Subject index

Peters anomaly (PA) and primary congenital glaucoma (PCG) are genetically and phenotypically distinct conditions. Mutations in cytochrome P4501B1 (CYP1B1) are the most common cause of PCG in Saudi Arabia. Recent evidence suggests that there may be common genetic factors to these conditions. To determine the molecular basis of PA, 11 study subjects with PA from 10 Saudi Arabian families were recruited. Experienced ophthalmologists examined all affected subjects and most of their available unaffected relatives. The diagnosis of PA was confirmed by pathological examination of excised corneal buttons in seven subjects. The coding exons of FOXC1, PITX2, and PAX6 were screened and those of CYP1B1 and FOXE3 sequenced. Homozygous CYP1B1 mutations were identified in six individuals in five families. Five individuals were homozygous for G61E and one was homozygous for 143del10. No mutations were identified in FOXC1, PITX2, PAX6, or FOXE3. The clinical or pathologic phenotype of the subjects with CYP1B1 mutations was not different from that of the other PA patients in this study. Two families included at least one individual with homozygous CYP1B1 mutations and no ocular anomalies (nonpenetrant). Mutations in CYP1B1 may be a substantive cause for PA in this population. Thus, PA and PCG may share a common molecular pathophysiology. Indeed, PA and PCG may share the same spectrum of anterior segment dysgenesis. Finally, the occurrence of PA, PCG, and unaffected individuals with identical homozygous CYP1B1 mutations in the same sibship suggests the presence of modifiers that modulate the clinical severity of the phenotypic expression of the same CYP1B1 mutation(s).     

Novel CYP1B1 and known PAX6 mutations in anterior segment dysgenesis (ASD)

PURPOSE: The study intended to define the underlying genetic defects for 21 index patients affected with different forms of anterior segment dysgenesis. Sequence analysis for the PAX6, PITX2, FOXC1, and CYP1B1 genes has been implemented for this purpose. METHODS: Ten patients affected with Peters anomaly, 8 with Rieger anomaly, and 3 with aniridia were included in this study. All patients underwent a complete eye examination, including anterior segment evaluation, with slit-lamp microsocopy, fundoscopy, tonography, and gonioscopy. Twenty-one intronic primer pairs were used to amplify the coding exons of the FOXC1, CYP1B1, PITX2, and PAX6 genes for sequence analysis on an automated sequencer (ABI 3730). RESULTS: We were able to detect mutations in 5 of 21 patients with anterior segment malformations. We found mutations in individuals suffering from Rieger anomaly and aniridia, in CYP1B1 and PAX6, respectively. None of the 10 Peters anomaly patients had causative mutations in any of the 4 genes we screened. CONCLUSIONS: Our results suggest primary congenital glaucoma and the anterior segment dysgenesis disorders may share a common molecular pathophysiology in the CYP1B1 pathway.     

Genetic analysis of patients with primary congenital glaucoma

Purpose

To determine the common gene mutation in patients with primary congenital glaucoma (PCG) in the Southeast region of Turkey via genetic analysis and to evaluate whether there were other gene mutations in these patients.

Methods

A total of 25 patients with PCG were included in this study. We performed sequence analysis including all exons of cytochrome p450 1B1 (CYP1B1), myocilin (MYOC), forkhead box C1 (FOXC1), and paired-like homeodomain 2 (PITX2) genes of the obtained samples. Further, we analyzed the results using the Nextgen analysis program.

Results

The CYP1B1 gene mutation was detected in 20 (80%) of 25 patients, and FOXC1 gene mutation was detected in one (4%) patient. The mutation site of nine (45%) of the 20 CYP1B1 genes was found in the second exon. The pathogenic variant (p.Gly61Glu) was observed in 12 (60%) patients (in the first and second exons); the mutation type of six (50%) of these patients was homozygous. The mutation site of one patient with FOXC1 gene mutation was found to be in the first exon; its pathogenic variant was p.Met400lle. The mutation type in this gene was observed to be heterozygous. Lastly, there were no mutations in the MYOC, FOXC1, and PITX2 genes in combination with the CYP1B1 gene mutation.

Conclusion

The most common cause of PCG in our region is the CYP1B1 gene mutation, and the most frequent pathogenic variant is c.182G?>?A (p.Gly61Glu). We also determined that the CYP1B1 gene mutation was alone and did not occur with other gene mutations (MYOC, FOXC1, and PITX2).

     

Molecular characterization of Axenfeld-Rieger spectrum and other anterior segment dysgeneses in a sample of Mexican patients

ABSTRACT

Background: Anterior segment dysgenesis (ASD) and Axenfeld-Rieger spectrum (ARS) are mainly due to PITX2 and FOXC1 defects, but it is difficult in some patients to differentiate among PITX2-, FOXC1-, PAX6- and CYP1B1-related disorders. Here, we set out to characterize the pathogenic variants (PV) in PITX2, FOXC1, CYP1B1 and PAX6 in nine unrelated Mexican ARS/ASD patients and in their available affected/unaffected relatives.

Materials and methods: Automated Sanger sequencing of PITX2, FOXC1, PAX6 and CYP1B1 was performed; those patients without a PV were subsequently analyzed by Multiplex Ligation-dependent Probe Amplification (MLPA) for PITX2, FOXC1 and PAX6. Missense variants were evaluated with the MutPred, Provean, PMUT, SIFT, PolyPhen-2, CUPSAT and HOPE programs.

Results: We identified three novel PV in PITX2 (NM_153427.2:c.217G>A, c.233T>C and c.279del) and two in FOXC1 [NM_001453.2:c.274C>T (novel) and c.454T>A] in five ARS patients. The previously reported FOXC1 c.367C>T or p.(Gln123*) variant was identified in a patient with ASD. The ocular phenotype related to FOXC1 included aniridia, corneal opacity and early onset glaucoma, while an asymmetric ocular phenotype and aniridia were associated with PITX2. No gene rearrangements were documented by MLPA analysis, nor were any PV identified in PAX6 or CYP1B1.

Conclusions: Heterozygous PV in the PITX2 and FOXC1 genes accounted for 66% (6/9) of the ARS/ASD cases. The absence of PAX6 or CYP1B1 abnormalities could reflect our small sample size, although their analysis could be justified in ARS/ASD patients that present with congenital glaucoma or aniridia.     

A new autosomal dominant Peters’ anomaly phenotype expanding the anterior segment dysgenesis spectrum

Purpose: To test the association of genes involved in anterior segment development in a family with autosomal dominantly inherited Peters’ anomaly (PA) with a unique ocular phenotype. Methods: Six members of a five‐generation family with PA were extensively phenotyped and linkage analysis of candidate genes, namely, PAX6, PITX2, FOXC1, CYP1B1 and MAF, was performed. Results: The complete pedigree consisted of 38 members, 19 of whom were affected. The six probands examined had bilateral microcornea, corneal opacity, iridocorneal adhesions, nystagmus and strabismus, but cataract, keratolenticular adhesions, glaucoma and posterior embryotoxon were absent. PAX6 gene mutations had been previously excluded in one of the affected members. DNA markers for candidate genes CYP1B1 on 2p22, PITX2 on 4q25, PAX6 on 11p13, MAF on 16q23 and FOXC1 on 6p25 were genotyped. Highly negative lod scores were obtained for all markers. Conclusions: The exclusion of these genes as likely candidates supports the hypothesis that the ocular phenotype associated with PA segregating in this family is a distinct, new, autosomal dominant entity in the anterior segment dysgenesis spectrum.     

Molecular Characterization of Newborn Glaucoma Including a Distinct Aniridic Phenotype

Purpose: To characterize the underlying genetic defect in otherwise healthy Saudi newborns with buphthalmos, including those with iris abnormalities.

Methods: Prospective case series of affected Saudi Arabian probands who were referred for genetic counseling over a 4 year period. All had CYP1B1 sequencing. Selected patients with visible iris abnormalities had PAX6, FOXC1, and PITX2 sequencing. CYP1B1-negative patients had LTBP2 sequencing.

Results: All 67 probands had corneal enlargement with variable haze/scarring evident to caregivers at birth; 46 had a family history of infantile or early childhood glaucoma. All families were consanguineous except for 6, 2 of which were endogamous. Eight probands had mild ectropion uveae with partial aniridia; 2 probands had thick scarred corneas that precluded careful iris examination. Homozygous or compound heterozygous CYP1B1 mutations were identified in 91% (61/67), including all 8 probands with ectopion uveae and partial aniridia. The common Saudi mutation p.G61E occurred in most cases (38 homozygous, 8 compound heterozygous). Four novel mutations were identified (p.N252K, p.V460E, p.S485F, p.N519D). No mutations were identified in the other screened genes.

Conclusions: Newborn glaucoma on the Arabian Peninsula is typically CYP1B1-related even in the setting of developmental iris abnormality. Mild iris ectropion with partial aniridia in a newborn with glaucoma suggests mutations in CYP1B1 rather than in other genes associated with anterior segment dysgenesis. On the Arabian Peninsula p.G61E mutations are the major cause of newborn glaucoma but novel CYP1B1 mutations continue to be documented. The fact that the 9% of cases that were CYP1B1-negative did not have mutations in LTBP2 suggests that there exists at least 1 additional locus for this condition.     

东北地区原发性闭角型青光眼家系PITX2基因和FOXC1基因突变筛查

目的通过分子遗传学研究筛查原发性闭角型青光眼家系PITX2基因和FOXC1基因突变情况。设计实验研究。研究对象东北地区原发性闭角型青光眼4个家系13例患者和24例健康成员。方法应用聚合酶链反应(PCR)扩增PITX2基因和FOXC1基因所有编码外显子,直接测序法筛查致病突变。主要指标PITX2基因、FOXC1基因序列。结果所分析的4个家系13例患者基因组DNA中均未检测到PITX2基因、FOXC1基因突变。结论 PITX2基因和FOXC1基因不是中国东北地区该原发性闭角型青光眼家系的致病病因。     

Structural assessment of PITX2, FOXC1, CYP1B1, and GJA1 genes in patients with Axenfeld-Rieger syndrome with developmental glaucoma

PURPOSE: Axenfeld-Rieger (AR) is an autosomal dominant disorder with phenotypic heterogeneity characterized by anterior segment dysgenesis, facial bone defects, and redundant periumbilical skin. The PITX2 gene, on chromosome 4q25, and the FOXC1 gene, on chromosome 6p25, have been implicated in the different phenotypes of the syndrome through mutational events. Recently, the CYP1B1 gene was found to be associated with Peters' anomaly, and the gene associated with oculodentodigital dysplasia syndrome, which presents some similarities with AR, was identified (connexin 43--GJA1 gene). The purpose of this study was to evaluate PITX2, FOXC1, CYP1B1, and GJA1 gene mutations in Brazilian families with AR. METHODS: Eight unrelated patients affected by AR (all eight with glaucoma and three with systemic manifestations) and their families were ophthalmologically evaluated and their blood was collected for DNA extraction purposes. The coding regions of PITX2, FOXC1, CYP1B1, and GJA1 genes were completely evaluated through direct sequencing. RESULTS: The frequency of mutations in the FOXC1, GJA1, PITX2, and CYP1B1 genes in this study were 25%, 12.5%, 0% and 0%, respectively. In the FOXC1 gene, two GGC triplet insertions (GGC375ins and GGC447ins) defined as a polymorphism, and two new mutations--a deletion (718 to 719delCT) and a nonsense mutation (Trp152STOP)--were identified. One polymorphism (Ala253Val) was identified in the GJA1 gene in the same family presenting the Trp152STOP mutation in the FOXC1 gene. In this family harboring both structural alterations, two patients who carried the GJA1 (Ala253Val) and FOXC1 (Trp152STOP) mutations developed less severe glaucoma compared with family members presenting the FOXC1 (Trp152STOP) mutation alone. CONCLUSIONS: Two new structural alterations in the FOXC1 gene and a polymorphism in the GJA1 gene were first described in Brazilian patients with AR and developmental glaucoma. A polymorphism in the GJA1 gene (Ala253Val), for the first time identified in association with AR, raises the possibility of its participation as a modifier gene.     

A clinical and molecular genetic study of Egyptian and Saudi Arabian patients with primary congenital glaucoma (PCG)

PURPOSE: To undertake mutation screening of cytochrome P4501B1 (CYP1B1, OMIM 601771) and myocilin (MYOC, OMIM 601652) genes in Egyptian and Saudi Arabian patients with primary congenital glaucoma (PCG). PATIENTS AND METHODS: A clinical and molecular genetic study was performed on 11 Egyptian and Saudi Arabian patients with PCG. Clinical diagnosis was confirmed by slit lamp biomicroscopy, gonioscopy, measurement of intraocular pressure, and corneal diameter. The coding regions of CYP1B1 and MYOC genes were amplified by polymerase chain reaction for all affected subjects. Direct sequence analysis was performed to search for sequence alterations. Haplotype analysis and genotype/phenotype correlation were carried out. RESULTS: Three CYP1B1 mutations were identified in 5 PCG patients (45.4%) of which 2 were novel (homozygous E173K and heterozygous N498D) and the third (G61E) had previously been reported. In addition 10 single nucleotide polymorphisms were identified in CYP1B1 and MYOC genes of which 2 were novel. However, no pathologic changes in either of the genes were detected in the remaining 6 patients. CONCLUSIONS: This is the first report of molecular genetic analysis of PCG in the Egyptian population in which 2 novel mutations have been identified. It is possible that these mutations are specific to this population and may lead to alterations in the protein structure encoded by the gene. Patients with no mutations in the screened genes may have mutations in genes yet to be identified.     

Of mice and men: tyrosinase modification of congenital glaucoma in mice but not in humans

PURPOSE: Primary congenital glaucoma (PCG) is an autosomal recessive ocular trait caused by mutations in the gene for cytochrome P4501B1 (CYP1B1). Although PCG is often considered to be fully penetrant, the disease shows 50% penetrance in some Saudi Arabian families. The familial segregation of the nonpenetrance suggests a genetic modifier. Recently, tyrosinase (Tyr) deficiency was found to worsen the drainage structure/ocular dysgenesis phenotype of Cyp1b1-/- mice, suggesting that Tyr is a modifier of the phenotype. In the current study, tyrosinase (TYR) was investigated in human PCG. METHODS: A genome-wide screen, a single nucleotide polymorphism (SNP) analysis in the TYR chromosomal region 11q13-q21, and sequencing of the TYR gene was performed with individuals from Saudi Arabian families with multiple, clinically confirmed, molecularly proven, nonpenetrant members. RESULTS: The study outcome did not support TYR as a modifier of the PCG phenotype in this population. The sequencing data showed no TYR mutations in the nonpenetrant family members and no difference in polymorphism frequencies between nonpenetrant or fully penetrant families. CONCLUSIONS: TYR is not a modifier of the CYP1B1-associated PCG phenotype in the Saudi Arabian population.     

Molecular and clinical evaluation of primary congenital glaucoma in Kuwait

PURPOSE: To report the spectrum of the CYP1B1 mutation in Kuwaiti patients with primary congenital glaucoma (PCG). DESIGN: Clinical diagnosis of PCG and laboratory based experimental study. METHODS: Polymerase chain reaction-restriction polymorphism length fragment (PCR-RPLF) and direct sequencing of exon 2 and the coding region of exon 3 of CYP1B1 gene were the methods used for screening 17 PCG patients, their families, and 105 health individuals from the same ethnicity. RESULTS: Four different mutations were detected in CYP1B1 in 70.6% of the screened patients. The most common one (47%) was homozygote Gly61Glu mutation, previously described in Saudi Arabia, Turkey, and Morocco; all patients were products of consanguineous marriages. The second common mutation was a novel missense (Ala388Thr) mutation found in three patients (17.6%) as compound heterozygote with Arg368His in one patient, and with Gly61Glu in another one while the second mutation in third patient was not detected in the CYP1B1 gene. One patient (5.8%) was homozygote for Cyt280X mutation previously reported in only one Japanese family. In addition to these mutations, a novel Val422Gly polymorphic site was found in three of the PCG patients and in 18 of the 210 tested chromosomes of healthy volunteers. CONCLUSIONS: The CYP1B1 mutation spectrum of Kuwaiti PCG patients is similar to that detected in the neighboring countries. No clear genotype-phenotype correlation detected in patients showed different types of CYP1B1 mutation.     

Identification of novel mutations causing familial primary congenital glaucoma in Indian pedigrees

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.     

Overview of Cytochrome P450 1B1 gene mutations in patients with primary congenital glaucoma

The objective of this study was to investigate the distribution of mutations in the Cytochrome P450 1B1 gene (CYP1B1) in patients with primary congenital glaucoma (PCG) among different populations. All identifiable original studies on CYP1B1 gene mutations of patients with PCG were reviewed. Finally, DNA mutations within the CYP1B1 gene were identified in 542 patients with PCG according to 52 scientific articles and 147 distinct mutations were found. The 3987G>A (G61E) missense mutation is a founder mutation in Middle Eastern population, responsible for 45.52% of CYP1B1 mutations. In Gypsies, missense mutation 7996G>A (E387K) seems to be a founder mutation, accounting for 79.63% of CYP1B1 mutations. It seems that there is no founder mutation in Asian or Caucasian population, but also accumulates in some spots. Mutations 7927G>A (V364M), 7990C>T (L385F) and 8006G>A (R390H) are common in Asian population. In Caucasians, 7940G>A (R368H), 8037dup10, 8006G>A (R390H), 7901del13, 4340delG, 3987G>A (G61E), 7996G>A (E387K), 4490G>A (E229K) and 8005C>T/A (R390C/S) are common mutations. The findings suggest that ethnic differences and the geographical distribution of PCG may be associated with different CYP1B1 mutation patterns. Such information may be useful in developing strategies for reliable clinical genetic testing of patients with PCG and their families.     

Cytochrome P4501B1 mutations cause only part of primary congenital glaucoma in Ecuador

Purpose: To determine the role of cytochrome P4501B1 ( CYP1B1 ) mutations in causing primary congenital glaucoma (PCG) in a cohort of Native Americans from Quito, Ecuador. Materials and methods: Seventeen patients with PCG from 15 Native American families were recruited from the Ophthalmology Clinic at Hospital Metropolitano, Quito, Ecuador. Experienced ophthalmologists examined all affected study subjects. Purified DNA was prepared from peripheral blood samples and CYP1B1 coding exons (exons 2 and 3) were amplified and sequenced. Southern blot was performed only on those affected patients who showed no mutations in the CYP1B1 coding exons. Results: The molecular basis of PCG in two families was determined: two novel mutations (a deletion and a point mutation) and one novel polymorphism in CYP1B1 were identified in addition to a previously described single amino acid substitution. Southern blot analyses on whole genomic DNA from affected individuals in whom no mutations were identified by the direct PCR/sequencing approach did not detect any large rearrangements or mutations outside the coding region. Conclusion: These findings suggest that mutations in CYP1B1 are not a major cause of PCG in this population and that at least one additional locus for this condition is responsible for most cases. Further, the PCG phenotype did not correlate readily with the molecular basis of the disorder, suggesting that careful clinical analysis of the phenotype cannot predict the molecular basis of the disease with accuracy.     

Two novel variants in CYP1B1 gene: a major contributor of autosomal recessive primary congenital glaucoma with allelic heterogeneity in Pakistani patients

AIM: To find the CYP1B1 mutations associated with primary congenital glaucoma (PCG) in Pakistani consanguineous pedigrees. METHODS: After getting informed consent, 11 consanguineous pedigrees belonging to different ethnic groups were enrolled. Detailed medical history was recorded and pedigrees were drawn. The standard ophthalmological examination was done to characterize the phenotype. Genomic DNA was extracted from 10 mL whole blood and coding exons and exon intron boundaries of CYP1B1 gene were directly sequenced. Bioinformatics tools were used to model the mutant protein and predict the effect of novel variants on protein structure and function. RESULTS: Sequencing analysis revealed 5 different CYP1B1 variants in 7 families (7/11; 64%), including two novel variants. A common mutation, p.R390H was found in four families, whereas p.P437L was found once in a family. Two novel variants, a homozygous non sense variant p.L13* and a compound heterozygous variant, p.P350T along with p.V364M were segregating with PCG in two families. All the patients had the variable onset and severity of the disease. The success rate of early clinical interventions was observed dependent on mutation types and position. Two different haplotypes were associated with frequently found mutation, p.R390H. CONCLUSION: Identification of novel CYP1B1 variants reassert the genetic heterogeneity of Pakistani PCG patients. The patients with missense mutations show severe phenotypic presentations and poor vision after surgical interventions as compare to patients with null variants. This may help to better understand the role of CYP1B1 mutations in the development of PCG and its course of pathogenicity.     

Cytochrome P4501B1 mutations cause only part of primary congenital glaucoma in Ecuador

PURPOSE: To determine the role of cytochrome P450IBI (CYP1B1) mutations in causing primary congenital glaucoma (PCG) in a cohort of Native Americans from Quito, Ecuador. MATERIALS AND METHODS: Seventeen patients with PCG from 15 Native American families were recruited from the Ophthalmology Clinic at Hospital Metropolitano, Quito, Ecuador. Experienced ophthalmologists examined all affected study subjects. Purified DNA was prepared from peripheral blood samples and CYP1B1 coding exons (exons 2 and 3) were amplified and sequenced. Southern blot was performed only on those affected patients who showed no mutations in the CYP1B1 coding exons. RESULTS: The molecular basis of PCG in two families was determined: two novel mutations (a deletion and a point mutation) and one novel polymorphism in CYP1B1 were identified in addition to a previously described single amino acid substitution. Southern blot analyses on whole genomic DNA from affected individuals in whom no mutations were identified by the direct PCR/sequencing approach did not detect any large rearrangements or mutations outside the coding region. CONCLUSION: These findings suggest that mutations in CYPIBI are not a major cause of PCG in this population and that at least one additional locus for this condition is responsible for most cases. Further, the PCG phenotype did not correlate readily with the molecular basis of the disorder, suggesting that careful clinical analysis of the phenotype cannot predict the molecular basis of the disease with accuracy.     

Genetic analysis of PITX2 and FOXC1 in Rieger Syndrome patients from Brazil

PURPOSE: Axenfeld-Rieger syndrome is a genetically heterogeneous, autosomal dominant disorder that is characterized by anterior segment defects, glaucoma, and extraocular anomalies. This study examined the two genes known to cause Rieger syndrome, PITX2 and FOXC1, for mutations in five Brazilian families with Axenfeld-Rieger syndrome. METHODS: Five families with a total of 23 persons affected by Axenfeld-Rieger syndrome were recruited for this study. A sequencing-based mutation screen was undertaken for the PITX2 and FOXC1 genes. Linkage analysis was used to study one large family for which no mutations were detected in the PITX2 or FOXC1 genes. RESULTS: Two of the five families harbored mutations in the PITX2 gene, but none of the families had a detectable FOXC1 mutation. Haplotypic analysis of three Rieger syndrome regions in a large family with Axenfeld-Rieger syndrome excluded linkage to the 4q25 (PITX2), 6p25 (FOXC1), and 13q14 (RIEG2) regions. CONCLUSIONS: It appears that the PITX2 gene is responsible for a significant portion of Axenfeld-Rieger syndrome in the Brazilian population. Furthermore, there is also evidence for the presence of genetic heterogeneity of the disorder within the Brazilian population. Finally, a large family with Axenfeld-Rieger syndrome has been identified that does not appear to harbor any of the three known loci. Axenfeld-Rieger syndrome gene segregation in this family likely represents a novel locus.     

Molecular genetics of primary congenital glaucoma in Brazil

PURPOSE: To determine the distribution of CYP1B1 gene mutations in Brazilian patients with primary congenital glaucoma (PCG). METHODS: PCG diagnosis was established by presence of buphthalmos in at least one affected eye and associated high intraocular pressures before the age of 3 years. CYP1B1 mutation screening of 52 patients with PCG was performed by SSCP and direct sequencing of PCR fragments. RESULTS: Eleven mutations, four of which are novel, were observed in 26 (50%) individuals. A new frameshift mutation (4340delG) was observed in 20.2% of all individuals screened. These individuals had early-onset, bilateral glaucoma that necessitated multiple surgical interventions. CYP1B1 mutations were twice as frequent in affected individuals of European descent as in individuals of African descent. Analysis of six intragenic single nucleotide polymorphisms (SNPs) established 5'-C-C-G-G-T-A-3' as the most common haplotype among the affected Brazilian individuals. A nonsense mutation (W57X) previously reported in an individual with Peters anomaly (compound heterozygote) was also observed in two individuals with PCG but combined with different mutations. A newly developed SSCP assay enabled us to detect all DNA mutations and polymorphisms previously detected by direct sequencing. CONCLUSIONS: Our results indicate that CYP1B1 mutations may be responsible for half of cases of PCG in the Brazilian population. The SNP haplotype 5'-C-C-G-G-T-A-3' was associated with the majority of CYP1B1 mutations. This haplotype harbors the high-activity V432 allele, which is emerging as a putative susceptibility factor in several cancers.     

湖北地区原发性先天性青光眼患儿CYP1B1基因的新突变研究

目的探讨湖北地区汉族原发性先天性青光眼（PCG）患儿的基因突变情况并为基因诊断奠定基础。方法对47例无关个体PCG患儿及100例健康正常儿童进行基因分析。采取外周静脉血4ml,制备外周白细胞基因组DNA,参照文献所报道的引物序列,聚合酶链反应（PCR）分别扩增CYP1B1基因的第2、3外显子,琼脂糖凝胶电泳鉴定产物后,应用单链构象多态性（SSCP）、变性高效液相色谱分析（DHPLC）及DNA序列分析技术对患儿和对照组进行基因分析。结果7例PCG患儿呈现CYP1B1基因的第3外显子第385密码子的第1个碱基C→T碱基点突变,致对应的亮氨酸转变为苯丙氨酸（L385F）。这一变异在正常对照组成员中未检出,且检索国内外文献尚未见报道。结论湖北地区汉族PCG患者存在CYP1B1基因第3外显子突变,这一新突变位点位于P450蛋白的重要功能区,可能为病理性突变。在汉族PCG患者中进行CYP1B1基因突变的深入研究并寻找其他致病基因,对探讨PCG发病机制具有重要意义。