Differential expression and imprinting status of Ins1 and Ins2 genes in extraembryonic tissues of laboratory mice.

There are two functional insulin genes in the mouse genome. The Ins2 gene is imprinted and expressed monoallelically from the paternal allele in the yolk sac. In the present study we have re-examined the imprinting status of Ins1. We found that Ins1 is not expressed in the yolk sac of several laboratory mouse strains. The asynchrony of replication at the wild type locus was significantly lower than at imprinted loci and was more similar to non-imprinted loci. Finally, we have taken the advantage of the Ins1(neo) allele created by homologous recombination to examine the allelic usage at this locus. We observed that the neo gene inserted at the Ins1 locus was expressed from both the paternally and the maternally transmitted allele. Therefore, the Ins1 gene does not share any of the basic properties of imprinted genes. On the basis of these data, we concluded that Ins1 locus is unlikely to be imprinted in common laboratory mice.

Impaired retinol utilization in Adh4 alcohol dehydrogenase mutant mice.

Adh4, a member of the mouse alcohol dehydrogenase (ADH) gene family, encodes an enzyme that functions in vitro as a retinol dehydrogenase in the conversion of retinol to retinoic acid, an important developmental signaling molecule. To explore the role of Adh4 in retinoid signaling in vivo, gene targeting was used to create a null mutation at the Adh4 locus. Homozygous Adh4 mutant mice were viable and fertile and demonstrated no obvious defects when maintained on a standard mouse diet. However, when subjected to vitamin A deficiency during gestation, Adh4 mutant mice demonstrated a higher number of stillbirths than did wild-type mice. The proportion of liveborn second generation vitamin A-deficient newborn mice was only 15% for Adh4 mutant mice but 49% for wild-type mice. After retinol administration to vitamin A-deficient dams in order to rescue embryonic development, Adh4 mutant mice demonstrated a higher resorption rate at stage E12.5 (69%), compared with wild-type mice (30%). The relative ability of Adh4 mutant and wild-type mice to metabolize retinol to retinoic acid was measured after administration of a 100-mg/kg dose of retinol. Whereas kidney retinoic acid levels were below the level of detection in all vehicle-treated mice (< 1 pmol/g), retinol treatment resulted in very high kidney retinoic acid levels in wild-type mice (273 pmol/g) but 8-fold lower levels in Adh4 mutant mice (32 pmol/g), indicating a defect in metabolism of retinol to retinoic acid. These findings demonstrate that another retinol dehydrogenase can compensate for a lack of Adh4 when vitamin A is sufficient, but that Adh4 helps optimize retinol utilization under conditions of both retinol deficiency and excess.

Metabolic deficiencies in alcohol dehydrogenase Adh1, Adh3, and Adh4 null mutant mice. Overlapping roles of Adh1 and Adh4 in ethanol clearance and metabolism of retinol to retinoic acid.

Targeting of mouse alcohol dehydrogenase genes Adh1, Adh3, and Adh4 resulted in null mutant mice that all developed and reproduced apparently normally but differed markedly in clearance of ethanol and formaldehyde plus metabolism of retinol to the signaling molecule retinoic acid. Following administration of an intoxicating dose of ethanol, Adh1 -/- mice, and to a lesser extent Adh4 -/- mice, but not Adh3 -/- mice, displayed significant reductions in blood ethanol clearance. Ethanol-induced sleep was significantly longer only in Adh1 -/- mice. The incidence of embryonic resorption following ethanol administration was increased 3-fold in Adh1 -/- mice and 1.5-fold in Adh4 -/- mice but was unchanged in Adh3 -/- mice. Formaldehyde toxicity studies revealed that only Adh3 -/- mice had a significantly reduced LD50 value. Retinoic acid production following retinol administration was reduced 4.8-fold in Adh1 -/- mice and 8.5-fold in Adh4 -/- mice. Thus, Adh1 and Adh4 demonstrate overlapping functions in ethanol and retinol metabolism in vivo, whereas Adh3 plays no role with these substrates but instead functions in formaldehyde metabolism. Redundant roles for Adh1 and Adh4 in retinoic acid production may explain the apparent normal development of mutant mice.

Retinoic acid and alcohol/retinol dehydrogenase in the mouse adrenal gland: a potential endocrine source of retinoic acid during development.

Retinoid signaling requires the conversion of retinol to retinoic acid by a two-step process, the first of which can be catalyzed in vitro by class I and class IV alcohol dehydrogenases (ADH). These enzymes may participate in local retinoic acid synthesis in some target tissues, although other studies suggest retinoic acid may also be supplied to tissues via the bloodstream, much like an endocrine hormone. Here we have analyzed the expression of these two ADHs as well as retinoic acid production in the adrenal gland, an organ known to be an endocrine source of other hormones. In situ hybridization revealed high levels of both class I and class IV ADH messenger RNAs in adrenal glands of 16.5-day mouse embryos and adults. Class I ADH protein was immunohistochemically detected in embryonic and adult adrenal glands, the latter primarily in the zona fasiculata of the cortex. Abundant class IV ADH protein was detected in the embryonic adrenal as well as in the zona glomerulosa and zona fasiculata of the adult adrenal cortex. Interestingly, class IV ADH protein was found in only a subset of adult cortical cells arranged in radial columns, thus providing further evidence for centripetal cell migration during adrenocortical differentiation. Using a retinoic acid bioassay, adrenal glands from 16.5 day embryos were found to have significantly higher levels of retinoic acid than embryonic liver. The adult adrenal was found to have approximately 15.5 pmol/g of retinoic acid, whereas the adult liver had 24.8 pmol/g, and brain, heart, and spleen each had less than 1.0 pmol/g. Because previous findings indicate that the adrenal gland is not a retinoid target tissue, our detection of both alcohol/retinol dehydrogenases and significant amounts of retinoic acid in this organ suggests that it functions as a potential endocrine source of this hormone during mouse development.

Phenotypic alterations in insulin-deficient mutant mice.

Two mouse insulin genes, Ins1 and Ins2, were disrupted and lacZ was inserted at the Ins2 locus by gene targeting. Double nullizygous insulin-deficient pups were growth-retarded. They did not show any glycosuria at birth but soon after suckling developed diabetes mellitus with ketoacidosis and liver steatosis and died within 48 h. Interestingly, insulin deficiency did not preclude pancreas organogenesis and the appearance of the various cell types of the endocrine pancreas. The presence of lacZ expressing beta cells and glucagon-positive alpha cells was demonstrated by cytochemistry and immunocytochemistry. Reverse transcription-coupled PCR analysis showed that somatostatin and pancreatic polypeptide mRNAs were present, although at reduced levels, accounting for the presence also of delta and pancreatic polypeptide cells, respectively. Morphometric analysis revealed enlarged islets of Langherans in the pancreas from insulin-deficient pups, suggesting that insulin might function as a negative regulator of islet cell growth. Whether insulin controls the growth of specific islet cell types and the molecular basis for this action remain to be elucidated.

Gene structure and promoter for Adh3 encoding mouse class IV alcohol dehydrogenase (retinol dehydrogenase).

Class IV alcohol dehydrogenase (ADH) has been shown to function in vitro as a retinol dehydrogenase catalyzing the synthesis of retinoic acid, a pleiotropic gene regulator. To enable genetic studies on the function of this enzyme and regulation of its gene, we have screened a genomic library and isolated the mouse class IV ADH gene (Adh3). The complete mouse class IV ADH coding region was found in nine exons spanning a 14-kb region. Primer extension analysis was used to map the transcription initiation site to a position lying 30 bp upstream of the ATG translation start codon. Nucleotide sequence analysis of the promoter region indicated an absence of both TATA-box and GC-box sequences; this distinguishes it from the promoters for class I, II, and III ADH genes. Sequence comparison of the mouse and human class IV ADH promoters indicated that they share a conserved region located 125-145 bp upstream of the coding region containing adjacent sequences matching the consensus binding sites for transcription factors AP-1 and C/EBP.

Localization of class I and class IV alcohol dehydrogenases in mouse testis and epididymis: potential retinol dehydrogenases for endogenous retinoic acid synthesis.

The vitamin A metabolite retinoic acid plays an essential signaling role in spermatogenesis by acting as a ligand for nuclear retinoic acid receptors. However, little is known about the regulation of retinoic acid synthesis from vitamin A (retinol). Here we have examined mouse testis and epididymis for the presence of endogenous retinoic acid and for the expression of genes encoding class I and class IV alcohol dehydrogenases (ADH), both of which catalyze retinol oxidation, the rate-limiting step in the conversion of retinol to retinoic acid. Using a bioassay we found that mouse testis and epididymis both have significant levels of retinoic acid ranging from 7 to 8 pmol/g, an amount known to be sufficient to optimally activate retinoic acid receptors. In situ hybridization analysis of mouse testis revealed that class I ADH mRNA was localized in Sertoli cells and Leydig cells, while class IV ADH mRNA was confined to late spermatids. In the epididymis, class I ADH mRNA was detected in both principal and basal cells, whereas class IV ADH mRNA was limited to basal cells. Immunohistochemical analyses of testis indicated that class I ADH protein was localized in Sertoli and Leydig cells, whereas class IV ADH protein was observed only in late spermatids. Class I ADH protein was localized in principal and basal cells of the cauda epididymidis but only in basal cells of the caput epididymidis. Class IV ADH protein was limited to basal cells along the entire length of the epididymis. These results support a role for ADHs during spermatogenesis, potentially as retinol dehydrogenases catalyzing local retinoic acid synthesis in the testis and epididymis.

Expression patterns of class I and class IV alcohol dehydrogenase genes in developing epithelia suggest a role for alcohol dehydrogenase in local retinoic acid synthesis.

Vitamin A (retinol) regulates embryonic development and adult epithelial function via metabolism to retinoic acid, a pleiotrophic regulator of gene expression. Retinoic acid is synthesized locally and functions in an autocrine or paracrine fashion, but the enzymes involved remain obscure. Alcohol dehydrogenase (ADH) isozymes capable of metabolizing retinol include class I and class IV ADHs, with class III ADH unable to perform this function. ADHs also metabolize ethanol, and high levels of ethanol inhibit retinol metabolism, suggesting a possible mode of action for some of the medical complications of alcoholism. To explore whether any ADH isozymes are linked to retinoic acid synthesis, herein we have examined the expression patterns of all known classes of ADH in mouse embryonic and adult tissues, and also measured retinoic acid levels. Using in situ hybridization, class I ADH mRNA was localized in the embryo to the epithelia of the genitourinary tract, intestinal tract, adrenal gland, liver, conjunctival sac, epidermis, nasal epithelium, and lung, plus in the adult to epithelia within the testis, epididymis, uterus, kidney, intestine, adrenal cortex, and liver. Class IV ADH mRNA was localized in the embryo to the adrenal gland and nasal epithelium, plus in the adult to the epithelia of the esophagus, stomach, testis, epididymis, epidermis, and adrenal cortex. Class III ADH mRNA, in contrast, was present at low levels and not highly localized in the embryonic and adult tissues examined. We detected significant retinoic acid levels in the fetal kidney, fetal/adult intestine and adrenal gland, as well as the adult liver, lung, testis, epididymis, and uterus--all sites of class I and/or class IV ADH gene expression. These findings indicate that the expression patterns of class I ADH and class IV ADH, but not class III ADH, are consistent with a function in local retinoic acid synthesis needed for the development and maintenance of many specialized epithelial tissues.

Ethanol inhibition of retinoic acid synthesis as a potential mechanism for fetal alcohol syndrome.

Retinoic acid (RA) is known to act as a signaling molecule during embryonic development, but little is known about the regulation of RA synthesis from retinol. The rate-limiting step in RA synthesis is the oxidation of retinol, a reaction that can be catalyzed by alcohol dehydrogenase (ADH). Ethanol is also a substrate for ADH, and high levels of ethanol inhibit ADH-catalyzed retinol oxidation. This has prompted us to hypothesize that ethanol-induced defects observed in fetal alcohol syndrome involve ethanol inhibition of ADH-catalyzed RA synthesis. Here, we have examined the effect of ethanol on RA levels in cultured mouse embryos by using a bioassay. Treatment with 100 mM ethanol, but no 10 mM, led to a significant decrease in RA detection in 7.5-day-old embryos. Using whole-mount in situ hybridization, we detected mRNA for class IV ADH, but not ethanol-active cytochrome P450 2E1, in 7.5- and 8.5-day-old embryos, indicating that an ADH-linked pathway exists at these stages for metabolizing retinol and ethanol. Thus, the observed ethanol-induced reduction in RA may be caused by ethanol inhibition of retinol oxidation catalyzed by class IV ADH. In our postulated mechanism for fetal alcohol syndrome, this enzyme may well play a crucial role.

Retinoic acid synthesis in mouse embryos during gastrulation and craniofacial development linked to class IV alcohol dehydrogenase gene expression.

Endogenous retinoic acid (RA) has been observed in vertebrate embryos as early as gastrulation, but the mechanism controlling spatiotemporal synthesis of this important regulatory molecule remains unknown. Some members of the alcohol dehydrogenase (ADH) family catalyze retinol oxidation, the rate-limiting step in RA synthesis. Here we have examined mouse embryos for the presence of endogenous RA and expression of ADH genes. RA was not detected in egg cylinder stage embryos but was detected in late primitive streak stage embryos. Detection of class IV ADH mRNA, but not class I or class III, coincided with the onset of RA synthesis, being absent in egg cylinder embryos but present in the posterior mesoderm of late primitive streak embryos. During neurulation, RA and class IV ADH mRNA were colocalized in the craniofacial region, trunk, and forelimb bud. Class IV ADH mRNA was detected in cranial neural crest cells and craniofacial mesenchyme as well as trunk and forelimb bud mesenchyme. The spatiotemporal expression pattern and enzymatic properties of class IV ADH are thus consistent with a crucial function in RA synthesis during embryogenesis. In addition, the finding of endogenous RA and class IV ADH mRNA in the craniofacial region has implications for the mechanism of fetal alcohol syndrome.

Tissue- and developmental stage-specific imprinting of the mouse proinsulin gene, Ins2.

We have investigated the imprinting status of two insulin genes using an interspecific recombinant congenic mouse strain carrying Ins1 and Ins2 alleles from Mus spretus on a C57BL/6 genetic background. At Days 12.5, 13.5, and 14.5 of gestation, expression of both parental alleles of both Ins1 and Ins2 was detected in the bodies of the embryos. In the heads, only Ins2 expression was detected, and, again, both parental alleles were expressed. In yolk sacs, only Ins2 transcripts were found. Both parental alleles were expressed on Day 12.5, but the expression of the maternal allele gradually declined with only the paternal allele remaining active by Day 14.5. Thus, Ins2 is subject to genomic imprinting in the yolk sac. This imprinting is not only tissue-specific, but appears to be a multistep process with postzygotic events likely to play an important role in repression of the maternal allele.

Insulin gene can be expressed in the absence of Isl-1.

The possible role of Isl-1 in insulin-gene transcription was investigated using Northern blot analysis to determine whether insulin and Isl-1 gene expression are correlated in various somatic cell hybrids. Among several hybrid cell lines obtained by fusing insulin-producing rat insulinoma (RIN) cells and mouse spleen cells, three (RR2, RR5, and RR11) had amounts of insulin transcripts similar to those of the parental RIN cells, although two of them, RR5 and RR11, lacked Isl-1 protein. In contrast, two RIN x mouse L cell hybrids where insulin expression was extinct still expressed Isl-1. RT-PCR analysis showed that Isl-1 transcripts are widely distributed in various mouse tissues, including pancreas, brain, lung, thymus, and ovary. These results indicate that Isl-1 is not essential for insulin gene expression.

Cis effect of lacZ sequences in transgenic mice.

Transgenic mice carrying the 3-hydroxy-3-methylglutarylCoA reductase (HMG) promoter driving the Escherichia coli beta-galactosidase (lacZ) gene did not display the expected ubiquitous and constitutive expression in HMG-lacZ transgenic mice. The same promoter is however able to drive ubiquitous expression of the chloramphenicol acetyltransferase (cat) gene. Two lines of double HMG-lacZ and HMG-cat transgenic mice were obtained in which the two constructs were integrated at the same genomic sites. These mice expressed both reporter genes, but exclusively in the testes. These results suggest that the lacZ sequence might interfere negatively with the expression of the adjacent HMG-cat transgene.

Differential expression of the two nonallelic proinsulin genes in the developing mouse embryo.

In the mouse, insulin is produced from two similar but nonallelic genes that encode proinsulins I and II. We have investigated expression of these two genes during mouse embryonic development, using a PCR to detect the two gene transcripts and immunocytochemistry to visualize the two corresponding proteins. At appearance of the dorsal pancreatic anlage at day 9.5 of gestation, both mRNAs could be detected in the embryos, and both proteins were present together in the same cells of the developing pancreas. At days 9.5 and 10.5, when the ventral anlage appears, there were fewer proinsulin II mRNAs than proinsulin I mRNAs. At day 12.5 this ratio was reversed. Proinsulin II mRNA, but not proinsulin I mRNA, could be detected at day 8.5 in the prepancreatic embryo. Proinsulin II mRNA, but not proinsulin I mRNA, was also found in the heads of embryos at day 9.5 and at all later stages studied. These results indicate that the two proinsulin genes are regulated independently, at least in part. They also suggest that insulin might play a role as a growth factor in the developing mouse brain.

Polyclonal origin of pancreatic islets in aggregation mouse chimaeras.

In the present study, we have examined the origin and growth pattern of the beta cells in pancreatic islets, to determine whether a single progenitor cell gave rise to all the precursors of the islets, or if each of a few progenitor cells is the founder of a different islet, or if each islet is a mixture of cells originating from a pool of progenitor cells. Aggregation mouse chimaeras where the pancreatic beta cells derived from each embryo can be identified in the islets on histological sections were analyzed. In two chimaeras, all the islets contained cells from both the aggregated embryo. This clearly demonstrates that each islet resulted from several independent cells. In addition, the beta cells derived from either embryo component were in very small clusters in the islets, suggesting that in situ cell division did not account significantly for islet growth.

[Changes in the glucose tolerance parameters in non-diabetic hypertensive patients treated with cicletanine]. / Etude de l'évolution des paramètres de la tolérance glucidique chez des patients hypertendus non diabétiques traités par le ciclétanine.

The effects of cicletanine hydrochloride on glucose tolerance parameters were studied in a two-phase trial in which patients received a placebo for 2 weeks, followed by cicletanine 50 mg/day for 3 months. Ten patients with mild to moderate hypertension, who were neither obese nor diabetic and had no disorder of glucose tolerance entered the study. None of the patients was withdrawn. Glucose tolerance was evaluated by two oral glucose tolerance tests performed at 90 days' interval, each with half hourly blood glucose and insulin assays. The clinical effectiveness of the drug was assessed by monthly blood pressure measurements. No significant change in glycaemia and insulinaemia was observed. There was a significant decrease of supine SBP from 170.7 +/- 9.1 mmHg to 150.3 +/- 6.7 mmHg (p less than 0.0001) and of supine DBP from 101.3 +/- 4.1 to 80.3 +/- 7.7 mmHg (p less than 0.0001). At the end of the study, 9 of the 10 patients had normal blood pressure values. No undesirable clinical or biochemical effect was noted. thus, cicletanine, an antihypertensive drug derived from furopyridine, proved to be devoid of adverse effects on glycoregulation and clinically effective on hypertension.