Tissue-specific and hormonally regulated expression of a rat alpha 2u globulin gene in transgenic mice.

To investigate the tissue-specific and hormonal regulation of the rat alpha 2u globulin gene family, we introduced one cloned member of the gene family into the mouse germ line and studied its expression in the resulting transgenic mice. Alpha 2u globulingene 207 was microinjected on a 7-kilobase DNA fragment, and four transgenic lines were analyzed. The transgene was expressed at very high levels, specifically in the liver and the preputial gland of adult male mice. The expression in male liver was first detected at puberty, and no expression was detected in female transgenic mice. This pattern of expression is similar to the expression of endogenous alpha 2u globulin genes in the rat but differs from the expression of the homologous mouse major urinary protein (MUP) gene family in that MUPs are synthesized in female liver and not in the male preputial gland. We conclude that these differences between rat alpha 2u globulin and mouse MUP gene expression are due to evolutionary differences in cis-acting regulatory elements. The expression of the alpha 2u globulin transgene in the liver was abolished by castration and fully restored after testosterone replacement. The expression could also be induced in the livers of female mice by treatment with either testosterone or dexamethasone, following ovariectomy and adrenalectomy. Therefore, the cis-acting elements responsible for regulation by these two hormones, as well as those responsible for tissue-specific expression, are closely linked to the alpha 2u globulin gene.     

Tissue-specific control of alpha 2u globulin gene expression: constitutive synthesis in the submaxillary gland

Synthesis of alpha 2u globulin, previously thought to occur only in the male rat liver, has now been demonstrated in the submaxillary salivary gland. Unlike liver, submaxillary synthesis of alpha 2u globulin mRNA is constitutive--that is, independent of the endocrine state, age and sex. Liver and submaxillary alpha 2u globulin mRNAs are of similar size, and their 5' ends map to the same region of the gene. Isoelectric focusing of in vitro translation products revealed that submaxillary mRNA encodes a more acidic subset of alpha 2u globulins than does liver. Salivary alpha 2u globulin mRNA manifests 5% nucleotide divergence, encoding 20 amino acid substitutions, which specifies a more acidic polypeptide than its hepatic counterpart. Thus the liver and submaxillary gland synthesize alpha 2u globulin from different sets of genes that are subject to very different developmental and hormonal control.     

Tissue-specific and differential expression of prothymosin alpha gene during rat development.

We have analyzed the RNA expression of prothymosin alpha (ProT alpha) gene during rat development in several tissues and compared it to that of two proteins related to cell proliferation: proliferating cell nuclear antigen (PCNA)/cyclin and histone H3 (H3). The expression of ProT alpha gene was found to be regulated in a developmental and tissue-specific manner. The mRNA levels of ProT alpha followed a similar time-course in liver, brain, kidney, and testis, being highly increased in the early periods of postnatal development. However, in thymus ProT alpha mRNA showed only moderate changes throughout development. Our findings suggest that ProT alpha participates in developmental processes like cell proliferation and/or differentiation.     

Tissue-specific developmental expression of the kallikrein gene family in the rat

Using a series of gene-specific oligonucleotide probes, we have explored the developmental pattern of expression of six members of the rat kallikrein gene family (PS, S1, S2, S3, K1, and P1) in the submandibular gland (SMG) and kidney of both sexes, the prostate and testis of the male, and the anterior pituitary gland (AP) of the female rat. PS (true kallikrein) mRNA was detected in early neonatal life in the SMG and kidney of both sexes. K1, a second kallikrein gene family member expressed in the adult kidney, had a developmental pattern similar to PS in the kidney. In contrast, tonin (S2), S3, K1, and P1, all of which are expressed in the adult SMG, did not reach detectable SMG mRNA levels until puberty in either the male or female rat. Both S3 and P1, which are expressed in the adult prostate, and the novel P1-like mRNA previously detected in the adult rat testis, first appeared in early puberty. In the female AP, PS mRNA levels were not detected until early puberty and thus exhibited a developmental profile different from that of prolactin. The demonstration that S1, S2, S3, P1, and K1 are not expressed in the SMG or prostate until puberty is consistent with the expression of these genes in these tissues being androgen-regulated; the first appearance of PS mRNA in the female AP in early puberty similarly reflects the estrogen dependence of PS gene expression in this tissue. The presence of PS mRNA levels in the SMG and kidney prior to sexual maturation reflects the androgen independence of PS gene expression and suggests that PS (true kallikrein) may play a constitutive and/or developmental role in SMG or renal physiology.     

Tissue-specific expression of the rat secretin precursor gene.

Secretin is a 27-amino acid gastrointestinal hormone that stimulates the secretion of bicarbonate-rich pancreatic fluid. We previously demonstrated that the secretin precursor gene is expressed in the brain as well as in the small intestine. In this study, we demonstrated that the abundance of secretin precursor mRNA in the heart, lung, and kidney was comparable to that of the small intestine. The nucleotide sequences of the coding regions of the secretin precursor mRNAs in these tissues were identical to those of the small intestine, indicating that secretin precursor proteins produced in these tissues are identical to those in the small intestine. This is the first report that the secretin precursor gene is also expressed in the heart, lung, kidney, and testis as well as in the gastrointestinal tract and brain.     

Tissue-specific regulation of the expression of rat kallikrein gene family members by thyroid hormone.

We have altered the thyroid hormonal status of both male and female rats and examined the expression of six functional members of the rat kallikrein gene family (PS, S1, S2, S3, K1 and P1) in the submandibular gland (SMG), kidney, prostate, testis and anterior pituitary gland (AP) of these animals. On Northern-blot analysis with gene-specific oligonucleotide probes, the steady-state mRNA levels of S1, S2, S3, K1 and P1 were all dramatically altered in the SMG of male and female rats treated with propylthiouracil (PTU; 100 mg/litre of drinking water) or thyroxine (T4; 10 micrograms/100 mg body wt.) for 3 weeks. The SMG mRNA levels of these five genes were all lowered (30-90%) in hypothyroid (PTU-treated) male and female rats and elevated (1.4-4-fold, male; 1.5-11-fold, female) in the hyperthyroid (T4-treated) and PTU/T4-treated animals. In contrast, PS (true kallikrein) mRNA levels in the male or female SMG or kidney were essentially unchanged. K1 mRNA levels in the kidney were considerably less responsive to thyroid status than those in the SMG. Changes in S3 and P1 mRNA levels in the prostate were also variable, but essentially unaffected by these treatments. AP PS mRNA levels were also unaffected by changes in thyroid-hormonal status, as were levels of a novel P1-like mRNA in the testis. In summary, these studies demonstrate that the same kallikrein gene family member(s) may be differentially regulated by thyroid hormones in the rat SMG, kidney, prostate and pituitary, and thus further extend the concept of tissue-specific expression and hormonal regulation of the kallikrein gene family in the rat.     

Differential regulation of alpha 2u globulin gene expression in liver, lachrymal gland, and salivary gland

The alpha 2u globulins, products of a highly homologous multigene family, are synthesized in the liver and submaxillary salivary glands of the rat. Although their precise function has not been ascertained, they are of interest because of the complex developmental and hormonal regulation of their tissue levels. We now report that alpha 2u globulin is synthesized in a third tissue of the rat, the extraorbital lachrymal gland. Immunocytochemical studies indicate that the distribution of alpha 2u globulin is more homogeneous in the lachrymal gland than in the liver or submaxillary gland. In situ hybridization to alpha 2u globulin RNA reveals specific signal only over the acinar cells of the lachrymal gland. Several different isoelectric forms of alpha 2u globulin are encoded by lachrymal gland mRNA. The major lachrymal and salivary gland isoforms are indistinguishable from one another, but more acidic than the hepatic isoforms. In addition, analysis of double-stranded cDNAs with a diagnostic restriction-enzyme pair detects no differences between the alpha 2u globulin mRNAs of lachrymal and salivary gland, but clearly distinguishes these from their hepatic counterparts. In spite of the similarity between the lachrymal and salivary gland alpha 2u globulin gene products, we find that the hormonal and developmental regulation of alpha 2u globulin expression differs markedly in these two tissues. In the liver, where a different subset of alpha 2u globulin genes is expressed, a third regulatory phenotype is observed.     

Age-dependent reversal of the lobular distribution of androgen-inducible alpha 2u globulin and androgen-repressible SMP-2 in rat liver.

Hepatocytes situated at pericentral and periportal zones of the liver lobule show differences in the expression of several liver-specific genes, such as androgen-inducible alpha 2u globulin and androgen-repressible senescence marker protein-2 (SMP-2). A marked temporal difference in the expression of these two androgen-regulated genes has also been observed. The liver of the pre-pubertal male rat is insensitive to androgen, and during this period hepatocytes synthesize only SMP-2. During young adult life (greater than 40 days), the liver becomes androgen sensitive and concomitant synthesis of alpha 2u globulin and repression of SMP-2 occur. In the senescent male rat (greater than 750 days), the liver again becomes androgen insensitive when the decline in alpha 2u globulin is accompanied by an increase in SMP-2 synthesis. In this article we present results to show a correlation between the temporal and spatial (intralobular) changes in the expression of the androgen-inducible alpha 2u globulin and the androgen-repressible SMP-2 in rat hepatocytes. Results indicate that the temporal changes in hepatic androgen sensitivity are dictated by the intralobular location of the hepatocytes. Hepatocytes located around the central vein (pericentral/perivenous) may benefit from a paracrine advantage for the expression of a subset of genes, including the gene for the androgen receptor.     

Hormonal regulation of the hepatic messenger RNA levels for alpha2u globulin.

The messenger RNA rat alpha2u globulin has been identified and quantitated in a cell-free translational system derived from Krebs II ascites cells. Hepatic tissue of the mature male rats which normally produce alpha2u globulin was also found to contain a high level of alpha2u mRNA. Approximately 1.6 per cent of all poly(A) containing RNA of the adult male rat liver could be accounted for alpha2u messenger activity. Female rats do not produce alpha2u globulin and no alpha2u mRNA activity could be detected in the poly(A) containing RNA fraction obtained from the livers of these animals. However, androgen treatment to spayed female rats was found to induce the parallel appearance to both alpha2u globulin and its corresponding mRNA. Both hypophysectomy and adrenalectomy which are known to reduce the level of alpha2u globulin in the urine of male rats were found also to reduce the hepatic level of alpha2u mRNA. The results indicate that hormonal control of alpha2u globulin synthesis in rat liver is achieved primarily through regulation of its translatable mRNA level and that more than one hormone may participate in this regulation.     

Translational control of hepatic alpha2u globulin synthesis by growth hormone.

α_2u Globulin is a male rat liver protein under complex hormonal control which represents approximately 1% of hepatic protein synthesis in an adult male rat. Hypophysectomy completely abolishes the hepatic synthesis of this protein, and the reinduction of its synthesis can be effected by the simultaneous administration of glucocorticoid, androgen, thyroid hormone and pituitary growth hormone. Growth hormone is absolutely required for the synthesis of a normal level of α_2u globulin. It was found, however, that hepatic α_2u globulin mRNA can be raised to a normal level in hypophysectomized animals by administration of steroids and thyroid hormone alone; nevertheless, no detectable synthesis of the protein occurs in these animals. Administration of growth hormone to the hypophysectomized animals that had been pretreated with steroids and thyroid hormone results in the immediate synthesis of α_2u globulin protein with very little change in the level of α_2u globulin mRNA. In an intact male animal, α_2u globulin mRNA sequences are found to be preferentially associated with bound polysomes. By contrast, the untranslated α_2u globulin mRNA sequences that accumulate in the livers of hypophysectomized rats treated with steroids and thyroid hormone are found on free polysomes and in the supernatant (nonpolysomal) fractions. Administration of growth hormone to these animals effects a shift of α_2u globulin mRNA sequences to bound polysomes, concurrent with the induction of detectable synthesis of the protein. This effect of growth hormone in vivo can be mimicked by administration of high doses of insulin, indicating that this effect may be somatomedin-mediated. It thus appears that growth hormone induces hepatic α_2u globulin synthesis by way of a translational control mechanism.     

Synthesis and immunocytochemical localization of alpha 2u globulin in the duct cells of the rat submaxillary gland

Alpha 2u globulin, a protein of unknown function so far believed to be synthesized exclusively in the male liver under multihormonal control, is now shown to be localized by immunocytochemistry in the granular convoluted tubules of the adult male submaxillary gland. In addition, using Northern blot analysis, we have shown specific alpha 2u globulin mRNA sequences in the RNA extracted from the submaxillary gland. Thus, it is evident that the protein is being synthesized therein. Alpha 2u globulin was also detected in the submaxillary gland duct cells of adult female and immature animals of both sexes, all of which are known not to synthesize alpha 2u globulin in their livers. The present data have established that alpha 2u globulin is synthesized in the rat submaxillary gland and indicate that the control of alpha 2u globulin gene expression in the rat liver and in the submaxillary gland is different.     

Induction of alpha 2u globulin mRNA by phenobarbital in rat liver: characterization of a cDNA clone

A clone has been selected from a cDNA library previously constructed from phenobarbital pre-treated rat liver polysomal poly(A)+ RNA, which was reverse transcribed. The double-stranded cDNA was inserted by GC homopolymeric tailing in the Pst I site of pAT 153, and further cloned in E. coli HB101. This clone, called 2A9, corresponds to a mRNA whose concentration is increased five fold 16 h after phenobarbital treatment. Its length is 1200 nucleotides as revealed by RNA dot and Northern blot analysis respectively. The two strands of a 450 bp fragment from the 2A9 580 bp double-stranded cDNA insert have been sequenced and proven to correspond to alpha 2u globulin mRNA. It shows one single bp difference from the sequence previously published by Unterman et al. (1981, PNAS, 78, 3478). Thus, alpha 2u globulin, a hormone regulated gene product, is inducible by phenobarbital.