Transcriptional dysregulation of inflammatory/immune pathways after active vaccination against Huntington's disease.

Immunotherapy, both active and passive, is increasingly recognized as a powerful approach to a wide range of diseases, including Alzheimer's and Parkinson's. Huntington's disease (HD), an autosomal dominant disorder triggered by misfolding of huntingtin (HTT) protein with an expanded polyglutamine tract, could also benefit from this approach. Individuals can be identified genetically at the earliest stages of disease, and there may be particular benefits to a therapy that can target peripheral tissues in addition to brain. In this active vaccination study, we first examined safety and immunogenicity for a broad series of peptide, protein and DNA plasmid immunization protocols, using fragment (R6/1), and knock-in (zQ175) models. No safety issues were found. The strongest and most uniform immune response was to a combination of three non-overlapping HTT Exon1 coded peptides, conjugated to KLH, delivered with alum adjuvant. An N586-82Q plasmid, delivered via gene gun, also showed ELISA responses, mainly in the zQ175 strain, but with more variability, and less robust responses in HD compared with wild-type controls. Transcriptome profiling of spleens from the triple peptide-immunized cohort showed substantial HD-specific differences including differential activation of genes associated with innate immune responses, absence of negative feedback control of gene expression by regulators, a temporal dysregulation of innate immune responses and transcriptional repression of genes associated with memory T cell responses. These studies highlight critical issues for immunotherapy and HD disease management in general.