Mouse Major Urinary Protein Gene Research Articles

The Expansion of House Mouse Major Urinary Protein Genes Likely Did Not Facilitate Commensalism with Humans.

Mouse wild-derived strains (WDSs) combine the advantages of classical laboratory stocks and wild animals, and thus appear to be promising tools for diverse biomedical and evolutionary studies. We employed 18 WDSs representing three non-synanthropic species (Mus spretus, Mus spicilegus, and M. macedonicus) and three house mouse subspecies (Mus musculus musculus, M. m. domesticus, M. m. castaneus), which are all important human commensals to explore whether the number of major urinary protein (MUP) genes and their final protein levels in urine are correlated with the level of commensalism. Contrary to expectations, the MUP copy number (CN) and protein excretion in the strains derived from M. m. castaneus, which is supposed to be the strongest commensal, were not significantly different from the non-commensal species. Regardless of an overall tendency for higher MUP amounts in taxa with a higher CN, there was no significant correlation at the strain level. Our study thus suggests that expansion of the Mup cluster, which appeared before the house mouse diversification, is unlikely to facilitate commensalism with humans in three house mouse subspecies. Finally, we found considerable variation among con(sub)specific WDSs, warning against generalisations of results based on a few strains.

Regulation of Hepatic Mouse Major Urinary Protein Genes by the Zinc Finger and Hemeoboxes 2 and Alpha‐fetoprotein Regulator 2

ObjectivesWe have previously found that AFP, H19, Glypican 3 (Gpc3) and Lipoprotein lipase (Lpl) are targets of Zinc Finger and Hemeoboxes (Zhx) 2 based on their elevated expression in the adult liver of BALB/cJ mice compared to other strains. Since mouse major urinary proteins (MUP) mRNA are expressed at lower levels in the adult liver of BALB/cJ mice compared to other mouse strains, we tested whether this trait is due to Zhx2.MethodsAt first, by using Real‐Time Polymerase Chain Reaction (PCR) techniques, we tested hepatic MUP mRNA levels in different mouse strains including BALB/c, BALB/cJ mice, BALB/cJ mice with Zhx2 liver transgene, and recently developed Zhx2 knock‐out mice. Next we performed liver regeneration and Afr2 analysis, C3H/HeJ (Afr2a) and C57BL/6 (Afr2b) mice (2–3 months old) were given intraperitoneal injections of 50 mL of mineral oil (MO) containing 10% (vol/vol) carbon tetrachloride (CCl4); control animals were given intraperitoneal injections of 50 mL of MO alone (22). Three days later, the animals were killed, and their livers were removed for RNA preparation and analysis. Lastly, we studied how Zhx2 regulates MUP using in‐vitro cell based assays.ResultsOur data indicate that MUP genes are target of Zhx2 regulation. In contrast to previous Zhx2 targets, which are elevated when Zhx2 levels are reduced, MUP expression decreases when Zhx2 levels are lower. AFP, H19, Gpc3 and Lpl are reactivated in regenerating liver and HCC. With all four genes, the level of induction is significantly less in C57BL/6 mice than in other mouse strains; this trait is governed by a single locus on mouse chromosome 2 called alpha‐fetoprotein regulator 2 (Afr2). The gene for the Afr2 phenotype has not yet been identified. Since all known Zhx2 targets are also regulated by Afr2, we tested whether MUP expression was influenced by this locus in regenerating liver. We found that MUP mRNA levels decreased in regenerating liver (in contrast to AFP, H19, Gpc3 and Lpl, which are increased in regenerating liver) and that this decrease is influenced by Afr2. Additionally, data from in vitro cell‐based assays demonstrated that Zhx2 could activate MUP24 promoter and increase MUP expression in AML cells.ConclusionTaken together, MUP is a new target of Zhx2 and it is positively regulated by Zhx2.

Identification of an Enhancer Required for the Expression of a Mouse Major Urinary Protein Gene in the Submaxillary Gland

The MUP1.5b gene was previously found to be expressed specifically in the submaxillary gland and at high levels when introduced into mice as a transgene including 4.7 kb of 5'-flanking DNA and 0.3 kb of 3'-flanking DNA. To localize regulatory elements responsible for this tissue-specific pattern of expression, we tested the expression of three additional MUP1.5b transgenes including various amounts of 5'-flanking DNA. These experiments indicated that sequences between -1.85 and -3.46 kb from the transcription initiation site were required for high-level expression in the submaxillary gland. The presence of regulatory elements in this region was also suggested by the detection of a DNase I-hypersensitive site, seen only in submaxillary gland nuclei, at position -2.5 kb upstream from the MUP1.5a gene, a member of the same MUP gene subfamily and virtually identical to the MUP1.5b gene. Further evidence for enhancer activity was provided by the ability of the 1.6-kb DNA fragment including sequences between -1.85 and -3.46 kb to stimulate the expression of an otherwise inactive MUP1.5b-chloramphenicol acetyltransferase fusion gene specifically in the submaxillary gland. The nucleotide sequence of this 1.6-kb DNA fragment was found to be identical for the MUP1.5a and MUP1.5b genes. Together, these results provide the first localization of a cis-acting regulatory sequence involved in the differential tissue-specific expression of the MUP gene family.

Identification of an enhancer required for the expression of a mouse major urinary protein gene in the submaxillary gland.

The MUP1.5b gene was previously found to be expressed specifically in the submaxillary gland and at high levels when introduced into mice as a transgene including 4.7 kb of 5'-flanking DNA and 0.3 kb of 3'-flanking DNA. To localize regulatory elements responsible for this tissue-specific pattern of expression, we tested the expression of three additional MUP1.5b transgenes including various amounts of 5'-flanking DNA. These experiments indicated that sequences between -1.85 and -3.46 kb from the transcription initiation site were required for high-level expression in the submaxillary gland. The presence of regulatory elements in this region was also suggested by the detection of a DNase I-hypersensitive site, seen only in submaxillary gland nuclei, at position -2.5 kb upstream from the MUP1.5a gene, a member of the same MUP gene subfamily and virtually identical to the MUP1.5b gene. Further evidence for enhancer activity was provided by the ability of the 1.6-kb DNA fragment including sequences between -1.85 and -3.46 kb to stimulate the expression of an otherwise inactive MUP1.5b-chloramphenicol acetyltransferase fusion gene specifically in the submaxillary gland. The nucleotide sequence of this 1.6-kb DNA fragment was found to be identical for the MUP1.5a and MUP1.5b genes. Together, these results provide the first localization of a cis-acting regulatory sequence involved in the differential tissue-specific expression of the MUP gene family.

Silent genes in the mouse major urinary protein gene family.

To date, two classes of mouse major urinary protein (MUP)-encoding genes have been described, the expressed genes and the intervening-sequence-containing pseudogenes. The data presented in this paper define a third class, the silent Mup genes, which are potentially functional but appear not to be expressed under normal circumstances. We describe a MUP subfamily (Mup-1.5) containing two genes, Mup-1.5a and Mup-1.5b, that are nearly identical, differing at only three positions (greater than 99.9% identity) over the entire 4-kilobase (kb) transcription unit and approximately 1 kb of flanking DNA. The similarity between these two genes extends over greater than 35 kb. Using specific oligonucleotides, we have shown that the 5a gene is expressed in BALB/cByJ mice, primarily in the submaxillary gland, whereas the 5b gene is not expressed. However, we found that when a 9.4-kb DNA fragment containing the Mup-1.5b gene was introduced into the mouse germ line, mice in two of the four transgenic lines expressed this gene at a high level and with the tissue-specificity characteristic of the Mup-1.5a gene. These results suggest that the inactivity of the endogenous Mup-1.5b gene is due not to a lack of functional positive regulatory elements, but to long-range, inhibitory position effects.

T antigen expression and tumorigenesis in transgenic mice containing a mouse major urinary protein/SV40 T antigen hybrid gene.

A hybrid mouse major urinary protein (MUP)/SV40 T antigen gene was microinjected into fertilized mouse embryos and the resulting transgenic mice analyzed for the regulated expression of the transgene. Available evidence indicates that the MUP gene used for the hybrid gene construct is expressed in both male and female liver and possibly mammary gland. Three different transgenic lines exhibited a consistent pattern of tissue specific expression of the transgene. As a consequence of transgene expression and T antigen synthesis in the liver, both male and female transgenic animals developed liver hyperplasia and tumors. Transgene expression and liver hyperplasia commenced at approximately 2-4 weeks of age, the same time that MUP gene expression is first detected in the liver. The expression of the transgene resulted in an immediate strong suppression of liver MUP mRNA levels but had relatively little effect on other liver specific mRNAs. From 4 to 8 weeks, the liver increased several fold in size, relative to non-transgenic littermates. Definitive tumor nodules were not apparent until 8-10 weeks. The transgene was also consistently found to be expressed in the skin sebaceous glands and the preputial gland, a modified sebaceous gland. The expression of the transgene in the skin sebaceous glands is consistent with the presence of MUP mRNA in the skin and a putative role for MUPs in the transport and excretion of small molecules. Occasional expression of the transgene in other tissues (kidney and mammary connective tissues) was also noted.(ABSTRACT TRUNCATED AT 250 WORDS)

Tissue-Specific and Hormonally Regulated Expression of a Rat α2u 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 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.

Expression of six mouse major urinary protein genes in the mammary, parotid, sublingual, submaxillary, and lachrymal glands and in the liver.

Mouse major urinary proteins (MUPs) are encoded by a family of about 35 to 40 highly conserved genes. In the preceding paper (K. Shahan, M. Gilmartin, and E. Derman, Mol. Cell. Biol. 7:1938-1946, 1987), we presented the sequences of the most abundant MUP mRNAs in the liver (MUP I, II, and III) and in the lachrymal (MUP IV) and submaxillary (MUP V) glands. We have shown that these five mRNAs are coded by five distinct genes, MUP I through V. In the present communication, we examine the expression of MUP genes in all of the six tissues in which MUP mRNAs are synthesized, the mammary, parotid, sublingual, lachrymal, and submaxillary glands and the liver. We show that gene MUP II is expressed in the liver and in the mammary gland, that gene MUP IV is expressed in the lachrymal and parotid glands, and that gene MUP V is expressed in the submaxillary, sublingual, and lachrymal and parotid glands, and that gene MUP V is expressed in the submaxillary, sublingual, and lachrymal glands. Furthermore, we present evidence that in addition to genes MUP I through V, another gene, MUP VI, is expressed in BALB/c mice in the parotid gland. The tissue-specific synthesis of MUP mRNAs is thus brought about by two major mechanisms: the expression, in different tissues, of different members of the family and the expression of a single gene at various levels in different tissues. When a particular MUP gene is expressed in several tissues, transcripts of this gene initiate at the same site and are spliced and polyadenylated in the same manner.

Expression of six mouse major urinary protein genes in the mammary, parotid, sublingual, submaxillary, and lachrymal glands and in the liver.

Mouse major urinary proteins (MUPs) are encoded by a family of about 35 to 40 highly conserved genes. In the preceding paper (K. Shahan, M. Gilmartin, and E. Derman, Mol. Cell. Biol. 7:1938-1946, 1987), we presented the sequences of the most abundant MUP mRNAs in the liver (MUP I, II, and III) and in the lachrymal (MUP IV) and submaxillary (MUP V) glands. We have shown that these five mRNAs are coded by five distinct genes, MUP I through V. In the present communication, we examine the expression of MUP genes in all of the six tissues in which MUP mRNAs are synthesized, the mammary, parotid, sublingual, lachrymal, and submaxillary glands and the liver. We show that gene MUP II is expressed in the liver and in the mammary gland, that gene MUP IV is expressed in the lachrymal and parotid glands, and that gene MUP V is expressed in the submaxillary, sublingual, and lachrymal and parotid glands, and that gene MUP V is expressed in the submaxillary, sublingual, and lachrymal glands. Furthermore, we present evidence that in addition to genes MUP I through V, another gene, MUP VI, is expressed in BALB/c mice in the parotid gland. The tissue-specific synthesis of MUP mRNAs is thus brought about by two major mechanisms: the expression, in different tissues, of different members of the family and the expression of a single gene at various levels in different tissues. When a particular MUP gene is expressed in several tissues, transcripts of this gene initiate at the same site and are spliced and polyadenylated in the same manner.

Analysis of mouse major urinary protein genes: variation between the exonic sequences of group 1 genes and a comparison with an active gene out with group 1 both suggest that gene conversion has occurred between MUP genes.

Here we compare the exonic sequences of four Group 1 mouse major urinary protein (MUP) genes and four Group 1 cDNA sequences. These define seven different nucleotide sequences which differ from each other by 0.35% of bases on average, and which would code for seven different MUP proteins that could probably be resolved physically into at least five classes. The sequences differ at 13 nucleotide positions and at six codons, and although they are closely related their descent cannot be described by a simple series of duplications. We also describe the sequence of another liver cDNA (pMUP15) which has diverged from the Group 1 consensus sequence in 14.6% of bases. The divergence is much greater over exons 1-3 than over exons 4-6, suggesting that an ancestral gene conversion event has occurred. pMUP15 also differs from the Group 1 genes in having a longer signal peptide sequence and a different splice configuration between exons 6 and 7. Unlike the Group 1 sequences, pMUP15 contains a potential N-linked glycosylation site. Other published work has shown that a shorter cDNA clone which is identical over their common sequence to pMUP15 codes for MUP proteins that are unusually large in size and acidic in pI. We show here that mouse urine does indeed contain a glycosylated MUP protein with those properties, presumably the product of the gene that corresponds to pMUP15.

Structure of mouse major urinary protein genes: different splicing configurations in the 3'-non-coding region.

The multigene family which codes for the mouse major urinary proteins (MUPs) consists of approximately 35 genes. Most of these are members of two different groups, Group 1 and Group 2, which can be distinguished by nucleic acid hybridisation. Here we describe the structure of a Group 1 gene and show that two size classes of MUP mRNA which are found in mouse liver result from different splicing events in the 3'-non-coding region and contain different polyadenylation sites. Short mRNA is approximately 750 nucleotides long, contains six exons, and is the main product of the Group 2 genes. Long mRNA is approximately 880 nucleotides long, contains seven exons and is the main product of the Group 1 genes. Five exons and part of the sixth are common to long and short mRNA and contain the coding region. This codes for an acidic protein of 180 amino acids containing an 18 residue signal peptide. A comparison of the mouse sequence with a homologous rat alpha 2u-globulin sequence shows that the rate of evolutionary divergence of the two proteins has been high. Silent sites have diverged four times more rapidly than replacement sites, showing that there has been selection against change in the protein sequence.

Differential, Multihormonal Regulation of the Mouse Major Urinary Protein Gene Family in the Liver

Differential, Multihormonal Regulation of the Mouse Major Urinary Protein Gene Family in the Liver

Differential, Multihormonal Regulation of the Mouse Major Urinary Protein Gene Family in the Liver

Differential, Multihormonal Regulation of the Mouse Major Urinary Protein Gene Family in the Liver

Differential, multihormonal regulation of the mouse major urinary protein gene family in the liver.

The hormonal requirements for the regulation of the major urinary protein (MUP) mRNA levels in mouse liver have been examined. Previous experiments have shown that administration of testosterone to female or castrated male mice increases MUP mRNA levels approximately fivefold to normal male levels. We have found that thyroxine and the peptide hormone, growth hormone, each had a pronounced effect on MUP mRNA levels. MUP mRNA was reduced 150-fold in growth-hormone-deficient mutant mice (little). The administration of growth hormone and thyroxine induced MUP mRNA approximately 150-fold, and when administered together, they induced MUP mRNA approximately 1,000-fold. testosterone administration. When administered separately to these mice, growth hormone and thyroxine induced with MUP mRNA approximately 150-fold, and when administered together, they induced MUP mRNA approximately 1,000-fold. Testicular feminized mice, which lack a functional major testosterone receptor protein, can also be induced to male levels by treatment with both growth hormone and thyroxine. In addition, we present evidence which indicates that growth hormone, thyroxine, and testosterone differentially regulate the levels of distinct MUP mRNA species.

Differential, multihormonal regulation of the mouse major urinary protein gene family in the liver.

The hormonal requirements for the regulation of the major urinary protein (MUP) mRNA levels in mouse liver have been examined. Previous experiments have shown that administration of testosterone to female or castrated male mice increases MUP mRNA levels approximately fivefold to normal male levels. We have found that thyroxine and the peptide hormone, growth hormone, each had a pronounced effect on MUP mRNA levels. MUP mRNA was reduced 150-fold in growth-hormone-deficient mutant mice (little). The administration of growth hormone and thyroxine induced MUP mRNA approximately 150-fold, and when administered together, they induced MUP mRNA approximately 1,000-fold. testosterone administration. When administered separately to these mice, growth hormone and thyroxine induced with MUP mRNA approximately 150-fold, and when administered together, they induced MUP mRNA approximately 1,000-fold. Testicular feminized mice, which lack a functional major testosterone receptor protein, can also be induced to male levels by treatment with both growth hormone and thyroxine. In addition, we present evidence which indicates that growth hormone, thyroxine, and testosterone differentially regulate the levels of distinct MUP mRNA species.

Variation in mouse major urinary protein (MUP) genes and the MUP gene products within and between inbred lines

The mouse major urinary proteins (MUPs) and the unprocessed in vitro translation products of MUP mRNA were each resolved by isoelectric focusing (IEF). The urinary MUPs showed about 15 distinct components, and the unprocessed MUPs about 20. In each case wide variation was observed in the relative intensities of individual bands. A comparison of three inbred lines (C57BL, BALB/c and JU) showed inter-line variation in the patterns both of the urinary MUPs and of the unprocessed MUPs. A series of experiments was carried out with a cloned MUP cDNA probe. All three inbred lines contain the same number (about 20) of MUP genes per haploid genome. In Southern blot analysis of genomic DNA the MUP genes displayed complex patterns which we interpret as showing variation on a common basic MUP gene sequence. For each combination of restriction enzymes tested, one size of fragment carried more than half of the total label, and this fragment was always the same in the three inbred lines. Inter-line differences were observed in the patterns of some of the less reactive fragments. MUP mRNA consists of at least two distinct species with sizes of 1 and 1.2 kb, which reacted with the probe in a label ratio of about 0.5 to 1. In the three inbred lines this ratio was essentially the same.

Variation between mouse major urinary protein genes isolated from a single inbred line

We describe ten Charon 4A genomic DNA clones from BALB/c mice which include at least seven different major urinary protein (MUP) genes. We have established the orientation of all seven sequences, and have placed six of them in precise register by means of restriction site maps and Southern blot hybridization with cloned cDNA sequences. Four of the seven genomic sequences (family I sequences) form hybrids with six independent cDNA clones that have a high thermal stability and hybridize more strongly with mRNA from three inbred mouse lines. Hybrids between the remaining three genomic sequences and the cDNA clones have a lower thermal stability and hybridize less strongly with mRNA from the three inbred lines. Homologies between different cloned sequences extend over as much as 15 kb. No clone contains parts of two MUP genes, and no homology has been detected between the 3' flanking region of one MUP gene and the 5' flanking region of another.

Two main groups of mouse major urinary protein genes, both largely located on chromosome 4.

Fourteen different major urinary protein (MUP) genomic clones from BALB/c mice were isolated. By restriction site mapping, six of these form two sets of three overlapping clones. By the criterion of cross-hybridization, the 10 different genes fall into two groups of four (Group 1) and three (Group 2) genes, while three genes fall into neither group. Southern blot analysis of genomic DNA with Group 1 and Group 2 plasmid subclones shows that the haploid mouse (BALB/c) genome contains approximately 15 Group 1 genes, 12 Group 2 genes and at least seven MUP genes that belong to neither group. An analysis of mouse-Chinese hamster hybrid cell lines shows that most, if not all, Group 1 and Group 2 genes are located on mouse chromosome 4.