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.     

Deletion analysis of the human CD2 gene locus control region in transgenic mice.

Genomic sequences located at the 3' flanking region of the human CD2 gene confer high level tissue-specific, position-independent expression of the gene when introduced in the germ line of mice. In order to further characterize these sequences a range of deletions, from the 3' end were produced and transgenic mice were generated with the human CD2 (hCD2) gene linked to these deleted fragments. This allowed us to establish the minimum sequences necessary for the copy-dependent transgene expression. 2.1 kb or 1.5 kb of 3' flanking sequences linked to a hCD2 mini-gene is sufficient to allow T-cell specific, copy-dependent, integration-independent expression in transgenic mice. 1.1 kb of 3' sequences results in the gene being expressed in a T-cell specific manner, but copy-dependent, integration-independent expression was not observed in a small number of transgenic animals. 0.2 or 0.5 kb of 3' flanking sequences were insufficient to allow expression above the level previously found with a human CD2 gene which lacked 3' flanking sequences. We conclude that the Locus Control Region (LCR) effect is caused by 1.5 kb of flanking sequences immediately 3' to the polyadenylation signal of the gene.     

Tissue-specific, high level expression of the rat whey acidic protein gene in transgenic mice.

The importance of intragenic and 3' flanking sequences in the control of the temporal, hormonal and tissue-specific expression of milk whey acidic protein (WAP) has been demonstrated in transgenic mice. Mouse lines carrying a 4.3 kb genomic clone containing the entire rat WAP gene minus 200 bp of the first intron with 0.949 kb of 5' and 1.4 kb of 3' flanking DNA were generated. In eight of nine independent lines of mice analyzed, WAP transgene expression was detected at levels ranging from 1% to 95% (average, 27%) of the endogenous gene. The transgene was expressed preferentially in the mammary gland. Although developmentally regulated during pregnancy and lactation, the temporal pattern of WAP transgene expression differed from the endogenous gene. A precocious increase in expression of the transgene was detected at 7 days of pregnancy, several days earlier in pregnancy than the major increase observed in endogenous mouse WAP mRNA. The rat WAP transgene was translated and secreted into the milk of transgenic mice at levels comparable to the endogenous mouse WAP. This is the first report of a gene that is negatively regulated in dissociated cell cultures as well as in transfected cells, yet is expressed efficiently in the correct multicellular environment of the transgenic mouse.     

Complementation of null CF mice with a human CFTR YAC transgene.

We have made transgenic mice carrying a 320 kb YAC with the intact human cystic fibrosis transmembrane regulator (CFTR) gene. Mice that only express the human transgene were obtained by breeding with Cambridge null CF mice. One line has approximately two copies of the intact YAC. Mice carrying this transgene and expressing no mouse cftr appear normal and breed well, in marked contrast to the null mice, where 50% die by approximately 5 days after birth. The chloride secretory responses in these mice are as large or larger than in wild-type tissues. Expression of the transgene is highly cell type specific and matches that of the endogenous mouse gene in the crypt epithelia throughout the gut and in salivary gland tissue. However, there is no transgene expression in some tissues, such as the Brunner's glands, where it would be expected. Where there are differences between the mouse and human pattern of expression, the transgene follows the mouse pattern. We have thus defined a cloned fragment of DNA which directs physiological levels of expression in many of the specific cells where CFTR is normally expressed.     

High-level salivary gland expression in transgenic mice

A 7.1 kb mini-gene construct containing cloned DNA from the murine parotid secretory protein (PSP) gene with 6.2 kb of the promoter, has previously been shown to direct specific mRNA expression to the salivary glands in transgenic mice. However, the level of transgene expression in the parotid gland was only a few percent of the endogenous level. This indicated that elements necessary for high-level expression are still to be found. In this study, we have searched for such regulatory elements in additional flanking regions by using a 25 kb clonedPsp ^b fragment containing the complete structural gene, 11.4 kb of 5-flanking sequence, and 2.5 kb 3-flanking sequence as a transgene. To distinguish the expression of the transgene from that of the endogenous gene, we took advantage of an allelic difference, using an oligonucleotide that recognized the mRNA fromPsp ^b and the transgene but not that from the other allele,Psp ^a . The expression of the transgene was examined in animals homozygous forPsp ^a . Three independent integrations all exhibited a level of parotid-gland-specific expression that corresponded to that of the endogenous gene. Thus, sequences responsible for this high-level PSP mRNA expression are situated within the genomic DNA of the transgene.     

Differential regulation of the rat phosphoenolpyruvate carboxykinase gene expression in several tissues of transgenic mice.

The selective expression of a unique copy gene in several mammalian tissues has been approached by studying the regulatory sequences needed to control expression of the rat phosphoenolpyruvate carboxykinase (PEPCK) gene in transgenic mice. A transgene containing the entire PEPCK gene, including 2.2 kb of the 5'-flanking region and 0.5 kb of the 3'-flanking region, exhibits tissue-specific expression in the liver, kidney, and adipose tissue, as well as the hormonal and developmental regulation inherent to endogenous gene expression. Deletions of the 5'-flanking region of the gene have shown the need for sequences downstream of position -540 of the PEPCK gene for expression in the liver and sequences downstream of position -362 for expression in the kidney. Additional sequences upstream of position -540 (up to -2200) are required for expression in adipose tissue. In addition, the region containing the glucocorticoid-responsive elements of the gene used by the kidney was identified. This same sequence was found to be needed specifically for developmental regulation of gene expression in the kidney and, together with upstream sequences, in the intestine. The apparently distinct sequence requirements in the various tissues indicate that the tissues use different mechanisms for expression of the same gene.     

Synthesis and secretion of the mouse whey acidic protein in transgenic sheep

The synthesis of foreign proteins can be targeted to the mammary gland of transgenic animals, thus permitting commercial purification of otherwise unavailable proteins from milk. Genetic regulatory elements from the mouse whey acidic protein (WAP) gene have been used successfully to direct expression of transgenes to the mammary gland of mice, goats and pigs. To extend the practical usefulness of WAP promoter-driven fusion genes and further characterize WAP expression in heterologous species, we introduced a 6.8 kb DNA fragment containing the genomic form of the mouse WAP gene into sheep zygotes. Two lines of transgenic sheep were produced. The transgene was expressed in mammary tissue of both lines and intact WAP was secreted into milk at concentrations estimated to range from 100 to 500 mg/litre. Ectopic WAP gene expression was found in salivary gland, spleen, liver, lung, heart muscle, kidney and bone marrow of one founder ewe. WAP RNA was not detected in skeletal muscle and intestine. These data suggest that unlike pigs, sheep may possess nuclear factors in a variety of tissues that interact with WAP regulatory sequences. Though the data presented are based on only two lines, these findings suggest WAP regulatory sequences may not be suitable as control elements for transgenes in sheep bioreactors.     

Analysis of the Alternative Promoters that Regulate Tissue-Specific Expression of Human Aromatic l-Amino Acid Decarboxylase

Abstract: Previously we identified two alternative first exons (exon N1 and exon L1) coding for 5' untranslated regions of human aromatic l -amino acid decarboxylase (AADC) and found that their alternative usage produced two types of mRNAs in a tissue-specific manner. To determine the cis -acting element regulating the tissue-specific expression of human AADC, we produced three kinds of transgenic mice harboring 5' flanking regions of the human AADC gene fused to the bacterial chloramphenicol acetyltransferase (CAT) gene. The transgene termed ACA contained −7.0 kb to −30 bp in exon N1, including the entire exon L1; ACN contained −3.6 kb to −30 bp in exon N1; and ACL contained −2.8 kb to −42 bp in exon L1. The ACA transgenic mice expressed CAT at extremely high levels in peripheral nonneuronal tissues, such as pancreas, liver, kidney, small intestine, and colon, that contained endogenous high AADC activity, whereas CAT immunoreactivity was not detected in either catecholaminergic or serotonergic neurons in the CNS. Thus, it was suggested that the ACA transgene contained the major part of cis -regulatory elements for the expression of AADC in peripheral nonneuronal tissues. On the other hand, the ACN transgenic mice moderately expressed CAT in various tissues except for the lung and liver, and the ACL transgenic mice showed moderate CAT expression only in the kidney.