Biomaterial Database

Gene regulation by engineered CRISPR-Cas systems. 2014

Peter C Fineran, and Ron L Dy

Department of Microbiology and Immunology, University of Otago, PO Box 56, Dunedin 9054, New Zealand. Electronic address: peter.fineran@otago.ac.nz.

The clustered regularly interspaced short palindromic repeat (CRISPR) arrays and their CRISPR associated (Cas) proteins constitute adaptive immune systems in bacteria and archaea that provide protection from bacteriophages, plasmids and other mobile genetic elements (MGEs). Recently, the ability to direct these systems to DNA in a sequence-specific manner has led to the emergence of new technologies for engineered gene regulation in bacteria and eukaryotes. These systems have the potential to enable facile high-throughput functional genomics studies aimed at identifying gene function and will be a crucial tool for synthetic biology. Here, we review the recent engineering of these systems for controlling gene expression.

UI	MeSH Term	Description	Entries
D008967	Molecular Biology	A discipline concerned with studying biological phenomena in terms of the chemical and physical interactions of molecules.	Biochemical Genetics,Biology, Molecular,Genetics, Biochemical,Genetics, Molecular,Molecular Genetics,Biochemical Genetic,Genetic, Biochemical,Genetic, Molecular,Molecular Genetic
D005786	Gene Expression Regulation	Any of the processes by which nuclear, cytoplasmic, or intercellular factors influence the differential control (induction or repression) of gene action at the level of transcription or translation.	Gene Action Regulation,Regulation of Gene Expression,Expression Regulation, Gene,Regulation, Gene Action,Regulation, Gene Expression
D001105	Archaea	One of the three domains of life (the others being BACTERIA and Eukarya), formerly called Archaebacteria under the taxon Bacteria, but now considered separate and distinct. They are characterized by: (1) the presence of characteristic tRNAs and ribosomal RNAs; (2) the absence of peptidoglycan cell walls; (3) the presence of ether-linked lipids built from branched-chain subunits; and (4) their occurrence in unusual habitats. While archaea resemble bacteria in morphology and genomic organization, they resemble eukarya in their method of genomic replication. The domain contains at least four kingdoms: CRENARCHAEOTA; EURYARCHAEOTA; NANOARCHAEOTA; and KORARCHAEOTA.	Archaebacteria,Archaeobacteria,Archaeon,Archebacteria
D001419	Bacteria	One of the three domains of life (the others being Eukarya and ARCHAEA), also called Eubacteria. They are unicellular prokaryotic microorganisms which generally possess rigid cell walls, multiply by cell division, and exhibit three principal forms: round or coccal, rodlike or bacillary, and spiral or spirochetal. Bacteria can be classified by their response to OXYGEN: aerobic, anaerobic, or facultatively anaerobic; by the mode by which they obtain their energy: chemotrophy (via chemical reaction) or PHOTOTROPHY (via light reaction); for chemotrophs by their source of chemical energy: CHEMOLITHOTROPHY (from inorganic compounds) or chemoorganotrophy (from organic compounds); and by their source for CARBON; NITROGEN; etc.; HETEROTROPHY (from organic sources) or AUTOTROPHY (from CARBON DIOXIDE). They can also be classified by whether or not they stain (based on the structure of their CELL WALLS) with CRYSTAL VIOLET dye: gram-negative or gram-positive.	Eubacteria
D056890	Eukaryota	One of the three domains of life (the others being BACTERIA and ARCHAEA), also called Eukarya. These are organisms whose cells are enclosed in membranes and possess a nucleus. They comprise almost all multicellular and many unicellular organisms, and are traditionally divided into groups (sometimes called kingdoms) including ANIMALS; PLANTS; FUNGI; and various algae and other taxa that were previously part of the old kingdom Protista.	Eukaryotes,Eucarya,Eukarya,Eukaryotas,Eukaryote
D060847	Metabolic Engineering	Methods and techniques used to genetically modify cells' biosynthetic product output and develop conditions for growing the cells as BIOREACTORS.	Engineering, Metabolic
D020071	Interspersed Repetitive Sequences	Copies of transposable elements interspersed throughout the genome, some of which are still active and often referred to as "jumping genes". There are two classes of interspersed repetitive elements. Class I elements (or RETROELEMENTS - such as retrotransposons, retroviruses, LONG INTERSPERSED NUCLEOTIDE ELEMENTS and SHORT INTERSPERSED NUCLEOTIDE ELEMENTS) transpose via reverse transcription of an RNA intermediate. Class II elements (or DNA TRANSPOSABLE ELEMENTS - such as transposons, Tn elements, insertion sequence elements and mobile gene cassettes of bacterial integrons) transpose directly from one site in the DNA to another.	Dispersed Repetitive Sequences,Genes, Jumping,Interspersed Repetitive Elements,Jumping Genes,Mobile Genetic Elements,Repetitive Sequences, Dispersed,Repetitive Sequences, Interspersed,Elements, Mobile Genetic,Genetic Elements, Mobile,Dispersed Repetitive Sequence,Element, Interspersed Repetitive,Element, Mobile Genetic,Elements, Interspersed Repetitive,Gene, Jumping,Genetic Element, Mobile,Interspersed Repetitive Element,Interspersed Repetitive Sequence,Jumping Gene,Mobile Genetic Element,Repetitive Element, Interspersed,Repetitive Elements, Interspersed,Repetitive Sequence, Dispersed,Repetitive Sequence, Interspersed,Sequence, Dispersed Repetitive,Sequence, Interspersed Repetitive,Sequences, Dispersed Repetitive,Sequences, Interspersed Repetitive
D064113	CRISPR-Cas Systems	Adaptive antiviral defense mechanisms, in archaea and bacteria, based on DNA repeat arrays called CLUSTERED REGULARLY INTERSPACED SHORT PALINDROMIC REPEATS (CRISPR elements) that function in conjunction with CRISPR-ASSOCIATED PROTEINS (Cas proteins). Several types have been distinguished, including Type I, Type II, and Type III, based on signature motifs of CRISPR-ASSOCIATED PROTEINS.	CRISPR Cas Systems,CRISPR-Cas System,System, CRISPR-Cas,Systems, CRISPR-Cas