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Your search keyword '"Reza Kalhor"' showing total 9 results
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9 results on '"Reza Kalhor"'

2. Massively parallel multi-target CRISPR system interrogates Cas9-based target recognition, DNA cleavage, and DNA repair

Author

Roger S. Zou, Alberto Marin-Gonzalez, Yang Liu, Hans B. Liu, Leo Shen, Rachel K. Dveirin, Jay X. J. Luo, Reza Kalhor, and Taekjip Ha

Abstract

CRISPR-Cas9 nucleases, and particularly Streptococcus pyogenes Cas9, are widespread tools for genome editing. However, many aspects of intracellular Cas9 activity and the ensuing DNA damage response remain incompletely characterized. In order to address these issues, we developed a multiplexed CRISPR approach, where a single, degenerate multi-target gRNA (mgRNA) directs the Cas9 enzyme to target hundred endogenous sites at once. When combined with next-generation sequencing readouts, this system enables interrogation of Cas9 activity and DNA double-strand break (DSB) repair response in high-throughput. Here, we present a step-by-step protocol to deliver a Cas9:mgRNA ribonucleoprotein complex into cultured cells and measure key processes related to Cas9 activity and DSB repair.

Published
2022

4. Amyloid fibril reduction through covalently modified lysine in HEWL and insulin

Author

Mohsen Rezaei and Hamid Reza Kalhor

Subjects
Amyloid, Circular Dichroism, Lysine, Biophysics, Animals, Insulin, Cattle, Muramidase, Molecular Biology, Biochemistry, Chickens
Abstract

Proteins possess a variety of nucleophiles, which can carry out different reactions in the functioning cells. Proteins endogenously and synthetically can be modified through their nucleophilic sites. The roles of these chemical modifications have not been completely revealed. These modifications can alter the protein folding process. Protein folding directly affects the function of proteins. If an error in protein folding occurs, it may cause protein malfunction leading to several neurodegenerative disorders such as Alzheimer's and Parkinson's. In this study, Hen Egg White Lysozyme (HEWL) and bovine insulin, as model proteins for studying the amyloid formation, were covalently attached with 5(6)-thiophenolfluorescein. The amyloid formation of the covalently labeled lysozyme and insulin were compared with the native proteins. Interestingly, the results indicated that the covalent attachment of fluorescein slowed down the amyloid formation of HEWL and insulin significantly. The amyloid formation was examined using Thioflavin T (ThT) fluorescence assay, circular dichroism, FTIR, and gel electrophoresis. Tandem mass spectrometry was employed to identify the sites of covalent modifications in HEWL. It turned out that two surface lysine residues (K97 and K 116) in HEWL were modified. Computational studies, including docking and molecular simulations, revealed that 5(6)-thiophenolfluorescein makes several non-covalent interactions with HEWL residues, including Lys 97, leading to the reduction of the β-sheet in the protein. Additionally, AFM analysis confirmed the amyloid fibril reduction of lysine-modified bovine insulin and HEWL. Altogether, our results expand mechanistic insights into preventing amyloid formation by providing an approach for reducing amyloid formation by modifying specific lysine residues in the proteins.

Published
2022

5. Quantitative fate mapping: Reconstructing progenitor field dynamics via retrospective lineage barcoding

Author

Weixiang Fang, Claire M. Bell, Abel Sapirstein, Soichiro Asami, Kathleen Leeper, Donald J. Zack, Hongkai Ji, and Reza Kalhor

Abstract

Natural and induced somatic mutations that accumulate in the genome during development record the phylogenetic relationships of cells; however, whether these lineage barcodes can capture the dynamics of complex progenitor fields remains unclear. Here, we introduce quantitative fate mapping, an approach to simultaneously map the fate and quantify the commitment time, commitment bias, and population size of multiple progenitor groups during development based on a time-scaled phylogeny of their descendants. To reconstruct time-scaled phylogenies from lineage barcodes, we introduce Phylotime, a scalable maximum likelihood clustering approach based on a generalizable barcoding mutagenesis model. We validate these approaches using realistically-simulated barcoding results as well as experimental results from a barcoding stem cell line. We further establish criteria for the minimum number of cells that must be analyzed for robust quantitative fate mapping. Overall, this work demonstrates how lineage barcodes, natural or synthetic, can be used to obtain quantitative fate maps, thus enabling analysis of progenitor dynamics long after embryonic development in any organism.

Published
2022

6. Massively parallel genomic perturbations with multi-target CRISPR interrogates Cas9 activity and DNA repair at endogenous sites

Author

Roger S. Zou, Alberto Marin-Gonzalez, Yang Liu, Hans B. Liu, Leo Shen, Rachel K. Dveirin, Jay X. J. Luo, Reza Kalhor, and Taekjip Ha

Subjects
DNA Repair, Cell Biology, DNA, Genomics, CRISPR-Cas Systems, Chromatin, RNA, Guide, Kinetoplastida
Abstract

Here we present an approach that combines a clustered regularly interspaced short palindromic repeats (CRISPR) system that simultaneously targets hundreds of epigenetically diverse endogenous genomic sites with high-throughput sequencing to measure Cas9 dynamics and cellular responses at scale. This massive multiplexing of CRISPR is enabled by means of multi-target guide RNAs (mgRNAs), degenerate guide RNAs that direct Cas9 to a pre-determined number of well-mapped sites. mgRNAs uncovered generalizable insights into Cas9 binding and cleavage, revealing rapid post-cleavage Cas9 departure and repair factor loading at protospacer adjacent motif-proximal genomic DNA. Moreover, by bypassing confounding effects from guide RNA sequence, mgRNAs unveiled that Cas9 binding is enhanced at chromatin-accessible regions, and cleavage by bound Cas9 is more efficient near transcribed regions. Combined with light-mediated activation and deactivation of Cas9 activity, mgRNAs further enabled high-throughput study of the cellular response to double-strand breaks with high temporal resolution, revealing the presence, extent (under 2 kb) and kinetics (~1 h) of reversible DNA damage-induced chromatin decompaction. Altogether, this work establishes mgRNAs as a generalizable platform for multiplexing CRISPR and advances our understanding of intracellular Cas9 activity and the DNA damage response at endogenous loci.

Published
2022

7. Massively parallel genomic perturbations with multi-target CRISPR reveal new insights on Cas9 activity and DNA damage responses at endogenous sites

Author

Roger S. Zou, Alberto Marin-Gonzalez, Yang Liu, Hans B. Liu, Leo Shen, Rachel Dveirin, Jay X. J. Luo, Reza Kalhor, and Taekjip Ha

Abstract

We present an approach that combines a Cas9 that simultaneously targets hundreds of epigenetically diverse endogenous genomic sites with high-throughput sequencing technologies to measure Cas9 dynamics and cellular responses at scale. This massive multiplexing of CRISPR is enabled by means of novel multi-target gRNAs (mgRNAs), degenerate gRNAs that direct Cas9 to a pre-determined number of well-mapped sites. mgRNAs uncovered generalizable insights into Cas9 binding and cleavage, discovering rapid post-cleavage Cas9 departure and repair factor loading at PAM-proximal genomic DNA. Moreover, by bypassing confounding effects from gRNA sequence, mgRNAs unveiled that Cas9 binding is enhanced at chromatin-accessible regions, and Cas9 cleavage is more efficient near transcribed regions. Combined with light-mediated activation and deactivation of Cas9 activity, mgRNAs further enabled high-throughput study of the cellular response to double strand breaks with high temporal resolution, discovering the presence, extent (under 2 kb), and kinetics (~ 0.5 hr) of reversible DNA damage-induced chromatin decompaction. Altogether, this work establishes mgRNAs as a generalizable platform for multiplexing CRISPR and advances our understanding of intracellular Cas9 activity and the DNA damage response at endogenous loci.

Published
2022

8. Quantitative fate mapping: A general framework for analyzing progenitor state dynamics via retrospective lineage barcoding

Author

Weixiang Fang, Claire M. Bell, Abel Sapirstein, Soichiro Asami, Kathleen Leeper, Donald J. Zack, Hongkai Ji, and Reza Kalhor

Subjects
Mutagenesis, Embryonic Development, Cell Lineage, Phylogeny, General Biochemistry, Genetics and Molecular Biology, Retrospective Studies
Abstract

Natural and induced somatic mutations that accumulate in the genome during development record the phylogenetic relationships of cells; whether these lineage barcodes capture the complex dynamics of progenitor states remains unclear. We introduce quantitative fate mapping, an approach to reconstruct the hierarchy, commitment times, population sizes, and commitment biases of intermediate progenitor states during development based on a time-scaled phylogeny of their descendants. To reconstruct time-scaled phylogenies from lineage barcodes, we introduce Phylotime, a scalable maximum likelihood clustering approach based on a general barcoding mutagenesis model. We validate these approaches using realistic in silico and in vitro barcoding experiments. We further establish criteria for the number of cells that must be analyzed for robust quantitative fate mapping and a progenitor state coverage statistic to assess the robustness. This work demonstrates how lineage barcodes, natural or synthetic, enable analyzing progenitor fate and dynamics long after embryonic development in any organism.

Published
2022

9. Recording Temporal Signals with Minutes Resolution Using Enzymatic DNA Synthesis

Author

Namita Bhan, Keith E. J. Tyo, Jonathan Strutz, Alec Callisto, Konrad P. Kording, Edward S. Boyden, Reza Kalhor, George M. Church, and Joshua I. Glaser

Subjects
chemistry.chemical_classification, DNA synthesis, Chemistry, General Chemistry, ENCODE, Biochemistry, Signal, Catalysis, Article, chemistry.chemical_compound, Colloid and Surface Chemistry, Enzyme, Terminal deoxynucleotidyl transferase, DNA Nucleotidylexotransferase, Biophysics, Nucleotide, Biosensor, DNA
Abstract

Employing DNA as a high-density data storage medium has paved the way for next-generation digital storage and biosensing technologies. However, the multipart architecture of current DNA-based recording techniques renders them inherently slow and incapable of recording fluctuating signals with sub-hour frequencies. To address this limitation, we developed a simplified system employing a single enzyme, terminal deoxynucleotidyl transferase (TdT), to transduce environmental signals into DNA. TdT adds nucleotides to the 3’ ends of single-stranded DNA (ssDNA) in a template-independent manner, selecting bases according to inherent preferences and environmental conditions. By characterizing TdT nucleotide selectivity under different conditions, we show that TdT can encode various physiologically relevant signals like Co(2+), Ca(2+), Zn(2+) concentrations and temperature changes in vitro. Further, by considering the average rate of nucleotide incorporation, we show that the resulting ssDNA functions as a molecular ticker tape. With this method we accurately encode a temporal record of fluctuations in Co(2+) concentration to within 1 minute over a 60-minute period. Finally, we engineer TdT to allosterically turn off in the presence of physiologically relevant concentration of calcium. We use this engineered TdT in concert with a reference TdT to develop a two-polymerase system capable of recording a single step change in Ca(2+) signal to within 1 minute over a 60-minute period. This work expands the repertoire of DNA-based recording techniques by developing a novel DNA synthesis-based system that can record temporal environmental signals into DNA with minutes resolution.

Published
2021

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