Mapping the genomic landscape of CRISPR-Cas9 cleavage.

RNA-guided CRISPR-Cas9 endonucleases are widely used for genome engineering, but our understanding of Cas9 specificity remains incomplete. Here, we developed a biochemical method (SITE-Seq), using Cas9 programmed with single-guide RNAs (sgRNAs), to identify the sequence of cut sites within genomic DNA. Cells edited with the same Cas9-sgRNA complexes are then assayed for mutations at each cut site using amplicon sequencing. We used SITE-Seq to examine Cas9 specificity with sgRNAs targeting the human genome. The number of sites identified depended on sgRNA sequence and nuclease concentration. Sites identified at lower concentrations showed a higher propensity for off-target mutations in cells. The list of off-target sites showing activity in cells was influenced by sgRNP delivery, cell type and duration of exposure to the nuclease. Collectively, our results underscore the utility of combining comprehensive biochemical identification of off-target sites with independent cell-based measurements of activity at those sites when assessing nuclease activity and specificity.

Low-coverage single-cell mRNA sequencing reveals cellular heterogeneity and activated signaling pathways in developing cerebral cortex.

Large-scale surveys of single-cell gene expression have the potential to reveal rare cell populations and lineage relationships but require efficient methods for cell capture and mRNA sequencing. Although cellular barcoding strategies allow parallel sequencing of single cells at ultra-low depths, the limitations of shallow sequencing have not been investigated directly. By capturing 301 single cells from 11 populations using microfluidics and analyzing single-cell transcriptomes across downsampled sequencing depths, we demonstrate that shallow single-cell mRNA sequencing (~50,000 reads per cell) is sufficient for unbiased cell-type classification and biomarker identification. In the developing cortex, we identify diverse cell types, including multiple progenitor and neuronal subtypes, and we identify EGR1 and FOS as previously unreported candidate targets of Notch signaling in human but not mouse radial glia. Our strategy establishes an efficient method for unbiased analysis and comparison of cell populations from heterogeneous tissue by microfluidic single-cell capture and low-coverage sequencing of many cells.

A split active site couples cap recognition by Dcp2 to activation.

Decapping by Dcp2 is an essential step in 5'-to-3' mRNA decay. In yeast, decapping requires an open-to-closed transition in Dcp2, though the link between closure and catalysis remains elusive. Here we show using NMR that cap binds conserved residues on both the catalytic and regulatory domains of Dcp2. Lesions in the cap-binding site on the regulatory domain reduce the catalytic step by two orders of magnitude and block the formation of the closed state, whereas Dcp1 enhances the catalytic step by a factor of 10 and promotes closure. We conclude that closure occurs during the rate-limiting catalytic step of decapping, juxtaposing the cap-binding region of each domain to form a composite active site. This work suggests a model for regulation of decapping where coactivators trigger decapping by stabilizing a labile composite active site.

Identification and analysis of the interaction between Edc3 and Dcp2 in Saccharomyces cerevisiae.

Cap hydrolysis is a critical control point in the life of eukaryotic mRNAs and is catalyzed by the evolutionarily conserved Dcp1-Dcp2 complex. In Saccharomyces cerevisiae, decapping is modulated by several factors, including the Lsm family protein Edc3, which directly binds to Dcp2. We show that Edc3 binding to Dcp2 is mediated by a short peptide sequence located C terminal to the catalytic domain of Dcp2. This sequence is required for Edc3 to stimulate decapping activity of Dcp2 in vitro, for Dcp2 to efficiently accumulate in P-bodies, and for efficient degradation of the RPS28B mRNA, whose decay is enhanced by Edc3. In contrast, degradation of YRA1 pre-mRNA, another Edc3-regulated transcript, occurs independently from this region, suggesting that the effect of Edc3 on YRA1 is independent of its interaction with Dcp2. Deletion of the sequence also results in a subtle but significant defect in turnover of the MFA2pG reporter transcript, which is not affected by deletion of EDC3, suggesting that the region affects some other aspect of Dcp2 function in addition to binding Edc3. These results raise a model for Dcp2 recruitment to specific mRNAs where regions outside the catalytic core promote the formation of different complexes involved in mRNA decapping.

A kinetic assay to monitor RNA decapping under single- turnover conditions.

The stability of all RNA polymerase II transcripts depends on the 5'-terminal cap structure. Removal of the cap is a prerequisite for 5' to 3'-decay and is catalyzed by distinct cellular and viral decapping activities. Over the past decade, several decapping enzymes have been characterized through functional and structural studies. An emerging theme is that function is regulated by protein interactions; however, in vitro assays to dissect the effects on enzyme activity are unavailable. Here we present a kinetic assay to monitor decapping by the heterodimeric yeast Dcp1/Dcp2 complex. Kinetic constants related to RNA binding and the rate of the catalytic step can be determined with recombinant enzyme and cap-radiolabeled RNA substrate, allowing substrate specificity and the role of activating factors to be firmly established.

Control of mRNA decapping by Dcp2: An open and shut case?

mRNA decapping by Dcp2 is a critical step in several major eukaryotic mRNA decay pathways. Dcp2 forms the catalytic core of a mRNP that is configured for processing diverse substrates by pathway-specific activators. Here we elaborate a model of catalysis by Dcp2 which posits that activity is controlled by a conformational equilibrium between an open, inactive and closed, active form of the enzyme. Structural studies on yeast Dcp2 indicate that the general activator Dcp1 and substrate promote the closed form of the enzyme. Kinetic studies indicate the catalytic step of decapping is rate-limiting and accelerated by Dcp1. We propose that regulation of conformational transitions in Dcp2 during a rate-limiting step after assembly of the decapping mRNP provides a checkpoint for determining if an mRNA is degraded or recycled to translation.

mRNA decapping is promoted by an RNA-binding channel in Dcp2.

Cap hydrolysis by Dcp2 is a critical step in several eukaryotic mRNA decay pathways. Processing requires access to cap-proximal nucleotides and the coordinated assembly of a decapping mRNP, but the mechanism of substrate recognition and regulation by protein interactions have remained elusive. Using NMR spectroscopy and kinetic analyses, we show that yeast Dcp2 resolves interactions with the cap and RNA body using a bipartite surface that forms a channel intersecting the catalytic and regulatory Dcp1-binding domains. The interaction with cap is weak but specific and requires binding of the RNA body to a dynamic interface. The catalytic step is stimulated by Dcp1 and its interaction domain, likely through a substrate-induced conformational change. Thus, activation of the decapping mRNP is restricted by access to 5'-proximal nucleotides, a feature that could act as a checkpoint in mRNA metabolism.