CRISPR-Cas, el editor de genes / CRISPR, gene editor

El término CRISPR, por su acrónimo en inglés refiere a Clustered Regularly Interspaced Short Palindromic Repeats, es decir, repeticiones palindrómicas cortas, agrupadas y regularmente esparcidas, por sus características en el genoma, pertenece naturalmente al sistema de defensa de bacterias y arqueas. Este ha sido adaptado biotecnológicamente para la edición del ADN de células eucariotas, incluso de células humanas. El sistema CRISPR-Cas para editar genes consta, en forma generalizada, de dos componentes: una proteína nucleasa (Cas) y un ARN guía (sgRNA). La simplicidad del complejo lo hace una herramienta molecular reprogramable capaz de ser dirigida y de editar cualquier sitio en un genoma conocido. Su principal foco son las terapias para enfermedades hereditarias monogénicas y para el cáncer. Sin embargo, además de editor de genes, la tecnología CRISPR se utiliza para edición epigenética, regulación de la expresión génica y método de diagnóstico molecular. Este artículo tiene por objetivo presentar una revisión de las aplicaciones de la herramienta molecular CRISPR-Cas, particularmente en el campo biomédico, posibles tratamientos y diagnósticos, y los avances en investigación clínica, utilizando terapia génica con CRISPR/Cas más relevantes hasta la fecha. (AU)

CRISPR are Clustered Regularly Interspaced Short Palindromic Repeats, which naturally belong to the defense system of bacteria and archaea. It has been biotechnologically adapted for editing the DNA of eukaryotic cells, including human cells. The CRISPR-Cas system for editing genes generally consists of two components, a nuclease protein (Cas) and a guide RNA (sgRNA). The simplicity of the complex makes it a reprogrammable molecular tool capable of being targeted and editing any site in a known genome. Its main focus is therapies for monogenic inherited diseases and cancer. However, in addition to gene editor, CRISPR technology is used for epigenetic editing, regulation of gene expression, and molecular diagnostic methods. This article aims to present a review of the applications of the CRISPR-Cas molecular tool, particularly in the biomedical field, possible treatments and diagnoses, and the advances in clinical research, using the most relevant CRISPR-Cas gene therapy to date. (AU)

Aplicación de la nanobiotecnología con el sistema CRISPR-cas / Application of the nanobiotechnology with the system CRISP-Cas

Resumen Introducción: La nanobiotecnología y la biología sintética son ciencias que impactan en la actualidad con el lanzamiento de aplicaciones innovadoras y beneficiosas para el ser humano, estas ciencias se han fusionado para fabricar nuevos componentes para la construcción de células totalmente artificiales y la creación de biomoléculas sintéticas. Objetivo: Conocer las aplicaciones de la nanobiotecnología relacionadas con el uso del sistema CRISPR/Cas en el almacenamiento de información en el ADN bacteriano y alternativas terapéuticas. Materiales y métodos: Se realizó una revisión bibliográfica sobre las principales aplicaciones de la nanobiotecnología, en las bases de datos ScienceDirect, SciELO, PubMed y en revistas como: Nature biotechnology, Biochemistry, Science y Journal Microbiology. Resultados: La revisión de literatura describe y analiza las nuevas aplicaciones nanobiotecnológicas utilizadas para escribir información en el código genético de las células bacterianas, en el que se emplean el sistema basado en repeticiones palindrómicas cortas agrupadas y regularmente interespaciadas (CRISPR/Cas) y la producción de ADN sintético, así como las alternativas terapéuticas relacionadas con la terapia génica. Conclusión: Entre las aplicaciones nanobiotecnológicas se han demostrado dos métodos para grabar información en el ADN de células bacterianas, de Escherichia coli y Sulfolobus tokodai vinculados con el empleo del sistema CRISPR/Cas y la producción de ADN sintético, así como el uso del CRISPR/Cas en la terapia génica y celular.

Abstract Introduction: Nanobiotechnology and synthetic biology are sciences that impact today with the launching of innovative and beneficial applications for the human being. These sciences have been amalgamated to manufacture new components for the construction of totally artificial cells and the creation of synthetic biomolecules. Objective: To know the applications of nanobiotechnology related to the use of the system CRISPR/Cas in the storage of bacterial DNA and therapeutic alternatives. Materials and methods: A bibliographical review on the main applications of nanobiotechnology was carried out in ScienceDirect, SciELO, PubMed databases and in magazines such as: Nature Biotechnology, Biochemistry, Science and Journal Microbiology. Results: The literature review describes and analyzes the new nanobiotechnology applications used to write information in the genetic code of bacterial cells, in which the system is used based on short grouped and regularly interspaced palindromic repetitions (CRISPR/Cas) and the production of synthetic DNA, as well as therapeutic alternatives related to gene therapy. Conclusion: Among the nanobiotechnology applications, two methods to record information in the DNA of bacterial cells Escherichia coli and Sulfolobus Tokodai have been shown, which are linked to the use of the system CRISPR/Cas and the production of synthetic DNA, as well as the use of CRISPR/Cas in gene and cellular therapy.

Clustered regularly interspaced short palindromic repeat associated protein genes cas1 and cas2 in Shigella / 中华流行病学杂志

<p><b>OBJECTIVE</b>To detect the distribution of clustered regularly interspaced short palindromic repeat (CRISPR) associated protein genes cas1 and cas2 in Shigella and to understand the characteristics of CRISPR with relationship between CRISPR and related characteristics on drug resistance.</p><p><b>METHODS</b>CRISPR associated protein genes cas1 and cas2 in Shigella were detected by PCR, with its products sequenced and compared.</p><p><b>RESULTS</b>The CRISPR-associated protein genes cas1 and cas2 were found in all the 196 Shigella isolates which were isolated at different times and locations in China. Consistencies showed through related sequencing appeared as follows: cas2, cas1 (a) and cas1 (b) were 96.44%, 97.61% and 96.97%, respectively. There were two mutations including 3177129 site(C→G)and 3177126 site (G→C) of cas1 (b) gene in 2003135 strain which were not found in the corresponding sites of Z23 and 2008113.</p><p><b>RESULTS</b>showed that in terms of both susceptibility and antibiotic-resistance, strain 2003135 was stronger than Z23 and 2008113.</p><p><b>CONCLUSION</b>CRISPR system widely existed in Shigella, with the level of drug resistance in cas1 (b) gene mutant strains higher than in wild strains. Cas1 (b) gene mutation might be one of the reasons causing the different levels of resistance.</p>