Established and Emerging Nucleic Acid Therapies for Familial Hypercholesterolemia.

Familial hypercholesterolemia (FH) is a genetic disease that leads to elevated low-density lipoprotein cholesterol levels and risk of coronary heart disease. Current therapeutic options for FH remain relatively limited and only partially effective in both lowering low-density lipoprotein cholesterol and modifying coronary heart disease risk. The unique characteristics of nucleic acid therapies to target the underlying cause of the disease can offer solutions unachievable with conventional medications. DNA- and RNA-based therapeutics have the potential to transform the care of patients with FH. Recent advances are overcoming obstacles to clinical translation of nucleic acid-based medications, including greater stability of the formulations as well as site-specific delivery, making gene-based therapy for FH an alternative approach for treatment of FH.

Thioflavin T as a noncovalent reporter for a label-free, non-enzymatic, catalytic DNA amplifier.

DNA-DNA reactions can be monitored with a label-free fluorogenic reaction. Guanosine-rich, single-stranded DNA oligonucleotides bind to thioflavin-T (ThT) and enhance the fluorescence of the dye. We discovered a novel DNA sequence that produces fluorescence upon binding to ThT. We denote this oligonucleotide ThTSignal. We use ThTSignal as a label-free reporter for the activity of several designed DNA-DNA reactions (DNA circuits). The DNA circuits conditionally produce the ThTSignal oligonucleotide by association or by liberating the ThTSignal oligonucleotide from double-stranded DNA. This strategy offers label-free, cost-effective, fluorogenic detection of the molecular beacon reaction, split reporter reaction, one-step strand displacement reaction, and the entropy-driven amplifier reaction (a catalytic DNA circuit).

Open source and DIY hardware for DNA nanotechnology labs.

A set of instruments and specialized equipment is necessary to equip a laboratory to work with DNA. Reducing the barrier to entry for DNA manipulation should enable and encourage new labs to enter the field. We present three examples of open source/DIY technology with significantly reduced costs relative to commercial equipment. This includes a gel scanner, a horizontal PAGE gel mold, and a homogenizer for generating DNA-coated particles. The overall cost savings obtained by using open source/DIY equipment was between 50 and 90%.