Widespread long-term gene transfer to mouse skeletal muscles and heart

Successful treatment of muscular disorders awaits an adapted gene delivery protocol. The clinically applicable technique used for hematopoietic cells which is centered around implantation of retrovirally modified cells may not prove sufficient for a reversal of phenotype when muscle diseases are concerned. We report here efficient, long-term in vivo gene transfer throughout mouse skeletal and cardiac muscles after intravenous administration of a recombinant adenovirus. This simple, direct procedure raises the possibility that muscular degenerative diseases might one day be treatable by gene therapy.

Interleukin-13 gene expression is regulated by GATA-3 in T cells: role of a critical association of a GATA and two GATG motifs

Using a transgenic approach, we studied the role of GATA-3 in T cells. As previously shown, enforced GATA-3 expression in transgenic mice inhibits Th1 differentiation of CD4 T cells, but unexpectedly, both type 1 (interferon gamma) and type 2 (interleukin (IL)-4 and IL-13) cytokine genes were activated in the transgenic CD8 T cells. Because IL-13 gene expression was highly enhanced in vivo by GATA-3 expression, we studied the human and the mouse IL-13 gene promoters and found an evolutionary-conserved association of a consensus GATA binding site and two GATG motifs. We showed that efficient GATA-3 binding to this regulatory sequence required these three motifs and that the affinity of the GATA zinc fingers for this association was five times higher than for the consensus GATA binding site alone. Transfections in a T cell line or transactivation by GATA-3 showed that the combination of the three sites was required for full transcriptional activity of the IL-13 gene promoter. Finally we showed that this association of binding sites causes a very high sensitivity of the IL-13 gene promoter to small variations in the level of GATA-3 protein. Altogether, these results indicate an important role of GATA-3 in CD8 cytokine gene expression and demonstrate that a critical network of GATA binding sites highly modulates GATA-3 activity.

Determinants of the brain-specific expression of the rat aldolase C gene: ex vivo and in vivo analysis

A 115-bp promoter fragment of the aldolase C gene is sufficient for conferring neural cell specificity on a reporter gene, in cultured PC12 cells and in transgenic mice. In vitro DNase I protection experiments detected two footprints on the promoter, termed boxes A/A', and B. The 5' A/A' box contains overlapping Sp1 and Krox20/Krox24 binding sites; it binds Sp1 in fibroblasts (box A') and a different complex in brain (box A). Any deletion or mutation of this box that impairs protein recognition also suppresses promoter activity. The replacement of box A/A' by a Sp1 consensus binding site results in the loss of the brain specificity of expression in transgenic mice. Further 3', box B is composed of a 5' direct repeat and a 3' GC box consisting of overlapping Sp1 and Krox20/Krox24 binding sites. Mutation of the direct repeat subregion appears to be more deleterious for the promoter activity than mutation of the G+C-rich subregion.

Specific atrial overexpression of G protein coupled human beta 1 adrenoceptors in transgenic mice

OBJECTIVE

The aim was to develop a transgenic mouse model of atrial beta 1 adrenoceptor overexpression in order to create atrial alteration of the receptor transduction system.

METHODS

Transgenic founders were generated after microinjection of the transgene construct into the pronucleus of fertilised mouse eggs. Heterozygous progeny were screened for RNA expression of the human beta 1 adrenoceptor gene under the control of a 0.56 kb proximal promoter of the human atrial natriuretic factor. One line, out of the three obtained, was selected and further characterised for overexpression of the human beta 1 adrenoceptor. Polymerase chain reaction was employed to detect beta 1 adrenoceptor mRNA, and 125I-cyanopindolol (ICYP) binding assays were used to quantify receptors in heart membranes. A quantitative autoradiographic ICYP binding technique was also used to visualise atrial and ventricular beta adrenoceptors in heart sections.

RESULTS

The human beta 1 adrenoceptor was overexpressed specifically in the atria of transgenic mice. The level of the beta 1 adrenoceptor was 5-10-fold higher in transgenic mice compared to basal murine beta 1 adrenoceptors in non-transgenic control mice. Left and right atrial receptor overexpression was confirmed by in vitro autoradiography. The human receptors were able to couple to the murine stimulatory G proteins (Gs), as shown by high affinity binding site dosage using the beta adrenoceptor agonist isoprenaline. Isoprenaline displacement studies allowed the determination of two different affinity sites, one of high affinity (KH = 5.8 nM), and one of low affinity (KL = 520 nM). When expressed in terms of protein density (fmol.mg-1), atrial transgenic beta 1 adrenoceptors displayed a threefold increase in high affinity sites (KH) as compared to control mice. Preliminary electrocardiographic data showed supraventricular premature beats in 6/14 transgenic mice v 2/16 control mice.

CONCLUSIONS

These transgenic mice may provide a useful pharmacological tool to investigate the pathophysiological consequences of the overactivation of atrial beta 1 adrenoceptor-adenylyl cyclase signalling system.

Cell-type-specific expression and regulation of a c-fos-NGF fusion gene in neurons and astrocytes of transgenic mice

A mouse line transgenic for nerve growth factor (NGF) was developed using the mouse prepro-NGF cDNA inserted within a plasmid containing the proximal region (-10 to -550 bp) of the c-fos promoter and the transcription termination and polyadenylation signals of the rabbit beta-globin gene. No significant modification of gross behavior or central nervous system anatomy was detected in adult animals as assessed by immunohistochemistry and in situ hybridization for NGF and choline acetyltransferase. The expression of the transgene and the possible regulation of its expression by agents acting on the promoter were investigated in vitro. Despite the presence of an additional pool of NGF mRNA specific to the transgene, basal levels of NGF in the supernatant of transgenic astrocytes were similar to normal ones. On the other hand, transgenic neurons spontaneously synthesized and released levels of NGF two to three times higher than normal neurons, while mRNA levels were barely detectable by conventional Northern blotting. The tissue-specificity of NGF expression was respected, with higher levels in hippocampal than neocortical neurons. Increases of NGF mRNA by agents acting on the promoter could be observed in normal and transgenic astrocytes only after inhibition of the protein synthesis by cycloheximide, suggesting a similar rapid turnover of normal and transgenic transcripts. Cyclic AMP agonists specifically increased the secretion of NGF protein by transgenic astrocytes and neurons, while activators of the protein kinase C had a similar effect on transgenic and normal cells. Differences between amounts of NGF secreted by neurons and astrocytes with regards to their respective content in mRNA suggest that transgenic transcripts are subject to normal cell- and tissue-specific post-transcriptional regulations. Agents acting on the c-fos promoter through the protein kinase C or cyclic AMP routes differentially increased the secretion of NGF by transgenic astrocytes or neurons, supporting this hypothesis.

Analysis of a brain-specific isozyme. Expression and chromatin structure of the rat aldolase C gene and transgenes

Aldolase C mRNA is detected by Northern blot in all fetal tissues in rat; it is very abundant in the adult brain and undetectable in the other adult tissues. However, reverse transcriptase polymerase chain reaction amplification indicates that this gene is not totally repressed in these tissues. A DNase-I hypersensitivity site located in a 115-base pair proximal promoter fragment is detectable in the brain as well as in other adult tissues. Two MspI/HpaII restriction sites located at -3800 and -450 base pairs are demethylated in the brain and totally or partially methylated in other tissues. In transgenic mice, a 12.5-kilobase genomic fragment is strongly and tissue specifically expressed in different lines, with conservation of a methylation pattern similar to that of the endogenous gene. A chloramphenicol acetyltransferase gene directed by either 800 or 115 base pairs of aldolase C 5'-flanking sequences is tissue specifically expressed in transgenic mice, but the level of expression is very low. This level is greatly increased when the transgene consists of a chloramphenicol acetyltransferase hybrid gene directed by 5.5 kilobases of aldolase C 5'-flanking sequences. We propose therefore that the chromatin structure around the aldolase C promoter is accessible in fetal tissues, then remains open in the adult brain, where the gene is very active, as well as in tissues in which it is practically inactive. The specificity of expression in the brain is conferred by a short 115-base pair proximal promoter fragment that needs more upstream sequences to be fully active.