Martina Cesani

Metachromatic leukodystrophy – mutation analysis provides further evidence of genotype–phenotype correlation

Metachromatic leukodystrophy (MLD) is a rare lysosomal storage disorder resulting from the inherited deficiency of the arylsulfatase A (ARSA) enzyme. Currently, no valid therapeutic options are available for affected patients. A thorough knowledge of disease progression in its diverse clinical variants, together with the identification of reliable prognostic factors, could be instrumental in accurate patient selection for new upcoming therapeutic opportunities, such as enzyme replacement and gene therapy. The described correlation between genotype and clinical presentation proved helpful in predicting patient’s prognosis, only in the minority of MLD patients harboring common mutations. Molecular characterization of a cohort of 26 MLD patients allowed us to identify 18 mutations, excluding the common 0 and R alleles, 10 of which are rare and 8 are novel. By categorizing the rare mutations, we were able to confirm a correlation between ARSA gene mutations, age at onset and patterns of disease progression, not only in those patients bearing common mutations, but also in those carrying rare mutant alleles. Moreover, in the case of absent or delayed molecular diagnosis, or of newly identified mutations, the involvement of peripheral nervous system from disease onset proved to be a sensitive prognostic marker predicting a severe progression.

Human Hematopoietic Stem Cells in Gene Therapy : Pre-Clinical and Clinical Issues

Hematopoietic stem and progenitor cells (HSC) have been widely used in allogeneic transplant procedures, therefore their intrinsic characteristics, the biology of their niche in the bone marrow, and the mobilization and homing processes have been extensively investigated. With the development of gene therapy strategies, new therapeutic options based on autologous HSC have become available which may reduce the morbidity and mortality associated to allogeneic transplantation, but require an ex vivo manipulation of the cells to be corrected before re-infusion. For the success of these approaches it is necessary to optimize culture conditions in order to achieve efficient cell transduction while preserving the biological properties of the stem cells. We review here the factors critical for achieving efficient HSC transduction and maintenance of HSC stemness and homing capacity upon ex vivo culture. When HSC gene therapy is used in genetic disorders, permanent integration of therapeutic genes into the chromosomes of affected cells is needed. Indeed, by use of integrating vectors, such as retroviruses, gene therapy has met significant success in immunodeficiency syndromes characterized by a selective advantage of the transduced cells. However, retroviral integration can take place in stem cells at a variety of chromosomal sites, and examples have been reported of integration of therapeutic vectors causing cancer in patients. The clinical benefit arising from the long-term correction of the genetic defect, due to vector integration into the HSC genome, and the adverse consequences of these events are also here discussed, together with the new and challenging perspectives of HSC gene therapy.

Mutation Update of ARSA and PSAP Genes Causing Metachromatic Leukodystrophy

Metachromatic leukodystrophy is a neurodegenerative disorder characterized by progressive demyelination. The disease is caused by variants in the ARSA gene, which codes for the lysosomal enzyme arylsulfatase A, or, more rarely, in the PSAP gene, which codes for the activator protein saposin B. In this Mutation Update, an extensive review of all the ARSA‐ and PSAP‐causative variants published in the literature to date, accounting for a total of 200 ARSA and 10 PSAP allele types, is presented. The detailed ARSA and PSAP variant lists are freely available on the Leiden Online Variation Database (LOVD) platform at http://www.LOVD.nl/ARSA and http://www.LOVD.nl/PSAP, respectively.

Metallothioneins as dynamic markers for brain disease in lysosomal disorders

To facilitate development of novel disease‐modifying therapies for lysosomal storage disorder (LSDs) characterized by nervous system involvement such as metachromatic leukodystrophy (MLD), molecular markers for monitoring disease progression and therapeutic response are needed. To this end, we sought to identify blood transcripts associated with the progression of MLD.

Shedding of clinical-grade lentiviral vectors is not detected in a gene therapy setting.

Gene therapy using viral vectors that stably integrate into ex vivo cultured cells holds great promises for the treatment of monogenic diseases as well as cancer. However, carry-over of infectious vector particles has been described to occur upon ex vivo transduction of target cells. This, in turn, may lead to inadvertent spreading of viral particles to off-target cells in vivo, raising concerns for potential adverse effects, such as toxicity of ectopic transgene expression, immunogenicity from in vivo transduced antigen-presenting cells and, possibly, gene transfer to germline cells. Here, we have investigated factors influencing the extent of lentiviral vector (LV) shedding upon ex vivo transduction of human hematopoietic stem and progenitor cells. Our results indicate that, although vector carry-over is detectable when using laboratory-grade vector stocks, the use of clinical-grade vector stocks strongly decreases the extent of inadvertent transduction of secondary targets, likely because of the higher degree of purification. These data provide supportive evidence for the safe use of the LV platform in clinical settings.

Critical issues for the proper diagnosis of Metachromatic Leukodystrophy

Metachromatic Leukodystrophy is a lysosomal storage disorder caused by Arylsulfatase A deficiency. Diagnosis is usually performed by measurement of enzymatic activity and/or characterization of the gene mutations. Here we describe a family case in which the determination of enzyme activity alone did not allow diagnosis of the pre-symptomatic sibling of the index case. Only combination of gene sequencing with thorough biochemical analysis allowed the correct diagnosis of the sibling, who was promptly directed to treatment.

Metallothioneins are neuroprotective agents in lysosomal storage disorders: Metallothioneins as Neuroprotective Agents in LSDs

Lysosomal storage disorders (LSDs) are a broad class of inherited metabolic diseases caused by the defective activity of lysosomal enzymes. Central nervous system (CNS) manifestations are present in roughly 50% of LSD patients and represent an unmet medical need for them. We explored the therapeutic potential of metallothioneins (MTs), a newly identified family of proteins with reported neuroprotective roles, in the murine models of two LSDs with CNS involvement.