👤 Christian Brendel

In Alzheimer's disease, carriage of the ApoE4 risk allele is linked to faster tau accumulation at lower amyloid-PET levels, thereby accelerating disease progression. However, it remains unclear whether this ApoE4-facilitated transition from amyloidosis to tauopathy is mechanistically promoted by increased secretion of phosphorylated (p)tau, a key intermediate that drives the amyloid-to-tauopathy transition, or alternatively by increased ptau-driven tau aggregation. Therefore, we investigated where along the amyloid-to-tau axis ApoE4 accelerates tau aggregation and assessed i) whether ApoE4 increases ptau secretion or ii) whether ApoE4 increases ptau-associated tau aggregation. To this end, we analysed two large-scale APOE-genotyped cohorts covering the full Alzheimer's disease spectrum (ADNI: n=201) as well as a preclinical cohort (A4-LEARN: n=200), integrating baseline amyloid-PET, plasma ptau217 and CSF ptau181 with longitudinal tau-PET. Using linear regression, we tested whether ApoE4-carriage moderates i) amyloid-PET-associated plasma ptau217 increases or ii) ptau217-associated tau spreading from local epicentres across patient-tailored tau spreading stages. All analyses were independently validated across both cohorts, including an additional replication in an ADNI subset (n=115) with available CSF ptau181 measures as an alternative marker of ptau secretion. Finally, we used logistic regression to determine ApoE4 allele count-stratified plasma ptau217 thresholds marking early pathological tau-PET increases. We found that ApoE4 did not facilitate amyloid-PET-associated ptau increases, suggesting that amyloid-related ptau secretion is not altered by ApoE4-carriage. Contrastingly, we found that plasma ptau217 elevations were linked to faster tau-PET spread from local epicentres across connected brain regions in an ApoE4-allele dose-dependent manner, independent of amyloid (ADNI/A4-LEARN: mean β=0.44/0.56, p<0.001/<0.001). Lastly, we found that a higher ApoE4 allele count was linked to lower ptau217 thresholds marking transition to tauopathy, i.e. early abnormal tau-PET increases, consistently across both samples (ADNI: 0/1/2 ApoE4 alleles=0.62/0.34/0.15pg/ml, representing ∼45% and ∼76% reductions from non-carriers; Fujirebio ptau217 assay; A4/LEARN: 0/1/2 ApoE4 alleles=0.31/0.23/0.18pg/ml, representing ∼26% and ∼42% reductions; Eli Lilly ptau217 assay). These findings suggest that ApoE4, i.e. the key genetic risk factor for sporadic Alzheimer's disease, facilitates amyloid-dependent tau aggregation in an allele dose-dependent manner by enhancing the ptau-driven spread of fibrillar tau, leading to an earlier transition from amyloidosis to tauopathy at lower ptau217 levels. This has implications for plasma ptau-based screening approaches and therapeutic timing of anti-amyloid drugs in ApoE4 carriers: Specifically, ApoE4 carriers may require genotype-adjusted ptau thresholds to detect Alzheimer's disease pathophysiology, as well as anti-amyloid treatment at lower ptau levels to prevent the transition to tauopathy, which ultimately drives neurodegeneration and cognitive decline. Show less

All clinical BACE1-inhibitor trials for the treatment of Alzheimer's Disease (AD) have failed due to insufficient efficacy or side effects like worsening of cognitive symptoms. However, the scientific evidence to date suggests that BACE1-inhibition could be an effective preventative measure if applied prior to the accumulation of amyloid-beta (Aβ)-peptide and resultant impairment of synaptic function. Preclinical studies have associated BACE1-inhibition-induced cognitive deficits with decreased dendritic spine density. Therefore, we investigated dose-dependent effects of BACE1-inhibition on hippocampal dendritic spine dynamics in an APP knock-in mouse line for the first time. We conducted Show less

Retrovirus-based vectors are commonly used as delivery vehicles to correct genetic diseases because of their ability to integrate new sequences stably. However, adverse events in which vector integration activates proto-oncogenes, leading to clonal expansion and leukemogenesis hamper their application. The host cell-encoded lens epithelium-derived growth factor (LEDGF/p75) binds lentiviral integrase and targets integration to active transcription units. We demonstrated earlier that replacing the LEDGF/p75 chromatin interaction domain with an alternative DNA-binding protein could retarget integration. Here, we show that transient expression of the chimeric protein using mRNA electroporation efficiently redirects lentiviral vector (LV) integration in wild-type (WT) cells. We then employed this technology in a model for X-linked chronic granulomatous disease (X-CGD) using myelomonocytic PLB-985 gp91(-/-) cells. Following electroporation with mRNA encoding the LEDGF-chimera, the cells were treated with a therapeutic lentivector encoding gp91(phox). Integration site analysis revealed retargeted integration away from genes and towards heterochromatin-binding protein 1β (CBX1)-binding sites, in regions enriched in marks associated with gene silencing. Nevertheless, gp91(phox) expression was stable for at least 6 months after electroporation and NADPH-oxidase activity was restored to normal levels as determined by superoxide production. Together, these data provide proof-of-principle that transient expression of engineered LEDGF-chimera can retarget lentivector integration and rescues the disease phenotype in a cell model, opening perspectives for safer gene therapy.Molecular Therapy - Nucleic Acids (2013) 2, e77; doi:10.1038/mtna.2013.4; published online 5 March 2013. Show less