Current Gene Therapy - Volume 15, Issue 4, 2015

Myotonic Dystrophy (DM), one of the most common neuromuscular disorders in adults, comprises two genetically distinct forms triggered by unstable expanded repeats in non-coding regions. The most common DM1 is caused by expanded CTG repeats in the 3’UTR of the DMPK gene, whereas DM2 is due to large expanded CCTG repeats in the first intron of the CNBP gene. Both mutations induce a pathogenic RNA gain-of-function mechanism. Mutant RNAs containing CUG or CCUG expanded repeats, which are retained in the nuclei as aggregates alter activities of alternative splicing regulators such as MBNL proteins and CELF1. As a consequence, alternative splicing misregulations of several pre-mRNAs are associated with DM clinical symptoms. Currently, there is no available cure for this dominant neuromuscular disease. Nevertheless, promising therapeutic strategies have been developed in the last decade. Preclinical progress in DM research prompted the first DM1 clinical trial based on antisense oligonucleotides promoting a RNase-H-mediated degradation of the expanded CUG transcripts. The ongoing Phase 1/2a clinical trial will hopefully give further insights into the quest to find a bona fide cure for DM1. In this review, we will provide an overview of the different strategies that were developed to neutralize the RNA toxicity in DM1. Different approaches including antisense oligonucleotide technologies, gene therapies or small molecules have been tested and validated in cellular and animal models. Remaining challenges and additional avenues to explore will be discussed.

Glycogen storage disease (GSD) consists of more than 10 discrete conditions for which the biochemical and genetic bases have been determined, and new therapies have been under development for several of these conditions. Gene therapy research has generated proof-of-concept for GSD types I (von Gierke disease) and II (Pompe disease). Key features of these gene therapy strategies include the choice of vector and regulatory cassette, and recently adeno-associated virus (AAV) vectors containing tissue-specific promoters have achieved a high degree of efficacy. Efficacy of gene therapy for Pompe disease depend upon the induction of immune tolerance to the therapeutic enzyme. Efficacy of von Gierke disease is transient, waning gradually over the months following vector administration. Small molecule therapies have been evaluated with the goal of improving standard of care therapy or ameliorating the cellular abnormalities associated with specific GSDs. The receptor-mediated uptake of the therapeutic enzyme in Pompe disease was enhanced by administration of β2 agonists. Rapamycin reduced the liver fibrosis observed in GSD III. Further development of gene therapy could provide curative therapy for patients with GSD, if efficacy from preclinical research is observed in future clinical trials and these treatments become clinically available.

Satellite cells are unipotent stem cells involved in muscle regeneration. However, the skeletal muscle microenvironment exerts a dominant influence over stem cell function. The cell intrinsic complexity of the skeletal muscle niche located within the connective tissue between fibers includes motor neurons, tendons, blood vessels, immune response mediators and interstitial cells. All these cell types modulate the trafficking of stimuli responsible of muscle fiber regeneration. In addition, several stem cell types have been discovered in skeletal muscle tissue, mainly located in the interstitium. The majority of these stem cells appears to directly contribute to myogenic differentiation, although some of them are mainly implicated in paracrine effects. This review focuses on adult stem cells, which have been used for therapeutic purposes, mainly in animal models of chronic muscle degeneration. Emerging literature identifies other myogenic progenitors generated from pluripotent stem cells as potential candidates for the treatment of skeletal muscle degeneration. However, adult stem cells still represent the gold standard for future comparative studies.

Human pluripotent stem cells represent a unique source for cell-based therapies and regenerative medicine. The intrinsic features of these cells such as their easy accessibility and their capacity to be expanded indefinitely overcome some limitations of conventional adult stem cells. Furthermore, the possibility to derive patient-specific induced pluripotent stem (iPS) cells in combination with the current development of gene modification methods could be used for autologous cell therapies of some genetic diseases. In particular, muscular dystrophies are considered to be a good candidate due to the lack of efficacious therapeutic treatments for patients to date, and in view of the encouraging results arising from recent preclinical studies. Some hurdles, including possible genetic instability and their efficient differentiation into muscle progenitors through vector/transgene-free methods have still to be overcome or need further optimization. Additionally, engraftment and functional contribution to muscle regeneration in pre-clinical models need to be carefully assessed before clinical translation. This review offers a summary of the advanced methods recently developed to derive muscle progenitors from pluripotent stem cells, as well as gene therapy by gene addition and gene editing methods using ZFNs, TALENs or CRISPR/Cas9. We have also discussed the main issues that need to be addressed for successful clinical translation of genetically corrected patient-specific pluripotent stem cells in autologous transplantation trials for skeletal muscle disorders.

Since the early days of gene therapy, muscle has been one the most studied tissue targets for the correction of enzyme deficiencies and myopathies. Several preclinical and clinical studies have been conducted using adeno-associated virus (AAV) vectors. Exciting progress has been made in the gene delivery technologies, from the identification of novel AAV serotypes to the development of novel vector delivery techniques. In parallel, significant knowledge has been generated on the host immune system and its interaction with both the vector and the transgene at the muscle level. In particular, the role of underlying muscle inflammation, characteristic of several diseases affecting the muscle, has been defined in terms of its potential detrimental impact on gene transfer with AAV vectors. At the same time, feedback immunomodulatory mechanisms peculiar of skeletal muscle involving resident regulatory T cells have been identified, which seem to play an important role in maintaining, at least to some extent, muscle homeostasis during inflammation and regenerative processes. Devising strategies to tip this balance towards unresponsiveness may represent an avenue to improve the safety and efficacy of muscle gene transfer with AAV vectors.

Duchenne muscular dystrophy (DMD), an X-linked inherited musclewasting disease primarily affecting young boys with prevalence of between1:3,500- 1:5,000, is a rare genetic disease caused by defects in the gene for dystrophin. Dystrophin protein is critical to the stability of myofibers in skeletal and cardiac muscle. There is currently no cure available to ameliorate DMD and/or its patho-physiology. A number of therapeutic strategies including molecular-based therapeutics that replace or correct the missing or nonfunctional dystrophin protein have been devised to correct the patho-physiological consequences induced by dystrophin absence. We will review the current in vivo experimentation status (including preclinical models and clinical trials) for two of these approaches, namely: 1) Adeno-associated virus (AAV) mediated (micro) dystrophin gene augmentation/ supplementation and 2) Antisense oligonucleotide (AON)-mediated exon skipping strategies.

We report on a series of sequential events leading to long-term survival and cure of pediatric X-linked chronic granulomatous disease (X-CGD) patients after gamma-retroviral gene therapy (GT) and rescue HSCT. Due to therapyrefractory life-threatening infections requiring hematopoietic stem cell transplantation (HSCT) but absence of HLAidentical donors, we treated 2 boys with X-CGD by GT. Following GT both children completely resolved invasive Aspergillus nidulans infections. However, one child developed dual insertional activation of ecotropic viral integration site 1 (EVI1) and signal transducer and activator of transcription 3 (STAT3) genes, leading to myelodysplastic syndrome (MDS) with monosomy 7. Despite resistance to mismatched allo-HSCT with standard myeloablative conditioning, secondary intensified rescue allo-HSCT resulted in 100 % donor chimerism and disappearance of MDS. The other child did not develop MDS despite expansion of a clone with a single insertion in the myelodysplasia syndrome 1 (MDS1) gene and was cured by early standard allo-HSCT. The slowly developing dominance of clones harboring integrations in MDS1-EVI1 may guide clinical intervention strategies, i.e. early rescue allo-HSCT, prior to malignant transformation. GT was essential for both children to survive and to clear therapy-refractory infections, and future GT with safer lentiviral self-inactivated (SIN) vectors may offer a therapeutic alternative for X-CGD patients suffering from life-threatening infections and lacking HLA-identical HSC donors.

The difficulty in producing genetically modified human embryonic stem cells (hESCs) limits research on their applications. Virus-based gene transfer is not safe for clinical use, whereas DNAbased non-viral methods are not efficient or safe, and mRNA-based methods are useful for genetic manipulation. In this study, we easily obtained multiple types and large amounts of in vitrosynthesized mRNA by PCR. The efficiency of different transfection methods was studied by flow cytometry. The effect of different mRNA modifications on protein translation efficiency and dynamics of luciferase mRNA expression in hESCs were studied using a bioluminescence imaging system. The pluripotency of hESCs after transfection was studied by immunofluorescence. In vitro-synthesized pancreatic-duodenal homeobox 1 (PDX1) mRNA was used to induce the differentiation of hESCs into insulin-producing cells. We found that electroporation is the most efficient transfection method, and it produces more than 95% transgene expression in multiple hESC lines. Synthesized mRNA with a combination of a polyA tail, cap and base analogues is more efficiently translated into protein in hESCs compared with single-modified mRNA. Transfection of mRNA into hESCs by trypsinizing the cells into single-cell suspensions did not affect their pluripotency, and multiple types of mRNAs can be transfected into hESCs efficiently. We found that PDX-1 mRNA transfection significantly improved the expression level of genes related to beta cells and differentiated cells that express insulin and C-peptide. ELISA analysis validate the insulin secretion of islet-like cell clusters in response to glucose stimulation. Our results indicate that electroporation of in vitro-synthesized mRNA is useful for genetic manipulation of hESCs and differentiation of hESCs into particular cell types, and this finding will pave the way for clinical applications of this method.

Successful normalization of blood glucose in patients transplanted with pancreatic islets isolated from cadaveric donors established the proof-of-concept that Type 1 Diabetes Mellitus is a curable disease. Nonetheless, major caveats to the widespread use of this cell therapy approach have been the shortage of islets combined with the low viability and functional rates subsequent to transplantation. Gene therapy targeted to enhance survival and performance prior to transplantation could offer a feasible approach to circumvent these issues and sustain a durable functional β-cell mass in vivo. However, efficient and safe delivery of nucleic acids to intact islet remains a challenging task. Here we describe a simple and easy-to-use lentiviral transduction protocol that allows the transduction of approximately 80 % of mouse and human islet cells while preserving islet architecture, metabolic function and glucose-dependent stimulation of insulin secretion. Our protocol will facilitate to fully determine the potential of gene expression modulation of therapeutically promising targets in entire pancreatic islets for xenotransplantation purposes.