Duplication of 12q24.21q24.33 in a Girl with Epilepsy, Expanding the Phenotype.

Introduction: Duplication of 12q is characterized by craniofacial dysmorphia, growth failure, occasional brain malformations, abnormalities of the extremities, skeletal and thoracic malformations, cardiovascular defects, anogenital abnormalities like cryptorchidism, psychomotor delay, and intellectual disability. Case presentation: We describe a female patient with typical manifestations of duplication 12q and epilepsy. She had a normal 46,XX karyotype. The microarray assay exhibited a 19.35-Mb gain at 12q24.21q24.33 due to ins(21;12)(p11.2;q24.21q24.33)mat. Discussion and Conclusion: The duplicated region in the patient encompasses 219 genes, 24 considered as pathological. No relation between epilepsy and the genes reported as pathological has been reported.

Submicroscopic 11p13 deletion including the elongator acetyltransferase complex subunit 4 gene in a girl with language failure, intellectual disability and congenital malformations: A case report.

BACKGROUND: We described the main features of an infant diagnosed with facial dysmorphic, language failure, intellectual disability and congenital malformations to strengthen our understanding of the disease. Currently, treatment is only rehabilitation and surgery for cleft lip and palate. CASE SUMMARY: The proband was a 2-years-8-months-old girl. Familial history was negative for congenital malformations or intellectual disability. The patient had microcephaly, upward-slanting palpebral fissures, depressed nasal bridge, bulbous nose and bilateral cleft lip and palate. Brain magnetic resonance imaging showed cortical atrophy and band heterotopia. Her motor and intellectual development is delayed. A submicroscopic deletion in 11p13 involving the elongator acetyltransferase complex subunit 4 gene (ELP4) and a loss of heterozygosity in Xq25-q26.3 were detected. CONCLUSION: There is no treatment for the ELP4 deletion caused by a submicroscopic 11p3 deletion. We describe a second case of deletion of the ELP4 gene without aniridia, which confirms the association between ELP4 gene with several defects and absence of this ocular defect. Additional clinical data in the deletion of the ELP4 gene as cleft palate, facial dysmorphism, and changes at level brain could be associated to this gene or be part of the effect of the recessives genes involved in the loss of heterozygosity region of Xq25-26.3.

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

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.

Familial Blau syndrome without uveitis caused by a novel mutation in the nucleotide-binding oligomerization domain-containing protein 2 gene with good response to infliximab.

The proband in this study was a 4-year-old Mexican girl with Blau syndrome. She and her affected family members had skin rash and arthritis but no uveitis. Exome sequencing and DNA direct sequencing from blood samples revealed a novel nucleotide-binding oligomerization domain-containing protein 2 gene mutation in the affected family members. This study is the first report of a Mexican family with Blau syndrome showing good infliximab treatment response. The novel mutation in the nucleotide-binding oligomerization domain-containing protein 2 gene (c.1808A>G) enriches the mutation spectrum in Blau syndrome. This family represents one of the few cases of autosomal Blau syndrome with no uveitis; because of phenotype variability, it is important to recognize Blau syndrome's clinical spectrum and recommend genetic consultation.

Inherited Congenital Cataract: A Guide to Suspect the Genetic Etiology in the Cataract Genesis.

Cataracts are the principal cause of treatable blindness worldwide. Inherited congenital cataract (CC) shows all types of inheritance patterns in a syndromic and nonsyndromic form. There are more than 100 genes associated with cataract with a predominance of autosomal dominant inheritance. A cataract is defined as an opacity of the lens producing a variation of the refractive index of the lens. This variation derives from modifications in the lens structure resulting in light scattering, frequently a consequence of a significant concentration of high-molecular-weight protein aggregates. The aim of this review is to introduce a guide to identify the gene involved in inherited CC. Due to the manifold clinical and genetic heterogeneity, we discarded the cataract phenotype as a cardinal sign; a 4-group classification with the genes implicated in inherited CC is proposed. We consider that this classification will assist in identifying the probable gene involved in inherited CC.

Whole Exome Sequencing Reveals a Mutation in CRYBB2 in a Large Mexican Family with Autosomal Dominant Pulverulent Cataract.

Congenital cataract, an important cause of reversible blindness, is due to several causes including Mendelian inheritance. Thirty percent of cataracts are hereditary with participation of the gamma crystallin genes. Clinical and genetic heterogeneity is observed in patients with gene mutations and congenital cataract; about 40 genetic loci have been associated with hereditary cataract. In this study, we identified the underlying genetic cause of an autosomal dominant pulverulent cataract (ADPC) in a large Mexican family. Twenty-one affected patients and 20 healthy members of a family with ADPC were included. Genomic DNA was analyzed by whole exome sequencing in the proband, a normal daughter, and in an affected son, whereas DNA Sanger sequencing was performed in all members of the family. After the bioinformatics analysis, all samples were genotyped using Sanger sequencing to eliminate variants that do not cosegregate with the cataract. We observed a perfect cosegregation of a nonsense mutation c.475C>T (p.Q155*) in exon 6 of the CRYBB2 gene with ADPC. We calculated a logarithm of the odds score of 5.5. This mutation was not detected in healthy members of the family and in 100 normal controls. This is the first Mexican family with ADPC associated with a p.Q155* mutation. Interestingly, this specific mutation in the CRYBB2 gene seems to be exclusively associated with pulverulent/cerulean cataract (with some clinical variability) independent of the population's genetic background.

A Family with Craniofrontonasal Syndrome and a Mutation (p.G151S) in the EFNB1 Gene: Expanding the Phenotype.

Craniofrontonasal syndrome (CFNS) is a rare genetic entity with X-linked dominant inheritance. CFNS is due to mutations in the Ephrin-B1 (EFNB1) gene. It is characterized by brachycephaly, frontonasal dysplasia, palate/lip defects, dental malocclusion, short neck, split nails, syndactyly, toe and finger defects, and minor skeletal defects. Intelligence is usually unaffected. CFNS exhibits unexpected manifestations between males and females as the latter are more affected. Cellular or metabolic interference due to X inactivation explains the more severe phenotype in heterozygous females. One family with several members affected with CFNS and 100 healthy controls were examined. DNA from leukocytes was isolated to analyze the EFNB1 gene. We did molecular modeling to assess the impact of the mutation on the EFNB1-encoded protein. DNA sequencing analysis of the EFNB1 gene of the affected members showed the heterozygous missense mutation c.451G>A in the EFNB1 gene (GRcH38, chrX: 68,839,708; GERP score in hg38 of 9.961). This transition mutation resulted in the substitution of Gly at position 151 by Ser. Analysis of the healthy members of the family and 100 unrelated controls showed a normal sequence of the EFNB1 gene. Phenotypes of the patients in this family differ from the classical CFNS due to the decreased size of sulci and fissures, subarachnoid space and ventricles, and the absence of a cleft lip/palate.

Jacobsen Syndrome: Surgical Complications due to Unsuspected Diagnosis, the Importance of Molecular Studies in Patients with Craniosynostosis.

Jacobsen syndrome (JBS) is an uncommon contiguous gene syndrome. About 85-92% of cases have a de novo origin. Clinical variability and severity probably depend on the size of the affected region. The typical clinical features in JBS include intellectual disability, growth retardation, craniofacial dysmorphism as well as craniosynostosis, congenital heart disease, and platelet abnormalities. The proband was a 1 year/3-month-old Mexican male. Oligonucleotide-SNP array analysis using the GeneChip Human Cytoscan HD was carried out for the patient from genomic DNA. The SNP array showed a 14.2-Mb deletion in chromosome 11q23.3q25 (120,706-134,938 Mb), which involved 163 RefSeq genes in the database of genomic variation. We report a novel deletion in JBS that increases the knowledge of the variability in the mutation sites in this region and expands the spectrum of molecular and clinical defects in this syndrome.

Characterization of a Complex Chromosomal Rearrangement Involving a de novo Duplication of 9p and 9q and a Deletion of 9q.

Rearrangements of the distal region of 9p are important chromosome imbalances in human beings. Trisomy 9p is the fourth most frequent chromosome anomaly and is a clinically recognizable syndrome. Kleefstra syndrome, previously named 9q subtelomeric deletion syndrome, is either caused by a submicroscopic deletion in 9q34.3 or an intragenic mutation of EHMT1. We report a Mexican male patient with abnormal development, dysmorphism, systemic anomalies and a complex chromosomal rearrangement (CCR). GTG-banding revealed a 46,XY,add(9)(q34.3) karyotype, whereas array analysis resulted in arr[hg19] 9p24.3p23(203,861-11,842,172)×3, 9q34.3(138,959,881-139,753,294)×3, 9q34.3(139,784,913-141,020,389)×1. Array and karyotype analyses were normal in both parents. Partial duplication of 9p is one of the most commonly detected autosomal structural abnormalities in liveborn infants. A microdeletion in 9q34.3 corresponds to Kleefstra syndrome, whereas a microduplication in 9q34.3 shows a great clinical variability. Here, we present a CCR in a patient with multiple congenital anomalies who represents the first case with partial 9p trisomy, partial 9q trisomy and partial 9q monosomy.

ADRB1 and ADBR2 gene polymorphisms and the ocular hypotensive response to topical betaxolol in healthy Mexican subjects.

BACKGROUND: The ß adrenergic receptors (ADRB) are expressed in the ciliary body and trabecular meshwork, structures involved in aqueous humor production and outflow, respectively. ADRB are members of the adrenergic family of G-protein-coupled receptors. Topic ß blockers have a good local and systemic tolerance; they reduce the aqueous humor production and eye strain blocking the ADRB of the ciliary body and interfering with adenylate cyclase. However, the ocular hypotensive response is not the same in all patients and could be mediated by the polymorphisms of the ADRB genes. MATERIALS AND METHODS: Seventy-two healthy subjects were studied after treatment with topical betaxolol in both eyes. We analyzed ADRB1 and ADRB2 gene polymorphisms by PCR and automated DNA sequencing. RESULTS: There was statistically significant difference between baseline intraocular pressure (IOP) and final IOP of both eyes (baseline IOP 16.2 ± 1.2 - follow-up IOP 13.6 ± 2.0 (mean difference-2.5 ± 1.3, p < 0.001). Gly389 had a higher baseline IOP than Arg389 (17.0 ± 1.2 mmHg versus 16.0 ± 1.2 mmHg; p = 0.02), and conversely Arg389 had a greater magnitude of response than Gly389 to betaxolol therapy (-2.9 ± 1.1 mmHg versus -0.7 ± 0.4 mmHg; p < 0.001). Gln27 had a higher response than Glu27 (-2.7 ± 1.3 mmHg versus -1.9 ± 1.0; p = 0.02). CONCLUSION: Arg389 polymorphism of the ADRB1 gene and Gln27 polymorphism of the ADRB2 gene were associated with the hypotensive response to topic betaxolol in healthy Mexican volunteers.

A CRYGC gene mutation associated with autosomal dominant pulverulent cataract.

PURPOSE: To describe at molecular level a family with pulverulent congenital cataract associated with a CRYGC gene mutation. METHODS: One family with several affected members with pulverulent congenital cataract and 230 healthy controls were examined. Genomic DNA from leukocytes was isolated to analyze the CRYGA-D cluster, CX46, CX50 and MIP genes through high-resolution melting curve and DNA sequencing. RESULTS: DNA sequencing in the affected members revealed the c.143G>A mutation (p.R48H) in exon 2 of the CRYGC gene; 230 healthy controls and ten healthy relatives were also analyzed and none of them showed the c.143G>A mutation. No other polymorphisms or mutations were found to be present. CONCLUSION: In the present study, we described a family with pulverulent congenital cataract that segregated the c.143G>A mutation (p.R48H) in the CRYGC gene. A few mutations have been described in the CRYGC gene in autosomal dominant cataract, none of them with pulverulent cataract making clear the clinical heterogeneity of congenital cataract. This mutation has been associated with the phenotype of congenital cataract but also is considered an SNP in the NCBI data base. Our data and previous report suggest that p.R48H could be a disease-causing mutation and not an SNP.

Complete monosomy mosaic of chromosome 21: case report and review of literature.

Complete monosomy mosaic of chromosome 21 is a rare disorder. The syndromic features are highly variable. This study describes a girl of Mexican origin with complete monosomy 21 in mosaicism with novel findings, including cortical atrophy, macrostomia, pectum excavatum and immune deficiencies. Parental karyotypes were normal. FISH analysis with probes from 21q22.1-q22.2 region and centromere of X DNA probe was performed on peripheral blood lymphocytes whereas 21q22.1-q22.2 and 21q, 4p, 4q subtelomeric DNA probes were tested in fibroblasts. We propose that the monosomy 21 mosaicism is the cause of the survival of children with more than 4 months of age.

Identification of two novel mutations in TRPS1 gene in families with tricho-rhino-phalangeal type I syndrome.

BACKGROUND: Autosomal dominant tricho-rhino-phalangeal syndrome I (TRPS I) is due to mutations in the TRPS1 gene. Tricho-rhino-phalangeal syndrome I is characterized by peculiar face and skeletal anomalies. Cone-shaped epiphyses are the characteristic radiographic findings. OBJECTIVE: To describe 2 families with TRPS I and 2 novel mutations in the TRPS1 gene. PATIENTS: The study included 2 nonrelated families with TRPS I. All exons of the TRPS1 gene were analyzed from genomic DNA. RESULTS: The TRPS1 gene mutation analysis showed in family 1 the c.978C>A nonsense mutation within exon 4 and in family 2 the c.164A>C missense mutation within exon 3. CONCLUSIONS: We found 2 families with TRPS1 caused by 2 novel mutations in the TRPS gene, particularly a missense mutation in exon 3, outside the GATA zinc finger domain, that leads a mild TRPS phenotype. Our data show a higher genotypic spectrum in the TRPS I and demonstrate that mutations in the amino terminus of the transcription factor result in TRPS I syndrome.

Familial pycnodysostosis: identification of a novel mutation in the CTSK gene (cathepsin K).

BACKGROUND: Pycnodysostosis, an autosomal recessive skeletal dysplasia, is characterized by short stature, osteosclerosis, delayed cranial suture closure, hypoplastic mandible, acro-osteolysis, hypoplastic clavicle, and dental anomalies. The disorder is caused by CTSK gene defects, a gene localized on 1q21. PURPOSE: To describe the clinical, radiological, and molecular findings in a family with pycnodysostosis. METHODS: The CTSK gene was analyzed from genomic DNA in a nonconsanguinity Mexican family with 3 affected members with pycnodysostosis and 100 healthy controls. RESULTS AND INTERPRETATION: We identified the novel homozygous mutation c.908G>A within exon 8 of the CTSK gene. This missense mutation leads to the substitution of the amino acid glycine at position 303 by glutamic acid (G303E) in cathepsin K protease. No genotype/phenotype correlation was present in affected members of the family with pycnodysostosis.

A family with autosomal dominant primary congenital cataract associated with a CRYGC mutation: evidence of clinical heterogeneity.

PURPOSE: To describe a family with primary congenital cataract associated with a CRYGC mutation. METHODS: One family with several affected members with primary congenital cataract and 170 healthy controls were examined. DNA from leukocytes was isolated to analyze the CRYGA-D gene cluster. RESULTS: DNA sequencing analysis of the CRYGA-D gene cluster of the affected members showed the heterozygous missense mutation c.502C>T in the CRYGC gene. This transition mutation resulted in the substitution of Arg at position 168 by Trp. Analysis of the healthy members of the family and 170 unrelated controls showed a normal sequence of the CRYGA-D gene cluster. CONCLUSIONS: In the present study, we described a family with nuclear congenital cataract that segregated the CRYGC missense mutation c.502C>T. This mutation has been associated with the phenotype of lamellar cataract but is also considered a single nucleotide polymorphism (SNP) in the NCBI database. Our data and previous report support that R168W is the actual disease-causing mutation and should no longer be considered a SNP. This is the first case of phenotypic heterogeneity in the primary congenital cataract specifically associated with the R168W mutation in the CRYGC gene.