CHANGE-seq reveals genetic and epigenetic effects on CRISPR-Cas9 genome-wide activity.

Current methods can illuminate the genome-wide activity of CRISPR-Cas9 nucleases, but are not easily scalable to the throughput needed to fully understand the principles that govern Cas9 specificity. Here we describe 'circularization for high-throughput analysis of nuclease genome-wide effects by sequencing' (CHANGE-seq), a scalable, automatable tagmentation-based method for measuring the genome-wide activity of Cas9 in vitro. We applied CHANGE-seq to 110 single guide RNA targets across 13 therapeutically relevant loci in human primary T cells and identified 201,934 off-target sites, enabling the training of a machine learning model to predict off-target activity. Comparing matched genome-wide off-target, chromatin modification and accessibility, and transcriptional data, we found that cellular off-target activity was two to four times more likely to occur near active promoters, enhancers and transcribed regions. Finally, CHANGE-seq analysis of six targets across eight individual genomes revealed that human single-nucleotide variation had significant effects on activity at ~15.2% of off-target sites analyzed. CHANGE-seq is a simplified, sensitive and scalable approach to understanding the specificity of genome editors.

Mutational and bioinformatics analysis of proline- and glycine-rich motifs in vesicular acetylcholine transporter.

The vesicular acetylcholine transporter (VAChT) contains six conserved sequence motifs that are rich in proline and glycine. Because these residues can have special roles in the conformation of polypeptide backbone, the motifs might have special roles in conformational changes during transport. Using published bioinformatics insights, the amino acid sequences of the 12 putative, helical, transmembrane segments of wild-type and mutant VAChTs were analyzed for propensity to form non-alpha-helical conformations and molecular notches. Many instances were found. In particular, high propensity for kinks and notches are robustly predicted for motifs D2, C and C'. Mutations in these motifs either increase or decrease Vmax for transport, but they rarely affect the equilibrium dissociation constants for ACh and the allosteric inhibitor, vesamicol. The near absence of equilibrium effects implies that the mutations do not alter the backbone conformation. In contrast, the Vmax effects demonstrate that the mutations alter the difficulty of a major conformational change in transport. Interestingly, mutation of an alanine to a glycine residue in motif C significantly increases the rates for reorientation across the membrane. These latter rates are deduced from the kinetics model of the transport cycle. This mutation is also predicted to produce a more flexible kink and tighter tandem notches than are present in wild-type. For the full set of mutations, faster reorientation rates correlate with greater predicted propensity for kinks and notches. The results of the study argue that conserved motifs mediate conformational changes in the VAChT backbone during transport.

Structural requirements for steady-state localization of the vesicular acetylcholine transporter.

The vesicular acetylcholine transporter (VAChT) regulates the amount of acetylcholine stored in synaptic vesicles. However, the mechanisms that control the targeting of VAChT and other synaptic vesicle proteins are still poorly comprehended. These processes are likely to depend, at least partially, on structural determinants present in the primary sequence of the protein. Here, we use site-directed mutagenesis to evaluate the contribution of the C-terminal tail of VAChT to the targeting of this transporter to synaptic-like microvesicles in cholinergic SN56 cells. We found that residues 481-490 contain the trafficking information necessary for VAChT localization and that within this region L485 and L486 are strictly necessary. Deletion and alanine-scanning mutants lacking most of the carboxyl tail of VAChT, but containing residues 481-490, were still targeted to microvesicles. Moreover, we found that clathrin-mediated endocytosis of VAChT is required for targeting to microvesicles in SN56 and PC12 cells. The data provide novel information on the mechanisms and structural determinants necessary for VAChT localization to synaptic vesicles.

New transport assay demonstrates vesicular acetylcholine transporter has many alternative substrates.

The acetylcholine-binding site in vesicular acetylcholine transporter faces predominantly toward the outside of the vesicle when resting but predominantly toward the inside when transporting. Transport-related reorientation is detected by an ATP-induced decrease in the ability of saturating substrate to displace allosterically bound [(3)H]vesamicol. The assay was used here to determine whether structurally diverse compounds are transported by rat VAChT expressed in PC12(A123.7) cells. Competition by ethidium, tetraphenylphosphonium and other monovalent organic cations with [(3)H]vesamicol is decreased when ATP is added, and the effect depends on proton-motive force. The results indicate that many organic molecules carrying +1 charge are transported, even though the compounds do not resemble acetylcholine in structural details.

Mutational and pH analysis of ionic residues in transmembrane domains of vesicular acetylcholine transporter.

This research investigated the roles of 7 conserved ionic residues in the 12 putative transmembrane domains (TMDs) of vesicular acetylcholine transporter (VAChT). Rat VAChT in wild-type and mutant forms was expressed in PC12(A123.7) cells. Transport and ligand binding were characterized at different pH values using filter assays. The ACh binding site is shown to exhibit high or low affinity (K(d) values are approximately 10 and 200 mM, respectively). Mutation of the lysine and aspartate residues in TMDs II and IV, respectively, can decrease the fraction of sites having high affinity. In three-dimensional structures of related transporters, these TMDs lie next to each other and distantly from TMDs VIII and X, which probably contain the binding sites for ACh and the allosteric inhibitor vesamicol. Importantly, mutation of the aspartate in TMD XI can create extra-high affinities for ACh (K(d) approximately 4 mM) and vesamicol (K(d) approximately 2 nM compared to approximately 20 nM). Effects of different external pH values on transport indicate a site that must be protonated (apparent pK(a) approximately 7.6) likely is the aspartate in TMD XI. The observations suggest a model in which the known ion pair between lysine in TMD II and aspartate in TMD XI controls the conformation or relative position of TMD XI, which in turn controls additional TMDs in the C-terminal half of VAChT. The pH effects also indicate that sites that must be unprotonated for transport (apparent pK(a) approximately 6.4) and vesamicol binding (apparent pK(a) approximately 6.3) remain unidentified.

Choline is transported by vesicular acetylcholine transporter.

Previously published results appeared to show that vesicular acetylcholine transporter (VAChT) does not transport choline (Ch). Because it is uniquely suited to detect transport of weakly bound substrates, a recently developed assay that detects transmembrane reorientation of the substrate binding site was used to re-examine transport selectivity. Rat VAChT was expressed in PC12(A1237) cells, postnuclear supernatant-containing microvesicles was prepared, and the reorientation assay was conducted with unlabeled Ch and tetramethylammonium (TMA). Also, [(14)C]Ch and [(3)H]acetylcholine (ACh) were used in an optimized accumulation assay. The results demonstrate that Ch is transported at least as well as ACh is, but with sevenfold lower affinity. Even TMA is transported, but with 26-fold lower affinity. Ch transport by VAChT is of interest in view of the possibilities that Ch (i) occurs at higher concentration than ACh does in terminal cytoplasm under some conditions, and (ii) is an agonist for alpha 7 nicotinic receptors.

Acetylcholine binding site in the vesicular acetylcholine transporter.

This study sought primarily to locate the acetylcholine (ACh) binding site in the vesicular acetylcholine transporter (VAChT). The design of the study also allowed us to locate residues linked to (a) the binding site for the allosteric inhibitor vesamicol and (b) the rates of the two transmembrane reorientation steps of a transport cycle. In more characterized proteins, ACh is known to be bound in part through cation-pi solvation by tryptophan, tyrosine, and phenylalanine residues. Each of 11 highly conserved W, Y, and F residues in putative transmembrane domains (TMDs) of rat VAChT was mutated to A and a different aromatic residue to test for loss of cation-pi solvation. Mutated VAChTs were expressed in PC12(A123.7) cells and characterized with the goal of determining whether mutations widely perturbed structure. The thermodynamic affinity for ACh was determined by displacement of trace [(3)H]-(-)-trans-2-(4-phenylpiperidino)cyclohexanol (vesamicol) with ACh, and Michaelis-Menten parameters were determined for [(3)H]ACh transport. Expression levels were determined with [(3)H]vesamicol saturation curves and Western blots, and they were used to normalize V(max) values. "Microscopic" parameters for individual binding and rate steps in the transport cycle were calculated on the basis of a published kinetics model. All mutants were expressed adequately, were properly glycosylated, and bound ACh and vesamicol. Subcellular mistargeting was shown not to be responsible for poor transport by some mutants. Mutation of residue W331, which lies in the beginning of TMD VIII proximal to the vesicular lumen, produced 5- and 9-fold decreased ACh affinities and no change in other parameters. This residue is a good candidate for cation-pi solvation of bound ACh. Mutation of four other residues decreased the ACh affinity up to 6-fold and also affected microscopic rate constants. The roles of these residues in ACh binding and transport thus are complex. Nine mutations allowed us to resolve the ACh and vesamicol binding sites from each other. Other mutations affected only the rates of the transmembrane reorientation steps, and four mutations increased the rate of one or the other. Two mutations increased the value of K(M) up to 5-fold as a result of rate effects with no ACh affinity effect. The results demonstrate that analysis of microscopic kinetics is required for the correct interpretation of mutational effects in VAChT. Results also are discussed in terms of recently determined three-dimensional structures for other transporters in the major facilitator superfamily.

Transmembrane reorientation of the substrate-binding site in vesicular acetylcholine transporter.

Active transport of acetylcholine (ACh) by vesicular ACh transporter (VAChT) is driven by a proton-motive force established by V-ATPase. A published microscopic kinetics model predicts the ACh-binding site is primarily oriented toward the outside for nontransporting VAChT and toward the inside for transporting VAChT. The allosteric ligand [(3)H]vesamicol cannot bind when the ACh-binding site is outwardly oriented and occupied by ACh, but it can bind when the ACh site is inwardly oriented. The kinetics model was tested in the paper reported here using rat VAChT expressed in PC12(A1237) cells. Equilibrium titrations of [(3)H]vesamicol binding and ACh competition show that ATP blocks competition between vesamicol and ACh in over one-half of the VAChT. NaCl did not mimic ACh chloride, and bafilomycin A(1) and FCCP completely blocked the ATP effect, which shows that it is mediated by a proton-motive force. The data are consistent with reorientation of over one-half of the ACh-binding sites from the outside to the inside of vesicles upon activation of transport. The observations support the proposed microscopic kinetics model, and they should be useful in characterizing effects of mutations on the VAChT transport cycle.