Directing neuron-specific transgene expression in the mouse CNS

Recent advances in molecular genetics have produced many novel strategies for directing the expression of both functional and regulatory elements in transgenic mice. With the application of such approaches, the specific populations that comprise CNS networks can be both visualized and manipulated. Transgenic methods now range from the use of specific enhancer elements and large genomic regions assembled using BACs and PACs, to the use of gene targeting to a specific locus. In addition, the advent of transactivators and site-specific recombinases has provided unprecedented spatial and temporal control for directing expression in the CNS using a combination of appropriate alleles. As a result, the promise of being able to use transgenics to target specific neuronal populations is now being realized.     

Immunohistochemical detection of transgene expression in the brain using small epitope tags

Background  

In vivo overexpression of proteins is a powerful approach to study their biological function, generate disease models or evaluate gene therapy approaches. In order to investigate an exogenously expressed protein, specific and sensitive detection is essential. Unfortunately, antibodies that allow histological detection of the protein of interest are not always readily available. The use of an epitope tag fused to the protein can circumvent this problem as well as provide the possibility to discriminate endogenous from overexpressed proteins. In order to minimize impact on the bioactivity and biodistribution of the overexpressed protein, preference is given to small tags.     

Relative transgene expression frequencies in homozygous versus hemizygous transgenic mice

We have used a simple binomial model of stochastic transgene inactivation at the level of the chromosome or transgene, rather than the cellular level, for the analysis of two mouse transgenic lines that show variegated patterns of expression. This predicts the percentages of cells that express one, both or neither alleles of the transgene in homozygotes from the observed percentages of cells, which express the transgene in hemizygotes. It adequately explained the relationship between the numbers of cells expressing the transgene in hemizygous and homozygous mosaic 21OH/LacZ mouse adrenals and mosaic BLG/7 mouse mammary glands. The binomial model also predicted that a small proportion of cells in mosaic mammary glands of BLG/7 homozygotes would express both BLG/7 alleles but published data indicated that all cells expressing the transgene showed monoallelic expression. Although it didn’t fit all of the BLG/7 data as precisely as a more complex model, which used several ad hoc assumptions to explain these results, the simple binomial model was able to explain the relationship in observed transgene expression frequencies between hemizygous and homozygous mosaic tissues for both 21OH/LacZ and BLG/7 mice. It may prove to be a useful general model for analysing other transgenic animals showing mosaic transgene expression.     

Quantitative analysis of lentiviral transgene expression in mice over seven generations

Lentiviral transgenesis is now recognized as an extremely efficient and cost-effective method to produce transgenic animals. Transgenes delivered by lentiviral vectors exhibited inheritable expression in many species including those which are refractory to genetic modification such as non-human primates. However, epigenetic modification was frequently observed in lentiviral integrants, and transgene expression found to be inversely correlated with methylation density. Recent data showed that about one-third lentiviral integrants exhibited hypermethylation and low expression, but did not demonstrate whether those integrants with high expression could remain constant expression and hypomethylated during long term germline transmission. In this study, using lentiviral eGFP transgenic mice as the experimental animals, lentiviral eGFP expression levels and its integrant numbers in genome were quantitatively analyzed by fluorescent quantitative polymerase-chain reaction (FQ-PCR), using the house-keeping gene ribosomal protein S18 (Rps18) and the single copy gene fatty acid binding protein of the intestine (Fabpi) as the internal controls respectively. The methylation densities of the integrants were quantitatively analyzed by bisulfite sequencing. We found that the lentiviral integrants with high expression exhibited a relative constant expression level per integrant over at least seven generations. Besides, the individuals containing these integrants exhibited eGFP expression levels which were positively and almost linearly correlated with the integrant numbers in their genomes, suggesting that no remarkable position effect on transgene expression of the integrants analyzed was observed. In addition, over seven generations the methylation density of these integrants did not increase, but rather decreased remarkably, indicating that these high expressing integrants were not subjected to de novo methylation during at least seven generations of germline transmission. Taken together, these data suggested that transgenic lines with long term stable expression and no position effect can be established by lentiviral transgenesis.     

Multiple effects of genetic background on variegated transgene expression in mice

BLG/7 transgenic mice express an ovine beta-lactoglobulin transgene during lactation. Unusually, transgene expression levels in milk differ between siblings. This variable expression is due to variegated transgene expression in the mammary gland and is reminiscent of position-effect variegation. The BLG/7 line was created and maintained on a mixed CBA x C57BL/6 background. We have investigated the effect on transgene expression of backcrossing for 13 generations into these backgrounds. Variable transgene expression was observed in all populations examined, confirming that it is an inherent property of the transgene array at its site of integration. There were also strain-specific effects on transgene expression that appear to be independent of the inherent variegation. The transgene, compared to endogenous milk protein genes, is specifically susceptible to inbreeding depression. Outcrossing restored transgene expression levels to that of the parental population; thus suppression was not inherited. Finally, no generation-dependent decrease in mean expression levels was observed in the parental population. Thus, although the BLG/7 transgene is expressed in a variegated manner, there was no generation-associated accumulated silencing of transgene expression.     

Altered expression after expansion of a v-erbA transgene in transgenic mice

Repetitive DNA is known to undergo size variations based on an increase or decrease in the number of monomer units. We describe here the spontaneous expansion of an experimentally introduced tandem array of repeats in a transgenic mouse consisting of the human -actin promoter fused to the viral oncogene v-erbA and an SV40 polyadenylation signal (hAP/v-erbA). The expansion of the transgene was identified during routine screening of transgenic offspring for heterozygosity or homozygosity in one founder line. The control heterozygote genome consisted of the hAP/v-erbA transgene organized as a tandem array approximately five monomer units at a single chromosomal locus. The number of units increased to 20–21 copies, and germline transmission of the expanded units was stable for at least two generations. The majority of animals carrying the expanded monomer units retained their RNA expression patterns; however, some of these animals had drastically reduced expression levels. We discuss the possibility that expansion of repeated units may provide a mechanism by which the expression of a deleterious transgene is reduced.     

Cross-contamination with tamoxifen induces transgene expression in non-exposed inducible transgenic mice

Inducible transgenic mouse models that impose a constraint on both temporal and spatial expression of a given transgene are invaluable. These animals facilitate experiments that can address the role of a specific cell or group of cells within an animal or in a particular window of time. A common approach to achieve inducibility involves the site-specific recombinase 'Cre', which is linked to a modified version of one of various steroid hormone-binding domains. Thus, the expression of Cre is regulated such that a functional nuclear transgene product can only be generated with the addition of an exogenous ligand. However, critical requirements of this system are that the nuclear localization of the transgene product be tightly regulated, that the dosage of the inducing agent remains consistent among experimental animals and that the transgene cassette cannot express in the absence of the inducing agent. We used the Cre ER(T2) cassette, which is regulated by the addition of the estrogen antagonist tamoxifen to determine whether cross-contamination of tamoxifen between animals housed together can be a significant source of spurious results. We found that cross-contamination of exogenous tamoxifen does occur. It occurred in all animals tested. We suggest that the mechanism of contamination is through exposure to tamoxifen in the general environment and/or to coprophagous behavior. These results have important implications for the interpretation and design of experiments that use 'inducible' transgenic animals.     

MicroRNA-restricted transgene expression in the retina

Background

Gene transfer using adeno-associated viral (AAV) vectors has been successfully applied in the retina for the treatment of inherited retinal dystrophies. Recently, microRNAs have been exploited to fine-tune transgene expression improving therapeutic outcomes. Here we evaluated the ability of retinal-expressed microRNAs to restrict AAV-mediated transgene expression to specific retinal cell types that represent the main targets of common inherited blinding conditions.

Methodology/Principal Findings

To this end, we generated AAV2/5 vectors expressing EGFP and containing four tandem copies of miR-124 or miR-204 complementary sequences in the 3′UTR of the transgene expression cassette. These vectors were administered subretinally to adult C57BL/6 mice and Large White pigs. Our results demonstrate that miR-124 and miR-204 target sequences can efficiently restrict AAV2/5-mediated transgene expression to retinal pigment epithelium and photoreceptors, respectively, in mice and pigs. Interestingly, transgene restriction was observed at low vector doses relevant to therapy.

Conclusions

We conclude that microRNA-mediated regulation of transgene expression can be applied in the retina to either restrict to a specific cell type the robust expression obtained using ubiquitous promoters or to provide an additional layer of gene expression regulation when using cell-specific promoters.     

Complement inhibition rescued mice allowing observation of transgene expression following intraportal delivery of baculovirus in mice

BACKGROUND: The baculovirus Autographa californica nucleo-polyhedrosis virus (AcNPV) is an alternative to other viral vectors for hepatic gene delivery. A barrier to AcNPV being used in vivo is its susceptibility to inactivation by serum complement 1. In vivo utility has only been demonstrated using methods that avoid contact with serum 2-5. We have studied the complement pathways involved in baculovirus inactivation in vitro and the systemic administration of baculovirus vectors in vivo, with the co-administration of the complement inhibitor, soluble complement inhibitor 1 (sCR1). RESULTS: EDTA increased baculovirus survival in human serum more than EGTA showing that both the alternative and classical pathways of complement are activated. Depleting serum of IgM increased survival, whereas reconstitution with pooled IgM restored activity against baculovirus, suggesting naturally occurring IgM antibodies with affinity for baculovirus may be partially responsible for complement activation. Intraportal administration of baculovirus led to hepatic expression when the complement inhibitor sCR1 (soluble complement receptor type 1) was co-administered by tail vein injection; however, liver histology showed hepatic necrosis. Without co-administration of sCR1, intraportal infusion of baculovirus was fatal within 24 h. Histology demonstrated massive hepatic necrosis. Yolk sac vein injection of baculovirus was associated with fetal death. CONCLUSIONS: Transgene expression was demonstrated following intraportal infusion of recombinant baculovirus vectors in combination with sCR1; however, our experiments suggest a significant associated toxicity.     

Relevance of BAC transgene copy number in mice: transgene copy number variation across multiple transgenic lines and correlations with transgene integrity and expression

Bacterial artificial chromosomes (BACs) are excellent tools for manipulating large DNA fragments and, as a result, are increasingly utilized to engineer transgenic mice by pronuclear injection. The demand for BAC transgenic mice underscores the need for careful inspection of BAC integrity and fidelity following transgenesis, which may be crucial for interpreting transgene function. Thus, it is imperative that reliable methods for assessing these parameters are available. However, there are limited data regarding whether BAC transgenes routinely integrate in the mouse genome as intact molecules, how BAC transgenes behave as they are passed through the germline across successive generations, and how variation in BAC transgene copy number relates to transgene expression. To address these questions, we used TaqMan real-time PCR to estimate BAC transgene copy number in BAC transgenic embryos and lines. Here we demonstrate the reproducibility of copy number quantification with this method and describe the variation in copy number across independent transgenic lines. In addition, polymorphic marker analysis suggests that the majority of BAC transgenic lines contain intact molecules. Notably, all lines containing multiple BAC copies also contain all BAC-specific markers. Three of 23 founders analyzed contained BAC transgenes integrated into more than one genomic location. Finally, we show increased BAC transgene copy number correlates with increased BAC transgene expression. In sum, our efforts have provided a reliable method for assaying BAC transgene integrity and fidelity, and data that should be useful for researchers using BACs as transgenic vectors.     

Variations of cervical vertebrae after expression of a Hox-1.1 transgene in mice

To understand the function of murine homeobox genes, a genetic analysis is mandatory. We generated gain-of-function mutants by introducing genomic sequences of the Hox-1.1 gene under the control of a chicken beta-actin promoter into mice. Our previous data had shown that these transgenic mice are nonviable after birth and are born with craniofacial abnormalities. In a subsequent detailed analysis of severely affected animals, malformations of the basioccipital bone, the atlas, and the axis were observed. Manifestation of an additional vertebra, a proatlas, occurred at the craniocervical transition. The dominant interference of the Hox-1.1 transgene with developmental programs seems to occur around day 9 of gestation, the time of neural crest migration and somite differentiation. We discuss the resulting phenotype with respect to a developmental control function of Hox-1.1.     

The human growth hormone transgene: expression in hemizygous and homozygous mice

Female transgenic mice carrying the mouse metallothionein-I/human growth hormone (hGH) fusion gene are sterile. Transmission of the transgene has been limited to the male germ line, resulting in the production of hemizygous (He) progeny containing only a single (paternal) copy of the gene. Using ovary transfer, we have developed procedures for producing homozygous (Ho) TG mice, viz., male TG mice were mated with control (non-TG) females carrying ovaries donated by female TG mice. In both He and Ho TG animals, serum levels of hGH were higher (1.5-fold) in males than in females, tended to decrease with age of the animal, and were increased (about 5-fold) by zinc induction. However, in comparison to He animals of the same sex, the Ho TG mice attained a greater body weight and had more than 2-fold higher levels of liver hGH-mRNA and serum hGH, both under basal conditions and in response to zinc induction. That is, the expression of the transgene was qualitatively similar in He and Ho TG mice, but the level of transgene activity was greater in the Ho animals. We interpret this to indicate that both copies (maternal and paternal) of the transgene were active and expressed additively (or cooperatively) in the Ho TG animal.     

Failure of founder transgenic male mice to transmit an attenuated HSV thymidine kinase transgene results from mosaicism and sperm competition

Previously we found that male mice carrying either of two attenuated herpes simplex virus thymidine kinase reporter transgenes displayed low level ectopic expression of the reporter gene in the testis and, although fertile, exhibited reduced fecundity. In contrast to males of later generations, many of the founder males failed to transmit the transgene to their progeny. This led to the suggestion that these fertile non-transmitting males are mosaic, with the sperm developing from the non-transgenic lineage outperforming those from the heterozygous transgenic lineage. Here we present the results of artificial insemination (AI) and in vitro fertilization (IVF) experiments designed to test this hypothesis. Albino CF(1) hybrid females were inseminated with mixtures of equal numbers of sperm from heterozygous transgenic (HT) males (equivalent to C57BL/6 x CBAF(2)) and CF(1) males. Similar mixed inseminations were carried out in parallel with sperm from non-transgenic (NT) siblings of the HT mice and 13-day fetuses were scored by eye color to determine their paternity. The pooled data from five experiments gave ratios of CF(1) to HT and CF(1) to NT offspring of 8.13 and 0.22 respectively, implying a calculated HT to NT ratio of 0.027. This indicates that, in competition with each other, the NT sperm would be almost 40 times more successful in fertilization than the HT sperm. Smaller differences were observed between HT and NT when AI was performed with unmixed sperm, consistent with the fertility of HT non-founder males. However, in five IVF experiments carried out with unmixed sperm, 142/212 oocytes exposed to NT sperm were activated and divided, while only 8/226 oocytes treated with HT sperm reached the two-cell stage. This confirms that HT sperm are defective and indicates that the IVF method employed amplified these deficiencies, which may have only a small effect upon natural reproduction when the HT sperm are not in competition with normal sperm.