- Research article
- Open Access
Genetic context determines susceptibility to intraocular pressure elevation in a mouse pigmentary glaucoma
BMC Biology volume 4, Article number: 20 (2006)
DBA/2J (D2) mice develop an age-related form of glaucoma. Their eyes progressively develop iris pigment dispersion and iris atrophy followed by increased intraocular pressure (IOP) and glaucomatous optic nerve damage. Mutant alleles of the Gpnmb and Tyrp1 genes are necessary for the iris disease, but it is unknown whether alleles of other D2 gene(s) are necessary for the distinct later stages of disease. We initiated a study of congenic strains to further define the genetic requirements and disease mechanisms of the D2 glaucoma.
To further understand D2 glaucoma, we created congenic strains of mice on the C57BL/6J (B6) genetic background. B6 double-congenic mice carrying D2-derived Gpnmb and Tyrp1 mutations develop a D2-like iris disease. B6 single-congenics with only the Gpnmb and Tyrp1 mutations develop milder forms of iris disease. Genetic epistasis experiments introducing a B6 tyrosinase mutation into the congenic strains demonstrated that both the single and double-congenic iris diseases are rescued by interruption of melanin synthesis. Importantly, our experiments analyzing mice at ages up to 27 months indicate that the B6 double-congenic mice are much less prone to IOP elevation and glaucoma than are D2 mice.
As demonstrated here, the Gpnmb and Tyrp1 iris phenotypes are both individually dependent on tyrosinase function. These results support involvement of abnormal melanosomal events in the diseases caused by each gene. In the context of the inbred D2 mouse strain, the glaucoma phenotype is clearly influenced by more genes than just Gpnmb and Tyrp1. Despite the outward similarity of pigment-dispersing iris disease between D2 and the B6 double-congenic mice, the congenic mice are much less susceptible to developing high IOP and glaucoma. These new congenic strains provide a valuable new resource for further studying the genetic and mechanistic complexity of this form of glaucoma.
The glaucomas are a common group of diseases sharing a characteristic pattern of retinal ganglion cell (RGC) degeneration and optic nerve head excavation [1–3]. Increased intraocular pressure (IOP) is a significant predisposing risk factor for glaucoma, and all current glaucoma treatments aim to manipulate this trait [4, 5]. Pigment dispersion syndrome (PDS) is a common condition that results in the dispersion of iris pigment into the anterior chamber (AC) [6, 7]. The dispersed pigment accumulates within the ocular drainage structures, resulting in IOP elevation and glaucoma in some but not all individuals with PDS [8–12]. The molecular events that underlie PDS and that determine whether pigment dispersion leads to IOP elevation and pigmentary glaucoma remain largely unknown. A promising approach for gaining insight into these complex processes is to use the mouse as an experimental system [13–16]. A benefit of this approach is that genetic and environmental factors can be significantly controlled and manipulated, thus making the biological complexity of a disease such as glaucoma easier to approach experimentally.
DBA/2J (D2) mice, and some related substrains, develop a form of glaucoma characterized by a pigment-dispersing iris disease that aberrantly deposits pigment throughout the AC, including the drainage structures of the eye. As a consequence, IOP becomes elevated and glaucomatous RGC degeneration ensues [17–21]. The D2 iris disease is initiated by the combined interactions of the Tyrp1 band Gpnmb R150Xmutations [22, 23]. Tyrp1 encodes a membrane-bound melanosomal protein with enzymatic activity involved in melanin synthesis [24–26]. Relatively little is known about Gpnmb function. The GPNMB protein has been detected in melanocytes , dendritic cells , and a small list of other cell types [29–33]. Despite these findings, the cellular mechanisms by which Tyrp1 and Gpnmb contribute to the glaucoma remain largely unknown. Furthermore, it is also unknown whether the Gpnmb and Tyrp1 mutations are sufficient to elicit the D2 form of glaucoma, or whether additional alleles are necessary during distinct stages of disease.
Here, we report experiments utilizing an analysis of congenic strains of mice that further probe the genetic requirements contributing to the D2 form of glaucoma. The D2-derived Tyrp1 band Gpnmb R150Xmutations were backcrossed into the widely used C57BL/6J (B6) background. B6 double-congenic mice (homozygous for both mutations) were utilized in genetic epistasis experiments and compared with D2 with respect to clinical indices of iris disease, IOP elevation, and optic nerve damage. Similar to D2 mice, B6 double-congenic mice develop a severe depigmenting iris disease leading to massive pigment dispersion and aberrant pigment deposition on AC tissues. In comparison to D2, the B6 double-congenic mice are much less likely to develop increased IOP in response to this pigment dispersing disease. These results indicate that initiation (iris disease) and progression (high IOP) of glaucomatous phenotypes in D2 mice are genetically separable and that additional D2-derived hereditary factors relevant to glaucoma remain to be characterized. Identification of these factors in mice may promote understanding of factors contributing to human glaucoma and suggest improved strategies for preventing glaucoma progression.
Generation of B6 congenic strains containing the Tyrp1 band Gpnmb R150Xmutations
In order to further probe the genetic requirements contributing to the D2 form of glaucoma, we created congenic strains of mice on the B6 genetic background. Our approach for transferring the D2-derived Tyrp1 band Gpnmb R150Xmutations to the B6 background was to first create separate congenic strains for each of the respective chromosomal regions (Figure 1). Successive rounds of backcrossing utilizing markers flanking Tyrp1 (Figure 1A) and Gpnmb (Figure 1B) yielded the single-congenic strains for Tyrp1 b(B6.D2-Tyrp1 b/Sj; here after abbreviated B6.Tyrp1 b) and Gpnmb R150X(B6.D2-Gpnmb R150X/Sj; here after abbreviated B6.Gpnmb R150X). The final sizes of the N10 congenic intervals were determined to be 14–36 cM (23.6–63.2 Mb) for B6. Tyrp1 band 9–15 cM (10.0–36.8 Mb) for B6. Gpnmb R150X. After each single N10 congenic strain was established, mice were intercrossed to generate a double-congenic stock homozygous for both congenic intervals (B6.D2-Tyrp1 b Gpnmb R150X/Sj; here after abbreviated B6.Tyrp1 b Gpnmb R150Xor referred to as B6 double-congenic).
B6 background is permissive to Tyrp1 band Gpnmb R150Xmediated iris disease
Cohorts of N10 mice of all three genotypes (B6.Tyrp1 b, B6. Gpnmb R150X, and B6.Tyrp1 b Gpnmb R150X) were aged and assayed for relevant phenotypes. As expected, congenic mice homozygous for the Tyrp1 bmutation had brown coat colors [34, 35], whereas the Gpnmb R150Xmutation had no effect on coat color in any of the stocks examined. Clinical analysis of iris phenotypes in aged cohorts of the single-congenic B6.Tyrp1 b(Figs. 1C to 1E), single-congenic B6.Gpnmb R150X(Figs. 1F to 1H), and double-congenic B6.Tyrp1 b Gpnmb R150X(Figure 2) strains of mice indicated that the B6 background was permissive to the iris disease. Iris phenotypes of the single-congenic strains closely resembled our previous observations of mice mutant for only Gpnmb or Tyrp1 in varying genetic contexts [22, 23, 36]. Furthermore, the timing and severity of pigment dispersing iris disease in the double-congenic B6.Tyrp1 b Gpnmb R150Xmice is essentially the same as in D2 mice mutant for the same Tyrp1 and Gpnmb alleles .
Pigmentary pathway contributes to Tyrp1 and Gpnmbmediated iris disease
We next took advantage of the B6 background to perform strain controlled genetic epistasis experiments that tested mechanisms contributing to the Tyrp1 and Gpnmb mediated iris disease. A significant result in understanding the Tyrp1 and Gpnmb mediated iris disease is that modulating pigment production with tyrosinase (Tyr, a gene essential for pigment production) and hypopigmentation mutations completely rescues iris atrophy and pigment dispersion [22, 23]. These experiments strongly implicated melanosomal functions of Tyrp1 and Gpnmb in pathogenesis. However, they were not absolutely complete, since only the effect of hypopigmentation mutations and not Tyr were assessed for Gpnmb. This is important because hypopigmentation mutations often affect multiple types of organelles [37, 38] whereas Tyr has no known function in any organelles other than melanosomes.
To assess the importance of pigmentary pathways on the B6 background, we used the Tyr c-2Jmutation that arose spontaneously in the B6 strain [39, 40]. We generated multiple cohorts of homozygous, Tyr c-2Jalbino mice that were also homozygous for both Tyrp1 band Gpnmb R150X(Figure 3), or also homozygous for only Tyrp1 bor Gpnmb R150X(data not shown). Aged cohorts of these albino mice were compared with normally pigmented mice of matched genotypes. All mice homozygous for the Tyr c-2Jmutation had albino coats (Figure 3A) and albino irides (Figure 3B–G). Importantly, the Tyr c-2Jmutation rescued all observable Tyrp1 b– and Gpnmb R150X-associated iris phenotypes in double-congenic B6.Tyrp1 b Gpnmb R150Xmice (Figure 3C, E, and 3G) and single-congenic B6.Tyrp1 b(n = 28 eyes, 12+ months) and B6.Gpnmb R150Xmice (n = 8 eyes, 12+ months). These results convincingly indicate that melanin production is a necessary component of the pathological events initiating iris disease on a B6 background, and they confirm a melanosomal component for both the Tyrp1 and Gpnmb mutant phenotypes.
B6. Tyrp1 band Gpnmb R150Xmice are less susceptible to IOP elevation than D2 mice
Having established that B6.Tyrp1 b Gpnmb R150Xmice exhibit a pigment-dispersing iris disease that is clinically, and mechanistically, similar to that in D2 mice, we next tested whether the B6 genetic background would influence the impact of this insult on IOP. Although the timing and severity of iris disease was similar, IOP elevation was significantly muted in B6.Tyrp1 b Gpnmb R150Xmice compared with D2 mice (Figure 4). We compared the IOP distributions of these strains in relation to IOP values of 19 mmHg and 21 mmHg. As a strain, young D2 mice have lower IOP than young B6 mice and 19 mmHg is > 2 SD above the mean of young pre-glaucomatous D2 mice. The value of 21 mmHg is glaucoma relevant, as individuals with an IOP of 21 mmHg are commonly regarded as glaucoma suspect . Strikingly, a far smaller proportion of B6.Tyrp1 b Gpnmb R150Xmice were detected with IOP > 21 mmHg compared with D2 mice (Figure 4A to 4D). For example, at 7–8 months only 2 % of B6.Tyrp1 b Gpnmb R150Xmice had IOP > 21 mmHg, compared with 16 % of D2 mice (P = 0.007,χ2 comparing number of mice with IOP < 19 mmHg, 19–21 mmHg, and > 21 mmHg for each strain at this age). Similarly, at 9–10 months, only 11% of B6.Tyrp1 b Gpnmb R150Xhad IOPs >21 mmHg, compared with 42 % of D2 (P < 0.0001, similar χ2 comparison for 9 to 10-months mice). The same trend was observed considering all mice, irrespective of age (P < 0.0001, χ2). Further demonstrating their lower susceptibility to developing high IOP, pressure elevation was delayed in B6.Tyrp1 b Gpnmb R150Xmice compared with D2 mice (Figure 4E and 4F). Whereas the greatest proportion of D2 mice had IOP > 21 mmHg (42%) at 9–10 months, the greatest proportion of B6.Tyrp1 b Gpnmb R150Xmice (16%) had IOP > 21 4 months later at 13–14 months of age (P < 0.0001, χ2 comparing B6.Tyrp1 b Gpnmb R150Xat 13–14 months with D2 at 9–10 months). Therefore, as a population, B6.Tyrp1 b Gpnmb R150Xmice are less susceptible to IOP elevation than D2 mice.
B6. Tyrp1 band Gpnmb R150Xmice do not develop glaucomatous nerve damage
The relatively low susceptibility of B6.Tyrp1 b Gpnmb R150Xmice to IOP elevation suggested that this strain may experience less glaucomatous nerve damage than D2 mice. In D2 mice, severe glaucomatous damage with substantial axon loss is detectable in over 50% of 11-month-old, 70% of 13-month-old and 80% of 19-month-old mice [42, 43]. In contrast, severe damage was almost never detected in B6.Tyrp1 b Gpnmb R150Xmice (Figure 5). At ages when 50–80% of D2 mice have severe damage, only one of 109 B6.Tyrp1 b Gpnmb R150Xnerves was severely affected (56 of these nerves were from mice >18 months old). The distributions of nerve-damage level were almost identical in B6.Tyrp1 b Gpnmb R150Xand wild-type B6 mice (Figure 5), indicating that the degree of damage in B6.Tyrp1 b Gpnmb R150Xmice represents standard aging changes for this strain background. To maximize the likelihood of detecting glaucoma, optic nerves from the mice with the highest IOPs were examined (Figure 5C and 5D), but none had a level of damage similar to the glaucomatous damage of D2 mice. Additionally, no significant difference in the number of healthy axons was detected between normal B6 and B6.Tyrp1 isa Gpnmb R150Xmice aged either 4–5 or 22–27 months (Figure 5G). Combined, the analysis of optic nerves from these cohorts of B6.Tyrp1 isa Gpnmb R150Xmice convincingly shows that on the B6 genetic background, the Tyrp-1 and Gpnmb-mediated iris disease does not result in glaucoma.
On a D2 background, mutations in Tyrp1 and Gpnmb underlie a form of pigmentary glaucoma involving a pigment-dispersing iris disease, increased IOP, and optic-nerve disease [18, 19, 22, 23]. Here, we report transfer of the D2-derived Tyrp1 band Gpnmb R150Xmutations to the B6 genetic background to produce a B6 double-congenic strain that develops the iris disease. Surprisingly, the B6 double-congenic mice were less susceptible to IOP elevation than D2 mice and did not develop glaucomatous nerve damage. These strains provide a powerful resource for studying the functions of Tyrp1 and Gpnmb, dissecting the molecular mechanisms by which pigment dispersion leads to IOP elevation, and identifying additional genes contributing to the D2 form of glaucoma. Furthermore, congenic strains are broadly useful resources, and these strains will likely have additional benefit to the broader mouse-genetics community .
Melanosomal processes contribute to both Gpnmb and Tyrp1phenotypes
The current experiments demonstrate that melanosomal defects associated with melanin synthesis play a key role in the initiation of both Tyrp-1 and Gpnmb-mediated iris disease. Melanosomal synthesis of melanin involves a series of reactions creating the biopolymer melanin from the precursor tyrosine . Many of the indole-quinone intermediates of these reactions are cytotoxic, and the mechanisms regulating their cytotoxicity are only partially understood [46, 47]. Our results indicate that mutations in Tyrp1 and Gpnmb act in the melanosome, where they promote cytotoxicity in a manner that can be rescued by halting production of these toxic intermediates. Based on these findings, it will be important to examine other genes encoding melanosomal proteins that may participate in these events and that may also cause similar diseases of the iris.
Genetic background affects susceptibility to IOP elevation and subsequent glaucoma
The experiments described above demonstrate that the severity and timing of the pigment-dispersing iris disease of B6 double-congenic mice is essentially the same as that of D2 mice. This suggests that the dispersed pigment and iris debris similarly insult the ocular drainage structures of both strains. Nevertheless, the B6 double-congenic mice were much less susceptible to IOP elevation than D2 mice. Probably because of their resistance to IOP elevation, the B6 double-congenics were not found to develop glaucoma. In fact, the degree of optic-nerve damage observed was largely similar to age-matched wild-type B6, indicating that the small degree of optic neuropathy observed was likely an independent phenomenon, such as the result of the normal aging process or a low-penetrance developmental abnormality. Experiments to understand this strain difference in IOP elevation are underway.
These experiments also suggest that the cytotoxicity mediated by Tyrp1 and Gpnmb does not kill the RGCs, and that iris disease and RGC death can be dissociated from each other. Therefore, RGC death in D2 mice appears to be a pressure-dependent process resembling the pathology of human glaucoma. In support of this, RGC death in this model is not uniformly distributed [48, 49], as would be expected if damaged by an iris-derived diffusible toxin. Rather, it appears that RGCs are uniquely susceptible retinal neurons, and the pattern of damage is consistent with an insult to RGC axons in the optic nerve [17, 49].
Genetics and human PDS
The broader implications of the strain-specific phenotypes may be important for studies of the heredity and mechanism of human pigmentary glaucoma. In humans, PDS/PG exhibits strong hereditary associations [50–52]. A few families with clear inheritance of PDS are reported. However, the low incidence of PDS in family members of the majority of affected individuals suggests a more complex etiology, possibly influenced by multiple genetic and environmental factors. In some families, linkage was initially reported between the disease phenotype and markers on 7q35-q36 . However, causative mutations at this locus have thus far not been found. Analysis of candidate genes suggested by experiments with D2 mice (such as TYRP1 and GPNMB) have also failed to identify any clear mutations in these families . Thus, the disease in these families may be more complex than initially suspected. The lack of identified mutations in GPNMB and TYRP1 in these families does not preclude the involvement of these genes (or genes of similar function) in patients of other families or in the more common, more complex cases. It remains to be determined whether PDS/PG in other patient populations is caused by more tractable loci, or whether the identification of genes associated with human PDS/PG may simply necessitate approaches that can overcome genetic complexity.
Genetic context and human glaucoma
From a mechanistic view, the dichotomy between the differing responses of the B6 double-congenics versus D2 mice is analogous to the differing responses of people with PDS. Many human eyes tolerate significant amounts of dispersed pigment without developing glaucoma [6, 7]. Indeed, fewer than half of human eyes with pigment dispersion progress to pigmentary glaucoma [8–12]. This, along with the expected minor degree of aqueous humor outflow obstruction due to pigment itself [54, 55], suggests that individual differences in the ocular reaction to dispersed pigment are important in determining whether pigment dispersion progresses to pigmentary glaucoma. The D2 and B6 congenic strains provide a tractable resource for mechanistically deciphering the ocular reactions that determine whether IOP becomes harmfully elevated after the drainage structures are insulted by dispersed pigment and iris debris. Future studies of these reactions will not only improve our mechanistic understanding of the disease, but may also suggest new classes of genes worthy of analysis among human PDS/PG patients.
Experimental implications of strain specific effects
Our results highlight the profound importance of genetic background to complex diseases such as glaucoma. In addition to understanding human glaucoma, it is important to consider effects of genetic background when using animal models. As a genetic resource, these congenic mouse strains will help to address this issue. Until now, a strain-matched control for Tyrp1 – and Gpnmb-mediated disease has been problematic. For instance, although any standard inbred mouse strain that does not develop glaucoma can be utilized as a control for D2 mice, this experimental design does not distinguish whether any observed differences relate to the disease state of the eye, or are merely previously unappreciated strain-dependent background effects. Given the complexity of these glaucoma phenotypes, experiments comparing between different strain backgrounds or using segregating backgrounds can be misleading [13, 56]. Importantly, the congenic mice generated here can be utilized with strain-matched normal B6 mice to perform appropriately controlled experiments.
Pressure-independent RGC death in C57BL/6 mice
Pressure-independent RGC death has been reported in C57BL/6 mice and may depend on environment or substrain used. In wild-type C57BL/6 mice from the supplier Harlan (C57BL/6Hsd), an age-related reduction in the number of RGCs has been described . By 18 months, the number of RGCs was reduced to approximately 46% that of young mice. In our current study, this age-related decline was absent in both the double-congenic B6.Tyrp1 b Gpnmb R150Xmice and normal B6 controls that all had a C57BL/6J background. Similarly, we did not detect glaucomatous RGC loss in another experiment where C57BL/6J mice were also aged to 19+ months . This difference in RGC death between studies may be explained by potential environmental influences, differences in analysis protocols, or genetic differences in the substrain utilized.
This work introduces B6 congenic strains that allow highly controlled experiments when studying glaucoma resulting from the Tyrp1 band Gpnmb R150Xalleles. Using this resource, we uncovered a striking strain dependence of developing high IOP and glaucoma when challenged by a profound pigment-dispersing iris disease. In future experiments, it will be particularly important to identify the pathways and genes influencing IOP elevation in this setting.
Mice were obtained from The Jackson Laboratory (Bar Harbor, ME, USA). All animals were treated according to the guidelines of the Association for Research in Vision and Ophthalmology for use of animals in research. All experimental protocols were approved by the Animal Care and Use Committee of The Jackson Laboratory. Data for the congenic B6 strains are compared with those with a D2 background. Many of the data for the D2 mice (more than 1500 mice) have been previously reported but some new IOP data are included here. The congenic B6 mice were bred, aged and analyzed at the same time as over 300 D2 mice. The D2 mice were maintained on an NIH 31 diet with a fat content of 6%. To avoid obesity, mice with a B6 background had to be maintained on essentially the same NIH 31 diet but with a 4% fat content. Our studies have shown that D2 IOP and other glaucoma phenotypes do not differ with this small dietary difference (unpublished data). For all mice, the diet was provided ad libitum, and the water was acidified to pH 2.8–3.2. Mice were housed in cages containing white-pine bedding and covered with polyester filters. The environment was kept at 21°C with a 14-hour light:10-hour dark cycle.
Generation of congenic strains and genotype analysis of congenic intervals
Chromosomal intervals of approximately 6–7 cM were selected for the regions flanking Tyrp1 (D4Mit178 to D4Mit327) and Gpnmb (D6Mit74 to D6Mit355). Mice were reiteratively bred to B6 mice and each successive generation genotyped to select breeders heterozygous for the respective D2 regions. This process was continued for 10 generations of backcrossing. At the 10th generation, mice were intercrossed and each region bred to homozygosity. Within the respective congenic intervals, the presence of the Tyrp1 ballele was confirmed by assaying for a D2-derived polymorphism creating a TaqI restriction-enzyme site in exon 4 , and the presence of the Gpnmb R150Xmutation was confirmed by assaying for a PvuII restriction-enzyme site created by the D2-derived mutation . The sizes of the congenic intervals were determined using genomic DNA prepared from homozygous mice at the 10th generation of backcrossing and assayed using polymorphic microsatellite markers with standard PCR conditions.
Intraocular pressure measurement
IOP was measured using the microneedle method as previously described in detail [58, 59]. All cohorts included male and female mice. Each mouse used in this study had only a single IOP measurement. Thus, each age group shown consists of cohorts of different individual mice. Because the IOPs of B6 mice are very consistent, B6 mice were interspersed with experimental mice during all experiments as a methodological control to ensure proper equipment calibration and performance. Statistical comparisons of IOP profiles generated from these strains utilize nonparametric data comparisons, with data grouped according to empirically set points relevant to these studies: 19 mmHg (i.e. > 2 SD above the mean for young pre-glaucomatous D2 mice) and 21 mmHg (a value commonly regarded as glaucoma suspect in humans) .
Clinical and histologic analysis
Eyes were examined with a slit-lamp biomicroscope and photographed with a 40× objective lens. Phenotypic assessment of iris disease was determined by indices of iris atrophy and dispersed pigment following previously described criteria [18, 22, 23, 60]. Transillumination defects were also measured (transillumination is an assay of iris disease whereby reflected light passing through depigmented areas of iris tissue are visualized as red light). However, because transillumination is influenced by multiple strain-specific traits not controlled in these studies (such as iris thickness), it was not the primary means of following disease progression across different genetic backgrounds.
Optic nerve cross sections were examined for glaucomatous damage using a modified para-phenylenediamine (PPD) staining protocol to stain the myelin sheath of all axons and the axoplasma of damaged axons . Optic nerves were prepared for analysis by overnight fixation in phosphate-buffered glutaraldehyde/paraformaldehyde mixture at 4°C followed by overnight treatment in osmium tetroxide at 4°C. After osmification, nerves were rinsed twice for 10 minutes in 0.1 M phosphate buffer, once in 0.1 M sodium-acetate buffer, and dehydrated in graded ethanol concentrations. After embedding this tissue in resin, 1-μm-thick sections were stained in 1% PPD for 35–40 minutes.
Stained sections were compared using a previously described qualitative grading scale (including assessments of the approximate number of healthy axons, number of damaged axons, and scarring associated with gliosis) and used to perform quantitative axon counts [42, 43]. The grading scale has previously been validated by comparisons to axon counts [42, 43]. Quantitative axon counts imaged 18 non-overlapping fields at 1000× magnification, which were evenly spread throughout the cross-section of the nerve; the sum area of these fields was equal to 10% of the total nerve cross-sectional area. The majority of optic nerves were collected from mice within 48 hours of IOP measurement. Some mice with elevated IOPs were additionally age determined prior to assessment of the optic nerve. Each age group investigated contained samples from males and females, as well as left and right nerves.
Genetic nomenclature and stocks
The official gene abbreviations, full gene names, alleles, and stocks utilized in this study include the following. The full name for the Gpnmb gene is glycoprotein (transmembrane) nmb. The ipd allele of Gpnmb results from the R150X premature stop codon mutation, Gpnmb R150X. The full name for the Tyrp1 gene is tyrosinase-related protein 1. The b allele of Tyrp1 encodes two amino-acid substitutions, compared with the C57BL/6J-derived allele . This D2 allele is also referred to as isa in the mouse genome database and elsewhere [22, 23]. The DBA/2J stock utilized here was stock number 000671 from The Jackson Laboratory. The full name for the Tyr gene is tyrosinase. The c-2J mutation spontaneously arose within a C57BL/6J colony, resulting in a R77L amino acid substitution and also changing alternative splicing of the tyrosinase pre-mRNA [39, 40]. The Tyr c-2Jstock utilized here was C57BL/6J-Tyr c-2J/J (stock 000058 from The Jackson Laboratory).
Allingham RR, Damji KF, Freedman S, Moroi SE, Shafranov G, Shields MB: Shields' Textbook of Glaucoma. 2004, Philadelphia: Lippincott Williams and Wilkins;, 5
Nickells RW, Jampel HD, Zack DJ: Glaucoma. Emery & Rimoins Principles and Practices of Medical Genetics. Edited by: Rimoin DL, Conner MJ, Pyeritz RE, Korf BR. 2002, Churchill Livingstone, 3: 3491-3512. 4
Ritch R, Shields MB, Krupin T: The Glaucomas. 1996, St Louis Mosby
Palmberg PF, Wiggs JL: Mechanisms of glaucoma. Ophthalmology. Edited by: Yanoff M, Duker JS. 2004, St Louis: Mosby, 2
Weinreb RN, Khaw PT: Primary open-angle glaucoma. Lancet. 2004, 363 (9422): 1711-1720. 10.1016/S0140-6736(04)16257-0.
Ball SF: Pigmentary Glaucoma. Ophthalmology. Edited by: Yanoff M, Duker JS. 2004, St Louis: Mosby, 1504-1507. Second
Ritch R: A unification hypothesis of pigment dispersion syndrome. Trans Am Ophthalmol Soc. 1996, 94: 381-405. discussion 405–389
Farrar SM, Shields MB, Miller KN, Stoup CM: Risk factors for the development and severity of glaucoma in the pigment dispersion syndrome. Am J Ophthalmol. 1989, 108 (3): 223-229.
Migliazzo CV, Shaffer RN, Nykin R, Magee S: Long-term analysis of pigmentary dispersion syndrome and pigmentary glaucoma. Ophthalmology. 1986, 93 (12): 1528-1536.
Richter CU, Richardson TM, Grant WM: Pigmentary dispersion syndrome and pigmentary glaucoma. A prospective study of the natural history. Arch Ophthalmol. 1986, 104 (2): 211-215.
Scheie HG, Cameron JD: Pigment dispersion syndrome: aclinical study. Br J Ophthalmol. 1981, 65 (4): 264-269.
Siddiqui Y, Ten Hulzen RD, Cameron JD, Hodge DO, Johnson DH: What is the risk of developing pigmentary glaucoma from pigment dispersion syndrome?. Am J Ophthalmol. 2003, 135 (6): 794-799. 10.1016/S0002-9394(02)02289-4.
John SW, Anderson MG, Smith RS: Mouse genetics: a tool to help unlock the mechanisms of glaucoma. J Glaucoma. 1999, 8 (6): 400-412.
Libby RT, Gould DB, Anderson MG, John SW: Complex genetics of glaucoma susceptibility. Annu Rev Genomics Hum Genet. 2005, 6: 15-44. 10.1146/annurev.genom.6.080604.162209.
Lindsey JD, Weinreb RN: Elevated intraocular pressure and transgenic applications in the mouse. J Glaucoma. 2005, 14 (4): 318-320. 10.1097/01.ijg.0000169411.09258.f6.
Weinreb RN, Lindsey JD: The importance of models in glaucoma research. J Glaucoma. 2005, 14 (4): 302-304. 10.1097/01.ijg.0000169395.47921.02.
Bayer AU, Neuhardt T, May AC, Martus P, Maag KP, Brodie S, Lutjen-Drecoll E, Podos SM, Mittag T: Retinal morphology and ERG response in the DBA/2NNia mouse model of angle-closure glaucoma. Invest Ophthalmol Vis Sci. 2001, 42 (6): 1258-1265.
John SW, Smith RS, Savinova OV, Hawes NL, Chang B, Turnbull D, Davisson M, Roderick TH, Heckenlively JR: Essential iris atrophy, pigment dispersion, and glaucoma in DBA/2J mice. Invest Ophthalmol Vis Sci. 1998, 39 (6): 951-962.
Libby RT, Anderson MG, Pang I-H, Robinson ZH, Savinova O, Cosma IM, Snow A, Wilson LA, Smith RS, Clark AF, et al: Inherited glaucoma in DBA/2J mice: Pertinent disease features for studying the neurodegeneration. Visual Neuroscience. 2005, 22: 1-12. 10.1017/S0952523805221016.
Sheldon WG, Warbritton AR, Bucci TJ, Turturro A: Glaucoma in food-restricted and ad libitum-fed DBA/2NNia mice. Lab Anim Sci. 1995, 45 (5): 508-518.
Zhou X, Li F, Kong L, Tomita H, Li C, Cao W: Involvement of inflammation, degradation, and apoptosis in a mouse model of glaucoma. J Biol Chem. 2005, 280 (35): 31240-31248. 10.1074/jbc.M502641200.
Chang B, Smith RS, Hawes NL, Anderson MG, Zabaleta A, Savinova O, Roderick TH, Heckenlively JR, Davisson MT, John SW: Interacting loci cause severe iris atrophy and glaucoma in DBA/2J mice. Nat Genet. 1999, 21 (4): 405-409. 10.1038/7741.
Anderson MG, Smith RS, Hawes NL, Zabaleta A, Chang B, Wiggs JL, John SW: Mutations in genes encoding melanosomal proteins cause pigmentary glaucoma in DBA/2J mice. Nat Genet. 2002, 30 (1): 81-85. 10.1038/ng794.
Kobayashi T, Imokawa G, Bennett DC, Hearing VJ: Tyrosinase stabilization by Tyrp1 (the brown locus protein). J Biol Chem. 1998, 273 (48): 31801-31805. 10.1074/jbc.273.48.31801.
Kobayashi T, Urabe K, Winder A, Jimenez-Cervantes C, Imokawa G, Brewington T, Solano F, Garcia-Borron JC, Hearing VJ: Tyrosinase related protein 1 (TRP1) functions as a DHICA oxidase in melanin biosynthesis. Embo J. 1994, 13 (24): 5818-5825.
Kobayashi T, Urabe K, Winder A, Tsukamoto K, Brewington T, Imokawa G, Potterf B, Hearing VJ: DHICA oxidase activity of TRP1 and interactions with other melanogenic enzymes. Pigment Cell Res. 1994, 7 (4): 227-234.
Le Borgne R, Planque N, Martin P, Dewitte F, Saule S, Hoflack B: The AP-3-dependent targeting of the melanosomal glycoprotein QNR-71 requires a di-leucine-based sorting signal. J Cell Sci. 2001, 114 (Pt 15): 2831-2841.
Shikano S, Bonkobara M, Zukas PK, Ariizumi K: Molecular cloning of a dendritic cell-associated transmembrane protein, DC-HIL, that promotes RGD-dependent adhesion of endothelial cells through recognition of heparan sulfate proteoglycans. J Biol Chem. 2001, 276 (11): 8125-8134. 10.1074/jbc.M008539200.
Bachner D, Schroder D, Gross G: mRNA expression of the murine glycoprotein (transmembrane) nmb (Gpnmb) gene is linked to the developing retinal pigment epithelium and iris. Brain Res Gene Expr Patterns. 2002, 1 (3–4): 159-165. 10.1016/S1567-133X(02)00012-1.
Onaga M, Ido A, Hasuike S, Uto H, Moriuchi A, Nagata K, Hori T, Hayash K, Tsubouchi H: Osteoactivin expressed during cirrhosis development in rats fed a choline-deficient, L-amino acid-defined diet, accelerates motility of hepatoma cells. J Hepatol. 2003, 39 (5): 779-785. 10.1016/S0168-8278(03)00361-1.
Owen TA, Smock SL, Prakash S, Pinder L, Brees D, Krull D, Castleberry TA, Clancy YC, Marks SC, Safadi FF, et al: Identification and characterization of the genes encoding human and mouse osteoactivin. Crit Rev Eukaryot Gene Expr. 2003, 13 (2–4): 205-220.
Rich JN, Shi Q, Hjelmeland M, Cummings TJ, Kuan CT, Bigner DD, Counter CM, Wang XF: Bone-related genes expressed in advanced malignancies induce invasion and metastasis in a genetically defined human cancer model. J Biol Chem. 2003, 278 (18): 15951-15957. 10.1074/jbc.M211498200.
Safadi FF, Xu J, Smock SL, Rico MC, Owen TA, Popoff SN: Cloning and characterization of osteoactivin, a novel cDNA expressed in osteoblasts. J Cell Biochem. 2001, 84 (1): 12-26. 10.1002/jcb.1259.
Bennett DC, Lamoreux ML: The color loci of mice – a genetic century. Pigment Cell Res. 2003, 16 (4): 333-344. 10.1034/j.1600-0749.2003.00067.x.
Zdarsky E, Favor J, Jackson IJ: The molecular basis of brown, an old mouse mutation, and of an induced revertant to wild type. Genetics. 1990, 126 (2): 443-449.
Anderson MG, Smith RS, Savinova OV, Hawes NL, Chang B, Zabaleta A, Wilpan R, Heckenlively JR, Davisson M, John SW: Genetic modification of glaucoma associated phenotypes between AKXD-28/Ty and DBA/2J mice. BMC Genet. 2001, 2 (1): 1-10.1186/1471-2156-2-1.
Feng L, Novak EK, Hartnell LM, Bonifacino JS, Collinson LM, Swank RT: The Hermansky-Pudlak syndrome 1 (HPS1) and HPS2 genes independently contribute to the production and function of platelet dense granules, melanosomes, and lysosomes. Blood. 2002, 99 (5): 1651-1658.
Li W, Zhang Q, Oiso N, Novak EK, Gautam R, O'Brien EP, Tinsley CL, Blake DJ, Spritz RA, Copeland NG, et al: Hermansky-Pudlak syndrome type 7 (HPS-7) results from mutant dysbindin, a member of the biogenesis of lysosome-related organelles complex 1 (BLOC-1). Nat Genet. 2003, 35 (1): 84-89. 10.1038/ng1229.
Le Fur N, Kelsall SR, Mintz B: Base substitution at different alternative splice donor sites of the tyrosinase gene in murine albinism. Genomics. 1996, 37 (2): 245-248. 10.1006/geno.1996.0551.
Green E: Albino-2J (c < 2J >). Mouse News Lett. 1973, 49: 31-
Kaiser PK, Friedman NJ, Pineda R: The Massachusetts Eye and Ear Infirmary Illustrated Manual of Ophthalmology. 2004, Philadelphia: Saunders, 2
Anderson MG, Libby RT, Gould DB, Smith RS, John SW: High-dose radiation with bone marrow transfer prevents neurodegeneration in an inherited glaucoma. Proc Natl Acad Sci U S A. 2005, 102 (12): 4566-4571. 10.1073/pnas.0407357102.
Libby RT, Li Y, Savinova OV, Barter J, Smith RS, Nickells RW, John SW: Susceptibility to neurodegeneration in a glaucoma is modified by Bax gene dosage. PLoS Genet. 2005, 1 (1): 17-26. 10.1371/journal.pgen.0010004.
Lamoreux ML: The inbred mouse in pigmentation research: significance of a congenic developmental system. Pigment Cell Res. 2000, 13 (6): 421-430. 10.1034/j.1600-0749.2000.130603.x.
Hearing VJ: Biogenesis of pigment granules: a sensitive way to regulate melanocyte function. J Dermatol Sci. 2005, 37 (1): 3-14. 10.1016/j.jdermsci.2004.08.014.
Pawelek JM, Lerner AB: 5,6-Dihydroxyindole is a melanin precursor showing potent cytotoxicity. Nature. 1978, 276 (5688): 626-628. 10.1038/276627a0.
Smit NPM, Pavel S, Riley PA: Mechanisms of control of the cytotoxicity of orthoquinone intermediates of melanogenesis. Role of catechol quinone species in cellular toxicity. Edited by: Creveling CR. 2000, Johnson City, TN: F.P. Graham Publishing, 191-245.
Danias J, Lee KC, Zamora MF, Chen B, Shen F, Filippopoulos T, Su Y, Goldblum D, Podos SM, Mittag T: Quantitative analysis of retinal ganglion cell (RGC) loss in aging DBA/2NNia glaucomatous mice: comparison with RGC loss in aging C57/BL6 mice. Invest Ophthalmol Vis Sci. 2003, 44 (12): 5151-5162. 10.1167/iovs.02-1101.
Jakobs TC, Libby RT, Ben Y, John SW, Masland RH: Retinal ganglion cell degeneration is topological but not cell type specific in DBA/2J mice. J Cell Biol. 2005, 171 (2): 313-325. 10.1083/jcb.200506099.
Andersen JS, Pralea AM, DelBono EA, Haines JL, Gorin MB, Schuman JS, Mattox CG, Wiggs JL: A gene responsible for the pigment dispersion syndrome maps to chromosome 7q35-q36. Arch Ophthalmol. 2005, 115 (3): 384-388.
Bovell AM, Damji KF, Dohadwala AA, Hodge WG, Allingham RR: Familial occurrence of pigment dispersion syndrome. Can J Ophthalmol. 2001, 36 (1): 11-17.
Mandelkorn RM, Hoffman ME, Olander KW, Zimmerman T, Harsha D: Inheritance and the pigmentary dispersion syndrome. Ann Ophthalmol. 1983, 15 (6): 577-582.
Lynch S, Yanagi G, DelBono E, Wiggs JL: DNA sequence variants in the tyrosinase-related protein 1 (TYRP1) gene are not associated with human pigmentary glaucoma. Mol Vis. 2002, 8: 127-129.
Alvarado JA, Murphy CG: Outflow obstruction in pigmentary and primary open angle glaucoma. Arch Ophthalmol. 1992, 110 (12): 1769-1778.
Murphy CG, Johnson M, Alvarado JA: Juxtacanalicular tissue in pigmentary and primary open angle glaucoma. The hydrodynamic role of pigment and other constituents. Arch Ophthalmol. 1992, 110 (12): 1779-1785.
Smithies O, Maeda N: Gene targeting approaches to complex genetic diseases: atherosclerosis and essential hypertension. Proc Natl Acad Sci U S A. 1995, 92 (12): 5266-5272. 10.1073/pnas.92.12.5266.
Gould DB, Miceli-Libby L, Savinova OV, Torrado M, Tomarev SI, Smith RS, John SW: Genetically increasing Myoc expression supports a necessary pathologic role of abnormal proteins in glaucoma. Mol Cell Biol. 2004, 24 (20): 9019-9025. 10.1128/MCB.24.20.9019-9025.2004.
John SW, Savinova OV: Intraocular pressure measurement in mice: technical aspects. Systemic Evaluation of the Mouse Eye. Edited by: Smith RS. 2002, Boca Raton: CRC Press
Savinova OV, Sugiyama F, Martin JE, Tomarev SI, Paigen BJ, Smith RS, John SW: Intraocular pressure in genetically distinct mice: an update and strain survey. BMC Genet. 2001, 2 (1): 12-10.1186/1471-2156-2-12.
Mo JS, Anderson MG, Gregory M, Smith RS, Savinova OV, Serreze DV, Ksander BR, Streilein JW, John SW: By altering ocular immune privilege, bone marrow-derived cells pathogenically contribute to DBA/2J pigmentary glaucoma. J Exp Med. 2003, 197 (10): 1335-1344. 10.1084/jem.20022041.
Smith RS, Zabaleta A, John SW, Bechtold LS, Ikeda S, Relyea MJ, Sundberg JP, Kao WW-Y, Liu C-Y: General and Special Histopathology. Systemic Evaluation of the Mouse Eye. Edited by: Smith RS. 2002, Boca Raton: CRC Press, 265-297.
We thank O. Savinova and A. Snow for technical support in collection of IOP data and colony maintenance; J. Torrance and F. Farley for help preparing the figures and administrative assistance; and P. Finger and B. Mortimer of The Jackson Laboratory Scientific Services for technical support of histology. This work was supported in part by National Cancer Institute Grant CA34196 (to The Jackson Laboratory), and the National Eye Institute Grants F32EY07015 (MGA), F32EY014515 (RTL), EY01475 (RSS), and EY11721 (SWMJ). SWMJ is an Investigator of the Howard Hughes Medical Institute.
MGA carried out genetic crosses to generate the congenic and albino congenic strains, and performed the slit-lamp analysis of ocular phenotypes. MGA and SWMJ contributed to the conception, design, and coordination of all study components, analyzed the data, and wrote the manuscript. RTL analyzed IOP and optic nerve data and contributed to the design and presentation of the study. IMC measured IOP and participated in mouse breeding and genotyping. RSS, MM, and SWMJ participated in examining optic nerves. LAW managed the mouse colonies and coordinated experiments.
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Anderson, M.G., Libby, R.T., Mao, M. et al. Genetic context determines susceptibility to intraocular pressure elevation in a mouse pigmentary glaucoma . BMC Biol 4, 20 (2006). https://0-doi-org.brum.beds.ac.uk/10.1186/1741-7007-4-20
- Congenic Strain
- Congenic Mouse
- Pigment Dispersion
- Retinal Ganglion Cell Death