HOME HELP FEEDBACK SUBSCRIPTIONS ARCHIVE SEARCH TABLE OF CONTENTS		QUICK SEARCH:   [advanced] Author: Keyword(s): Year:  Vol:  Page:

This Article Abstract Full Text (PDF) Submit a response Alert me when this article is cited Alert me when eLetters are posted Alert me if a correction is posted Citation Map Services Email this article to a friend Similar articles in this journal Similar articles in PubMed Alert me to new issues of the journal Download to citation manager Citing Articles Citing Articles via HighWire Citing Articles via Google Scholar Google Scholar Articles by Panicker, S. G. Articles by Balasubramanian, D. Search for Related Content PubMed PubMed Citation Articles by Panicker, S. G. Articles by Balasubramanian, D.

Identification of Novel Mutations Causing Familial Primary Congenital Glaucoma in Indian Pedigrees

¹ From the Hyderabad Eye Research Foundation, L. V. Prasad Eye Institute, Hyderabad, India; and the ² Centre for DNA Fingerprinting and Diagnostics, Hyderabad, India.

	Abstract

Top Abstract Introduction Methods Results Discussion References

 
PURPOSE. To determine the possible molecular genetic defect underlying primary congenital glaucoma (PCG) in India and to identify the pathogenic mutations causing this childhood blindness.

METHODS. Twenty-two members of five clinically well-characterized consanguineous families were studied. The primary candidate gene CYP1B1 was amplified from genomic DNA, sequenced, and analyzed in control subjects and patients to identify the disease-causing mutations.

RESULTS. Five distinct mutations were identified in the coding region of CYP1B1 in eight patients of five PCG-affected families, of which three mutations are novel. These include a novel homozygous frameshift, compound heterozygous missense, and other known mutations. One family showed pseudodominance, whereas others were autosomal recessive with full penetrance. In contrast to all known CYP1B1 mutations, the newly identified frameshift is of special significance, because all functional motifs are missing. This, therefore, represents a rare example of a natural functional CYP1B1 knockout, resulting in a null allele (both patients are blind).

CONCLUSIONS. The molecular mechanism leading to the development of PCG is unknown. Because CYP1B1 knockout mice did not show a glaucoma phenotype, the functional knockout identified in this study has important implications in elucidating the pathogenesis of PCG. Further understanding of how this molecular defect leads to PCG could influence the development of specific therapies. This is the first study to describe the molecular basis of PCG from the Indian subcontinent and has profound and multiple clinical implications in diagnosis, genetic counseling, genotype-phenotype correlations and prognosis. Hence, it is a step forward in preventing this devastating childhood blindness.

	Introduction

Top Abstract Introduction Methods Results Discussion References

 
The glaucomas, a heterogeneous group of optic neuropathies, if untreated, lead to optic nerve atrophy and permanent loss of vision. Glaucoma accounts for 15% of blindness worldwide.¹ One severe form of glaucoma, which occurs at birth or in early infancy (up to 3 years of age), is primary congenital glaucoma (PCG), which is mainly inherited as an autosomal recessive disorder. In contrast to a prevalence of 1:10,000 in the West,² prevalence is as high as 1:1250 among the Romany population of Slovakia,³ and 1:2500 in the Middle East,⁴ where inbreeding occurs, suggesting a genetic etiology. In the Indian state of Andhra Pradesh, the prevalence is 1:3300, and the disease accounts for 4.2% of all childhood blindness.^{5 6} However, the genetic defect of this disorder was unknown, and this prompted us to undertake the investigation.

Genetic linkage studies by Sarfarazi et al.⁷ and Akarsu et al.⁸ mapped PCG to two different loci, GLC3A (at 2p21)⁷ and GLC3B (at 1p36),⁸ in which mutations within the CYP1B1 gene (encoding the cytochrome P450 enzyme at GLC3A) were associated with the disease.⁹ Several CYP1B1 mutations in various ethnic backgrounds have been implicated in the pathogenesis.^{10 11 12 13 14 15 16 17 18 19 20} To determine the possible genetic defect underlying PCG in India, molecular analyses of five families were undertaken, and the CYP1B1 coding region was screened for mutations. Herein, we describe the pathogenic mutations (some of which are novel), including a natural CYP1B1 functional knockout, their genotype–phenotype correlations, structure–function relationship, and the simple diagnostic methods developed for identifying these mutations.

	Methods

Top Abstract Introduction Methods Results Discussion References

 
Clinical Evaluation and Patient Selection
The study protocol adhered to the tenets of the Declaration of Helsinki. After providing informed consent, five consanguineous PCG families were recruited for the study. These families were selected because all family members were available for the investigation. Patients and family members were evaluated by a glaucoma specialist (AKM) and were followed up for 10 years. The clinical data of the patients are described in Table 1 . Ophthalmic examinations included slit lamp biomicroscopy, gonioscopy, measurement of intraocular pressure (IOP), and perimetry in some cases. Clinical manifestations included elevated IOP, enlargement of the globe, edema, opacification of the cornea with rupture of the Descemet’s membrane, thinning of anterior sclera and atrophy of the iris, anomalously deep anterior chamber, photophobia, blepharospasm, and excessive tearing.

	Results

Top Abstract Introduction Methods Results Discussion References

 
Identification of Pathogenic Mutations
Novel Frameshift Mutation and Functional Null Allele.
In family PCG4 (an uncle-to-niece marriage) two patients showed a homozygous insertion (Figs. 1A 1B ; Table 2 ) of a nucleotide A at cDNA position 376 (376insA). This novel mutation, not previously reported,^{10 11 12 13 14 15 16 17 18 19 20} resulted in a frameshift that truncated the open reading frame (ORF) by creating a premature stop codon (TGA), 636 bp downstream from this insertion. Consequently, a truncated 222-amino-acid (aa) protein missing 321 aa from the C terminus was generated (Fig. 1C) . This also abolished the restriction site Eco130I in exon II. Both the wild-type and the mutant proteins contained just 10 aa at the N terminus, which is similar in both, and the frameshift eliminated all CYP1B1 domains, resulting in a functional null allele. All unaffected members in family PCG4 were heterozygous for this mutation (Fig. 2A) .

View larger version (27K): [in this window] [in a new window]   Figure 1. Electropherogram of the sense strand of genomic DNA from the proband in family PCG4, showing a novel homozygous frameshift mutation. Note the homozygous insertion of a nucleotide A (376insA) in the mutant allele of the proband (B), which is absent in the control (A). The mutation, which is underlined and shown by an arrow, results in premature termination at aa 223. The comparison of normal versus all truncated protein known in exon II is also shown (C). () Sequences that are common between normal and wild-type protein; () mutant protein. The length of truncated protein and its references are shown on the right.

View larger version (74K): [in this window] [in a new window]   Figure 2. PCR-RFLP analyses of the cosegregation of different mutations with disease phenotypes. Filled squares and circles: Affected individuals; arrow: probands; dot in open symbol: carriers; double line: consanguinity. DNA molecular weight marker (lane M) in base pairs (left); allele sizes (right); control (lane C); mutant allele(s) (arrowheads). Restriction site changes and mutations (nucleotide as well as amino acid changes) are shown at the bottom of each panel. () Sample for analysis unavailable. (A) Wild-type allele amplification and restriction digestion of amplicon from control DNA generated 384- and 158-bp fragments (lane C). Mutation abolishes the Eco130I site. In heterozygous individuals (carriers) in addition to the wild-type allele, a mutant allele of 542 bp was present. In the disease phenotype (homozygous) only a mutant allele of 542 bp was evident. (B) CT substitution in PCG1 results in a gain of an Eco811 site, which is evident from the cleavage of the 648-bp fragment (lane C) into 523-bp and 125-bp fragments. In carriers, in addition to the wild-type allele a mutant allele of 648 bp was present. (C) Restriction digestion of the wild-type allele in the control generated 359- and 229-bp (lane C) fragments and abolished the Eam1104I site. In carriers, in addition to the wild-type allele 588, mutant alleles of 359 and 229 bp were present. (D) Restriction digestion of the wild-type allele in the control showing undigested fragment of 627 bp (lane C). Mutation creates a TaqI site. In carriers, in addition to the wild type allele, mutant alleles of 318 and 309 bp were present. In the disease phenotype (homozygous) only mutant alleles of 318 and 309 bp were present. (E, F) Restriction digestion of wild type allele in the control generated 507- and 200-bp fragments (lane C). Mutation creates a TaaI site. In carriers, in addition to the wild-type allele, a mutant allele of 352 bp was present. In the disease phenotype (homozygous) only mutant alleles of 507 and 352 bp were present.

View larger version (44K): [in this window] [in a new window]   Figure 3. (A) Pedigree showing segregation of alleles in PCG1 family. () Grandmother’s DNA was not available for analysis. Heterozygous alleles are denoted by a slash separating wild type in uppercase letters and mutant residues in lowercase letters. (B) Electropherogram of the sense strand of various members of family PCG1. Residues are numbered based on cDNA sequence. Arrows: mutated bases.

View larger version (34K): [in this window] [in a new window]   Figure 4. Multiple sequence alignment of various members of the cytochrome P450 superfamily. Bold letters with asterisk and shading: conserved residues (when mutated) causing PCG phenotype. Polymorphic residues. Right: sequence accession numbers. The human CYP1B1 sequence is underlined.

Patients in families PCG2 and PCG6 showed the same homozygous mutation: GA substitution at 1449 bp. This resulted in a arginine-to-histidine change at aa 368 (R368H) in CYP1B1 and a loss of restriction site TaaI in exon III (Table 2) . In PCG11, substitution of a nucleotide GA at cDNA position 528 resulted in a glycine-to-glutamic acid replacement at aa 61 (G61E) of CYP1B1 and a gain of the restriction site TaqI in exon II (Table 2) .

Nonpathogenic CYP1B1 Single Nucleotide Polymorphisms
In addition to pathogenic mutations five other single nucleotide polymorphisms (SNPs; Table 3 ) were identified in the less conserved region of CYP1B1. Because PCG6 had two different homozygous missense mutations, the highly conserved residue (R368H, reported earlier)¹⁵ was considered to be a pathogenic mutation, whereas the less conserved one (G184S) was taken to be a novel polymorphism (Fig. 4) .

Our examination of the translated product of the frameshift mutation (376insA) revealed that the amino acid sequence of the new ORF does not show an appreciable match with any of the known protein sequences in the PDB. A secondary structure prediction of the sequence showed that the translated product is mostly made of coiled regions.

Genotype–Phenotype Correlations
Correlation between genotype and phenotype based on this study was evident from a comparison of the different mutations associated with varying manifestations and prognoses of the disease (Table 4) . The PCG phenotypes associated with various mutations showed varying severity and manifestations. In some cases, there was asymmetric manifestation between eyes of the patients (mother in family PCG1), whereas the same mutation (R368H) exhibited interfamily (families PCG2 and -6) as well as intrafamily (family PCG6) variability (Tables 1 4) .

	Discussion

Top Abstract Introduction Methods Results Discussion References

Pseudodominant inheritance was seen in one family, whereas all others showed autosomal recessive inheritance with full penetrance. All patients inherited two mutant alleles, whereas unaffected members were heterozygous (carriers) for a single mutant allele segregating in that particular family, except in the pseudodominant family (Fig. 2) .

Of all mutations identified herein, the frameshift mutation resulted in the most severe phenotype. Only the first 10 aa of the 543-aa CYP1B1 protein remain unchanged by the frameshift, whereas the remainder of the protein was replaced by an out-of-frame polypeptide of 222 aa. Despite maximum medical and prompt surgical treatments, both patients in family PCG4 exhibited a most devastating phenotype and were blind (Fig. 5) .

View larger version (126K): [in this window] [in a new window]   Figure 5. Photograph showing blind phenotype in the proband in family PCG4, who had a novel homozygous frameshift mutation (376insA).

The mother had glaucoma diagnosed at age 30 (Table 1) and had ocular features indicating that disease may have begun in one eye before age 3. However, because the second CYP1B1 mutation has not been identified in the mother (II.1), and this missing allele, as passed on to her 8-year-old daughter (III.2), has resulted in a normal phenotype (Fig. 3A) , this seems to be a complex situation, for which various plausible explanations can be considered: (1) The dramatic phenotypic variability observed between the two eyes of the affected mother is possibly the consequence of an as yet unknown mutation within the promoter region (perhaps a promoter deletion), and may indicate that CYP1B1 is a dosage-sensitive gene. (2) The mother may simply be a carrier of congenital glaucoma who happens also to have an early-onset form of glaucoma caused by mutation at another locus or glaucoma of a nongenetic origin. (3) It may be possible that heterozygosity for the 923CT mutation causes late-onset disease, although to our knowledge there are no reported instances of development of late-onset disease in carriers of the CYP1B1 mutation. (4) If the mother has a new mutation and is mosaic for the mutation, she could have one eye more affected than the other, because of unequal representation of the defect in the two eyes. It is possible that she has an unaffected child who inherited that chromosome, because of the absence of the mutation in the germ line. Although various roles for CYP1B1 in eye development have been proposed recently,²³ it is tempting to speculate that the likely role of CYP1B1 is in the detoxification or elimination of a toxic metabolite, which may be harmful to the normal development of the eye.

Previous studies have indicated that the G61E and R368H mutations are not fully penetrant in Saudi families,^{10 15} whereas in these Indian families, both are fully penetrant. R368H, reported earlier,¹⁵ maps to helix K, which is one of the highly conserved core structures (CCSs). This homozygous mutation seen in three patients of two unrelated families (PCG2 and PCG6) shows a very severe phenotype, in either one or both eyes. The CCSs are suspected to be involved in proper protein folding and in active heme binding.²³ Therefore, any homozygous impairment of this domain could lead to a severe phenotype. The other highly conserved G61E mutation¹² is adjacent to the N-terminal proline-rich region of CYP1B1 and is also likely to affect the proper protein function and result in disease manifestation. The proline-proline-glycine-proline motif may serve to join the membrane-binding N terminus to the globular region of the P450 protein.^{9 10 15 23}

Because the anterior chamber angle in humans has undergone some very recent evolutionary changes, this may be a problem in using animal models, especially the CYP1B1 knockout mice, for studying PCG’s pathogenesis.²³ Typical trabecular meshwork can be found only in humans and higher primates, whereas lower species have only a reticular meshwork.²⁴ Although it may be difficult to extrapolate the findings obtained from the CYP1B1 null mice, the phenotype obtained in such mice need not be the same as that of the functional CYP1B1 knockout identified in the present study. This view is in fact substantiated by a study, wherein it was demonstrated that CYP1B1 null mice did not show any obvious blindness or evidence of glaucoma, as assessed by standard behavioral comparisons with wild-type mice in their response to light and dark.²⁵ Furthermore, a frequent observation in various knockout studies is that the phenotypes do not transfer identically across species.

The information derived from this study has both basic and clinical relevance. Genetic counseling can be provided to at-risk families that will aid in the prevention of PCG-related blindness. The characterization of CYP1B1 and the spectrum of mutations with evidence of pathogenicity and high penetrance could have profound clinical implications in the management of PCG. This will facilitate prenatal diagnosis for this condition, which carries high life-long morbidity. Indeed, further screening of probands using the simple, fast, and inexpensive PCR-RFLP diagnostic methods developed in this study has enabled us to rapidly identify similar mutations in several other PCG-affected families (Reddy et al., manuscript in preparation). However, further analysis of more families with PCG is needed to determine the clinical correlation with the severity of the disease, if any.

	Acknowledgements

 
The authors thank the families for their participation in this study; the Clinical Biochemistry Services and the Jasti V. Ramanamma Children’s Eye Care Center staff at L. V. Prasad Eye Institute for their assistance in sample collection; Chitra Kannabiran for suggestions, Gullapalli N. Rao for encouragement and support, and Ata-Ur Rasheed for help in extracting DNA from some control samples.

	Footnotes

 
Supported in part by grants from the Department of Biotechnology, Government of India to the L. V. Prasad Eye Institute and the Centre for DNA Fingerprinting and Diagnostics; the Hyderabad Eye Research Foundation; and the i2 Foundation, Dallas, Texas.

Submitted for publication October 1, 2001; revised December 20, 2001; accepted January 11, 2002.

Commercial relationships policy: N.

Presented at the annual meeting of the Association for Research in Vision and Ophthalmology, Fort Lauderdale, Florida, May 2001.

The publication costs of this article were defrayed in part by page charge payment. This article must therefore be marked "advertisement" in accordance with 18 U.S.C. 1734 solely to indicate this fact.

Corresponding author: Shirly G. Panicker, Molecular Genetics, Hyderabad Eye Research Foundation, L.V. Prasad Eye Institute, L.V. Prasad Marg, Banjara Hills, Hyderabad 500 034, Andhra Pradesh, India; shirly{at}lvpeye.stph.net.

	References

Top Abstract Introduction Methods Results Discussion References

 

1. Thylefors, B, Negrel, AD. (1994) The global impact of glaucoma Bull World Health Org 72,323-326[Medline][Order article via Infotrieve]
2. Francois, J. (1972) Congenital glaucoma and its inheritance Ophthalmologica 181,61-73
3. Genicek, A, Genicekova, A, Ferak, V. (1982) Population genetical aspects of primary congenital glaucoma. : I: incidence, prevalence, gene frequency, and age of onset Hum Genet 61,193-197[Medline][Order article via Infotrieve]
4. Jaffar, MS. (1988) Care of the Infantile Glaucoma Patient Reineck, RD eds. Ophthalmology Annual ,15 Raven Press New York.
5. Dandona, L, Williams, JD, Williams, BC, Rao, GN. (1998) Population-based assessment of childhood blindness in Southern India Arch Ophthalmol 116,545-546[Free Full Text]
6. Dandona, L, Dandona, R, Srinivas, M, et al (2001) Blindness in the Indian state of Andhra Pradesh Invest Ophthalmol Vis Sci 42,908-916
7. Sarfarazi, M, Akarsu, AN, Hossain, A. (1995) Assignment of a locus (GLC3A) for primary congenital glaucoma (buphthalmos) to 2p21and evidence for genetic heterogeneity Genomics 30,171-177[Medline][Order article via Infotrieve]
8. Akarsu, AN, Turacli, ME, Aktan, SG, et al (1996) A second locus (GLC3B) for primary congenital glaucoma (buphthalmos) maps to the 1p36 region Hum Mol Genet 5,1199-1203[Abstract/Free Full Text]
9. Stoilov, I, Akarsu, AN, Sarfarazi, M. (1997) Identification of three different truncating mutations in cytochrome P4501B1 (CYP1B1) as the principal cause of primary congenital glaucoma (buphthalmos) in families linked to the GLC3A locus on chromosome 2p21 Hum Mol Genet 6,641-647[Abstract/Free Full Text]
10. Bejjani, BA, Lewis, RA, Tomey, KF, et al (1998) Mutations in CYP1B1, the gene for cytochrome P4501B1, are the predominant cause of primary congenital glaucoma in Saudi Arabia Am J Hum Genet 62,325-333[Medline][Order article via Infotrieve]
11. Plasilova, M, Ferakova, E, Kadasi, L, et al (1998) Linkage of autosomal recessive primary congenital glaucoma to the GLC3A locus in Roms (Gypsies) from Slovakia Hum Hered 48,30-33[Medline][Order article via Infotrieve]
12. Stoilov, I, Akarsu, AN, Alozie, I, et al (1998) Sequence analysis and homology modeling suggest that primary congenital glaucoma on 2p21 results from mutations disrupting either the hinge region or the conserved core structures of cytochrome P4501B1 Am J Hum Genet 62,573-584[Medline][Order article via Infotrieve]
13. Kakiuchi-Matsumoto, T, Isashiki, Y, Nakao, K, Sonoda, S, Kimura, K, Ohba, N. (1999) A novel truncating mutation of cytochrome P4501B1 (CYP1B1) gene in primary infantile glaucoma Am J Ophthalmol 128,370-372[Medline][Order article via Infotrieve]
14. Plasilova, M, Stoilov, I, Sarfarazi, M, Kadasi, L, Ferakova, E, Ferak, V. (1999) Identification of a single ancestral CYP1B1 mutation in Slovak Gypsies (Roms) affected with primary congenital glaucoma J Med Genet 36,290-294[Abstract/Free Full Text]
15. Bejjani, BA, Stockton, DW, Lewis, RA, et al (2000) Multiple CYP1B1 mutations and incomplete penetrance in an inbred population segregating primary congenital glaucoma suggest frequent de novo events and a dominant modifier locus Hum Mol Genet 9,367-374[Abstract/Free Full Text]
16. Martin, SN, Sutherland, J, Levin, AV, Klose, R, Priston, M, Heon, E. (2000) Molecular characterization of congenital glaucoma in a consanguineous Canadian community: a step towards preventing glaucoma related blindness J Med Genet 37,422-427[Abstract/Free Full Text]
17. Ohtake, Y, Kubota, R, Tanino, T, Miyata, H, Mashima, Y. (2000) Novel compound heterozygous mutations in the cytochrome P450 1B1 (CYP1B1) in a Japanese patient with primary congenital glaucoma Ophthalmic Genet 21,191-193[Medline][Order article via Infotrieve]
18. Kakiuchi-Matsumoto, T, Isashiki, Y, Ohba, N, et al (2001) Cytochrome P4501B1 gene mutations in Japanese patients with primary congenital glaucoma Am J Ophthalmol 131,345-350[Medline][Order article via Infotrieve]
19. Mashima, Y, Susuki, Y, Sergeev, Y, et al (2001) Novel cytochrome P4501B1 (CYP1B1) gene mutations in Japanese patients with primary congenital glaucoma Invest Ophthalmol Vis Sci 42,2211-2216[Abstract/Free Full Text]
20. Stoilov, IR, Costa, VP, Vasconcellos, JPC, et al (2001) Mutation screening of the CYP1B1 gene and phenotype-genotype correlation in primary congenital glaucoma cases from Brazil [ARVO Abstract] Invest Ophthalmol Vis Sci 42(4),S530Abstract nr 2848
21. Tang, YM, Wo, YP, Stewart, J, et al (1996) Isolation and characterization of the human cytochrome P450 CYP1B1 gene J Biol Chem 271,28324-28330[Abstract/Free Full Text]
22. Panicker, SG, Reddy, ABM, Mandal, AK, Ahmed, N, Hasnain, SE, Balasubramanian, D. (2001) Molecular genetic basis of primary congenitalglaucoma in India [ARVO Abstract] Invest Ophthalmol Vis Sci 42(4),S530Abstract nr 2847
23. Sarfarazi, M, Stoilov, I. (2000) Molecular genetics of primary congenital glaucoma Eye 14,422-428
24. Rohen, JW. (1961) The histologic structure of the chamber angle in primates Am J Ophthalmol 52,529[Medline][Order article via Infotrieve]
25. Buters, JTM, Sakai, S, Richter, T, et al (1999) Cytochrome P450 CYP1B1 determines susceptibility to 7, 12-dimethylbenz [a] anthracene-induced lymphomas Proc Natl Acad Sci USA 96,1977-1982[Abstract/Free Full Text]

This article has been cited by other articles:

				S. Chakrabarti, K. R. Devi, S. Komatireddy, K. Kaur, R. S. Parikh, A. K. Mandal, G. Chandrasekhar, and R. Thomas Glaucoma-Associated CYP1B1 Mutations Share Similar Haplotype Backgrounds in POAG and PACG Phenotypes Invest. Ophthalmol. Vis. Sci., December 1, 2007; 48(12): 5439 - 5444. [Abstract] [Full Text] [PDF]

				F. Chitsazian, B. K. Tusi, E. Elahi, H. A. Saroei, M. H. Sanati, S. Yazdani, M. Pakravan, N. Nilforooshan, Y. Eslami, M. A. Z. Mehrjerdi, et al. CYP1B1 Mutation Profile of Iranian Primary Congenital Glaucoma Patients and Associated Haplotypes J. Mol. Diagn., July 1, 2007; 9(3): 382 - 393. [Abstract] [Full Text] [PDF]

				C. Bidinost, N. Hernandez, D. P. Edward, A. Al-Rajhi, R. A. Lewis, J. R. Lupski, D. W. Stockton, and B. A. Bejjani Of mice and men: tyrosinase modification of congenital glaucoma in mice but not in humans. Invest. Ophthalmol. Vis. Sci., April 1, 2006; 47(4): 1486 - 1490. [Abstract] [Full Text] [PDF]

				S. Chakrabarti, K. Kaur, I. Kaur, A. K. Mandal, R. S. Parikh, R. Thomas, and P. P. Majumder Globally, CYP1B1 Mutations in Primary Congenital Glaucoma Are Strongly Structured by Geographic and Haplotype Backgrounds Invest. Ophthalmol. Vis. Sci., January 1, 2006; 47(1): 43 - 47. [Abstract] [Full Text] [PDF]

				R Melki, E Colomb, N Lefort, A P Brezin, and H-J Garchon CYP1B1 mutations in French patients with early-onset primary open-angle glaucoma J. Med. Genet., September 1, 2004; 41(9): 647 - 651. [Abstract] [Full Text] [PDF]

				S. G. Panicker, A. K. Mandal, A. B. M. Reddy, V. K. Gothwal, and S. E. Hasnain Correlations of Genotype with Phenotype in Indian Patients with Primary Congenital Glaucoma Invest. Ophthalmol. Vis. Sci., April 1, 2004; 45(4): 1149 - 1156. [Abstract] [Full Text] [PDF]

				D F Sena, S Finzi, K Rodgers, E Del Bono, J L Haines, and J L Wiggs Founder mutations of CYP1B1 gene in patients with congenital glaucoma from the United States and Brazil J. Med. Genet., January 1, 2004; 41(1): e6 - 6. [Full Text] [PDF]

				A. B. M. Reddy, S. G. Panicker, A. K. Mandal, S. E. Hasnain, and D. Balasubramanian Identification of R368H as a Predominant CYP1B1 Allele Causing Primary Congenital Glaucoma in Indian Patients Invest. Ophthalmol. Vis. Sci., October 1, 2003; 44(10): 4200 - 4203. [Abstract] [Full Text] [PDF]

				Y Ohtake, T Tanino, Y Suzuki, H Miyata, M Taomoto, N Azuma, H Tanihara, M Araie, and Y Mashima Phenotype of cytochrome P4501B1 gene (CYP1B1) mutations in Japanese patients with primary congenital glaucoma Br. J. Ophthalmol., March 1, 2003; 87(3): 302 - 304. [Abstract] [Full Text] [PDF]

				T. Borras, T. V. Morozova, S. L. Heinsohn, R. F. Lyman, T. F. C. Mackay, and R. R. H. Anholt Transcription Profiling in Drosophila Eyes That Overexpress the Human Glaucoma-Associated Trabecular Meshwork-Inducible Glucocorticoid Response Protein/Myocilin (TIGR/MYOC) Genetics, February 1, 2003; 163(2): 637 - 645. [Abstract] [Full Text] [PDF]

This Article Abstract Full Text (PDF) Submit a response Alert me when this article is cited Alert me when eLetters are posted Alert me if a correction is posted Citation Map Services Email this article to a friend Similar articles in this journal Similar articles in PubMed Alert me to new issues of the journal Download to citation manager Citing Articles Citing Articles via HighWire Citing Articles via Google Scholar Google Scholar Articles by Panicker, S. G. Articles by Balasubramanian, D. Search for Related Content PubMed PubMed Citation Articles by Panicker, S. G. Articles by Balasubramanian, D.