Petros Petrou

Fras1 deficiency results in cryptophthalmos, renal agenesis and blebbed phenotype in mice.

Loss of tight association between epidermis and dermis underlies several blistering disorders and is frequently caused by impaired function of extracellular matrix (ECM) proteins. Here we describe a new protein in mouse, Fras1, that is specifically detected in a linear fashion underlying the epidermis and the basal surface of other epithelia in embryos. Loss of Fras1 function results in the formation of subepidermal hemorrhagic blisters as well as unilateral or bilateral renal agenesis during mouse embryogenesis. Postnatally, homozygous Fras1 mutants have fusion of the eyelids and digits and unilateral renal agenesis or dysplasia. The defects observed in Fras1−/− mice phenocopy those of the existing bl (blebbed) mouse mutants, which have been considered a model for the human genetic disorder Fraser syndrome. We show that bl/bl homozygous embryos are devoid of Fras1 protein, consistent with the finding that Fras1 is mutated in these mice. In sum, our data suggest that perturbations in the composition of the extracellular space underlying epithelia could account for the onset of the blebbed phenotype in mouse and Fraser syndrome manifestation in human.

Mutually regulated expression of Pax6 and Six3 and its implications for the Pax6 haploinsufficient lens phenotype

Pax6 is a key regulator of eye development in vertebrates and invertebrates, and heterozygous loss-of-function mutations of the mouse Pax6 gene result in the Small eye phenotype, in which a small lens is a constant feature. To provide an understanding of the mechanisms underlying this haploinsufficient phenotype, we evaluated in Pax6 heterozygous mice the effects of reduced Pax6 gene dosage on the activity of other transcription factors regulating eye formation. We found that Six3 expression was specifically reduced in lenses of Pax6 heterozygous mouse embryos. Interactions between orthologous genes from the Pax and Six families have been identified in Drosophila and vertebrate species, and we examined the control of Pax6 and Six3 gene expression in the developing mouse lens. Using in vitro and transgenic approaches, we found that either transcription factor binds regulatory sequences from the counterpart gene and that both genes mutually activate their expression. These studies define a functional relationship in the lens in which Six3 expression is dosage-dependent on Pax6 and where, conversely, Six3 activates Pax6. Accordingly, we show a rescue of the Pax6 haploinsufficient lens phenotype after lens-specific expression of Six3 in transgenic mice. This phenotypic rescue was accompanied by cell proliferation and activation of the platelet-derived growth factor α-R/cyclin D1 signaling pathway. Our findings thus provide a mechanism implicating gene regulatory interactions between Pax6 and Six3 in the tissue-specific defects found in Pax6 heterozygous mice.

Basement Membrane Distortions Impair Lung Lobation and Capillary Organization in the Mouse Model for Fraser Syndrome

Fras1 is a putative extracellular matrix protein that has been implicated in the structural adhesion of embryonic epidermis to dermis. Moreover, mutations in Fras1/FRAS1 have been associated with the mouse blebbed phenotype and the human rare genetic disorder Fraser syndrome, respectively. Here we report the mapping of Fras1 within the extracellular space and evaluate the effects of Fras1 deficiency on lung development in the mouse. Expression of Fras1 was detected in the mesothelial cells of the visceral pleura and in the conducting airway epithelia. Immunogold histochemistry identified Fras1 as a component of the extracellular matrix localized below the lamina densa of epithelial basement membranes in the embryonic lung. Embryos homozygous for a targeted mutation of Fras1 exhibited fused pulmonary lobes resulting from incomplete separation during development as well as a profound disarrangement of blood capillaries in the terminal air sacs. We demonstrate that loss of Fras1 causes alterations in the molecular composition of basement membranes, concomitant with local disruptions of epithelial-endothelial contacts and extravasation of erythrocytes into the embryonic respiratory lumen. Thus, our findings identify Fras1 as an important structural component of the sub-lamina densa of basement membranes required for lobar septation and the organization of blood capillaries in the peripheral lung.

Mouse Stbd1 is N-myristoylated and affects ER-mitochondria association and mitochondrial morphology

ABSTRACT Starch binding domain-containing protein 1 (Stbd1) is a carbohydrate-binding protein that has been proposed to be a selective autophagy receptor for glycogen. Here, we show that mouse Stbd1 is a transmembrane endoplasmic reticulum (ER)-resident protein with the capacity to induce the formation of organized ER structures in HeLa cells. In addition to bulk ER, Stbd1 was found to localize to mitochondria-associated membranes (MAMs), which represent regions of close apposition between the ER and mitochondria. We demonstrate that N-myristoylation and binding of Stbd1 to glycogen act as major determinants of its subcellular targeting. Moreover, overexpression of non-myristoylated Stbd1 enhanced the association between ER and mitochondria, and further induced prominent mitochondrial fragmentation and clustering. Conversely, shRNA-mediated Stbd1 silencing resulted in an increase in the spacing between ER and mitochondria, and an altered morphology of the mitochondrial network, suggesting elevated fusion and interconnectivity of mitochondria. Our data unravel the molecular mechanism underlying Stbd1 subcellular targeting, support and expand its proposed function as a selective autophagy receptor for glycogen and uncover a new role for the protein in the physical association between ER and mitochondria. Highlighted Article: The glycogen-binding protein Stbd1 is N-myristoylated and targeted to ER–mitochondria contact sites. Stbd1 loss- or gain-of-function affects ER–mitochondria association and mitochondrial morphology.

A Novel Large Deletion Encompassing the Whole of the Galactose-1-Phosphate Uridyltransferase ( GALT ) Gene and Extending into the Adjacent Interleukin 11 Receptor Alpha ( IL11RA ) Gene Causes Classic Galactosemia Associated with Additional Phenotypic Abnormalities

Objective The characterization of a novel large deletion in the galactose-1-phosphate uridyltransferase (GALT) gene accounting for the majority of disease alleles in Cypriot patients with classic galactosemia. Methods DNA sequencing was used to identify the mutations followed by multiplex ligation-dependent probe amplification (MLPA) analysis in the cases suspected of harboring a deletion. In order to map the breakpoints of the novel deletion, a PCR walking approach was employed. A simple PCR assay was validated for diagnostic testing for the new deletion. Haplotype analysis was performed using microsatellite markers in the chromosomal region 9p. RT-PCR was used to study RNA expression in lymphoblastoid cell lines. Results The new deletion spans a region of 8489 bp and eliminates all GALT exons as well as the non-translated sequences of the adjacent interleukin 11 receptor alpha (IL11RA) gene. In addition, the deletion is flanked by a 6 bp block of homologous sequence on either side suggesting that a single deletion event has occurred, probably mediated by a recombination mechanism. Microsatellite marker analysis revealed the existence of a common haplotype. The RNA expression studies showed a lack of IL11RA transcripts in patients homozygous for the deletion. Conclusions We have identified and characterized a novel contiguous deletion which affects both the GALT enzyme and the IL11RA protein resulting in classic galactosemia with additional phenotypic abnormalities such as craniosynostosis, a feature that has been associated with defects in the IL11RA gene.

Minimally symptomatic mcardle disease, expanding the genotype–phenotype spectrum

Introduction: We report the clinical, biochemical, and molecular findings in a Cypriot family with minimally symptomatic McArdle disease. Methods: Myophosphorylase in muscle was assessed by histochemistry, quantitative spectrophotometry, and western blot analysis. Mutation identification was performed by PCR amplification of all PYGM exons, followed by bidirectional sequencing. Screening for the new mutation was performed by restriction enzyme analysis. Results: We found that a novel c.1151C>T transition in exon 10 of the myophosphorylase gene (PYGM) is associated with minimally symptomatic McArdle disease. Homozygous carriers displayed an ischemic exercise response characterized by a blunted increase in post‐exercise blood lactate levels in conjunction with an exaggerated increase in ammonia. Myophosphorylase activity in muscle was 3.75% of normal, whereas the size and abundance of the enzyme were unaffected. Conclusions: These findings expand the genotype–phenotype spectrum of McArdle disease and suggest that enzymatic activity as low as 4% may be sufficient to ameliorate the phenotype. Muscle Nerve 52: 891–895, 2015

Chitotriosidase deficiency in the Cypriot population: Identification of a novel deletion in the CHIT1 gene

OBJECTIVES The purpose of this study was to determine the normal range of chitotriosidase activity in the Cypriot population and the frequency of the 24bp duplication polymorphism. Furthermore, we compared the allele frequency of this polymorphism in two locations with different malaria endemicity in the past. DESIGN AND METHODS Plasma chitotriosidase activity was measured using a fluorogenic substrate. The 24bp polymorphism was detected using PCR analysis of exon 10 of the CHIT1 gene. Additional mutations were detected using direct sequencing. RESULTS The normal range of chitotriosidase activity was found to be 9.5-44.0nmol/ml/hr. Among 114 normal individuals genotyped for the 24bp duplication, 7% were found to be homozygous, 36% heterozygous and 57% wild type (allele frequency 0.25). The allele frequency of this polymorphism in individuals originating from two locations with different malaria endemicity in the past was not significantly different. A novel deletion mutation in the CHIT1 gene was identified associated with loss of chitotriosidase activity. This new deletion eliminates 29 nucleotides from exon 9 resulting in the generation of a premature stop codon, probably leading to the production of an aberrant protein molecule. CONCLUSIONS The normal range of chitotriosidase activity and the allele frequency of the 24bp duplication polymorphism in the Cypriot population were found to be similar to those of other Mediterranean populations. No evidence for an association between the presence of the 24bp duplication polymorphism and susceptibility to malaria was found. A novel deletion in exon 9 of the CHIT1 gene was identified (allele frequency 0.01).

The “sweet” side of ER-mitochondria contact sites

ABSTRACT The regions at which the ER and mitochondria come into close proximity, known as ER-mitochondria contact sites provide essential platforms for the exchange of molecules between the two organelles and the coordination of various fundamental cellular processes. In addition to the well-established role of ER-mitochondria interfaces in calcium and lipid crosstalk, emerging evidence supports that a proper communication between ER and mitochondria is critical for the regulation of mitochondrial morphology and the initiation of autophagy. Within this context, our recent data indicate that glycogen is targeted to ER-mitochondria contacts through the Stbd1 protein, a proposed autophagy receptor for glycogen. Glycogen-bound Stbd1 influences ER-mitochondria tethering and the morphology of the mitochondrial network. We here suggest possible roles of glycogen recruitment to ER-mitochondria contact sites. Stbd1-mediated targeting of glycogen to ER-mitochondria junctions could represent a mechanism through which glycogen is sequestered into autophagosomes for lysosomal degradation, a process described as glycogen autophagy or glycophagy. Additionally, we discuss a possible mechanism which links the observed effects of Stbd1 on mitochondrial morphology with the previously reported impact of nutrient availability on mitochondrial dynamics. In this model we propose that glycogen-bound Stbd1 signals nutrient status to ER-mitochondria junctions resulting in adaptations in the morphology of the mitochondrial network.