Developing gene therapies for rare diseases: an interview with Geoff MacKay

Geoff MacKay is a pioneer in cell and gene therapy with a track record of successful leadership at innovative biotechs. He is currently the president and CEO of AVROBIO, a clinical-stage lentiviral gene therapy company that treats lysosomal disorders, and a board member of Talaris Therapeutics and Satellos Bioscience. He is also the founding CEO of eGenesis, a biotech that applies CRISPR-Cas9 gene editing to xenotransplantation and the former president and CEO of Organogenesis, a world-leading cell therapy company. Earlier in his career, MacKay spent 11 years at Novartis in senior leadership positions within the global transplantation and immunology franchise.

Cardiac Manifestations in a Group of Romanian Patients with Gaucher Disease Type 1 (a Monocentric Study)

Gaucher disease (GD), one of the most common lysosomal disorders, is characterised by clinical heterogeneity. Cardiac involvement is rare and refers to pulmonary hypertension (PH), valvular abnormalities and myocardial infiltrative damage. The aim of this study was to evaluate cardiac involvement in a group of Romanian GD patients. Phenotypic and genotypic characterisation was carried out in 69 patients with GD type 1. Annual echocardiography and electrocardiography were performed to assess pulmonary pressure, morphology and function of the valves and electrocardiographic changes. Nine patients (13%) exhibited baseline echocardiographic signs suggesting PH. Mitral regurgitation was present in 33 patients (48%) and aortic regurgitation in 11 patients (16%). One patient presented aortic stenosis. Significant valvular dysfunction was diagnosed in 10% of patients. PH was associated with greater age (p < 0.001), longer time since splenectomy (p = 0.045) and longer time between clinical onset and the start of enzyme replacing therapy (p < 0.001). Electrocardiographic changes were present in five patients (7%).

The Role of Exosomes in Lysosomal Storage Disorders

Exosomes, small membrane-bound organelles formed from endosomal membranes, represent a heterogenous source of biological and pathological biomarkers capturing the metabolic status of a cell. Exosomal cargo, including lipids, proteins, mRNAs, and miRNAs, can either act as inter-cellular messengers or are shuttled for autophagic/lysosomal degradation. Most cell types in the central nervous system (CNS) release exosomes, which serve as long and short distance communicators between neurons, astrocytes, oligodendrocytes, and microglia. Lysosomal storage disorders are diseases characterized by the accumulation of partially or undigested cellular waste. The exosomal content in these diseases is intrinsic to each individual disorder. Emerging research indicates that lysosomal dysfunction enhances exocytosis, and hence, in lysosomal disorders, exosomal secretion may play a role in disease pathogenesis. Furthermore, the unique properties of exosomes and their ability to carry cargo between adjacent cells and organs, and across the blood–brain barrier, make them attractive candidates for use as therapeutic delivery vehicles. Thus, understanding exosomal content and function may have utility in the treatment of specific lysosomal storage disorders. Since lysosomal dysfunction and the deficiency of at least one lysosomal enzyme, glucocerebrosidase, is associated with the development of parkinsonism, the study and use of exosomes may contribute to an improved understanding of Parkinson disease, potentially leading to new therapeutics.

Next-Generation Molecular Investigations in Lysosomal Diseases: Clinical Integration of a Comprehensive Targeted Panel

Diagnosis of lysosomal disorders (LDs) may be hampered by their clinical heterogeneity, phenotypic overlap, and variable age at onset. Conventional biological diagnostic procedures are based on a series of sequential investigations and require multiple sampling. Early diagnosis may allow for timely treatment and prevent clinical complications. In order to improve LDs diagnosis, we developed a capture-based next generation sequencing (NGS) panel allowing the detection of single nucleotide variants (SNVs), small insertions and deletions, and copy number variants (CNVs) in 51 genes related to LDs. The design of the LD panel covered at least coding regions, promoter region, and flanking intronic sequences for 51 genes. The validation of this panel consisted in testing 21 well-characterized samples and evaluating analytical and diagnostic performance metrics. Bioinformatics pipelines have been validated for SNVs, indels and CNVs. The clinical output of this panel was tested in five novel cases. This capture-based NGS panel provides an average coverage depth of 474× which allows the detection of SNVs and CNVs in one comprehensive assay. All the targeted regions were covered above the minimum required depth of 30×. To illustrate the clinical utility, five novel cases have been sequenced using this panel and the identified variants have been confirmed using Sanger sequencing or quantitative multiplex PCR of short fluorescent fragments (QMPSF). The application of NGS as first-line approach to analyze suspected LD cases may speed up the identification of alterations in LD-associated genes. NGS approaches combined with bioinformatics analyses, are a useful and cost-effective tool for identifying the causative variations in LDs.

The lysosomal chloride-proton exchanger CLC7 functions in melanosomes as a negative regulator of human pigmentation

Mutations in the Cl−/H+ exchanger CLC7 and its subunit OSTM1 result in osteopetrosis, lysosomal disorders, and pigmentation defects in mice and humans. How CLC7/OSTM1 regulates pigmentation in skin and hair melanocytes remains unexplored. In human epidermal melanocytes, we found CLC7/OSTM1 localized to melanosomes, the organelles in which melanin is synthesized, where it negatively regulates melanin production. Using a novel ratiometric melanosomal pH indicator, we showed that CLC7 acidifies melanosomes, opposing the function of the oculocutaneous albinism II (OCA2) Cl− ion channel. The de novo CLC7 variant (CLC7-Y715C) that causes albinism in humans and mice, decreased melanocytes pigmentation, which was restored by coexpression of OCA2. Remarkably, the enlarged hyperacidic vacuoles caused by CLC7-Y715C were also rescued by OCA2 coexpression in both melanocytes and non-melanocytic cells. Our data uncover a novel mechanism by which CLC7 regulates melanocyte pigmentation and identifies OCA2 as a tool to counteract the effects of CLC7 activating mutations.