Development and validation of a model gene therapy biodistribution assay for AVGN7 using digital droplet polymerase chain reaction.

Biodistribution assays are integral to gene therapy commercialization and have traditionally used real-time qPCR. Droplet digital PCR (ddPCR), however, has distinct advantages including higher sensitivity and absolute quantification but is underused because of lacking regulatory guidance and meaningful examples in the literature. We report a fit-for-purpose model process to validate a good laboratory practice (GLP)-compliant ddPCR assay for AVGN7, a Smad7 gene therapeutic for muscle wasting. Duplexed primer/probe sets for Smad7 and mouse TATA-box binding protein were optimized using gBlock DNA over a dynamic range of 10-80,000 copies/reaction in 250 ng mouse gDNA. Linearized plasmid and mouse gDNA were used for validation, which determined precision, accuracy, ruggedness/robustness, selectivity, recovery, specificity, dilution linearity, and stability. Inter-run precision and accuracy met previously established criteria with bias between -5% and 15%, coefficient of variation (CV) less than 19%, and total error within 8%-35%. The limit of detection was 2.5 copies/reaction, linearity was confirmed at 40-80,000 copies/reaction, specificity was demonstrated by single droplet populations and assay stability was demonstrated for benchtop, refrigerated storage, and repeated freeze-thaw cycles. The procedural road map provided exceeds recently established standards. It is also relevant to many IND-enabling processes, as validated ddPCR assays can be used in biodistribution studies and with vector titering and manufacturing quality control.

Brain clusterin protein isoforms and mitochondrial localization.

Clusterin (CLU), or apolipoprotein J (ApoJ), is the third most predominant genetic risk factor associated with late-onset Alzheimer's disease (LOAD). In this study, we use multiple rodent and human brain tissue and neural cell models to demonstrate that CLU is expressed as multiple isoforms that have distinct cellular or subcellular localizations in the brain. Of particular significance, we identify a non-glycosylated 45 kDa CLU isoform (mitoCLU) that is localized to the mitochondrial matrix and expressed in both rodent and human neurons and astrocytes. In addition, we show that rodent mitoCLU is translated from a non-canonical CUG (Leu) start site in Exon 3, a site that coincides with an AUG (Met) in human CLU. Last, we reveal that mitoCLU is present at the gene and protein level in the currently available CLU-/- mouse model. Collectively, these data provide foundational knowledge that is integral in elucidating the relationship between CLU and the development of LOAD.