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.     

A new member of the insulin receptor family, insulin receptor-related receptor, is expressed preferentially in the kidney.

Shier and Watt isolated human and guinea pig genomic DNA encoding a putative protein, insulin receptor-related receptor (IRR), the primary structure of which is similar to that of other members of the insulin receptor family, the insulin receptor and type-I IGF receptor (J. Biol. Chem. 264, 14605-14608 (1989)). However, the expression of the IRR gene remained unknown. In this paper, we isolated the IRR cDNA from the rat brain and examined the expression of the IRR mRNA in a variety of rat tissues, including the brain, heart, lung, liver, small intestine, kidney, thymus, spleen, muscle, adipose tissue and cartilage by polymerase chain reaction. In contrast to the wide distribution of the insulin receptor and type-I IGF receptor mRNAs, the IRR mRNA is expressed preferentially in the kidney, which indicates that IRR has unique functions as a member of the insulin receptor family.     

Development of insulin sensitivity in rat skeletal muscle. Studies of glucose transporter and insulin receptor mRNA levels.

Expression of GLUT-4 and insulin receptor mRNAs was investigated in rat skeletal muscle by Northern hybridization. GLUT-4 mRNA was barely detectable in foetal muscle, was expressed at low levels by 1-8 days and at 2-3-fold higher levels during and after weaning (18-40 days). In contrast there was little change in insulin receptor mRNA levels prior to weaning and a reduction in mRNA abundance between 18 and 40 days. Weaning rats on to a diet rich in fat prevented the increase in GLUT-4 abundance seen between 15 and 29 days in animals weaned on a high-carbohydrate diet.     

Tissue-specific regulation of rat estrogen receptor mRNAs

The estrogen receptor (ER) is present in a wide variety of mammalian tissues and is required for physiological estrogen responses, including estrogen-induced tissue-specific changes in gene expression. We studied the estrogen regulation of the mRNAs encoding the ER in rat uterus, liver, and pituitary. Ovariectomized (21-28 day post surgery) female CD-1 rats were injected daily with 17 beta-estradiol (E2, 10 micrograms/100 g BW) for 0, 1, or 4 h, 1, 3, or 7 days and compared with intact controls. Steady-state levels of ER mRNA were quantified using a human ER cDNA probe. Only one hybridizing species of approximately 6.2 kilobase (kb) was detected in uterine and liver RNA, similar to that observed in MCF7 human breast cancer cells. However, the ER mRNA regulation by E2 differed in direction depending on the tissue examined. In uterus, ER mRNA increased 3- to 6-fold after ovariectomy, and returned to intact levels within 24 h of E2 replacement. In contrast, liver ER mRNA declined 1.5- to 3-fold after ovariectomy and returned to intact levels after 1-3 days of E2. In pituitary tissue two hybridizing forms of ER mRNA were observed, with one species migrating at 6.2 kb, equivalent to the form in other tissues, and a second smaller species at approximately 5.5 kb. The lower molecular weight species varied somewhat in abundance from animal to animal, averaging about 20% of the intensity of the 6.2 kb band. The ER mRNA forms were regulated positively with E2.(ABSTRACT TRUNCATED AT 250 WORDS)     

Variation in insulin receptor messenger ribonucleic acid expression in human and rodent tissues

The expression of insulin receptor mRNA was studied in human and rodent tissues by Northern analysis. Human EBV-transformed lymphocytes contained four receptor mRNA species of sufficient length to encode the entire proreceptor: 9.5, 7.9, 7.1, and 5.7 kb. In human fibroblasts, the same four species were observed; however, the 7.9 and 5.7 kb mRNAs were markedly decreased. In mouse liver, rat hepatoma cells, and normal rat brain, kidney, liver, and muscle only two mRNA species (7.4 and 9.6 kb) were detected. Each of these human and rodent mRNAs hybridized equally well with cDNA sequences encoding the binding and kinase domains of the insulin receptor. Several smaller polyadenylated mRNAs (approximately 1.8 to 3.3 kb) were also identified in human cell lines that appeared to separately encode either alpha- or beta-subunit sequences of the receptor. In rats, liver had the highest content of insulin receptor mRNA, followed by kidney, brain, and muscle. The relative amount of the two mRNA species also varied among the rat tissues. The ratio of the 9.6-7.4 kb species was 2.7 in brain but only 1.0 to 1.6 in the other tissues (P less than 0.025). Dexamethasone treatment increased the content of the two insulin receptor mRNAs in rat liver by 2-fold. The half-life of both mRNA species was 70 min in rat hepatoma cells. These findings indicate that insulin receptor gene expression is complex and regulated with differential expression of insulin receptor mRNA and/or alterations in mRNA processing among various tissues.     

Placental, renal, and ileal sulfate transporter gene expression in mouse gestation

Sulfate is important for mammalian growth and development. During pregnancy, maternal circulating sulfate levels increase by 2-fold, enhancing sulfate availability to the fetus. We used quantitative real-time PCR to determine sulfate transporter mRNA levels during mouse gestation in three tissues: kidney and ileum, to identify transporters involved in sulfate absorption and maintaining high maternal circulating sulfate level; and placenta, to build a model of directional sulfate transport from mother to fetus. In the kidney, Slc13a1 and Slc26a1 were the most abundant sulfate transporter mRNAs, which increased by ≈2-fold at E4.5 or E6.5, whereas lower levels of Slc26a2, Slc26a6, and Slc26a7 mRNA increased by ≈3- to 6-fold from E4.5. Ileal sulfate transporter mRNA levels were not increased in gestation, but slight decreases (by ≈30-40%) were found for Slc26a3 and Slc26a6. In placentae, Slc13a4 and Slc26a2 mRNAs were most abundant, with levels increasing from E10.5 and peaking (≈8-fold) from E14.5 to E18.5, whereas Slc26a1 increased by ≈3-fold at E18.5. The spatial expression of placental mRNAs was determined by in situ hybridization showing Slc13a4 and Slc26a6 in yolk sac, Slc26a1 in spongiotrophoblasts, and Slc13a4, Slc26a2, Slc26a3, and Slc26a7 in the labyrinthine layer. Within the labyrinth, cell-specific staining revealed Slc13a4 expression in syncytiotrophoblast-II (SynT-II) and Slc26a2 in SynT-I. Together, these data show kidney Slc13a1 and Slc26a1 and placental Slc13a4 and Slc26a2 to be the most abundant sulfate transporter mRNAs in mouse gestation, which likely play important physiological roles in maintaining high maternal serum sulfate levels during pregnancy and mediating sulfate supply to the fetus.     

Expression of mRNA encoding insulin‐like growth factors I and II by uterine tissues and placenta during pregnancy in the rat

The uterus and the placenta synthesize insulin‐like growth factors (IGFs) and insulin‐like binding proteins (IGFBPs). These growth factors are implicated in processes of proliferation and differentiation that occur in the uterus. To determine the patterns of expression of IGFs during rat pregnancy we used in situ hybridization with digoxigenin labeled probes on uterus from day 7 to day 16 of pregnancy. In early gestation days (7–8) both IGF mRNAs showed similar tissue distribution with relative abundance in the stroma and circular muscle layer. On days 11 and 12 expression for IGF‐I mRNA was found in the mesometrial decidua and metrial gland and in the ectoplacental cone while clear expression of IGF‐II mRNA could only be found in the latter. On days 13 and 14, expression for IGF‐I mRNA could be detected in the mesometrial decidua and metrial gland but no expression was observed for IGF‐II mRNA. A gradient of IGF‐I mRNA expression could be observed in the placenta on day 16, with the trophoblastic cells of the basal zone expressing the signal with stronger intensity than in the labyrinthine zone. For IGF‐II mRNA the highest expression was associated with the labyrinthine zone. Endovascular trophoblast was positive for both mRNAs. The spatial and temporal patterns of expression suggests a role for IGFs in the process of decidualization as well as in the establishment, growth and differentiation of the various trophoblast cells of the placenta. Mol. Reprod. Dev. 53:294–305, 1999. © 1999 Wiley‐Liss, Inc.     

Different tissue distribution and hormonal regulation of messenger RNAs encoding rat insulin-like growth factor-binding proteins-1 and -2.

The insulin-like growth factor-binding proteins IGFBP-1 and IGFBP-2 are low mol wt IGFBPs that are similar in structure. They are not glycosylated and have a homologous amino acid sequence, including the number and position of 18 cysteine residues and a carboxyl-terminal Arg-Gly-Asp sequence that can be recognized by cell adhesion receptors. The present study demonstrates that expression of mRNAs encoding the two BPs differs in some fetal rat tissues and in the livers of adult rats after hypophysectomy, fasting, or streptozotocin-induced diabetes. As determined by Northern blot hybridization using cDNA probes for rat IGFBP-2 or human IGFBP-1, both mRNAs are expressed at high levels in liver of 21-day gestation and 1-day-old rats and at lower levels in 21- and 65-day-old rat liver. Levels of both mRNAs are higher in liver than in other fetal rat tissues. The relative abundance of the two mRNAs in most fetal tissues is similar to that in liver, except that kidney and brain have 8-fold and more than 25-fold higher relative levels of IGFBP-2 mRNA, respectively. IGFBP-2 mRNA is about 10- to 20-fold increased after hypophysectomy or fasting, whereas IGFBP-1 mRNA is relatively unchanged. IGFBP-2 mRNA levels are decreased completely by refeeding fasted rats for 3 days, but only partially decreased by treatment of hypophysectomized rats with GH, cortisone acetate, T4, and testosterone for 4 days.(ABSTRACT TRUNCATED AT 250 WORDS)     

Pattern of serum protein gene expression in mouse visceral yolk sac and foetal liver.

We have shown by molecular hybridisation that the mRNAs for albumin, transferrin, apolipoprotein-A1, and alpha 1-antitrypsin are expressed at high levels in mouse visceral yolk sac. In contrast, the mRNAs for contrapsin (a plasma protease inhibitor) and the major urinary proteins (MUPs) are not detected in the visceral yolk sac at any stage of embryonic development. Contrapsin and MUP mRNAs both appear late in liver development. These differences in expression suggest that the visceral yolk sac is more similar to the foetal than adult mouse liver in its pattern of gene expression. However, the developmental time course of expression of these mRNAs is different between the foetal liver and the yolk sac. Evidence is also presented that the visceral yolk sac synthesises and secretes other apolipoproteins in addition to apolipoprotein-A1. These results suggest that the visceral yolk sac and foetal liver, two tissues with different embryological lineages, perform similar functions but are independently programmed for expression of the same set of serum protein genes.     

Contrasting developmental and tissue-specific expression of alpha and beta thyroid hormone receptor genes.

Thyroid hormones and their receptors (TRs) have critical functions in development. Here we show that a chicken TR beta cDNA clone encodes a receptor with a novel, short N-terminal domain. In vitro-expressed TR beta protein bound thyroid hormone with similar affinity as the chicken TR alpha. Comparison of expression of TR alpha and TR beta mRNAs throughout chicken development until 3 weeks post-hatching revealed ubiquitous expression of TR alpha mRNAs (in 14 different tissues) with some variations in levels, from early embryonic stages. In contast, expression of TR beta mRNA was restricted, occurring notably in brain, eye, lung, yolk sac and kidney, and was subject to striking developmental control, especially in brain where levels increased 30-fold upon hatching. Levels also sharply increased in late embryonic lung, but were relatively high earlier in embryonic eye and yolk sac. RNase protection analyses detected no obvious mRNAs for alpha and beta TRs with variant C-termini as demonstrated previously for the rat TR alpha gene. The data suggest a general role for TR alpha and specific developmental functions for TR beta, and that thyroid-dependent development involves temporal and tissue-specific expression of the TR beta gene.     

Appearance of functional EGF receptor kinase during rodent embryogenesis.

Mouse and rat embryonic tissues at various stages of development were examined for epidermal growth factor (EGF) receptor kinase activity. The phosphorylated EGF receptor from embryonic tissues appeared as a band of mol. wt. 170 000 daltons on SDS gels. It was clearly demonstrable in the developing mouse fetus from 10 days of gestation onwards. The distribution of the EGF receptor kinase was studied in various tissues of 13 day mouse fetuses. The activity was apparent in the skin, developing skeletal muscles and various internal organs but was notably absent in the liver and brain. The amnion was found to be one of the richest sources of activity while the yolk sac was negative, and the placenta was weakly positive. In 16 day rat fetuses the distribution was quite similar to that of the 13 day mouse fetus. The liver acquired EGF receptor kinase activity by 18 days of gestation and had high activity in neonates. Phosphoamino acid analysis revealed that phosphotyrosine was the major labelled amino acid residue in the embryonic tissues. Thus, the EGF receptor of fetal tissues as studied by immune precipitation and phosphorylation appears to be a similar entity to that found in adult mammalian tissues. This functional EGF receptor kinase activity could first be detected at the time of onset of organogenesis.