Maciej R. Krawczynski

Splicing Mutations of 54-bp Exons in the COL11A1 Gene Cause Marshall Syndrome, but Other Mutations Cause Overlapping Marshall/Stickler Phenotypes

Stickler and Marshall syndromes are dominantly inherited chondrodysplasias characterized by midfacial hypoplasia, high myopia, and sensorineural-hearing deficit. Since the characteristics of these syndromes overlap, it has been argued whether they are distinct entities or different manifestations of a single syndrome. Several mutations causing Stickler syndrome have been found in the COL2A1 gene, and one mutation causing Stickler syndrome and one causing Marshall syndrome have been detected in the COL11A1 gene. We characterize here the genomic structure of the COL11A1 gene. Screening of patients with Stickler, Stickler-like, or Marshall syndrome pointed to 23 novel mutations. Genotypic-phenotypic comparison revealed an association between the Marshall syndrome phenotype and splicing mutations of 54-bp exons in the C-terminal region of the COL11A1 gene. Null-allele mutations in the COL2A1 gene led to a typical phenotype of Stickler syndrome. Some patients, however, presented with phenotypes of both Marshall and Stickler syndromes.

Achromatopsia mutations target sequential steps of ATF6 activation

Significance The unfolded protein response regulator activating transcription factor 6 (ATF6) was recently identified as a novel genetic cause of the cone photoreceptor disease achromatopsia. ATF6 upregulates genes that help cells cope with endoplasmic reticulum stress. We identified the pathomechanisms of all ATF6 achromatopsia mutations. Class 1 ATF6 mutants show impaired endoplasmic reticulum (ER)-to-Golgi trafficking and diminished production of the transcriptional activator fragment. Class 2 mutants encode the intact ATF6 transcriptional activator domain with full activity. Class 3 mutants have defective basic leucine zipper (bZIP) domains with abrogated function. Patient fibroblasts show increased apoptosis after ER stress. Our findings reveal that human ATF6 mutations interrupt distinct steps of ATF6 activation. ER stress-associated damage may underlie the pathology of achromatopsia arising from ATF6. Achromatopsia is an autosomal recessive disorder characterized by cone photoreceptor dysfunction. We recently identified activating transcription factor 6 (ATF6) as a genetic cause of achromatopsia. ATF6 is a key regulator of the unfolded protein response. In response to endoplasmic reticulum (ER) stress, ATF6 migrates from the ER to Golgi to undergo regulated intramembrane proteolysis to release a cytosolic domain containing a basic leucine zipper (bZIP) transcriptional activator. The cleaved ATF6 fragment migrates to the nucleus to transcriptionally up-regulate protein-folding enzymes and chaperones. ATF6 mutations in patients with achromatopsia include missense, nonsense, splice site, and single-nucleotide deletion or duplication changes found across the entire gene. Here, we comprehensively tested the function of achromatopsia-associated ATF6 mutations and found that they group into three distinct molecular pathomechanisms: class 1 ATF6 mutants show impaired ER-to-Golgi trafficking and diminished regulated intramembrane proteolysis and transcriptional activity; class 2 ATF6 mutants bear the entire ATF6 cytosolic domain with fully intact transcriptional activity and constitutive induction of downstream target genes, even in the absence of ER stress; and class 3 ATF6 mutants have complete loss of transcriptional activity because of absent or defective bZIP domains. Primary fibroblasts from patients with class 1 or class 3 ATF6 mutations show increased cell death in response to ER stress. Our findings reveal that human ATF6 mutations interrupt distinct sequential steps of the ATF6 activation mechanism. We suggest that increased susceptibility to ER stress-induced damage during retinal development underlies the pathology of achromatopsia in patients with ATF6 mutations.

PAX6 3' deletion in a family with aniridia.

Background: Aniridia is a congenital panocular malformation defined as iris aplasia or hypoplasia. It can be either isolated or be a part of multiple ocular anomalies such as cataracts, glaucoma, corneal pannus, optic nerve hypoplasia, absence of macular reflex or ectopia lentis. In the majority of cases the disease is caused by mutation in the PAX6 gene. Material and Methods: A Polish family with aniridia was screened for the presence of genomic rearrangements in PAX6, WT1 and the flanking genes by means of multiplex ligation probe amplification (MLPA). MLPA reaction was performed using the P219-B1 PAX6 commercial kit from MRC-Holland. Additionally, the coding sequence of PAX6 gene was sequenced in the proband. Array comparative genomic hybridization analysis was performed using the NimbleGen CGX-12 format. Results: MLPA examination revealed a heterozygous deletion of approximately 0.6 Mb, downstream of PAX6 gene on chromosome 11. Four genes lie in the deleted region. Bi-directional sequencing of 14 exons of the PAX6 gene did not reveal any causative alteration. Microarray analysis confirmed the deletion and determined its size which ranged from 598.87–651.76 kb. Conclusions: A small subset of aniridia cases is caused by rearrangements of PAX6 neighboring regions, and the so-called “position effect” is considered to be the underlying pathogenic mechanism. Molecular testing of aniridia patients should include sequencing of the PAX6 gene, followed by screening for larger structural abnormalities located on chromosome 11p13. MLPA can be a useful method in molecular testing of aniridia patients.

A novel GJA1 missense mutation in a Polish child with oculodentodigital dysplasia.

Oculodentodigital dysplasia (ODDD) (OMIM #164200) is a rare congenital, autosomal dominant disorder comprising craniofacial, ocular, dental, and digital anomalies. The syndrome is caused byGJA1 mutations. The clinical phenotype of ODDD involves a characteristic dysmorphic facies, ocular findings (microphthalmia, microcornea, glaucoma), syndactyly type III of the hands, phalangeal abnormalities, diffuse skeletal dysplasia, enamel dysplasia, and hypotrichosis. In a Polish child with the clinical symptoms typical of ODDD, we demonstrated a novel missense mutation c.C31T resulting in p.L11F substitution. Our report provides evidence on the importance of this highly conserved amino acid residue for the proper functioning of GJA1 protein.

Granular corneal dystrophy in 830-nm spectral optical coherence tomography.

Purpose: Spectral optical coherence tomography (SOCT) is a new imaging technique that can provide high-resolution tomograms much faster and with higher sensitivity than conventional Time domain (TdOCT) systems. Its usefulness in producing cross-sectional imaging of different corneal pathologies in vivo has already been presented. The aim of this case report is to show 830-nm SOCT findings in granular corneal dystrophy. Methods: A 48-year-old woman with granular corneal dystrophy was examined with a slit-lamp, confocal microscope (Confoscan 4) and a prototype SOCT instrument constructed at the Institute of Physics, Nicolaus Copernicus University, Torun, Poland. A genetic examination showed a mutation of arginine 555-to-tryptophan (Arg555Trp) in the TGFBI gene that confirmed the clinical diagnosis. Results: SOCT tomograms showed multiple hyperreflective changes throughout the corneal stroma that corresponded to hyaline deposits. Precise and objective assessment of the localization, size, shape, and light scattering properties of the pathologic changes was possible. Three-dimensional rendering of the acquired data allowed a comprehensive evaluation of the deposits in the central cornea. Conclusions: SOCT (830 nm) provides clinically valuable 2- and 3-dimensional assessments of pathomorphologic changes in granular corneal dystrophy in vivo.

Frequency of 22q11.2 microdeletion in children with congenital heart defects in western poland

BackgroundThe 22q11.2 microdeletion syndrome (22q11.2 deletion syndrome -22q11.2DS) refers to congenital abnormalities, including primarily heart defects and facial dysmorphy, thymic hypoplasia, cleft palate and hypocalcaemia. Microdeletion within chromosomal region 22q11.2 constitutes the molecular basis of this syndrome. The 22q11.2 microdeletion syndrome occurs in 1/4000 births. The aim of this study was to determine the frequency of 22q11.2 microdeletion in 87 children suffering from a congenital heart defect (conotruncal or non-conotruncal) coexisting with at least one additional 22q11.2DS feature and to carry out 22q11.2 microdeletion testing of the deleted childrens parents. We also attempted to identify the most frequent heart defects in both groups and phenotypic traits of patients with microdeletion to determine selection criteria for at risk patients.MethodsThe analysis of microdeletions was conducted using fluorescence in situ hybridization (FISH) on metaphase chromosomes and interphase nuclei isolated from venous peripheral blood cultures. A molecular probe (Tuple) specific to the HIRA (TUPLE1, DGCR1) region at 22q11 was used for the hybridisation.ResultsMicrodeletions of 22q11.2 region were detected in 13 children with a congenital heart defect (14.94% of the examined group). Microdeletion of 22q11.2 occurred in 20% and 11.54% of the conotruncal and non-conotruncal groups respectively. Tetralogy of Fallot was the most frequent heart defect in the first group of children with 22q11.2 microdeletion, while ventricular septal defect and atrial septal defect/ventricular septal defect were most frequent in the second group. The microdeletion was also detected in one of the parents of the deleted child (6.25%) without congenital heart defect, but with slight dysmorphism. In the remaining children, 22q11.2 microdeletion originated de novo.ConclusionsPatients with 22q11.2DS exhibit wide spectrum of phenotypic characteristics, ranging from discreet to quite strong. The deletion was inherited by one child. Our study suggests that screening for 22q11.2 microdeletion should be performed in children with conotruncal and non-conotruncal heart defects and with at least one typical feature of 22q11.2DS as well as in the deleted childrens parents.

Severe manifestation of Leber's hereditary optic neuropathy due to 11778G>A mtDNA mutation in a female with hypoestrogenism due to Perrault syndrome.

Perrault syndrome (PS) is a rare autosomal recessive condition with ovarian dysgenesis, hearing deficit and neurological abnormalities in female patients. The molecular basis of the syndrome is heterogeneous, mutations in the HSD17B4 gene have been identified in one family and mutations in the HARS2 gene have been found in another one. We have excluded pathogenic changes in the HSD17B4 gene and in the HARS2 gene by a direct sequencing of all coding exons in a female with clinical hallmarks of PS, ataxia and mild mental retardation. In addition, the patient suffers from severe Lebers hereditary optic neuropathy (LHON) due to 11778G>A mtDNA mutation. This case is the first reported patient with PS and LHON. Possible influence of hypoestrogenism on the manifestation of optic neuropathy in this patient is discussed in the context of recent findings concerning the crucial role of estrogens in supporting the vision capacity in LHON-related mtDNA mutation carriers.

11p13 deletions can be more frequent than the PAX6 gene point mutations in Polish patients with aniridia

Aniridia is a rare, bilateral, congenital ocular disorder causing incomplete formation of the iris, usually characterized by iris aplasia/hypoplasia. It can also appear with other ocular anomalies, such as cataracts, glaucoma, corneal pannus, optic nerve hypoplasia, macular hypoplasia, or ectopia lentis. In the majority of cases, it is caused by mutation in the PAX6 gene, but it can also be caused by microdeletions that involve the 11p13 region. Twelve unrelated patients of Polish origin with a clinical diagnosis of aniridia were screened for the presence of microdeletions in the 11p13 region by means of multiplex ligation probe amplification (MLPA). Additionally, the coding regions of the PAX6 gene were sequenced in all probands. MLPA examination revealed different size deletions of the 11p13 region in five patients. In three cases, deletions encompassed the entire PAX6 gene and a few adjacent genes. In one case, a fragment of the PAX6 gene was deleted only. In the final case, the deletion did not include any PAX6 sequence. Our molecular findings provide further evidence of the existence of the distant 3′ regulatory elements in the downstream region of the PAX6 gene, which is known from other studies to influence the level of protein expression. Sequence analysis of the PAX6 gene revealed the three different point mutations in the remaining four patients with aniridia. All the detected mutations were reported earlier. Based on accomplished results, the great diversity of the molecular basis of aniridia was found. It varies from point mutations to different size deletions in the 11p13 region which encompass partly or completely the PAX6 gene or cause a position effect.

Fundus albipunctatus: review of the literature and report of a novel RDH5 gene mutation affecting the invariant tyrosine (p.Tyr175Phe)

Fundus albipunctatus (FA) is a rare, congenital form of night blindness with rod system impairment, characterised by the presence of numerous small, white-yellow retinal lesions. FA belongs to a heterogenous group of so-called flecked retina syndromes. This disorder shows autosomal recessive inheritance and is caused mostly by mutations in the RDH5 gene. This gene encodes the enzyme that is a part of the visual cycle, the 11-cis retinol dehydrogenase. This study is a brief review of the literature on FA and a report of the first molecular evidence for RDH5 gene mutation in a Polish patient with this rare disorder. We present a novel pathogenic RDH5 gene mutation in a 16-year-old female patient with symptoms of night blindness. The patient underwent ophthalmological examinations, including colour vision testing, fundus photography, automated visual field testing, full-field electroretinography (ERG) and spectral optical coherent tomography (SOCT). The patient showed typical FA ERG records, the visual field was constricted and fundus examination revealed numerous characteristic, small, white-yellowish retinal lesions. DNA sequencing of the RDH5 gene coding sequence (exons 2–5) enabled the detection of the homozygous missense substitution c.524A > T (p.Tyr175Phe) in exon 3. This is the first report of RDH5 gene mutation that affects the invariant tyrosine, one of the most conserved amino acid residues in short-chain alcohol dehydrogenases/reductases (SDRs), crucial for these enzymes’ activity. The location of this substitution, together with its predicted influence on the protein function, indicate that the p.Tyr175Phe mutation is the cause of FA in our patient.

Autosomal recessive cone-rod dystrophy can be caused by mutations in the ATF6 gene

Inherited retinal dystrophies (IRDs) are clinically and genetically highly heterogeneous, making clinical diagnosis difficult. The advances in high-throughput sequencing (ie, panel, exome and genome sequencing) have proven highly effective on defining the molecular basis of these disorders by identifying the underlying variants in the respective gene. Here we report two siblings affected by an IRD phenotype and a novel homozygous c.1691A>G (p.(Asp564Gly)) ATF6 (activating transcription factor 6A) missense substitution identified by whole exome sequencing analysis. The pathogenicity of the variant was confirmed by functional analyses done on patients’ fibroblasts and on recombinant p.(Asp564Gly) protein. The ATF6Asp564Gly/Asp564Gly variant shows impaired production of the ATF6 cleaved transcriptional activator domain in response to endoplasmic reticulum stress. Detailed phenotypic examination revealed extinguished cone responses but also decreased rod responses together with the ability to discriminate some colours suggestive rather for cone-rod dystrophy than achromatopsia.