Vladimir Ćurić scite author profile

How fast can a cell locate a specific chromosomal DNA sequence specified by a single-stranded oligonucleotide? To address this question, we investigate the intracellular search processes of the Cas9 protein, which can be programmed by a guide RNA to bind essentially any DNA sequence. This targeting flexibility requires Cas9 to unwind the DNA double helix to test for correct base pairing to the guide RNA. Here we study the search mechanisms of the catalytically inactive Cas9 (dCas9) in living by combining single-molecule fluorescence microscopy and bulk restriction-protection assays. We find that it takes a single fluorescently labeled dCas9 6 hours to find the correct target sequence, which implies that each potential target is bound for less than 30 milliseconds. Once bound, dCas9 remains associated until replication. To achieve fast targeting, both Cas9 and its guide RNA have to be present at high concentrations.

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Pointwise error estimates in localization microscopy

Lindén¹,

Ćurić²,

Amselem³

et al. 2017

Nat Commun

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Pointwise localization of individual fluorophores is a critical step in super-resolution localization microscopy and single particle tracking. Although the methods are limited by the localization errors of individual fluorophores, the pointwise localization precision has so far been estimated using theoretical best case approximations that disregard, for example, motion blur, defocus effects and variations in fluorescence intensity. Here, we show that pointwise localization precision can be accurately estimated directly from imaging data using the Bayesian posterior density constrained by simple microscope properties. We further demonstrate that the estimated localization precision can be used to improve downstream quantitative analysis, such as estimation of diffusion constants and detection of changes in molecular motion patterns. Finally, the quality of actual point localizations in live cell super-resolution microscopy can be improved beyond the information theoretic lower bound for localization errors in individual images, by modelling the movement of fluorophores and accounting for their pointwise localization uncertainty.

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Kinetics of dCas9 Target Search in Escherichia Coli

Jones

Unoson

Leroy

et al. 2017

Biophysical Journal

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How fast can a cell locate a specific chromosomal DNA sequence specified by a single stranded oligonucleotide? To address this question we study the CRISPR-associated protein Cas9 which can be programmed by guide RNAs to bind essentially any DNA sequence. This targeting flexibility requires Cas9 to unwind the DNA double helix to test for correct base pairing to the guide RNA. Here we study the search mechanisms of the catalytically inactive dCas9 in living Escherichia coli by combining single molecule fluorescence microscopy and bulk restriction protection assays. We find that it takes a single dCas9~100 h to find and bind a specific target, in stark contrast to transcription factors such as LacI, which takes 5 minutes to locate its target. Thus, the price dCas9 pays for flexibility in targeting is time. We further identify a likely role for short-range (20-40) 1D sliding along DNA in dCas9 target search. The physical limitations for Cas9 likely generalize to all systems that are programmed by single stranded oligonucleotides to locate sequences in dsDNA, such as the homologous repair machinery.

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Simulated single molecule microscopy with SMeagol

Lindén¹,

Ćurić²,

Boucharin³

et al. 2016

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Summary: SMeagol is a software tool to simulate highly realistic microscopy data based on spatial systems biology models, in order to facilitate development, validation and optimization of advanced analysis methods for live cell single molecule microscopy data. Availability and implementation: SMeagol runs on Matlab R2014 and later, and uses compiled binaries in C for reaction–diffusion simulations. Documentation, source code and binaries for Mac OS, Windows and Ubuntu Linux can be downloaded from http://smeagol.sourceforge.net. Contact: johan.elf@icm.uu.se Supplementary information: Supplementary data are available at Bioinformatics online.

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