DNA insertions distinguish the duplicated renin genes of DBA/2 and M. hortulanus mice.

In a survey of inbred and wild mouse DNAs for genetic variation at the duplicate renin loci, Ren-1 and Ren-2, a variant Not I hybridization pattern was observed in the wild mouse M. hortulanus. To determine the basis for this variation, the structure of the M. hortulanus renin loci has been examined in detail and compared to that of the inbred strain DBA/2. Overall, the gross features of structure in this chromosomal region are conserved in both Mus species. In particular, the sequence at the recombination site between the linked Ren-1 and Ren-2 loci was found to be identical in both DBA/2 and M. hortulanus, indicating that the renin gene duplication occurred prior to the divergence of ancestors of these mice. Renin flanking sequences in M. hortulanus, however, were found to lack four DNA insertions totaling approximately 10.5 kb which reside near the DBA/2 loci. The postduplication evolution of the mouse renin genes is thus characterized by a number of insertion and/or deletion events within nearby flanking sequences. Analysis of renin expression showed little or no difference between these mice in steady state renin RNA levels in most tissues examined, suggesting that these insertions do not influence expression at those sites. A notable exception is the adrenal gland, in which DBA/2 and M. hortulanus mice exhibit different patterns of developmentally regulated renin expression.     

DNA insertions distinguish the duplicated renin genes of DBA/2 andM. hortulanus mice

In a survey of inbred and wild mouse DNAs for genetic variation at the duplicate renin loci,Ren-1 andRen-2, a variantNot I hybridization pattern was observed in the wild mouseM. hortulanus. To determine the basis for this variation, the structure of theM. hortulanus renin loci has been examined in detail and compared to that of the inbred strain DBA/2. Overall, the gross features of structure in this chromosomal region are conserved in bothMus species. In particular, the sequence at the recombination site between the linkedRen-1 andRen-2 loci was found to be identical in both DBA/2 andM. hortulanus, indicating that the renin gene duplication occurred prior to the divergence of ancestors of these mice. Renin flanking sequences inM. hortulanus, however, were found to lack four DNA insertions totaling approximately 10.5 kb which reside near the DBA/2 loci. The postduplication evolution of the mouse renin genes in thus characterized by a number of insertion and/or deletion events within nearby flanking sequences. Analysis of renin expression showed little or no difference between these mice in steady state renin RNA levels in most tissues examined, suggesting that these insertions do not influence expression at those sites. A notable exception is the adrenal gland, in which DBA/2 andM. hortulanus mice exhibit different patterns of developmentally regulated renin expression.     

Close physical linkage of the murine Ren-1 and Ren-2 loci

In addition to the Ren-1 gene common to all mice, some inbred strains carry a second copy of the renin structural gene, Ren-2. These two loci are tightly linked genetically on mouse chromosome one. We have used pulsed field gel electrophoresis (PFGE) to study the physical arrangement of the two renin genes in the inbred strain DBA/2. PFGE mapping permitted the construction of a restriction map of the Ren loci spanning roughly 120 Kb. The results indicate that the genes are transcribed in the same relative direction, that Ren-2 lies upstream relative to Ren-1, and that the respective coding sequences are separated by approximately 20 Kb.     

Physical Characterization of Genetic Rearrangements at the Mouse Renin Loci

Many inbred strains of mice have a single locus encoding renin, Ren-1, whereas other inbred strains have two tandemly linked loci, Ren-1 and Ren-2. Each of these renin genes in inbred mice exhibits a unique pattern of tissue-specific expression. As a prerequisite to understanding the structural basis for the expression differences, we have physically characterized the sequence organization of this chromosomal region in both types of strains. Pulsed field gel electrophoresis was initially used to compare the long-range structure of this region in C57BL/6 (Ren-1) and DBA/2 (Ren-1 + Ren-2) mice. The structure in both inbred strains is extremely similar, except for an additional 30 kb containing Ren-2 in DBA/2 mice. The boundaries of the extra 30-kb segment were sequenced and compared to homologous sequences flanking the Ren-1 alleles. This analysis identified the precise recombination site, and also the presence of a large insertion, between the renin loci in DBA/2. The renin gene duplication apparently resulted from recombination between sequences sharing little homology, suggesting that nonhomologous chromosomal breakage and rejoining may have been involved mechanistically in the event.     

Gene expression of the repulsive guidance molecules/neogenin in the developing and mature mouse visual system: C57BL/6J vs. the glaucoma model DBA/2J

We used in-situ hybridization to analyze the expression patterns of three known members (a, b and c) of the RGM (“repulsive guidance molecule”) gene family and of the RGMa receptor neogenin in a glaucoma mouse model (DBA/2J strain) and the C57BL/6J strain, which served as a control. In order to understand the role of the RGMs and neogenin in glaucoma, we characterized their expression patterns in the developing and mature mouse retina and in the optic nerve. In all investigated stages from post-natal day (P) 0 to 15 months (M) RGMa, RGMb and neogenin expression was detected in the ganglion cell layer (GCL). From P10 to 15 M, we found RGMa, RGMb and neogenin expression in the inner nuclear layer (INL) and the outer nuclear layer (ONL). In P10- and older mice, the expression patterns of RGMa and its receptor neogenin were similar, while that of RGMb differed from both. As expected, no specific retinal expression of RGMc was detected in any of the age groups investigated. C57BL/6J mice and DBA/2J mice displayed no differences in the expression pattern of RGMa, RGMb, RGMc and neogenin in the developing retina (gestational age 14.5 days (E14.5), P0 & P10). Interestingly, we found a higher expression of RGMa, RGMb and neogenin in the retinas of all glaucoma-affected mice than in the age-matched control strain. Furthermore, we detected a higher RGMa and RGMb expression in the optic nerves of glaucoma-affected DBA/2J-mice older than 11 M than in C57BL/6J mice of the same age.     

The nucleotide sequence of a mouse renin-encoding gene, Ren-1d, and its upstream region

The renin-encoding genes have been cloned from high (Ren-1d, Ren-2d)- and low (Ren-1c)-renin-producing strains of mice (DBA/2J and C57BL/10). Each of the genes is approx. 9.6 kb in length and consists of nine exons and eight introns. The entire nucleotide sequence of the Ren-1d gene has been determined and the 5'-flanking regions of the three genes, Ren-1c, Ren-1d and Ren-2d, have been compared. The significance of several potential regulatory signals found in the DNA is discussed.     

Gene expression of the repulsive guidance molecules/neogenin in the developing and mature mouse visual system: C57BL/6J vs. the glaucoma model DBA/2J

We used in-situ hybridization to analyze the expression patterns of three known members (a, b and c) of the RGM ("repulsive guidance molecule") gene family and of the RGMa receptor neogenin in a glaucoma mouse model (DBA/2J strain) and the C57BL/6J strain, which served as a control. In order to understand the role of the RGMs and neogenin in glaucoma, we characterized their expression patterns in the developing and mature mouse retina and in the optic nerve. In all investigated stages from post-natal day (P) 0 to 15 months (M) RGMa, RGMb and neogenin expression was detected in the ganglion cell layer (GCL). From P10 to 15M, we found RGMa, RGMb and neogenin expression in the inner nuclear layer (INL) and the outer nuclear layer (ONL). In P10- and older mice, the expression patterns of RGMa and its receptor neogenin were similar, while that of RGMb differed from both. As expected, no specific retinal expression of RGMc was detected in any of the age groups investigated. C57BL/6J mice and DBA/2J mice displayed no differences in the expression pattern of RGMa, RGMb, RGMc and neogenin in the developing retina (gestational age 14.5 days (E14.5), P0 & P10). Interestingly, we found a higher expression of RGMa, RGMb and neogenin in the retinas of all glaucoma-affected mice than in the age-matched control strain. Furthermore, we detected a higher RGMa and RGMb expression in the optic nerves of glaucoma-affected DBA/2J-mice older than 11M than in C57BL/6J mice of the same age.     

The angiotensinogen gene of Swiss mice is closely linked to a retrovirus-like element

Angiotensinogen is cleaved by renin and angiotensin-converting enzyme to liberate the potent vasocontrictor peptide angiotensin II. We have recently identified a cis-acting genetic lesion associated with high levels of angiotensinogen mRNA in the testis and salivary gland of Swiss mice. To determine the molecular basis of this mutation, the Swiss angiotensinogen gene was cloned, and its structure was compared to that from a low-expressing strain (BALB/c). I show that a retrovirus-like element belonging to the intracisternal A-particle gene family has been inserted 9 kb upstream from the cap site of the Swiss angiotensinogen gene. This intracisternal A-particle, named IAP-Agt, segregated concordantly with angiotensinogen expression phenotypes in CXB recombinant inbred mice. However, genomic Southern analysis showed that IAP-Agt was present in some, but not all, inbred laboratory mouse strains displaying high levels of angiotensinogen gene expression. On the basis of this evolutionary evidence, it is unlikely that IAP-Agt is the cause of the angiotensinogen mutation. It is intriguing that Ren-2, the duplicated mouse renin gene, is expressed to high levels in the male salivary gland and also contains a transposed intracisternal A-particle genome.     

A decrease in guanylate cyclase activity in some tissues of C3H/HeJ mice with retinal dystrophy

Guanylate cyclase activity was assayed in homogenates, in particulate and soluble fractions from retina, cerebellum, cerebral cortex and adrenal gland of adult C3H/HeJ mice with a dystrophic retinopathy. In comparison to control mice (DBA/1J), in C3H/HeJ strain a significant decrease in guanylate cyclase activity occurred in homogenates from retina, cerebellum and adrenal gland. In particular a significant decrease was found in particulate fraction of retina, in the soluble fraction of cerebral cortex and cerebellum and in both fractions of the adrenal gland. In contrast to the retina and cerebellum where guanylate cyclase activity in homogenates was found significantly decreased both in the male and female, in the cerebral cortex guanylate cyclase decreased in both sexes although in female this was more marked.     

Evolution and Variation of Renin Genes in Mice

Inbred strains of mice carry Ren-1, a gene encoding the thermostable Renin-1 isozyme. Ren-1 is expressed at relatively low levels in mouse submandibular gland and kidney. Some strains also carry Ren-2, a gene encoding the thermolabile Renin-2 isozyme. Ren-2 is expressed at high levels in the mouse submandibular gland and at very low levels, if at all, in the kidney. Ren-1 and Ren-2 are closely linked on mouse chromosome 1, show extensive homology in coding and noncoding regions and provide a model for studying the regulation of gene expression. An investigation of renin genes and enzymatic activity in wild-derived mice identified several restriction site polymorphisms as well as putative variants in renin gene expression and protein structure. The number of renin genes carried by different subpopulations of wild-derived mice is consistent with the occurrence of a gene duplication event prior to the divergence of M. spretus (2.75–5.5 million yr ago). This conclusion is in agreement with a prior estimate based upon comparative sequence analysis of Ren-1 and Ren-2 from inbred laboratory mice.     

Quantitative trait locus mapping of genes associated with vacuolation in the adrenal X-zone of the DDD/Sgn inbred mouse

Background

Adrenal gland of mice contains a transient zone between the adrenal cortex and the adrenal medulla: the X-zone. There are clear strain differences in terms of X-zone morphology. Nulliparous females of the inbred mouse DDD strain develop adrenal X-zones containing exclusively vacuolated cells, whereas females of the inbred mouse B6 strain develop X-zones containing only non-vacuolated cells. The X-zone vacuolation is a physiologic process associated with the X-zone degeneration and is tightly regulated by genetic factors. Identification of the genetic factors controlling such strain differences should help analyze the X-zone function. In this study, a quantitative trait locus (QTL) analysis for the extent of X-zone vacuolation was performed for two types of F₂ female mice: F₂A ^y mice (F₂ mice with the A ^y allele) and F₂ non-A ^y mice (F₂ mice without the A ^y allele). These were produced by crossing B6 females and DDD.Cg-A ^y males. DDD.Cg-A ^y is a congenic mouse strain for the A ^y allele at the agouti locus and is used for this study because a close association between the X-zone morphology and the agouti locus genotype has been suggested. The A ^y allele is dominant and homozygous lethal; therefore, living A ^y mice are invariably heterozygotes.

Results

Single QTL scans identified significant QTLs on chromosomes 1, 2, 6, and X for F₂ non-A ^y mice, and on chromosomes 2, 6, and 12 for F₂A ^y mice. The QTL on chromosome 2 was considered to be because of the agouti locus, which has been suggested to be associated with X-zone vacuolation. A significant QTL that interacted with the agouti locus was identified on chromosome 8.

Conclusions

The extent of X-zone vacuolation in DDD females was controlled by multiple genes with complex interactions. The murine X-zone is considered analogous structure to the human fetal zone. Therefore, the results of this study will aid in understanding function of not only of the X-zone but also of the human fetal zone. Identifying the genes responsible for the QTLs will be essential for understanding the molecular basis of X-zone function, which is currently unclear.