adult mouse brain with the rtTA2S-M2 system

To achieve inducible and reversible gene expression in the adult mouse brain, we exploited an improved version of the tetracycline-controlled transactivator-based system (rtTA2(S)-M2, rtTA2 hereafter) and combined it with the forebrain-specific CaMKIIalpha promoter. Several independent lines of transgenic mice carrying the CaMKIIalpha promoter-rtTA2 gene were generated and examined for anatomical profile, doxycycline (dox)-dependence, time course, and reversibility of gene expression using several lacZ reporter lines. In two independent rtTA2-expressing lines, dox-treatment in the diet induced lacZ reporter expression in neurons of several forebrain structures including cortex, striatum, hippocampus, amygdala, and olfactory bulb. Gene expression was dose-dependent and was fully reversible. Further, a similar pattern of expression was obtained in three independent reporter lines, indicating the consistency of gene expression. Transgene expression could also be activated in the developing brain (P0) by dox-treatment of gestating females. These new rtTA2-expressing mice allowing inducible and reversible gene expression in the adult or developing forebrain represent useful models for future genetic studies of brain functions.     

4-Epidoxycycline: an alternative to doxycycline to control gene expression in conditional mouse models

Since the pioneering work by Gossen and Bujard in 1992 demonstrating the usefulness of the Escherichia coli derived tet resistance operon for regulating gene expression a large collection of doxycycline-controlled transgenic mice has been established. Gene switching in eukaryotic tissue culture cells or mice requires administration of tetracycline, anhydrotetracycline or doxycycline to efficiently inactivate the transactivator protein tTA (TET-OFF system) or alternatively to activate the reverse transactivator protein rtTA (TET-ON system). However, the antibiotic activity of doxycycline can create an imbalance of the intestinal flora, resulting in diarrhoea and in a smaller number of animals in colitis. Previous studies reported that 4-epidoxycycline (4-ED), a hepatic metabolite of doxycycline, does not function as an antibiotic in mice. This gave us the idea that 4-ED might be useful for controlling gene expression in mice without the unwanted antibiotic side effect. To study the applicability of 4-ED for control of gene expression we used cell lines expressing the oncogene HER2 under control of tTA (TET-OFF) as well as rtTA (TET-ON). 4-ED and doxycycline were similarly efficient in switching on or -off HER2 expression. In vivo we used a conditional mouse model that allows switching off HER2 in tumor tissue. We show that (i) doxycycline, 7.5mg/ml in drinking water (used as a positive control), (ii) 4-ED, 7.5mg/ml in drinking water, (iii) 4-ED, 10mg/kg body weight, s.c., and (iv) anhydrotetracycline, 10mg/kg, s.c. (used as a second positive control), were similarly efficient. Using mice with tumor volumes of 1.6cm(3) all four schedules led to a tumor remission of more than 95% within 7 days. In conclusion, 4-ED is similarly efficient as doxycycline to control gene expression in vitro and in mice. Since 4-ED lacks the antibiotic activity of doxycycline it may help to avoid adverse side effects and selection of resistant bacteria.     

Homogeneity and long-term stability of tetracycline-regulated gene expression with low basal activity by using the rtTA2S-M2 transactivator and insulator-flanked reporter vectors

Inducible expression of tetracycline responsive element (TRE)-regulated genes in nearly all cells in a stable clone has generally been problematic, especially in long-term culture. Heterogeneity of tet-inducible expression is generally attributed to the instability of the original tet-transactivators tTA and rtTA. These transactivators have cryptic splice sites, prokaryotic codons and full VP16 domains, all of which contribute to their instability. Moreover, they also require high concentrations of Doxycycline (Dox). The 5 amino acid substitutions in the rtTA variant rtTA2S-M2 confer exquisite sensitivity to Dox. Moreover, humanized codons, removal of cryptic splice sites and minimal VP16 domains in rtTA2S-M2 results in its being better tolerated within cells. However, the ability of this modified transactivator to maintain homogeneous inducibility in long-term culture has not been examined. We demonstrate that rtTA2S-M2 expressing clones exhibit functional transactivator activity for over 7 months in culture. Furthermore, rtTA2S-M2 expressing clones with chromosomally integrated copies of a TRE-green fluorescent protein (GFP) reporter also exhibited homogeneous inducibility in long-term culture. Importantly, the inherent reduced toxicity and improved stability of rtTA2S-M2 obviates the need to continuously select for its message, once clones with functional transactivator are isolated. The use of rtTA2S-M2 did not, however, preclude clones with stably integrated TRE-reporter from exhibiting leakiness. However, inclusion of flanking double copies of a 'minimal core element' of the chicken beta-globin gene insulator, instead of the 1.4 kb region, in the TRE-reporter was sufficient to markedly reduce the frequency of clones with high basal expression. Inclusion of the insulator core also did not affect the maximal expression levels of the inducible gene, which typically equaled or exceeded that observed with the strong constitutive CMV promoter. Finally, with this system homogeneous inducibility was observed rapidly and with low doses of Dox.     

Generation and characterization of an inducible transgenic model for studying mouse esophageal biology

ABSTRACT: BACKGROUND: To facilitate the in vivo study of esophageal (stem) cell biology in homeostasis and cancer, novel mouse models are necessary to elicit expression of candidate genes in a tissue-specific and inducible fashion. To this aim, we developed and studied a mouse model to allow labeling of esophageal cells with the histone 2B-GFP (H2B-GFP) fusion protein. RESULTS: First, we generated a transgenic mouse model expressing the reverse tetracycline transactivator rtTA2-M2 under control of the promoter (ED-L2) of the Epstein-Barr virus (EBV) gene encoding the latent membrane protein-1 (LMP-1). The newly generated ED-L2-rtTA2-M2 (ED-L2-rtTA) mice were then bred with the previously developed tetOHIST1H2BJ/GFP (tetO-H2B-GFP) model to assess inducibility and tissue-specificity. Expression of the H2B-GFP fusion protein was observed upon doxycycline induction but was restricted to the terminally differentiated cells above the basal cell layer. To achieve expression in the basal compartment of the esophagus, we subsequently employed a different transgenic model expressing the reverse transactivator rtTA2S-M2 under the control of the ubiquitous, methylation-free CpG island of the human hnRNPA2B1-CBX3 gene (hnRNPrtTA). Upon doxycycline administration to the compound hnRNP-rtTA/tetO-H2B-GFP mice, near-complete labeling of all esophageal cells was achieved. Pulse-chase experiments confirmed that complete turnover of the esophageal epithelium in the adult mouse is achieved within 7-10 days. CONCLUSIONS: We show that the esophagus-specific promoter ED-L2 is expressed only in the differentiated cells above the basal layer. Moreover, we confirmed that esophageal turn-over in the adult mouse does not exceed 7-10 days.     

Variability of Inducible Expression across the Hematopoietic System of Tetracycline Transactivator Transgenic Mice

The tetracycline (tet)-regulated expression system allows for the inducible overexpression of protein-coding genes, or inducible gene knockdown based on expression of short hairpin RNAs (shRNAs). The system is widely used in mice, however it requires robust expression of a tet transactivator protein (tTA or rtTA) in the cell type of interest. Here we used an in vivo tet-regulated fluorescent reporter approach to characterise inducible gene/shRNA expression across a range of hematopoietic cell types of several commonly used transgenic tet transactivator mouse strains. We find that even in strains where the tet transactivator is expressed from a nominally ubiquitous promoter, the efficiency of tet-regulated expression can be highly variable between hematopoietic lineages and between differentiation stages within a lineage. In some cases tet-regulated reporter expression differs markedly between cells within a discrete, immunophenotypically defined population, suggesting mosaic transactivator expression. A recently developed CAG-rtTA3 transgenic mouse displays intense and efficient reporter expression in most blood cell types, establishing this strain as a highly effective tool for probing hematopoietic development and disease. These findings have important implications for interpreting tet-regulated hematopoietic phenotypes in mice, and identify mouse strains that provide optimal tet-regulated expression in particular hematopoietic progenitor cell types and mature blood lineages.     

Tetracycline-dependent gene regulation: combinations of transregulators yield a variety of expression windows

In addition to the originally described Tet transactivator tTA, several variants including transrepressors (tTRs) and reverse transactivators (rtTAs) have been constructed, which we employ here to establish a set of HeLa cell lines carrying different combinations of chromosomally integrated Tet transregulators. We first compare the regulatory properties of these lines using transient transfection of a luciferase reporter gene. Cell lines carrying rtTA-S2 or rtTA-M2 show reduced activity in the absence of dox and higher activation levels in its presence compared to an rtTA line. rtTA-M2 and its synthetic counterpart rtTA2S-M2 show the same regulation pattern. The replacement of the VP16 activation domain in rtTA-S2 or tTA by p65 leads to slightly reduced expression levels. Combination of an rtTA variant with the transrepressor tTR shows active repression of basal expression without affecting the activation level of the transiently transfected reporter gene. However, if the target gene is also chromosomally integrated, then tTR leads to a further reduction of basal expression and also of the maximal expression level. The results demonstrate that different regulatory windows can be achieved using various transregulators or combinations thereof. Thus, the most appropriate combination of regulators can be chosen depending on the application and cell line desired. We suspect that these properties would also allow the construction of transgenic organisms with preselected expression windows.     

Targeting reverse tetracycline-dependent transactivator to murine mammary epithelial cells that express the progesterone receptor

Through an established gene-targeting strategy, reverse tetracycline-dependent transactivator (rtTA) was targeted downstream of the murine progesterone receptor (PR) promoter. Mice were generated in which one (PR(+/rtTA)) or both (PR(rtTA/rtTA)) PR alleles harbor the rtTA insertion. The PR(+/rtTA) and PR(rtTA/rtTA) knockins exhibit phenotypes identical to the normal and the progesterone receptor knockout mouse, respectively. Crossed with the TZA reporter, which carries the TetO-LacZ responder transgene, the PR(+/rtTA)/TZA and PR(rtTA/rtTA)/TZA bigenics exhibit doxycycline-induced beta-galactosidase activity specifically in progesterone responsive target tissues such as the mammary gland, uterus, ovary, and pituitary gland. In the case of the PR(+/rtTA)/TZA mammary epithelium, dual immunofluorescence demonstrated that PR expression and doxycycline-induced beta-galactosidase activity colocalized; beta-galactosidase was not detected in the absence of doxycycline. Although both the PR(+/rtTA) and PR(rtTA/rtTA) knockins represent innovative animal models with which to further query progesterone's mechanism of action in vivo, the PR(rtTA/rtTA) mouse in particular promises to provide unique insight into the paracrine mechanism of action, which underpins progesterone's involvement in mammary morphogenesis with obvious implications for extending our understanding of this steroid's role in breast cancer progression.