In vitro Cre/loxP system in cells from developing gonads: investigation of the Sry promoter

There have been few studies on the regulatory elements of the Sry gene, mainly because no Sry-expressing cell lines have yet been established. This paper describes a useful tool for investigating the regulation and upstream region of Sry by means of the in vitro Cre/loxP system. Using plasmids containing the 9.9 kb mouse genomic Sry previously shown to induce testis development in XX transgenic mice, we constructed a Sry/Cre fusion gene plasmid in which Cre expression is controlled by the 5' and 3' untranslated regions of mouse Sry. To distinguish between male and female gonads of 11.5 days post-coitus (d.p.c.) fetuses, double transgenic fetuses carrying both the CAG (cytomegalovirus enhancer and beta-actin promoter)/loxP/lacZ transgene on the autosome and the green fluorescent protein transgene ubiquitously expressed on the Y chromosome were produced by crossing between two transgenic mouse lines. When Sry/Cre plasmids were transfected into the cells that had been prepared from the gonads, brains and livers of double transgenic fetuses, only a small number of X-gal-stained cells were detected among the primary cultured cells from male and female gonads, and none were detected among the cells from the other tissues. The X-gal-positive cells were negative for alkaline phosphatase, indicating that these cells were somatic cells expressing Sry. The Sry/Cre plasmids with a 0.4 kb upstream region of Sry yielded a large number of X-gal-positive cells in the cells from gonads, including various tissues of 11.5 d.p.c. fetuses, indicating the loss of the tissue-specific expression of Sry. The Sry/Cre with a 1.4 kb upstream region maintained tissue-specific activity of Sry. The results indicate that the present in vitro Cre/loxP system using transgenic mice is a simple and useful system for investigating the regulatory element of sex determination-related genes, including Sry.     

Enteroendocrine cell expression of a cholecystokinin gene construct in transgenic mice and cultured cells

CCK is predominantly expressed in subsets of endocrine cells in the intestine and neurons in the brain. We evaluated the expression of a CCK gene construct in transgenic mice and cultured cells to identify a genomic region that directs correct tissue- and cell-specific expression in enteroendocrine cells. The CCKL1 transgene contained 6.4 kb of mouse Cck fused to lacZ. Expression was evaluated in three transgenic lines (J11, J12, J14) by measurement of beta-galactosidase in tissue homogenates and frozen sections. Correct tissue-specific expression was observed, with beta-galactosidase activity detected in intestine and brain. However, there were differences seen in cell-specific expression in the intestine. Line J14 exhibited expression in CCK-endocrine cells, with expressing cells arising at the normal time during fetal development. However, transgene expression in line J12 intestine was limited to neurons of the enteric nervous system, which reflect an early fetal expression pattern for CCK. Analysis of an additional 15 transgenic founder mice demonstrated intestinal expression in 40% of transgenics, with expressing mice following either an endocrine cell pattern or a neuronal pattern in approximately equal numbers. CCKL1 transfection analysis in cultured cells also demonstrated enteroendocrine cell expression, with 100-fold enhanced activity in the enteroendocrine cell line STC-1 compared with nonendocrine cell lines. The results suggest that the minimal cis-regulatory DNA elements necessary for appropriate CCK expression in enteroendocrine cells reside within the 6.4-kb mouse genomic fragment.     

Analysis of spatiotemporal regulation of aromatase in the brain using transgenic mice

Brain aromatase is widely distributed in the vertebrates, from fish to mammals, and plays important roles in functional reproductive behavior through production of estrogen as a neurosteroid. It is expressed only in the nerve cells of specific brain regions with a transient peak in the neonatal period when sexual behavior becomes organized, and therefore provides a good model system to study regulatory mechanism of cell-specific, brain region-specific, and developmental stage-specific expression.

To elucidate spatiotemporal regulation of brain aromatase, we prepared transgenic mice carrying a reporter gene under the promoter of brain-specific exon 1f of the mouse aromatase gene. The reporter transgene carrying a 6.5 kb upstream region of the brain-specific promoter accurately reproduced the spatiotemporal expression patterns of aromatase in mouse brain, whereas transgenes carrying smaller fragments of the promoter showed ambiguous or inconsistent expression patterns.

The binding sites of Aro-AI, Aro-AII, and Aro-B for nuclear factors were also identified in the proximal region of the exon 1f brain-specific promoter. Introduction of a mutation into the Aro-AII site in the reporter transgene carrying −6.5 kb promoter region of exon 1f caused complete alteration of the spatiotemporal expression pattern of the reporter gene in the transgenic mice.

These results indicate that the −6.5 kb promoter region of exon 1f is the minimal essential element for brain-specific regulation, with both proximal and distal promoter regions required for accurate spatiotemporal expression of aromatase in the mouse brain.     

Comparison of amyloid deposition in two lines of transgenic mouse that model familial amyloidotic polyneuropathy,type I

We previously produced a transgenic mouse line designated MT-hMet30 by introducing the human mutant transthyretin (TTR) gene carrying the mouse metallothionein promoter, and showed that the presence of human variant TTR is sufficient for amyloid deposition in various tissues of these transgenic mice. However, the expression pattern of human mutant transthyretin gene in the mouse was different from that in man. To analyse pathologic processes, it is essential to establish a transgenic mouse line in which the developmental and tissue- specific expression of the human mutant TTR gene is the same as in man. Thus, we produced two additional transgenic mouse lines carrying the human mutant TTR gene containing either 0.6 kb (0.6- hMet30) or 6.0 kb (6.0-hMet30) of the upstream region. The expression levels of 6.0-hMet30 gene in the liver and serum were the same as in man and about 10 times higher than those of 0.6- hMet30 gene. In both lines amyloid deposition was observed in similar tissues to human patients except for the peripheral and autonomic nervous tissues. The amyloid deposition started earlier and was more extensive in 6.0-hMet30 than 0.6-hMet30 mice, suggesting that the serum levels of human mutant TTR are correlated with the occurrence and degree of amyloid deposition, to some extent. Neither amyloid deposition nor degenerative changes were observed in the peripheral and autonomic nervous systems despite the transgene expression in the choroid plexus of the 6.0-hMet30 mice. In the 6.0-hMet30 mice, amyloid deposition started at 9 months of age, although the serum level of human mutant TTR reached the adult level at 1 month. These results suggest that intrinsic environmental factors other than the mutant gene are involved in the late-onset deposition of amyloid fibrils. Transgenic mice described here should be useful for analysing such factors     

Analysis of control elements for position‐independent expression of human α‐lactalbumin YAC

A major problem in the production of transgenic animal bioreactors using microinjections is the low production rate of high‐expressing transgenic animals due to the position effect. We previously reported that transgenic rats carrying the 210 kb yeast artificial chromosome (YAC) including the human α‐lactalbumin gene express the transgene in a position‐independent manner. The 210 kb YAC was thought to have all the elements necessary for position‐independent expression. In this paper, we constructed fragmented YAC clones and a cosmid clone, and produced transgenic rats to analyze these elements. Transgenic rats with both the 50 kb upstream and downstream regions of the α‐lactalbumin gene had position‐independent expression. Transgenic rats with the 20 kb upstream and downstream regions, however, had position‐dependent expression. Therefore, all the elements necessary for position‐independent expression are thought to be located in the 50 kb upstream to 50 kb downstream region of the α‐lactalbumin gene. Furthermore, we replaced the human α‐lactalbumin promoter with the bovine αS1‐casein promoter in the 210 kb YAC and produced transgenic rats. Position‐dependent expression was observed. The elements required for position‐independent expression of the bovine αS1‐casein gene are different from those required for the human α‐lactalbumin gene, despite the fact that the two genes have the same tissue and developmental specificity. Mol. Reprod. Dev. 54:17–23, 1999. © 1999 Wiley‐Liss, Inc.     

Analysis of tissue-specific expression of human type II collagen cDNA driven by different sizes of the upstream region of the beta-casein promoter

To investigate the ability of 1.8 kb or 3.1 kb bovine beta-casein promoter sequences for the expression regulation of transgene in vivo, transgenic mice were produced with human type II collagen gene fused to 1.8 kb and 3.1 kb of bovine beta-casein promoter by DNA microinjection. Five and three transgenic founder mice were produced using transgene constructs with 1.8 kb and 3.1 kb of bovine beta-casein promoters respectively. Founder mice were outbred with the wild type to produce F1 and F2 progenies. Total RNAs were extracted from four tissues (mammary gland, liver, kidney, and muscle) of female F1 transgenic mice of each transgenic line following parturition. RT-PCR and Northern blot analysis revealed that the expression level of transgene was variable among the transgenic lines, but transgenic mice containing 1.8 kb of promoter sequences exhibited more leaky expression of transgene in other tissues compared to those with 3.1 kb promoter. Moreover, Western blot analysis of transgenic mouse milk showed that human type II collagen proteins secreted into the milk of lactating transgenic mice contained 1.8 kb and 3.1 kb of bovine beta-casein promoter. These results suggest that promoter sequences of 3.1 kb bovine beta-casein gene can be used for induction of mammary gland-specific expression of transgenes in transgenic animals.     

A potent far-upstream enhancer in the mouse pro alpha 2(I) collagen gene regulates expression of reporter genes in transgenic mice

We have identified three DNase I-hypersensitive sites in chromatin between 15 and 17 kb upstream of the mouse pro alpha 2 (I) collagen gene. These sites were detected in cells that produce type I collagen but not in cells that do not express these genes. A construction containing the sequences from -17 kb to +54 bp of the mouse pro alpha 2 (I) collagen gene, cloned upstream of either the Escherichia coli beta- galactosidase or the firefly luciferase reporter gene, showed strong enhancer activity in transgenic mice when compared with the levels seen previously in animals harboring shorter promoter fragments. Especially high levels of expression of the reporter gene were seen in dermis, fascia, and the fibrous layers of many internal organs. High levels of expression could also be detected in some osteoblastic cells. When various fragments of the 5' flanking sequences were cloned upstream of the 350-bp proximal pro alpha 2(I) collagen promoter linked to the lacZ gene, the cis-acting elements responsible for enhancement were localized in the region between -13.5 and -19.5 kb, the same region that contains the three DNase I-hypersensitive sites. Moreover, the DNA segment from -13.5 to -19.5 kb was also able to drive the cell-specific expression of a 220-bp mouse pro alpha 1(I) collagen promoter, which is silent in transgenic mice. Hence, our data suggest that a far-upstream enhancer element plays a role in regulating high levels of expression of the mouse pro alpha 2(I) collagen gene.