A major hurdle to curing HIV is the persistence of integrated proviruses in resting CD4+ T cells that remain in a transcriptionally silent, latent state. One strategy to eradicate latent HIV is to activate viral transcription, followed by elimination of infected cells through virus-mediated cytotoxicity or immune-mediated clearance. We hypothesised that mRNA-lipid nanoparticle (LNP) technology would provide an opportunity to deliver mRNA encoding proteins able to reverse HIV latency in resting CD4+ T cells. Here we develop an LNP formulation (LNP X) with unprecedented potency to deliver mRNA to hard-to-transfect resting CD4+ T cells in the absence of cellular toxicity or activation. Encapsulating an mRNA encoding the HIV Tat protein, an activator of HIV transcription, LNP X enhances HIV transcription in ex vivo CD4+ T cells from people living with HIV. LNP X further enables the delivery of clustered regularly interspaced short palindromic repeats (CRISPR) activation machinery to modulate both viral and host gene transcription. These findings offer potential for the development of a range of nucleic acid-based T cell therapeutics.

Resting T cells are difficult to manipulate, and are a reservoir for latent HIV. Here, the authors develop a lipid nanoparticle formulation with the ability to transfect resting primary human T cells, enabling delivery of mRNAs that result in reactivation of latent HIV. This could help development of HIV cure strategies.

Schematic illustration of two pathways for macromolecular therapeutics delivery: nanoparticle-adopted endocytosis (left) and DNA nanotubule-mediated cytosolic delivery (right). By bypassing conventio…

Traditional medical tests often require clinical samples to be sent off-site for analysis in a time-intensive and expensive process. Point-of-care diagnostics are instead low-cost, easy-to-use, and rapid tests performed at the site of patient care. Recently, researchers at the Carl R. Woese Institute for Genomic Biology reported new and optimized techniques to develop better biosensors for the early detection of disease biomarkers.

People have long been fascinated with the iridescence of peacock feathers, appearing to change color as light hits them from different angles. With no pigments present in the feathers, these colors are a result of light interactions with nanoscopic structures, called photonic crystals, patterned across the surface of the feathers.

Inspired by biology, scientists have harnessed the power of these photonic crystals for biosensing technologies due to their ability to manipulate how light is absorbed and reflected. Because their properties are a result of their nanostructure, photonic crystals can be precisely engineered for different purposes.