Screening of Chimeric GAA Variants in a Preclinical Study of Pompe Disease Results in Candidate Vector for Hematopoietic Stem Cell Gene Therapy

Pompe disease is a rare genetic neuromuscular disorder caused by acid alpha-glucosidase (GAA) deficiency resulting in lysosomal glycogen accumulation and progressive myopathy. Enzyme replacement therapy (ERT) is the current standard of care, which prolongs the quality of life for Pompe patients. However, ERT has limitations due to lack of enzyme penetration into the central nervous system (CNS) and skeletal muscles, immunogenicity against the recombinant enzyme, and requires life-long biweekly infusions. In a preclinical mouse model, a clinically relevant promoter to drive lentiviral vector-mediated expression of engineered GAA in autologous hematopoietic stem and progenitor cells (HSPC) was tested with nine unique human chimeric GAA coding sequences incorporating distinct peptide tags and codon-optimization iterations. Vectors including glycosylation independent lysosomal targeting (GILT) tags resulted in effective GAA enzyme delivery into key disease tissues with enhanced reduction of glycogen, myofiber and CNS vacuolation, compared to non-tagged GAA in Gaa knockout mice, a model of Pompe disease. Genetically modified microglial cells in brains were detected at low levels, but provided robust correction. Furthermore, an aminoacid substitution in the tag added to reduced capacity to induce insulin signaling and there was no evidence of off-target effects. This study demonstrated the therapeutic potential of lentiviral HSPC gene therapy exploiting optimized GAA tagged coding sequences to reverse Pompe disease pathology in a preclinical mouse model providing a promising vector candidate for further investigation.

Selective screening and molecular characteristics of Russian patients with Pompe disease

Introduction. Pompe disease (PD) or type II glycogenosis is a rare multisystem hereditary accumulation disease caused by a deficiency of the enzyme acid maltase (acid alpha-1,4-glucosidase), which leads to reduced activity to the accumulation of glycogen in various organs and tissues of the body. The aim of the study is to develop a high-performance method of early biochemical diagnosis of PD and optimization of its molecular genetic diagnosis. Materials and methods. The characteristics of the relative frequencies and spectrum of the detected mutations were studied using a sample of 7670 patients with suspected Pompe disease admitted to the National Medical Research Center of Children’s Health of the Ministry of Health of Russia as part of the selective screening, as well as eight patients with PD, whose laboratory diagnosis was made outside the framework of this selective screening. Results. As a result of selective screening of PD in Russian patients from high-risk groups, the detectability was 0.47%. PD’s clinical and age characteristics in both children and adults are described. The relative frequencies are calculated, and the spectrum of 47 pathogenic variants of the GAA gene responsible for the occurrence and development of Pompe disease in 44 patients is characterized. Seventeen new mutations of the GAA gene, unknown previously, have been identified and described, adding 2.7% to the HGMD database. Conclusion. Optimization of the algorithm of molecular diagnosis of Pompe disease in Russian patients is proposed.

The Action of Recombinant Human Lysosomal α-Glucosidase (rhGAA) on Human Liver Glycogen: Pathway to Complete Degradation

Glycogen is present in all tissues, but it is primarily stored in the liver and in muscle. As a branched chain carbohydrate, it is broken down by phosphorylase and debrancher enzymes, which are cytoplasmic. It is also degraded by a lysosomal α-glucosidase (GAA) also known as acid α-glucosidase and lysosomal acid α-glucosidase. The deficiency of GAA in patients is known as Pompe disease, and the phenotypes as infantile, juvenile and later onset forms. Pompe disease is treated by enzyme replacement therapy (ERT) with a recombinant form of rhGAA. Following ERT in Pompe mice and human patients there is residual carbohydrate material present in the cytoplasm of cells. The goal of this work is to improve ERT and attempt to identify and treat the residual cytoplasmic carbohydrate. Initial experiments were to determine if rhGAA can completely degrade glycogen. The enzyme cannot completely degrade glycogen. There is a residual glycosylated protein as well as a soluble glycosylated protein, which is a terminal degradation product of glycogen and as such serves as a biomarker for lysosomal glycogen degradation. The glycosylated protein has a very unusual carbohydrate composition for a glycosylated protein: m-inositol, s-inositol and sorbitol as the major carbohydrates, as well as mannitol, mannose, glucose and galactose. This work describes the residual material which likely contains the same protein as the soluble glycosylated protein. The biomarker is present in serum of control and Pompe patients on ERT, but it is not present in the serum of Pompe mice not on ERT. Pompe mice not on ERT have another glycosylated protein in their serum which may be a biomarker for Pompe disease. This protein has multiple glycosylation sites, each with different carbohydrate components. These glycosylated proteins as well as the complexity of glycogen structure are discussed, as well as future directions to try to improve the outcome of ERT for Pompe patients by being able to monitor the efficacy of ERT in the short term and possibly to adjust the timing and dose of enzyme infusions.

Case Report: Anesthetic Management and Electrical Cardiometry as Intensive Hemodynamic Monitoring During Cheiloplasty in an Infant With Enzyme-Replaced Pompe Disease and Preserved Preoperative Cardiac Function

Introduction: Pompe disease is caused by deficiency of the lysosomal enzyme acid α-glucosidase, which results in cardiac and muscular complications that can jeopardize perioperative outcomes. We report a 4-month-old infant with Pompe disease receiving cheiloplasty under general anesthesia with the aid of peripheral nerve blocks and intensive hemodynamic monitoring.Case Description: This case report describes a 4-month-old full-term Taiwanese female infant who presented with left unilateral cleft lip and palate in the prenatal examination. She was diagnosed with infantile-onset Pompe disease after acidic α-glucosidase (GAA) gene sequencing. She also received enzyme replacement therapy (ERT) 15 days after birth and regular ERT every other week. Cheiloplasty was performed under general anesthesia uneventfully, and peripheral nerve blocks were adopted for analgesia. Intensive hemodynamic monitoring using electrical cardiometry technology (ICON®) and pulse contour analysis (FloTrac system) were applied during the operation. No adverse effects were observed, and the wound healed well. Therefore, the patient was discharged 4 days after surgery.Conclusion: With the availability of ERT, severe organ dysfunction in infantile-onset Pompe disease patients is no longer common. However, moderate cardiac depression can still occur while increasing inspiratory pressure and deepening the anesthesia level despite a normal preoperative echocardiogram report. Therefore, careful, gradual titration is desirable. Furthermore, electrical cardiometry can detect hemodynamic changes more instantaneously and reliably than pulse contour analysis. In addition, we suggest taking advantage of the peripheral nerve block as a part of balanced anesthesia to alleviate the cardiac suppression caused by general anesthesia.