Tissue-specific expression of the human renin gene in transgenic mice

Transgenic mice carrying human renin gene were produced by microinjection of 15 kilobases (kb) DNA molecules with up to 3 kb of 5'-flanking sequence and 1.2 kb of 3'-flanking sequence. The transgenes have been shown to be stably transmitted to progeny. It was revealed by RNase protection assay that the human renin gene in a transgenic mouse is expressed preferentially in the kidney. The human renin RNA was also detected at a small level in a variety of tissues such as brain, heart, lung, pancreas, spleen, stomach, testis, and thymus. The direct radioimmunoassay using a monoclonal antibody specific for the active site of human renin demonstrated the synthesis of human active renin in the transgenic mouse kidney. These results suggest that the human renin gene in the transgenic mouse is regulated in a tissue-specific manner.     

Tissue-specific differences in cytosine methylation and their association with differential gene expression in sorghum

It has been well established that DNA cytosine methylation plays essential regulatory roles in imprinting gene expression in endosperm, and hence normal embryonic development, in the model plant Arabidopsis (Arabidopsis thaliana). Nonetheless, the developmental role of this epigenetic marker in cereal crops remains largely unexplored. Here, we report for sorghum (Sorghum bicolor) differences in relative cytosine methylation levels and patterns at 5'-CCGG sites in seven tissues (endosperm, embryo, leaf, root, young inflorescence, anther, and ovary), and characterize a set of tissue-specific differentially methylated regions (TDMRs). We found that the most enriched TDMRs in sorghum are specific for the endosperm and are generated concomitantly but imbalanced by decrease versus increase in cytosine methylation at multiple 5'-CCGG sites across the genome. This leads to more extensive demethylation in the endosperm than in other tissues, where TDMRs are mainly tissue nonspecific rather than specific to a particular tissue. Accordingly, relative to endosperm, the other six tissues showed grossly similar levels though distinct patterns of cytosine methylation, presumably as a result of a similar extent of concomitant decrease versus increase in cytosine methylation that occurred at variable genomic loci. All four tested TDMRs were validated by bisulfite genomic sequencing. Diverse sequences were found to underlie the TDMRs, including those encoding various known-function or predicted proteins, transposable elements, and those bearing homology to putative imprinted genes in maize (Zea mays). We further found that the expression pattern of at least some genic TDMRs was correlated with its tissue-specific methylation state, implicating a developmental role of DNA methylation in regulating tissue-specific or -preferential gene expression in sorghum.     

Tissue-specific and developmental expression of human transthyretin gene in transgenic mice

To analyze the regulation of transthyretin gene expression we have produced transgenic mice by microinjecting cloned human transthyretin genes into fertilized eggs of C57BL/6 mice. The 7.6-kilobase (kb) human transthyretin gene containing about 500 base pairs (bp) in the upstream region was used for microinjection. Seven out of nine transgenic mice had detectable amounts of human transthyretin in serum when analyzed by enzyme-linked immunosorbent assay. Transthyretin mRNA was detected in liver and yolk sac but not in other tissues including brain. The amount of mRNA was variable among transgenic mice and was about one-tenth of mouse endogenous transthyretin mRNA. Human and mouse transthyretin mRNAs were detected in liver of fetus and yolk sac at 13 days of gestation and unlike yolk sac the level of mRNA in liver increased gradually during development and reached the maximum at around 17 days of gestation. Human transthyretin was associated with mouse transthyretin to form tetramers as judged from the dilution curve of enzyme-linked immunosorbent assay and the spur formation in Ouchterlony assay.     

Tissue-specific differences in DNA methylation in various mammals

The only naturally occurring modified base in vertebrate DNA is 5-methylcytosine. Using a precise high-performance liquid chromatographic analysis of DNA enzymatically digested to deoxynucleosides, we have shown that rats, mice and four types of monkey display tissue-specific as well as species-specific differences in the extent of methylation of their cytosine residues. Several similarities in the patterns of tissue-specific DNA methylation in these mammals and in the previously studied human samples were observed. Compared to most other types of DNA examined, brain and thymus DNAs were hypermethylated, which suggests that this hypermethylation is a determinant or a necessary byproduct of mammalian differentiation. In all of the studied rodents and primates, the highly repeated DNA sequence fraction was more methylated than the moderately repetitive or single copy fractions. The tissue-specific differences in overall DNA methylation showed no correlation with what is known about average cell turnover rates nor with the percentage of the genome that is transcribed. Liver regeneration in the rat following partial hepatectomy did not detectably alter 5-methylcytosine levels in liver DNA. A considerable increase in the extent of methylation of total liver DNA was observed during normal development of the rat. The latter phenomenon may be due to a major change in the cellular composition of the liver.     

Tissue-specific expression of human arylsulfatase-C isozymes and steroid sulfatase.

Steroid sulfatase (STS; E.C.3.1.6.2), which acts on 3-hydroxysteroid sulfates, and arylsulfatase-C (ARC; E.C.3.1.6.1), assayed with aromatic artificial substrates, are both membrane-bound, microsomal enzymes with alkaline pH optima. Although they copurify during preparation and their gene loci are mapped to the short arm of the human X chromosome where they appear to have escaped from X inactivation, it has not been settled whether STS and ARC are the same enzyme or not. Recent work from our laboratory has shown that ARC exists in two electrophoretically distinct forms in human fibroblasts. We now report that these two forms--the faster migrating (F) and more slowly migrating (S)--occur in human tissues. Each of 11 human tissue types from 10 subjects showed a consistent pattern of ARC isozymes. Thyroid, heart, spleen, skeletal muscle, and adrenal tissue mainly had the S form. In contrast, kidney, liver, and pancreas tissue had mainly the F form, while gonadal, lung, and intestinal tissue had both the S and the F forms. The question of escape of their gene locus from X-chromosome inactivation was examined by comparing the specific activities of ARC and STS in male-derived vis-à-vis female-derived tissues. The majority of the tissues did not show any significant difference in these activities between the sexes, the exceptions being heart muscle, gonadal, and kidney tissue. None showed the 1:2 ratio between male- and female-derived tissues expected of a locus that had escaped X inactivation. The question of identity between ARC and STS was examined by comparing the ratios of their activities in these tissue types: if the enzymes were identical, the ratios of their activities should have remained constant across the different tissue types. It was thus shown that ARC activity varied by as much as 100-fold, depending on the ARC isozymic pattern of the tissue. STS, measured as estrone sulfatase and dehydroepiandrosterone sulfatase, did not show similar variations. This provides further evidence that ARC activity is not necessarily identical to that of STS.     

Tissue-specific expression of sialyltransferases

Three sialyltransferases which attach terminal sialic acids to glycoprotein sugar chains are shown to exhibit striking differential expression in seven tissues of the rat. Using cDNA probes for the Gal beta 1,4GlcNAc alpha-2,6-sialytransferase which forms a NeuAc alpha 2-6Gal beta 1-4GlcNAc sequence on N-linked sugar chains, three different sized mRNAs are detected, two of which (4.7 and 4.3 kilobases (kb] have high homology along the full length, and a third (3.6 kb, in kidney) which is missing the 5' region corresponding to 45% of the NH2-terminal coding sequence. The 4.7- and 4.3-kb mRNAs exhibit differential expression of over 50-fold with the highest levels in liver and lowest in brain and heart. Assays for enzyme activity in tissue homogenates show high correspondence to the levels of mRNA. Evidence of tissue-specific expression was also obtained for two other sialyltransferases which form the NeuAc alpha 2-3Gal beta 1-4/3GlcNAc and NeuAc alpha 2-3Gal beta 1-3GalNAc sequences on N-linked and O-linked sugar chains, respectively. Comparison of the ratios of the three enzymes in several tissues suggests that they are expressed independently. The results are discussed for their relevance to cellular control of terminal glycosylation sequences on glycoproteins and glycolipids.     

Tissue-specific determinants of human atrial natriuretic factor gene expression in cardiac tissue

Elements controlling tissue-specific expression of the human atrial natriuretic factor gene have been examined in primary cultures of neonatal rat cardiocytes. When a 68-base pair fragment from human atrial natriuretic factor (hANF) 5'-flanking sequence (positions -400 to -333) was placed upstream from the herpes simplex thymidine kinase promoter linked to a bacterial reporter gene (chloramphenicol acetyltransferase), a tissue-specific positive regulatory effect was observed in atrial as well as ventricular cardiocytes but not in nonmyocardial cells. The cis-acting element in this fragment was orientation- and position-dependent. Examination of nuclear protein extracts for the presence of factors capable of interacting with the 5'-flanking sequence of the hANF gene revealed a cardiocyte-specific factor which bound to the 68-base pair fragment. This association was both tissue- and sequence-specific. These findings indicate that a cis-acting element present in the proximal 5'-flanking sequence confers tissue-specific expression upon the hANF gene, possibly through association with a cardiac-specific nuclear protein.     

Tissue-specific expression of LeY antigen in high endothelial venules of human lymphoid tissues

In this study, we demonstrated that the anti-Le^Yantibody (BM-1) especially reacted with high endothelial venules (HEVs) in peripheral lymph nodes of blood group O individuals. The Le^Yexpression on HEVs showed a unique tissue-specific pattern, i.e., a large amount of the Le^Yexpression in peripheral lymph nodes and no or small amounts in mesenteric lymph node. Statistical analysis showed that there was the significant difference between the percentage of Le^Y-positive HEVs in peripheral lymph nodes and mesenteric lymph nodes. No expression of Le^Ywas observed in vessels of Payer's patch, thymus, spleen and other non-lymphoid organs. In blood group A or B individuals, the reactivity between HEVs and anti-Le^Yantibody increased after enzyme digestion with -N-acetylgalactosaminidase or -galactosidase. These findings show that the expression of difucosylated blood group ABH antigens are especially expressed on HEVs in peripheral lymph nodes. Furthermore, the tissue-specific pattern suggests that these antigens may be related to intercellular adhesion between lymphocytes and HEVs.     

Tissue-specific methylation patterns and expression of the human apolipoprotein AI gene.

To better understand the tissue-specific expression of the human apolipoprotein (apo)AI gene, we performed a detailed analysis of the pattern of methylation of the gene in various human adult and embryonic tissues and in tissues of transgenic mice harboring the human apo-AI gene. In addition, the gene was analyzed also in liver and intestine-derived human cell lines (HepG2 and Caco2, respectively). Using methyl-sensitive restriction enzymes (HpaII, HhaI, and SmaI) and the appropriate radioactive probes, we were able to determine separately the status of methylation of the 5'-end, the body of the gene, and 3'-end flanking sequences. The apo-AI gene in tissues that express the gene was undermethylated at the 5'-end. However, the 5'-end of the gene in sperm and in all adult tissues that do not express the gene was heavily methylated. The body of the gene which contains a CpG island and the 3'-end flanking sequences were, in general, hypomethylated except for specific sites that showed partial methylation. In contrast, while the gene showed tissue-specific expression already in a 12-week-old embryo, the 5'-end was invariably hypomethylated in all tissues of the embryo. A human apo-AI transgene has recently been shown to be active exclusively in the liver, while the endogenous gene is expressed in both liver and intestine (6). We show here that the 5'-end of the apo-AI transgene was methylated in all tissues of the mouse (including intestine) except liver. The results presented here demonstrate a clear correlation between hypomethylation of the 5'-end and activity of the apo-AI gene. However, the observed methylation pattern of the gene in embryonic tissues suggests that tissue-specific expression precedes formation of the tissue-specific methylation pattern.     

Tissue-specific differences in the accumulation of sequence rearrangements with age

Mitotic homologous recombination (HR) is a critical pathway for the accurate repair of DNA double strand breaks (DSBs) and broken replication forks. While generally error-free, HR can occur between misaligned sequences, resulting in deleterious sequence rearrangements that can contribute to cancer and aging. To learn more about the extent to which HR occurs in different tissues during the aging process, we used Fluorescent Yellow Direct Repeat (FYDR) mice in which an HR event in a transgene yields a fluorescent phenotype. Here, we show tissue-specific differences in the accumulation of recombinant cells with age. Unlike pancreas, which shows a dramatic 23-fold increase in recombinant cell frequency with age, skin shows no increase in vivo. In vitro studies indicate that juvenile and aged primary fibroblasts are similarly able to undergo HR in response to endogenous and exogenous DNA damage. Therefore, the lack of recombinant cell accumulation in the skin is most likely not due to an inability to undergo de novo HR events. We propose that tissue-specific differences in the accumulation of recombinant cells with age result from differences in the ability of recombinant cells to persist and clonally expand within tissues.     

Tissue-specific expression of a gene encoding a cell wall-localized lipid transfer protein from Arabidopsis.

Nonspecific lipid transfer proteins (LTPs) from plants are characterized by their ability to stimulate phospholipid transfer between membranes in vitro. However, because these proteins are generally located outside of the plasma membrane, it is unlikely that they have a similar role in vivo. As a step toward identifying the function of these proteins, one of several LTP genes from Arabidoposis has been cloned and the expression pattern of the gene has been examined by analysis of the tissue specificity of beta-glucuronidase (GUS) activity in transgenic plants containing LTP promoter-GUS fusions and by in situ mRNA localization. The LTP1 promoter was active early in development in protoderm cells of embryos, vascular tissues, lignified tips of cotyledons, shoot meristem, and stipules. In adult plants, the gene was expressed in epidermal cells of young leaves and the stem. In flowers, expression was observed in the epidermis of all developing influorescence and flower organ primordia, the epidermis of the siliques and the outer ovule wall, the stigma, petal tips, and floral nectaries of mature flowers, and the petal/sepal abscission zone of mature siliques. The presence of GUS activity in guard cells, lateral roots, pollen grains, leaf vascular tissue, and internal cells of stipules and nectaries was not confirmed by in situ hybridizations, supporting previous observations that suggest that the reporter gene is subject to artifactual expression. These results are consistent with a role for the LTP1 gene product in some aspect of secretion or deposition of lipophilic substances in the cell walls of expanding epidermal cells and certain secretory tissues. The LTP1 promoter region contained sequences homologous to putative regulatory elements of genes in the phenylpropanoid biosynthetic pathway, suggesting that the expression of the LTP1 gene may be regulated by the same or similar mechanisms as genes in the phenylpropanoid pathway.     

Tissue-specific and high-level expression of the human tyrosine hydroxylase gene in transgenic mice.

Transgenic mice carrying multiple copies of the human tyrosine hydroxylase (TH) gene have been produced. The transgenes were transcribed correctly and expressed specifically in brain and adrenal gland. The level of human TH mRNA in brain was about 50-fold higher than that of endogenous mouse TH mRNA. In situ hybridization demonstrated an enormous region-specific expression of the transgene in substantia nigra and ventral tegmental area. TH immunoreactivity in these regions, though not comparable to the increment of the mRNA, was definitely increased in transgenic mice. This observation was also supported by Western blot analysis and TH activity measurements. However, catecholamine levels in transgenics were not significantly different from those in nontransgenics. These results suggest unknown regulatory mechanisms for human TH gene expression and for the catecholamine levels in transgenic mice.