Short motif sequences determine the targets of the prokaryotic CRISPR defence system FJM Mojica, C Díez-Villaseñor, J García-Martínez, C Almendros Microbiology 155 (3), 733-740, 2009 | 2045 | 2009 |
Diversity of CRISPR loci in Escherichia coli C Díez-Villaseñor, C Almendros, J García-Martínez, FJM Mojica Microbiology 156 (5), 1351-1361, 2010 | 237 | 2010 |
CRISPR-spacer integration reporter plasmids reveal distinct genuine acquisition specificities among CRISPR-Cas I-E variants of Escherichia coli C Díez-Villaseñor, NM Guzmán, C Almendros, J García-Martínez, ... RNA biology 10 (5), 792-802, 2013 | 182 | 2013 |
Cas4 facilitates PAM-compatible spacer selection during CRISPR adaptation SN Kieper, C Almendros, J Behler, RE McKenzie, FL Nobrega, ... Cell reports 22 (13), 3377-3384, 2018 | 119 | 2018 |
Target Motifs Affecting Natural Immunity by a Constitutive CRISPR-Cas System in Escherichia coli C Almendros, NM Guzman, C Diez-Villasenor, J Garcia-Martinez, ... PLoS One 7 (11), e50797, 2012 | 69 | 2012 |
Direct visualization of native CRISPR target search in live bacteria reveals cascade DNA surveillance mechanism JNA Vink, KJA Martens, M Vlot, RE McKenzie, C Almendros, BE Bonilla, ... Molecular cell 77 (1), 39-50. e10, 2020 | 51 | 2020 |
CRISPR Content Correlates with the Pathogenic Potential of Escherichia coli E García-Gutiérrez, C Almendros, FJM Mojica, NM Guzmán, ... PloS one 10 (7), e0131935, 2015 | 47 | 2015 |
Anti-cas spacers in orphan CRISPR4 arrays prevent uptake of active CRISPR–Cas IF systems C Almendros, NM Guzmán, J García-Martínez, FJM Mojica Nature Microbiology 1 (8), 1-8, 2016 | 43 | 2016 |
Cas4–Cas1 fusions drive efficient PAM selection and control CRISPR adaptation C Almendros, FL Nobrega, RE McKenzie, SJJ Brouns Nucleic acids research 47 (10), 5223-5230, 2019 | 42 | 2019 |
CRISPR-Cas functional module exchange in Escherichia coli C Almendros, FJM Mojica, C Díez-Villaseñor, NM Guzmán, ... MBio 5 (1), 10.1128/mbio. 00767-13, 2014 | 42 | 2014 |
Mechanism for Cas4-assisted directional spacer acquisition in CRISPR–Cas C Hu, C Almendros, KH Nam, AR Costa, JNA Vink, AC Haagsma, ... Nature 598 (7881), 515-520, 2021 | 33 | 2021 |
Conserved motifs in the CRISPR leader sequence control spacer acquisition levels in Type ID CRISPR-Cas systems SN Kieper, C Almendros, SJJ Brouns FEMS Microbiology Letters 366 (11), fnz129, 2019 | 23 | 2019 |
Using CAPTURE to detect spacer acquisition in native CRISPR arrays RE McKenzie, C Almendros, JNA Vink, SJJ Brouns Nature protocols 14 (3), 976-990, 2019 | 20 | 2019 |
El descubrimiento del sistema CRISPR-Cas J Mojica, C Almendros Investigación y Ciencia, 20-29, 2017 | 14 | 2017 |
Cas4–Cas1 is a protospacer adjacent motif–processing factor mediating half-site spacer integration during CRISPR adaptation SN Kieper, C Almendros, AC Haagsma, A Barendregt, AJR Heck, ... The CRISPR Journal 4 (4), 536-548, 2021 | 8 | 2021 |
Raw data to results: a hands-on introduction and overview of computational analysis for single-molecule localization microscopy KJA Martens, B Turkowyd, U Endesfelder Frontiers in Bioinformatics 1, 817254, 2022 | 6 | 2022 |
Exploring CRISPR Interference by Transformation with Plasmid Mixtures: Identification of Target Interference Motifs in Escherichia coli C Almendros, FJM Mojica CRISPR: Methods and Protocols, 161-170, 2015 | 3 | 2015 |
Adaptation by Type VA and VB CRISPR-Cas Systems Demonstrates Conserved Protospacer Selection Mechanisms Between Diverse CRISPR-Cas Types WY Wu, SA Jackson, C Almendros, AC Haagsma, S Yilmaz, G Gort, ... The CRISPR Journal 5 (4), 536-547, 2022 | | 2022 |
crISPr-caS SySteMS SN Kieper, C Almendros, SJJ Brouns CRISPR'S lIttle HelpeRs 366, 111, 2019 | | 2019 |
CRISPR-Cas Systems Reduced to a Minimum C Almendros, SN Kieper, SJJ Brouns Molecular cell 73 (4), 641-642, 2019 | | 2019 |