Core transcriptional regulatory circuits in prion diseases.

Complex diseases involve dynamic perturbations of pathophysiological processes during disease progression. Transcriptional programs underlying such perturbations are unknown in many diseases. Here, we present core transcriptional regulatory circuits underlying early and late perturbations in prion disease.

Genotype-specific differences between mouse CNS stem cell lines expressing frontotemporal dementia mutant or wild type human tau.

Stem cell (SC) lines that capture the genetics of disease susceptibility provide new research tools. To assess the utility of mouse central nervous system (CNS) SC-containing neurosphere cultures for studying heritable neurodegenerative disease, we compared neurosphere cultures from transgenic mice that express human tau with the P301L familial frontotemporal dementia (FTD) mutation, rTg(tau(P301L))4510, with those expressing comparable levels of wild type human tau, rTg(tau(wt))21221. rTg(tau(P301L))4510 mice express the human tau(P301L) variant in their forebrains and display cellular, histological, biochemical and behavioral abnormalities similar to those in human FTD, including age-dependent differences in tau phosphorylation that distinguish them from rTg(tau(wt))21221 mice.

Down-regulation of Shadoo in prion infections traces a pre-clinical event inversely related to PrP(Sc) accumulation.

During prion infections of the central nervous system (CNS) the cellular prion protein, PrP(C), is templated to a conformationally distinct form, PrP(Sc). Recent studies have demonstrated that the Sprn gene encodes a GPI-linked glycoprotein Shadoo (Sho), which localizes to a similar membrane environment as PrP(C) and is reduced in the brains of rodents with terminal prion disease. Here, analyses of prion-infected mice revealed that down-regulation of Sho protein was not related to Sprn mRNA abundance at any stage in prion infection.

Development of targeted recombinant polymers that can deliver siRNA to the cytoplasm and plasmid DNA to the cell nucleus.

One of the major limitations to effective siRNA delivery is the lack of a siRNA-specific delivery system. Currently, the same delivery systems that are used for plasmid DNA (pDNA) delivery to the cell nucleus are used for siRNA delivery to the cytoplasm. To fill this gap, the objective of this study was to design a biopolymer that can be programmed via its amino acid sequence to deliver siRNA specifically to cytoplasm.

Evaluation of a multi-functional nanocarrier for targeted breast cancer iNOS gene therapy.

The present study determines whether the novel designer biomimetic vector (DBV) can condense and deliver the cytotoxic iNOS gene to breast cancer cells to achieve a therapeutic effect. We have previously shown the benefits of iNOS for cancer gene therapy but the stumbling block to future development has been the delivery system. The DBV was expressed, purified and complexed with the iNOS gene.

Development of recombinant cationic polymers for gene therapy research.

Cationic polymers created through recombinant DNA technology have the potential to fill a void in the area of gene delivery. The recombinant cationic polymers to be discussed here are amino acid based polymers synthesized in E. coli with the purpose to not only address the major barriers to efficient gene delivery but offer safety, biodegradability, targetability and cost-effectiveness.

Perspectives in vector development for systemic cancer gene therapy.

Gene therapy is perceived as a revolutionary technology with the promise to cure almost any disease, provided that we understand its genetic basis. However, enthusiasm has rapidly abated as multiple clinical trials have failed to show efficacy. The limiting factor seems to be the lack of a suitable delivery system to carry the therapeutic genes to the target tissue safely and efficiently.

Development of a genetically engineered biomimetic vector for targeted gene transfer to breast cancer cells.

A biomimetic vector was genetically engineered to contain at precise locations (a) an adenovirus mu peptide to condense pDNA into nanosize particles, (b) a synthetic cyclic peptide to target breast cancer cells and enhance internalization of nanoparticles, (c) a pH-responsive synthetic fusogenic peptide to disrupt endosome membranes and facilitate escape of the nanoparticles into the cytosol, and (d) a nuclear localization signal from human immunodeficiency virus for microtubule mediated transfer of genetic material to the nucleus. The vector was characterized using physicochemical and biological assays to demonstrate the functionality of each motif in the vector backbone. The results demonstrated that the vector is able to condense plasmid DNA into nanosize particles (<100 nm), protect pDNA from serum endonucleases, target ZR-75-1 breast cancer cells and internalize, efficiently disrupt endosome membranes, exploit microtubules to reach nucleus and mediate gene expression.

Biosynthesis and characterization of a novel genetically engineered polymer for targeted gene transfer to cancer cells.

A novel multi-domain biopolymer was designed and genetically engineered with the purpose to target and transfect cancer cells. The biopolymer contains at precise locations: 1) repeating units of arginine and histidine to condense pDNA and lyse endosome membranes, 2) a HER2 targeting affibody to target cancer cells, 3) a pH responsive fusogenic peptide to destabilize endosome membranes and enhance endosomolytic activity of histidine residues, and 4) a nuclear localization signal to enhance translocation of pDNA towards the cell nucleus. The results demonstrated that the biopolymer was able to condense pDNA into nanosize particles, protect pDNA from serum endonucleases, target HER2 positive cancer cells but not HER2 negative ones, efficiently disrupt endosomes, and effectively reach the cell nucleus of target cells to mediate gene expression.

A designer biomimetic vector with a chimeric architecture for targeted gene transfer.

Designer biomimetic vectors are genetically engineered biomacromolecules that are designed to mimic viral characteristics in order to overcome the cellular barriers associated with the targeted gene transfer. The vector in this study was genetically engineered to contain at precise locations: a) four tandem repeating units of N-terminal domain of histone H2A to condense DNA into stable nanosize particles suitable for cellular uptake, b) a model targeting motif to target HER2 and enhance internalization of nanoparticles, and c) a pH-responsive synthetic fusogenic peptide to disrupt endosome membranes and promote escape of the nanoparticles into the cytosol. The results demonstrate that a fully functional, multi-domain, designer vector can be engineered to target cells with high specificity, overcome the biological barriers associated with targeted gene transfer, and mediate efficient gene transfer.

Evaluation of the effect of vector architecture on DNA condensation and gene transfer efficiency.

The objective of this study was to evaluate the effect of vector architecture on DNA condensation, particle stability, and gene transfer efficiency. Two recombinant non-viral vectors with the same amino acid compositions but different architectures, composed of lysine-histidine (KH) repeating units fused to fibroblast growth factor, were genetically engineered. In one vector lysine residues were dispersed (KHKHKHKHKK)(6)-FGF2, whereas in the other they were in clusters (KKKHHHHKKK)(6)-FGF2.