The visna virus long terminal repeat directs expression of a reporter gene in activated macrophages, lymphocytes, and the central nervous systems of transgenic mice.

Visna virus is a lentivirus which causes a slow progressive disease involving the immune system and the central nervous system. To determine the role of the viral long terminal repeat (LTR) in targeting the virus to specific host cells and tissues, transgenic mice were constructed which contained the visna virus LTR directing expression of the bacterial gene encoding chloramphenicol acetyltransferase (CAT). Analysis of the transgenic mouse tissues for CAT activity revealed that the viral LTR was responsible, in part, for the tropism of visna virus for macrophages and the central nervous system. Expression of the LTR required the macrophage to be in an activated state both in vivo and in vitro. Thioglycolate activation of peritoneal macrophages in vivo and 12-O-tetradecanoylphorbol 13-acetate treatment in vitro induced expression of the visna virus LTR. Lymphocytes from the spleens of the transgenic mice expressed CAT activity, suggesting that visna virus was able to replicate in lymphocytes, as did human immunodeficiency virus and simian immunodeficiency virus. These studies demonstrated that the lentivirus LTR was responsible, in part, for cell and tissue tropism in vivo.     

Cryptic human growth hormone gene sequences direct gonadotroph-specific expression in transgenic mice

Our laboratory reported previously that chimeric genes encoding either rat somatostatin (SS) or human GH (hGH), but containing the identical mouse metallothionein-I (MT) promoter/enhancer sequences and hGH 3'-flanking sequences, were selectively expressed in the gonadotrophs of transgenic mice. The experiments reported here were designed to identify the DNA sequences responsible for this unexpected cell-specific expression within the anterior pituitary. We produced new transgenic mice expressing fusion genes that tested separately the requirement of the MT or 3'-hGH sequences for gonadotroph expression. A fusion gene that retained the original MT and SS sequences, with a simian virus 40 polyadenylation signal exchanged for the 3'-hGH sequences, no longer directed strong pituitary expression, but was active in the liver. In contrast, a cytomegalovirus promoter/enhancer-SS-hGH fusion gene was expressed at the same high level in the anterior pituitaries of transgenic mice as the originally studied MT-SS-hGH gene. Immunohistochemical analysis indicated that pituitary expression of the cytomegalovirus promoter/enhancer-SS-hGH fusion gene was also restricted to gonadotroph cells in adult mice. These studies indicate that sequences within the 3'-flanking region of the hGH gene can direct expression of chimeric genes to pituitary cells that do not normally produce growth hormone.     

Immunohistochemical detection of mammary tumor virus antigens in sweat and sebaceous glands of mice

Mammary tumor virus (MTV) antigens in both sexes of GRS/A, SHN and C3H mice were examined in the sweat and sebaceous glands by immunoperoxidase technique using antiserum against gp52, envelope protein, or p27, core protein. Balb/c mice were used for reciprocal foster nursing with these inbreds to discriminate the expression of endogenous MTV from that of exogenous MTV. Both antigens were first detected around the age of 4 months in the sweat glands of mice with endogenous GR- or SHN- MTV. A linear staining of gp52 was seen along the luminal borders of glandular cells, and the reaction products for gp52 were demonstrated on the apical cell membranes, where no virion could be seen ultrastructurally. A diffuse staining of p27 was found in the cytoplasm of some glandular cells, where MTV particles could not be detected. In the sebaceous gland of the same mice, however, only p27 was first detected at the age of 60 days. A dot-like staining of p27 was found in the perinuclear region of some glandular cells, where an aggregation of intracytoplasmic A particles could be seen under an electron microscope. These positive stainings were unrelated to sex. In such skin appendages of all examined C3H mice and Balb/c mice with GR- or SHN- MTV, no antigen expression could be seen up to the age of 500 days. Therefore, some genes might be able to regulate the expression of endogenous MTV antigens in the skin appendages, while their glandular cells would have no receptor for exogenous MTV, namely the so-called "milk factor".