Usher syndrome type IV: clinically and molecularly confirmed by novel ARSG variants.

Usher syndrome (USH) is an autosomal recessively inherited disease characterized by sensorineural hearing loss (SNHL) and retinitis pigmentosa (RP) with or without vestibular dysfunction. It is highly heterogeneous both clinically and genetically. Recently, variants in the arylsulfatase G (ARSG) gene have been reported to underlie USH type IV. This distinct type of USH is characterized by late-onset RP with predominantly pericentral and macular changes, and late onset SNHL without vestibular dysfunction. In this study, we describe the USH type IV phenotype in three unrelated subjects. We identified three novel pathogenic variants, two novel likely pathogenic variants, and one previously described pathogenic variant in ARSG. Functional experiments indicated a loss of sulfatase activity of the mutant proteins. Our findings confirm that ARSG variants cause the newly defined USH type IV and support the proposed extension of the phenotypic USH classification.

New clinical and molecular evidence linking mutations in ARSG to Usher syndrome type IV.

In murine and canine animal models, mutations in the Arylsulfatase G gene (ARSG) cause a particular lysosomal storage disorder characterized by neurological phenotypes. Recently, two variants in the same gene were found to be associated with an atypical form of Usher syndrome in humans, leading to visual and auditory impairment without the involvement of the central nervous system. In this study, we identified three novel pathogenic variants in ARSG, which segregated recessively with the disease in two families from Portugal. The probands were affected with retinitis pigmentosa and sensorineural hearing loss, generally with an onset of symptoms in their fourth decade of life. Functional experiments showed that these pathogenic variants abolish the sulfatase activity of the Arylsulfatase G enzyme and impede the appropriate lysosomal localization of the protein product, which appears to be retained in the endoplasmic reticulum. Our data enable to definitely confirm that different biallelic variants in ARSG cause a specific deaf-blindness syndrome, by abolishing the activity of the enzyme it encodes.

Development of thermo-reporting nanoparticles for accurate sensing of geothermal reservoir conditions.

The inaccessibility of geological reservoirs, both for oil and gas production or geothermal usage, makes detection of reservoir properties and conditions a key problem in the field of reservoir engineering, including for the development of geothermal power plants. Herein, an approach is presented for the development of messenger nanoparticles for the determination of reservoir conditions, with a proof of concept example of temperature detection under controlled laboratory conditions. Silica particles are synthesized with a two-layer architecture, an inner enclosed core and an outer porous shell, each doped with a different fluorescent dye to create a dual emission system. Temperature detection happens by a threshold temperature-triggered irreversible release of the outer dye, thus changing the fluorescence signal of the particles. The reported particle system consequently enables a direct, reliable and fast way to determine reservoir temperature. It also displays a sharp threshold for accurate sensing and allows detection at concentration ranges as low as few nanograms of nanoparticles per milliliter.

Substrate determinants of signal peptide peptidase-like 2a (SPPL2a)-mediated intramembrane proteolysis of the invariant chain CD74.

The presenilin homologue signal peptide peptidase-like 2a (SPPL2a) is an intramembrane protease of lysosomes/late endosomes which cleaves type II transmembrane proteins. We recently identified CD74, the invariant chain of the MHCII complex, as the first in vivo validated substrate of this protease. In endosomal compartments, CD74 undergoes sequential proteolysis leading to the generation of a membrane-bound N-terminal fragment (NTF) that requires cleavage by SPPL2a for its turnover. In SPPL2a(-/-) mice, this fragment accumulates in B-cells and significantly disturbs their maturation and functionality. To date, the substrate requirements of the protease SPPL2a have not been investigated. In the present study, we systematically analysed the molecular determinants of CD74 with regard to the intramembrane cleavage by SPPL2a. Using domain-exchange experiments, we demonstrate that the intracellular domain (ICD) of CD74 can be substituted without affecting cleavability by SPPL2a. Based on IP-MS analysis of the cleavage product, we report identification of the primary SPPL2a cleavage site between Y52 and F53 within the CD74 transmembrane segment. Furthermore, systematic alanine-scanning mutagenesis of the transmembrane and membrane-proximal parts of the CD74 NTF has been performed. We show that none of the analysed determinants within the CD74 NTF including the residues flanking the primary cleavage site are absolutely essential for SPPL2a cleavage. Importantly, we found that alanine substitution of helix-destabilizing glycines within the transmembrane segment and distinct residues within the luminal membrane-proximal segment led to a reduced efficiency of SPPL2a-mediated processing. Therefore we propose that elements within the transmembrane segment and the luminal juxtamembrane domain facilitate intramembrane proteolysis of CD74 by SPPL2a.