Phosphonoacetate Modifications Enhance the Stability and Editing Yields of Guide RNAs for Cas9 Editors.

CRISPR gene editing and control systems continue to emerge and inspire novel research and clinical applications. Advances in CRISPR performance such as optimizing the duration of activity in cells, tissues, and organisms, as well as limiting off-target activities, have been extremely important for expanding the utility of CRISPR-based systems. By investigating the effects of various chemical modifications in guide RNAs (gRNAs) at defined positions and combinations, we find that 2'--methyl-3'-phosphonoacetate (MP) modifications can be substantially more effective than 2'--methyl-3'-phosphorothioate (MS) modifications at the 3' ends of single-guide RNAs (sgRNAs) to promote high editing yields, in some instances showing an order of magnitude higher editing yield in human cells.

Chemically modified guide RNAs enhance CRISPR-Cas genome editing in human primary cells.

CRISPR-Cas-mediated genome editing relies on guide RNAs that direct site-specific DNA cleavage facilitated by the Cas endonuclease. Here we report that chemical alterations to synthesized single guide RNAs (sgRNAs) enhance genome editing efficiency in human primary T cells and CD34(+) hematopoietic stem and progenitor cells. Co-delivering chemically modified sgRNAs with Cas9 mRNA or protein is an efficient RNA- or ribonucleoprotein (RNP)-based delivery method for the CRISPR-Cas system, without the toxicity associated with DNA delivery.

The human mitochondrial tRNAMet: structure/function relationship of a unique modification in the decoding of unconventional codons.

Human mitochondrial mRNAs utilize the universal AUG and the unconventional isoleucine AUA codons for methionine. In contrast to translation in the cytoplasm, human mitochondria use one tRNA, hmtRNA(Met)(CAU), to read AUG and AUA codons at both the peptidyl- (P-), and aminoacyl- (A-) sites of the ribosome. The hmtRNA(Met)(CAU) has a unique post-transcriptional modification, 5-formylcytidine, at the wobble position 34 (f(5)C(34)), and a cytidine substituting for the invariant uridine at position 33 of the canonical U-turn in tRNAs.

Preparation of 5'-silyl-2'-orthoester ribonucleosides for use in oligoribonucleotide synthesis.

The recent discovery that small interfering RNAs (siRNAs) induce gene suppression in mammalian cells has sparked tremendous interest in using siRNA-based assays and high-throughput screens to study gene function. As a result, research programs at leading academic and commercial institutions have become a substantial and rapidly growing market for synthetic RNA. Important considerations in synthesizing RNA for biological gene function studies are sequence integrity, purity, scalability, and resistance to nucleases; ease of chemical modification, deprotection, and handling; and cost.

Chromophoric 5'-O-Silyl protection of N-protected 2'-ACE ribonucleosides for solid-phase RNA synthesis.

Recent advances in the understanding of the pivotal roles played by endogenous small RNAs in gene regulation have resulted in a substantial and rapidly growing market for synthetic RNA. 5'-Silyl-2'-ACE chemistry has proven to be a robust and reliable technology for the synthesis of oligoribonucleotides. This unit describes an important improvement to this chemistry, by adding a cycle-to-cycle traceability analogous to that inherent in 5'-dimethoxytrityl-based approaches.

Recent advances in the high-speed solid phase synthesis of RNA.

Development of rapid and reliable RNA synthesis strategies is fueled by the emergence of critical functional and regulatory roles for RNA, including RNA interference. Traditional methods are based on 5'-dimethoxytrityl-2'-silyl protection strategies which are derivatives of highly successful DNA synthesis methods. These approaches are limited in their ability to rapidly produce oligos of sufficient purity and length for genomic and pharmaceutical applications.

A rapid method for manual or automated purification of fluorescently labeled nucleic acids for sequencing, genotyping, and microarrays.

Fluorescent dyes provide specific, sensitive, and multiplexed detection of nucleic acids. To maximize sensitivity, fluorescently labeled reaction products (e.g.