Cas9

Last updated
CRISPR-associated endonuclease Cas9
Streptococcus pyogenes Cas9-DNA-RNA complex PDB 4OO8.png
S. pyogenes Cas9 in complex with sgRNA and its target DNA. PDB: 4OO8 [1]
Identifiers
Organism Streptococcus pyogenes M1
Symbolcas9
Alt. symbolsSpCas9
Entrez 901176
PDB 4OO8
RefSeq (mRNA) NC_002737.2
RefSeq (Prot) NP_269215.1
UniProt Q99ZW2
Other data
EC number 3.1.-.-
Chromosome Genomic: 0.85 - 0.86 Mb
Search for
Structures Swiss-model
Domains InterPro
Cas9
Identifiers
Symbol?
InterPro IPR028629

Cas9 (CRISPR associated protein 9, formerly called Cas5, Csn1, or Csx12) is a 160 kilodalton protein which plays a vital role in the immunological defense of certain bacteria against DNA viruses and plasmids, and is heavily utilized in genetic engineering applications. Its main function is to cut DNA and thereby alter a cell's genome. The CRISPR-Cas9 genome editing technique was a significant contributor to the Nobel Prize in Chemistry in 2020 being awarded to Emmanuelle Charpentier and Jennifer Doudna. [2]

Contents

More technically, Cas9 is a dual RNA-guided DNA endonuclease enzyme associated with the Clustered Regularly Interspaced Short Palindromic Repeats (CRISPR) adaptive immune system in Streptococcus pyogenes . [3] [4] [5] S. pyogenes utilizes CRISPR to memorize and Cas9 to later interrogate and cleave foreign DNA, such as invading bacteriophage DNA or plasmid DNA. [4] [6] [7] [8] Cas9 performs this interrogation by unwinding foreign DNA and checking for sites complementary to the 20 nucleotide spacer region of the guide RNA (gRNA). If the DNA substrate is complementary to the guide RNA, Cas9 cleaves the invading DNA. In this sense, the CRISPR-Cas9 mechanism has a number of parallels with the RNA interference (RNAi) mechanism in eukaryotes.

Apart from its original function in bacterial immunity, the Cas9 protein has been heavily utilized as a genome engineering tool to induce site-directed double-strand breaks in DNA. These breaks can lead to gene inactivation or the introduction of heterologous genes through non-homologous end joining and homologous recombination respectively in many laboratory model organisms. Research on the development of various cas9 variants has been a promising way of overcoming the limitation of the CRISPR-Cas9 genome editing. Some examples include Cas9 nickase (Cas9n), a variant that induces single-stranded breaks (SSBs) or variants recognizing different PAM sequences. [9] Alongside zinc finger nucleases and transcription activator-like effector nuclease (TALEN) proteins, Cas9 is becoming a prominent tool in the field of genome editing.

Cas9 has gained traction in recent years because it can cleave nearly any sequence complementary to the guide RNA. [4] Because the target specificity of Cas9 stems from the guide RNA:DNA complementarity and not modifications to the protein itself (like TALENs and zinc fingers), engineering Cas9 to target new DNA is straightforward. [10] Versions of Cas9 that bind but do not cleave cognate DNA can be used to locate transcriptional activator or repressors to specific DNA sequences in order to control transcriptional activation and repression. [11] [12] Native Cas9 requires a guide RNA composed of two disparate RNAs that associate – the CRISPR RNA (crRNA), and the trans-activating crRNA (tracrRNA). [3] Cas9 targeting has been simplified through the engineering of a chimeric single guide RNA (chiRNA). Scientists have suggested that Cas9-based gene drives may be capable of editing the genomes of entire populations of organisms. [13] In 2015, Cas9 was used to modify the genome of human embryos for the first time. [14]

CRISPR-mediated immunity

To survive in a variety of challenging, inhospitable habitats that are filled with bacteriophages, bacteria and archaea have evolved methods to evade and fend off predatory viruses. This includes the CRISPR system of adaptive immunity. In practice, CRISPR/Cas systems act as self-programmable restriction enzymes. CRISPR loci are composed of short, palindromic repeats that occur at regular intervals composed of alternate CRISPR repeats and variable CRISPR spacers between 24 and 48 nucleotides long. These CRISPR loci are usually accompanied by adjacent CRISPR-associated (cas) genes. In 2005, it was discovered by three separate groups that the spacer regions were homologous to foreign DNA elements, including plasmids and viruses. These reports provided the first biological evidence that CRISPRs might function as an immune system.

Cas9 has been used often as a genome-editing tool. Cas9 has been used in recent developments in preventing viruses from manipulating hosts' DNA. Since the CRISPR-Cas9 was developed from bacterial genome systems, it can be used to target the genetic material in viruses. The use of the enzyme Cas9 can be a solution to many viral infections. Cas9 possesses the ability to target specific viruses by the targeting of specific strands of the viral genetic information. More specifically the Cas9 enzyme targets certain sections of the viral genome that prevents the virus from carrying out its normal function. [15] Cas9 has also been used to disrupt the detrimental strand of DNA and RNA that cause diseases and mutated strands of DNA. Cas9 has already showed promise in disrupting the effects of HIV-1. Cas9 has been shown to suppress the expression of the long terminal repeats in HIV-1. When introduced into the HIV-1 genome Cas9 has shown the ability to mutate strands of HIV-1. [16] [17] Cas9 has also been used in the treatment of Hepatitis B through targeting of the ends of certain of long terminal repeats in the Hepatitis B viral genome. [18] Cas9 has been used to repair the mutations causing cataracts in mice.

Fig. 2: The Stages of CRISPR immunity The Stages of CRISPR immunity.svg
Fig. 2: The Stages of CRISPR immunity

CRISPR-Cas systems are divided into three major types (type I, type II, and type III) and twelve subtypes, which are based on their genetic content and structural differences. However, the core defining features of all CRISPR-Cas systems are the cas genes and their proteins: cas1 and cas2 are universal across types and subtypes, while cas3, cas9, and cas10 are signature genes for type I, type II, and type III, respectively.

CRISPR-Cas defense stages

Adaptation

Adaptation involves recognition and integration of spacers between two adjacent repeats in the CRISPR locus. The "Protospacer" refers to the sequence on the viral genome that corresponds to the spacer. A short stretch of conserved nucleotides exists proximal to the protospacer, which is called the protospacer adjacent motif (PAM). The PAM is a recognition motif that is used to acquire the DNA fragment. [8] In type II, Cas9 recognizes the PAM during adaptation in order to ensure the acquisition of functional spacers. [6]

Loss of spacers and even groups of several have also been observed by Aranaz et al. 2004 and Pourcel et al. 2007. This probably occurs through homologous recombination of the between-repeat material. [19]

CRISPR processing/biogenesis

CRISPR expression includes the transcription of a primary transcript called a CRISPR RNA (pre-crRNA), which is transcribed from the CRISPR locus by RNA polymerase. Specific endoribonucleases then cleave the pre-crRNAs into small CRISPR RNAs (crRNAs). [20]

Interference/immunity

Interference involves the crRNAs within a multi-protein complex called CASCADE, which can recognize and specifically base-pair with regions of inserting complementary foreign DNA. The crRNA-foreign nucleic acid complex is then cleaved, however if there are mismatches between the spacer and the target DNA, or if there are mutations in the PAM, then cleavage will not be initiated. In the latter scenario, the foreign DNA is not targeted for attack by the cell, thus the replication of the virus proceeds and the host is not immune to viral infection. The interference stage can be mechanistically and temporally distinct from CRISPR acquisition and expression, yet for complete function as a defense system, all three phases must be functional. [21]

Stage 1: CRISPR spacer integration. Protospacers and protospacer-associated motifs (shown in red) are acquired at the "leader" end of a CRISPR array in the host DNA. The CRISPR array is composed of spacer sequences (shown in colored boxes) flanked by repeats (black diamonds). This process requires Cas1 and Cas2 (and Cas9 in type II [6] ), which are encoded in the cas locus, which are usually located near the CRISPR array.

Stage 2: CRISPR expression. Pre-crRNA is transcribed starting at the leader region by the host RNA polymerase and then cleaved by Cas proteins into smaller crRNAs containing a single spacer and a partial repeat (shown as hairpin structure with colored spacers).

Stage 3: CRISPR interference. crRNA with a spacer that has strong complementarity to the incoming foreign DNA begins a cleavage event (depicted with scissors), which requires Cas proteins. DNA cleavage interferes with viral replication and provides immunity to the host. The interference stage can be functionally and temporarily distinct from CRISPR acquisition and expression (depicted by white line dividing the cell).

Transcription deactivation using dCas9

dCas9, also referred to as endonuclease deficient Cas9 can be utilized to edit gene expression when applied to the transcription binding site of the desired section of a gene. The optimal function of dCas9 is attributed to its mode of action. Gene expression is inhibited when nucleotides are no longer added to the RNA chain and therefore terminating elongation of that chain, and as a result affects the transcription process. This process occurs when dCas9 is mass-produced so it is able to affect the most genes at any given time via a sequence specific guide RNA molecule. Since dCas9 appears to down regulate gene expression, this action is amplified even more when it is used in conjunction with repressive chromatin modifier domains. [22] The dCas9 protein has other functions outside of the regulation of gene expression. A promoter can be added to the dCas9 protein which allows them to work with each other to become efficient at beginning or stopping transcription at different sequences along a strand of DNA. These two proteins are specific in where they act on a gene. This is prevalent in certain types of prokaryotes when a promoter and dCas9 align themselves together to impede the ability of elongation of polymer of nucleotides coming together to form a transcribed piece of DNA. Without the promoter, the dCas9 protein does not have the same effect by itself or with a gene body. [23]

When examining the effects of repression of transcription further, H3K27, an amino acid component of a histone, becomes methylated through the interaction of dCas9 and a peptide called FOG1. Essentially, this interaction causes gene repression on the C + N terminal section of the amino acid complex at the specific junction of the gene, and as a result, terminates transcription. [24]

dCas9 also proves to be efficient when it comes to altering certain proteins that can create diseases. When the dCas9 attaches to a form of RNA called guide-RNA, it prevents the proliferation of repeating codons and DNA sequences that might be harmful to an organism's genome. Essentially, when multiple repeat codons are produced, it elicits a response, or recruits an abundance of dCas9 to combat the overproduction of those codons and results in the shut-down of transcription. dCas9 works synergistically with gRNA and directly affects the DNA polymerase II from continuing transcription.

Further explanation of how the dCas9 protein works can be found in their utilization of plant genomes by the regulation of gene production in plants to either increase or decrease certain characteristics. The CRISPR-CAS9 system has the ability to either upregulate or downregulate genes. The dCas9 proteins are a component of the CRISPR-CAS9 system and these proteins can repress certain areas of a plant gene. This happens when dCAS9 binds to repressor domains, and in the case of the plants, deactivation of a regulatory gene such as AtCSTF64, does occur. [25]

Bacteria are another focus of the usage of dCas9 proteins as well. Since eukaryotes have a larger DNA makeup and genome; the much smaller bacteria are easy to manipulate. As a result, eukaryotes use dCas9 to inhibit RNA polymerase from continuing the process of transcription of genetic material. [26]

Structural and biochemical studies

Crystal structure

Crystal structure of CRISPR-associated protein Cas9, based on PDB 5AXW by Nishimasu et al. Cas9 5AXW.png
Crystal structure of CRISPR-associated protein Cas9, based on PDB 5AXW by Nishimasu et al.

Cas9 features a bi-lobed architecture with the guide RNA nestled between the alpha-helical lobe (blue) and the nuclease lobe (cyan, orange, and gray). These two lobes are connected through a single bridge helix. There are two nuclease domains located in the multi-domain nuclease lobe, the RuvC (gray) which cleaves the non-target DNA strand, and the HNH nuclease domain (cyan) that cleaves the target strand of DNA. The RuvC domain is encoded by sequentially disparate sites that interact in the tertiary structure to form the RuvC cleavage domain (See right figure).

Crystal structure of Cas9 in the Apo form. Structural rendition was performed using UCSF Chimera software. Cas9 Apo Structure.png
Crystal structure of Cas9 in the Apo form. Structural rendition was performed using UCSF Chimera software.

A key feature of the target DNA is that it must contain a protospacer adjacent motif (PAM) consisting of the three-nucleotide sequence- NGG. This PAM is recognized by the PAM-interacting domain (PI domain, orange) located near the C-terminal end of Cas9. Cas9 undergoes distinct conformational changes between the apo, guide RNA bound, and guide RNA:DNA bound states.

Cas9 recognizes the stem-loop architecture inherent in the CRISPR locus, which mediates the maturation of crRNA-tracrRNA ribonucleoprotein complex. [28] Cas9 in complex with CRISPR RNA (crRNA) and trans-activating crRNA (tracrRNA) further recognizes and degrades the target dsDNA. [29] In the co-crystal structure shown here, the crRNA-tracrRNA complex is replaced by a chimeric single-guide RNA (sgRNA, in red) which has been proved to have the same function as the natural RNA complex. [4] The sgRNA base paired with target ssDNA is anchored by Cas9 as a T-shaped architecture. This crystal structure of the DNA-bound Cas9 enzyme reveals distinct conformational changes in the alpha-helical lobe with respect to the nuclease lobe, as well as the location of the HNH domain. The protein consists of a recognition lobe (REC) and a nuclease lobe (NUC). All regions except the HNH form tight interactions with each other and sgRNA-ssDNA complex, while the HNH domain forms few contacts with the rest of the protein. In another conformation of Cas9 complex observed in the crystal, the HNH domain is not visible. These structures suggest the conformational flexibility of HNH domain.

To date, at least three crystal structures have been studied and published. One representing a conformation of Cas9 in the apo state, [27] and two representing Cas9 in the DNA bound state. [30] [1]

Interactions with sgRNA

CRISPR/Cas9 GRNA-Cas9.svg
CRISPR/Cas9

In sgRNA-Cas9 complex, based on the crystal structure, REC1, BH and PI domains have important contacts with backbone or bases in both repeat and spacer region. [1] [30] Several Cas9 mutants including REC1 or REC2 domains deletion and residues mutations in BH have been tested. REC1 and BH related mutants show lower or none activity compared with wild type, which indicate these two domains are crucial for the sgRNA recognition at repeat sequence and stabilization of the whole complex. Although the interactions between spacer sequence and Cas9 as well as PI domain and repeat region need further studies, the co-crystal demonstrates clear interface between Cas9 and sgRNA.

DNA cleavage

Cas9 nuclease and its DNA cleavage position Cas9 cleavage position.svg
Cas9 nuclease and its DNA cleavage position

Previous sequence analysis and biochemical studies have posited that Cas9 contains two nuclease domains: an McrA-like HNH nuclease domain and a RuvC-like nuclease domain. [31] These HNH and RuvC-like nuclease domains are responsible for cleavage of the complementary/target and non-complementary/non-target DNA strands, respectively. [4] Despite low sequence similarity, the sequence similar to RNase H has a RuvC fold (one member of RNase H family) and the HNH region folds as T4 Endo VII (one member of HNH endonuclease family).[ citation needed ]

Wild-type S. pyogenes Cas9 requires magnesium (Mg2+) cofactors for the RNA-mediated DNA cleavage; however, Cas9 has been shown to exhibit varying levels of activity in the presence of other divalent metal ions. [4] For instance, Cas9 in the presence of manganese (Mn2+) has been shown to be capable of RNA-independent DNA cleavage. [32] The kinetics of DNA cleavage by Cas9 have been of great interest to the scientific community, as this data provides insight into the intricacies of the reaction. While the cleavage of DNA by RNA-bound Cas9 has been shown to be relatively rapid ( k ≥ 700 s−1), the release of the cleavage products is very slow (t1/2 = ln(2)/k ≈ 43–91 h), essentially rendering Cas9 a single-turnover enzyme. [33] Additional studies regarding the kinetics of Cas9 have shown engineered Cas9 to be effective in reducing off-target effects by modifying the rate of the reaction. [34] [35]

The cleavage efficiency of Cas9 depends on numerous factors. A key requirement is the presence of a valid PAM at the non-target strand 3 nucleotides downstream from the cleavage site. [36] The canonical PAM sequence for S. Pyogenes Cas9 is NGG, but alternative motifs are tolerated with lower cleavage activity. The most efficient alternative PAM motifs for the wild-type S. Pyogenes Cas9 are NAG and NGA. [37] [38] The sequence composition at the target DNA site complementary to the 20 nucletode spacer region of the gRNA also affects cleavage efficiency. The most relevant nucleotide composition properties that impact efficiency are those in the PAM-proximal region. [39] [40] [38] Free energy changes of nucleic acids are also highly relevant in defining cleavage activity. [41] Guide RNAs that bind to the DNA forming a duplex that falls into a restricted range of binding free energy changes that excludes extremely weak or stable bindings generally perform efficiently. [38] Stable guide RNA folding conformations can also impair cleavage. [42]

Problems bacteria pose to Cas9 editing

Most archaea and bacteria stubbornly refuse to allow a Cas9 to edit their genome. This is because they can attach foreign DNA, that does not affect them, into their genome. Another way that these cells defy Cas9 is by process of restriction modification (RM) system. When a bacteriophage enters a bacteria or archaea cell it is targeted by the RM system. The RM system then cuts the bacteriophages DNA into separate pieces by restriction enzymes and uses endonucleases to further destroy the strands of DNA. This poses a problem to Cas9 editing because the RM system also targets the foreign genes added by the Cas9 process. [43]

Applications of Cas9 to transcription tuning

Interference of transcription by dCas9

Due to the unique ability of Cas9 to bind to essentially any complement sequence in any genome, researchers wanted to use this enzyme to repress transcription of various genomic loci. To accomplish this, the two crucial catalytic residues of the RuvC and HNH domain can be mutated to alanine abolishing all endonuclease activity of Cas9. The resulting protein coined 'dead' Cas9 or 'dCas9' for short, can still tightly bind to dsDNA. This catalytically inactive Cas9 variant has been used for both mechanistic studies into Cas9 DNA interrogative binding and as a general programmable DNA binding RNA-Protein complex.

The interaction of dCas9 with target dsDNA is so tight that high molarity urea protein denaturant can not fully dissociate the dCas9 RNA-protein complex from dsDNA target. [44] dCas9 has been targeted with engineered single guide RNAs to transcription initiation sites of any loci where dCas9 can compete with RNA polymerase at promoters to halt transcription. [45] Also, dCas9 can be targeted to the coding region of loci such that inhibition of RNA Polymerase occurs during the elongation phase of transcription. [45] In Eukaryotes, silencing of gene expression can be extended by targeting dCas9 to enhancer sequences, where dCas9 can block assembly of transcription factors leading to silencing of specific gene expression. [12] Moreover, the guide RNAs provided to dCas9 can be designed to include specific mismatches to its complementary cognate sequence that will quantitatively weaken the interaction of dCas9 for its programmed cognate sequence allowing a researcher to tune the extent of gene silencing applied to a gene of interest. [45] This technology is similar in principle to RNAi such that gene expression is being modulated at the RNA level. However, the dCas9 approach has gained much traction as there exist less off-target effects and in general larger and more reproducible silencing effects through the use of dCas9 compared to RNAi screens. [46] Furthermore, because the dCas9 approach to gene silencing can be quantitatively controlled, a researcher can now precisely control the extent to which a gene of interest is repressed allowing more questions about gene regulation and gene stoichiometry to be answered.

Beyond direct binding of dCas9 to transcriptionally sensitive positions of loci, dCas9 can be fused to a variety of modulatory protein domains to carry out a myriad of functions. Recently, dCas9 has been fused to chromatin remodeling proteins (HDACs/HATs) to reorganize the chromatin structure around various loci. [45] This is important in targeting various eukaryotic genes of interest as heterochromatin structures hinder Cas9 binding. Furthermore, because Cas9 can react to heterochromatin, it is theorized that this enzyme can be further applied to studying the chromatin structure of various loci. [45] Additionally, dCas9 has been employed in genome wide screens of gene repression. By employing large libraries of guide RNAs capable of targeting thousands of genes, genome wide genetic screens using dCas9 have been conducted. [47]

Another method for silencing transcription with Cas9 is to directly cleave mRNA products with the catalytically active Cas9 enzyme. [48] This approach is made possible by hybridizing ssDNA with a PAM complement sequence to ssRNA allowing for a dsDNA-RNA PAM site for Cas9 binding. This technology makes available the ability to isolate endogenous RNA transcripts in cells without the need to induce chemical modifications to RNA or RNA tagging methods.

Transcription activation by dCas9 fusion proteins

In contrast to silencing genes, dCas9 can also be used to activate genes when fused to transcription activating factors. [45] These factors include subunits of bacterial RNA Polymerase II and traditional transcription factors in eukaryotes. Recently, genome-wide screens of transcription activation have also been accomplished using dCas9 fusions named 'CRISPRa' for activation. [47]

See also

Related Research Articles

Gene knockdown is an experimental technique by which the expression of one or more of an organism's genes is reduced. The reduction can occur either through genetic modification or by treatment with a reagent such as a short DNA or RNA oligonucleotide that has a sequence complementary to either gene or an mRNA transcript.

<span class="mw-page-title-main">CRISPR</span> Family of DNA sequence found in prokaryotic organisms

CRISPR is a family of DNA sequences found in the genomes of prokaryotic organisms such as bacteria and archaea. These sequences are derived from DNA fragments of bacteriophages that had previously infected the prokaryote. They are used to detect and destroy DNA from similar bacteriophages during subsequent infections. Hence these sequences play a key role in the antiviral defense system of prokaryotes and provide a form of acquired immunity. CRISPR is found in approximately 50% of sequenced bacterial genomes and nearly 90% of sequenced archaea.

Guide RNA (gRNA) or single guide RNA (sgRNA) is a short sequence of RNA that functions as a guide for the Cas9-endonuclease or other Cas-proteins that cut the double-stranded DNA and thereby can be used for gene editing. In bacteria and archaea, gRNAs are a part of the CRISPR-Cas system that serves as an adaptive immune defense that protects the organism from viruses. Here the short gRNAs serve as detectors of foreign DNA and direct the Cas-enzymes that degrades the foreign nucleic acid.

<i>Fok</i>I Restriction enzyme

The restriction endonuclease Fok1, naturally found in Flavobacterium okeanokoites, is a bacterial type IIS restriction endonuclease consisting of an N-terminal DNA-binding domain and a non sequence-specific DNA cleavage domain at the C-terminal. Once the protein is bound to duplex DNA via its DNA-binding domain at the 5'-GGATG-3' recognition site, the DNA cleavage domain is activated and cleaves the DNA at two locations, regardless of the nucleotide sequence at the cut site. The DNA is cut 9 nucleotides downstream of the motif on the forward strand, and 13 nucleotides downstream of the motif on the reverse strand, producing two sticky ends with 4-bp overhangs.

<span class="mw-page-title-main">Genome editing</span> Type of genetic engineering

Genome editing, or genome engineering, or gene editing, is a type of genetic engineering in which DNA is inserted, deleted, modified or replaced in the genome of a living organism. Unlike early genetic engineering techniques that randomly inserts genetic material into a host genome, genome editing targets the insertions to site-specific locations. The basic mechanism involved in genetic manipulations through programmable nucleases is the recognition of target genomic loci and binding of effector DNA-binding domain (DBD), double-strand breaks (DSBs) in target DNA by the restriction endonucleases, and the repair of DSBs through homology-directed recombination (HDR) or non-homologous end joining (NHEJ).

<span class="mw-page-title-main">Genetic engineering techniques</span> Methods used to change the DNA of organisms

Genetic engineering techniques allow the modification of animal and plant genomes. Techniques have been devised to insert, delete, and modify DNA at multiple levels, ranging from a specific base pair in a specific gene to entire genes. There are a number of steps that are followed before a genetically modified organism (GMO) is created. Genetic engineers must first choose what gene they wish to insert, modify, or delete. The gene must then be isolated and incorporated, along with other genetic elements, into a suitable vector. This vector is then used to insert the gene into the host genome, creating a transgenic or edited organism.

<span class="mw-page-title-main">CRISPR interference</span> Genetic perturbation technique

CRISPR interference (CRISPRi) is a genetic perturbation technique that allows for sequence-specific repression of gene expression in prokaryotic and eukaryotic cells. It was first developed by Stanley Qi and colleagues in the laboratories of Wendell Lim, Adam Arkin, Jonathan Weissman, and Jennifer Doudna. Sequence-specific activation of gene expression refers to CRISPR activation (CRISPRa).

<span class="mw-page-title-main">Epigenome editing</span>

Epigenome editing or epigenome engineering is a type of genetic engineering in which the epigenome is modified at specific sites using engineered molecules targeted to those sites. Whereas gene editing involves changing the actual DNA sequence itself, epigenetic editing involves modifying and presenting DNA sequences to proteins and other DNA binding factors that influence DNA function. By "editing” epigenomic features in this manner, researchers can determine the exact biological role of an epigenetic modification at the site in question.

A protospacer adjacent motif (PAM) is a 2–6-base pair DNA sequence immediately following the DNA sequence targeted by the Cas9 nuclease in the CRISPR bacterial adaptive immune system. The PAM is a component of the invading virus or plasmid, but is not found in the bacterial host genome and hence is not a component of the bacterial CRISPR locus. Cas9 will not successfully bind to or cleave the target DNA sequence if it is not followed by the PAM sequence. PAM is an essential targeting component which distinguishes bacterial self from non-self DNA, thereby preventing the CRISPR locus from being targeted and destroyed by the CRISPR-associated nuclease.

<span class="mw-page-title-main">Cas12a</span> DNA-editing technology

Cas12a is a subtype of Cas12 proteins and an RNA-guided endonuclease that forms part of the CRISPR system in some bacteria and archaea. It originates as part of a bacterial immune mechanism, where it serves to destroy the genetic material of viruses and thus protect the cell and colony from viral infection. Cas12a and other CRISPR associated endonucleases use an RNA to target nucleic acid in a specific and programmable matter. In the organisms from which it originates, this guide RNA is a copy of a piece of foreign nucleic acid that previously infected the cell.

No-SCAR genome editing is an editing method that is able to manipulate the Escherichia coli genome. The system relies on recombineering whereby DNA sequences are combined and manipulated through homologous recombination. No-SCAR is able to manipulate the E. coli genome without the use of the chromosomal markers detailed in previous recombineering methods. Instead, the λ-Red recombination system facilitates donor DNA integration while Cas9 cleaves double-stranded DNA to counter-select against wild-type cells. Although λ-Red and Cas9 genome editing are widely used technologies, the no-SCAR method is novel in combining the two functions; this technique is able to establish point mutations, gene deletions, and short sequence insertions in several genomic loci with increased efficiency and time sensitivity.

J. Keith Joung is an American pathologist and molecular biologist who holds the Robert B. Colvin Endowed Chair in Pathology at Massachusetts General Hospital and is Professor of Pathology at Harvard Medical School. He is a leading figure in the field of genome editing and has pioneered the development of designer nucleases and sensitive off-target detection methods.

CRISPR-Display (CRISP-Disp) is a modification of the CRISPR/Cas9 system for genome editing. The CRISPR/Cas9 system uses a short guide RNA (sgRNA) sequence to direct a Streptococcus pyogenes Cas9 nuclease, acting as a programmable DNA binding protein, to cleave DNA at a site of interest.

CRISPR activation (CRISPRa) is a type of CRISPR tool that uses modified versions of CRISPR effectors without endonuclease activity, with added transcriptional activators on dCas9 or the guide RNAs (gRNAs).

Off-target genome editing refers to nonspecific and unintended genetic modifications that can arise through the use of engineered nuclease technologies such as: clustered, regularly interspaced, short palindromic repeats (CRISPR)-Cas9, transcription activator-like effector nucleases (TALEN), meganucleases, and zinc finger nucleases (ZFN). These tools use different mechanisms to bind a predetermined sequence of DNA (“target”), which they cleave, creating a double-stranded chromosomal break (DSB) that summons the cell's DNA repair mechanisms and leads to site-specific modifications. If these complexes do not bind at the target, often a result of homologous sequences and/or mismatch tolerance, they will cleave off-target DSB and cause non-specific genetic modifications. Specifically, off-target effects consist of unintended point mutations, deletions, insertions inversions, and translocations.

<span class="mw-page-title-main">CRISPR gene editing</span> Gene editing method

CRISPR gene editing standing for "Clustered Regularly Interspaced Short Palindromic Repeats" is a genetic engineering technique in molecular biology by which the genomes of living organisms may be modified. It is based on a simplified version of the bacterial CRISPR-Cas9 antiviral defense system. By delivering the Cas9 nuclease complexed with a synthetic guide RNA (gRNA) into a cell, the cell's genome can be cut at a desired location, allowing existing genes to be removed and/or new ones added in vivo.

<span class="mw-page-title-main">Anti-CRISPR</span> Group of proteins found in phages

Anti-CRISPR is a group of proteins found in phages, that inhibit the normal activity of CRISPR-Cas, the immune system of certain bacteria. CRISPR consists of genomic sequences that can be found in prokaryotic organisms, that come from bacteriophages that infected the bacteria beforehand, and are used to defend the cell from further viral attacks. Anti-CRISPR results from an evolutionary process occurred in phages in order to avoid having their genomes destroyed by the prokaryotic cells that they will infect.

Prime editing is a 'search-and-replace' genome editing technology in molecular biology by which the genome of living organisms may be modified. The technology directly writes new genetic information into a targeted DNA site. It uses a fusion protein, consisting of a catalytically impaired Cas9 endonuclease fused to an engineered reverse transcriptase enzyme, and a prime editing guide RNA (pegRNA), capable of identifying the target site and providing the new genetic information to replace the target DNA nucleotides. It mediates targeted insertions, deletions, and base-to-base conversions without the need for double strand breaks (DSBs) or donor DNA templates.

<span class="mw-page-title-main">CRISPR RNA</span> RNA transcript from the CRISPR locus

CRISPR RNA or crRNA is a RNA transcript from the CRISPR locus. CRISPR-Cas is an adaptive immune system found in bacteria and archaea to protect against mobile genetic elements, like viruses, plasmids, and transposons. The CRISPR locus contains a series of repeats interspaced with unique spacers. These unique spacers can be acquired from MGEs.

The Fanzor (Fz) protein is an eukaryotic, RNA-guided DNA endonuclease, which means it is a type of DNA cutting enzyme that uses RNA to target genes of interest. It has been recently discovered and explored in a number of studies. In bacteria, RNA-guided DNA endonuclease systems, such as the CRISPR/Cas system, serve as an immune system to prevent infection by cutting viral genetic material. Currently, CRISPR/Cas9-mediated's DNA cleavage has extensive application in biological research, and wide-reaching medical potential in human gene editing.

References

  1. 1 2 3 Nishimasu H, Ran FA, Hsu PD, Konermann S, Shehata SI, Dohmae N, Ishitani R, Zhang F, Nureki O (February 2014). "Crystal structure of Cas9 in complex with guide RNA and target DNA". Cell. 156 (5): 935–49. doi:10.1016/j.cell.2014.02.001. PMC   4139937 . PMID   24529477.
  2. "The Nobel Prize in Chemistry 2020". NobelPrize.org. Retrieved 2020-10-07.
  3. 1 2 Deltcheva E, Chylinski K, Sharma CM, Gonzales K, Chao Y, Pirzada ZA, Eckert MR, Vogel J, Charpentier E (March 2011). "CRISPR RNA maturation by trans-encoded small RNA and host factor RNase III". Nature. 471 (7340): 602–607. Bibcode:2011Natur.471..602D. doi:10.1038/nature09886. PMC   3070239 . PMID   21455174.
  4. 1 2 3 4 5 6 Jinek M, Chylinski K, Fonfara I, Hauer M, Doudna JA, Charpentier E (August 2012). "A programmable dual-RNA-guided DNA endonuclease in adaptive bacterial immunity". Science. 337 (6096): 816–21. Bibcode:2012Sci...337..816J. doi:10.1126/science.1225829. PMC   6286148 . PMID   22745249.
  5. Oh HS, Diaz FM, Zhou C, Carpenter N, Knipe DM (2022-01-01). "CRISPR-Cas9 Expressed in Stably Transduced Cell Lines Promotes Recombination and Selects for Herpes Simplex Virus Recombinants". Current Research in Virological Science. 3: 100023. doi:10.1016/j.crviro.2022.100023. PMC   9629518 . PMID   36330462.
  6. 1 2 3 Heler R, Samai P, Modell JW, Weiner C, Goldberg GW, Bikard D, Marraffini LA (March 2015). "Cas9 specifies functional viral targets during CRISPR-Cas adaptation". Nature. 519 (7542): 199–202. Bibcode:2015Natur.519..199H. doi:10.1038/nature14245. PMC   4385744 . PMID   25707807.
  7. Barrangou R, Fremaux C, Deveau H, Richards M, Boyaval P, Moineau S, et al. (March 2007). "CRISPR provides acquired resistance against viruses in prokaryotes". Science. 315 (5819): 1709–12. Bibcode:2007Sci...315.1709B. doi:10.1126/science.1138140. hdl: 20.500.11794/38902 . PMID   17379808. S2CID   3888761.
  8. 1 2 Garneau JE, Dupuis MÈ, Villion M, Romero DA, Barrangou R, Boyaval P, Fremaux C, Horvath P, Magadán AH, Moineau S (November 2010). "The CRISPR/Cas bacterial immune system cleaves bacteriophage and plasmid DNA". Nature. 468 (7320): 67–71. Bibcode:2010Natur.468...67G. CiteSeerX   10.1.1.451.9645 . doi:10.1038/nature09523. PMID   21048762. S2CID   205222849.
  9. Uddin, Fathema; M. Rudin, Charles; Sen, Triparna (August 2020). "CRISPR Gene Therapy: Applications, Limitations, and Implications for the Future". Frontiers in Oncology. 10: 1387. doi: 10.3389/fonc.2020.01387 . PMC   7427626 . PMID   32850447.
  10. Mali P, Esvelt KM, Church GM (October 2013). "Cas9 as a versatile tool for engineering biology". Nature Methods. 10 (10): 957–63. doi:10.1038/nmeth.2649. PMC   4051438 . PMID   24076990.
  11. Mali P, Aach J, Stranges PB, Esvelt KM, Moosburner M, Kosuri S, Yang L, Church GM (September 2013). "CAS9 transcriptional activators for target specificity screening and paired nickases for cooperative genome engineering". Nature Biotechnology. 31 (9): 833–8. doi:10.1038/nbt.2675. PMC   3818127 . PMID   23907171.
  12. 1 2 Gilbert LA, Larson MH, Morsut L, Liu Z, Brar GA, Torres SE, Stern-Ginossar N, Brandman O, Whitehead EH, Doudna JA, Lim WA, Weissman JS, Qi LS (July 2013). "CRISPR-mediated modular RNA-guided regulation of transcription in eukaryotes". Cell. 154 (2): 442–51. doi:10.1016/j.cell.2013.06.044. PMC   3770145 . PMID   23849981.
  13. Esvelt KM, Smidler AL, Catteruccia F, Church GM (July 2014). "Concerning RNA-guided gene drives for the alteration of wild populations". eLife. 3. doi: 10.7554/eLife.03401 . PMC   4117217 . PMID   25035423.
  14. Cyranoski D, Reardon S (22 April 2015). "Chinese scientists genetically modify human embryos". Nature. doi:10.1038/nature.2015.17378. S2CID   87604469.
  15. Doudna JA, Mali P (2016). CRISPR-Cas: a laboratory manual. Cold Spring Harbor, New York. ISBN   9781621821304. OCLC   922914104.{{cite book}}: CS1 maint: location missing publisher (link)
  16. Chen W, Page-McCaw PS (March 2019). "CRISPR/Cas9 gene editing". AccessScience. McGraw-Hill Education. doi:10.1036/1097-8542.168060.
  17. Ebina H, Misawa N, Kanemura Y, Koyanagi Y (2013-08-26). "Harnessing the CRISPR/Cas9 system to disrupt latent HIV-1 provirus". Scientific Reports. 3 (1): 2510. Bibcode:2013NatSR...3E2510E. doi:10.1038/srep02510. PMC   3752613 . PMID   23974631.
  18. Li H, Sheng C, Wang S, Yang L, Liang Y, Huang Y, Liu H, Li P, Yang C, Yang X, Jia L, Xie J, Wang L, Hao R, Du X, Xu D, Zhou J, Li M, Sun Y, Tong Y, Li Q, Qiu S, Song H (2017-03-22). "Removal of Integrated Hepatitis B Virus DNA Using CRISPR-Cas9". Frontiers in Cellular and Infection Microbiology. 7: 91. doi: 10.3389/fcimb.2017.00091 . PMC   5360708 . PMID   28382278.
  19. Deveau H, Garneau JE, Moineau S (2010-10-13). "CRISPR/Cas system and its role in phage-bacteria interactions". Annual Review of Microbiology. 64 (1). Annual Reviews: 475–493. doi:10.1146/annurev.micro.112408.134123. PMID   20528693.
  20. Horvath P, Barrangou R (January 2010). "CRISPR/Cas, the immune system of bacteria and archaea". Science. 327 (5962): 167–70. Bibcode:2010Sci...327..167H. doi:10.1126/science.1179555. PMID   20056882. S2CID   17960960.
  21. Karginov FV, Hannon GJ (January 2010). "The CRISPR system: small RNA-guided defense in bacteria and archaea". Molecular Cell. 37 (1): 7–19. doi:10.1016/j.molcel.2009.12.033. PMC   2819186 . PMID   20129051.
  22. Jensen ED, Ferreira R, Jakočiūnas T, Arsovska D, Zhang J, Ding L, et al. (March 2017). "Transcriptional reprogramming in yeast using dCas9 and combinatorial gRNA strategies". Microbial Cell Factories. 16 (1): 46. doi: 10.1186/s12934-017-0664-2 . PMC   5353793 . PMID   28298224.
  23. Pinto BS, Saxena T, Oliveira R, Méndez-Gómez HR, Cleary JD, Denes LT, McConnell O, Arboleda J, Xia G, Swanson MS, Wang ET (November 2017). "Impeding Transcription of Expanded Microsatellite Repeats by Deactivated Cas9". Molecular Cell. 68 (3): 479–490.e5. doi:10.1016/j.molcel.2017.09.033. PMC   6013302 . PMID   29056323.
  24. O'Geen H, Ren C, Nicolet CM, Perez AA, Halmai J, Le VM, Mackay JP, Farnham PJ, Segal DJ (September 2017). "dCas9-based epigenome editing suggests acquisition of histone methylation is not sufficient for target gene repression". Nucleic Acids Research. 45 (17): 9901–9916. doi:10.1093/nar/gkx578. PMC   5622328 . PMID   28973434.
  25. Lowder LG, Paul JW, Qi Y (2017). "Multiplexed Transcriptional Activation or Repression in Plants Using CRISPR-dCas9-Based Systems". Plant Gene Regulatory Networks. Methods in Molecular Biology. Vol. 1629. pp. 167–184. doi:10.1007/978-1-4939-7125-1_12. ISBN   978-1-4939-7124-4. PMID   28623586.
  26. Barrangou R, Horvath P (June 2017). "A decade of discovery: CRISPR functions and applications". Nature Microbiology. 2 (7): 17092. doi:10.1038/nmicrobiol.2017.92. PMID   28581505. S2CID   19072900.
  27. 1 2 Jinek M, Jiang F, Taylor DW, Sternberg SH, Kaya E, Ma E, Anders C, Hauer M, Zhou K, Lin S, Kaplan M, Iavarone AT, Charpentier E, Nogales E, Doudna JA (March 2014). "Structures of Cas9 endonucleases reveal RNA-mediated conformational activation". Science. 343 (6176): 1247997. doi:10.1126/science.1247997. PMC   4184034 . PMID   24505130.
  28. Wiedenheft B, Sternberg SH, Doudna JA (February 2012). "RNA-guided genetic silencing systems in bacteria and archaea". Nature. 482 (7385): 331–8. Bibcode:2012Natur.482..331W. doi:10.1038/nature10886. PMID   22337052. S2CID   205227944.
  29. Ran FA, Hsu PD, Wright J, Agarwala V, Scott DA, Zhang F (November 2013). "Genome engineering using the CRISPR-Cas9 system". Nature Protocols. 8 (11): 2281–2308. doi:10.1038/nprot.2013.143. PMC   3969860 . PMID   24157548.
  30. 1 2 Anders C, Niewoehner O, Duerst A, Jinek M (September 2014). "Structural basis of PAM-dependent target DNA recognition by the Cas9 endonuclease". Nature. 513 (7519): 569–73. Bibcode:2014Natur.513..569A. doi:10.1038/nature13579. PMC   4176945 . PMID   25079318.
  31. Makarova KS, Grishin NV, Shabalina SA, Wolf YI, Koonin EV (March 2006). "A putative RNA-interference-based immune system in prokaryotes: computational analysis of the predicted enzymatic machinery, functional analogies with eukaryotic RNAi, and hypothetical mechanisms of action". Biology Direct. 1 (1): 7. doi: 10.1186/1745-6150-1-7 . PMC   1462988 . PMID   16545108.
  32. Sundaresan R, Parameshwaran HP, Yogesha SD, Keilbarth MW, Rajan R (December 2017). "RNA-Independent DNA Cleavage Activities of Cas9 and Cas12a". Cell Reports. 21 (13): 3728–3739. doi:10.1016/j.celrep.2017.11.100. PMC   5760271 . PMID   29281823.
  33. Raper AT, Stephenson AA, Suo Z (February 2018). "Functional Insights Revealed by the Kinetic Mechanism of CRISPR/Cas9". Journal of the American Chemical Society. 140 (8): 2971–2984. doi:10.1021/jacs.7b13047. PMID   29442507.
  34. Lee JK, Jeong E, Lee J, Jung M, Shin E, Kim YH, et al. (August 2018). "Directed evolution of CRISPR-Cas9 to increase its specificity". Nature Communications. 9 (1): 3048. Bibcode:2018NatCo...9.3048L. doi:10.1038/s41467-018-05477-x. PMC   6078992 . PMID   30082838.
  35. Singh D, Wang Y, Mallon J, Yang O, Fei J, Poddar A, et al. (April 2018). "Mechanisms of improved specificity of engineered Cas9s revealed by single-molecule FRET analysis". Nature Structural & Molecular Biology. 25 (4): 347–354. doi:10.1038/s41594-018-0051-7. PMC   6195204 . PMID   29622787.
  36. Jinek M, Chylinski K, Fonfara I, Hauer M, Doudna JA, Charpentier E (August 2012). "A programmable dual-RNA-guided DNA endonuclease in adaptive bacterial immunity". Science. 337 (6096): 816–21. Bibcode:2012Sci...337..816J. doi:10.1126/science.1225829. PMC   6286148 . PMID   22745249.
  37. Kim N, Kim HK, Lee S, et al. (2020). "Prediction of the sequence-specific cleavage activity of Cas9 variants". Nat Biotechnol. 38 (11): 1328–1336. doi:10.1038/s41587-020-0537-9. PMID   32514125. S2CID   219542792.
  38. 1 2 3 Corsi GI, Qu K, Alkan F, Pan X, Luo Y, Gorodkin J (May 2022). "CRISPR/Cas9 gRNA activity depends on free energy changes and on the target PAM context". Nature Communications. 13 (3006): 3006. Bibcode:2022NatCo..13.3006C. doi: 10.1038/s41467-022-30515-0 . PMC   9151727 . PMID   35637227.
  39. Xu H, Xiao T, Chen CH, Li W, Meyer CA, Wu Q, Wu D, Cong L, Zhang F, Liu JS, Brown M, Liu XS (Aug 2015). "Sequence determinants of improved CRISPR sgRNA design". Genome Res. 25 (8): 1147–1157. doi:10.1101/gr.191452.115. PMC   4509999 . PMID   26063738.
  40. Xiang X, Corsi, GI, Anthon C, Qu K, Pan X, Liang X, Han P, Dong Z, Liu L, Zhong J, Ma T, Wang J, Zhang X, Jiang H, Xu F, Liu X, Xu X, Wang J, Yang H, Bolund L, Church GM, Lin L, Gorodkin J, Luo Y (May 2021). "Enhancing CRISPR-Cas9 gRNA efficiency prediction by data integration and deep learning". Nature Communications. 12 (1): 3238. Bibcode:2021NatCo..12.3238X. doi: 10.1038/s41467-021-23576-0 . PMC   8163799 . PMID   34050182.
  41. Alkan F, Wenzel A, Anthon C, Havgaard JH, Gorodkin J (October 2018). "CRISPR-Cas9 off-targeting assessment with nucleic acid duplex energy parameters". Genome Biology. 19 (177): 177. doi: 10.1186/s13059-018-1534-x . PMC   6203265 . PMID   30367669.
  42. Thyme SB, Akhmetova L, Montague TG, Valen E, Schier AF (Jun 2016). "Internal guide RNA interactions interfere with Cas9-mediated cleavage". Nature Communications. 7 (11750): 11750. Bibcode:2016NatCo...711750T. doi:10.1038/ncomms11750. PMC   4906408 . PMID   27282953.
  43. Kusano K, Naito T, Handa N, Kobayashi I (November 1995). "Restriction-modification systems as genomic parasites in competition for specific sequences". Proceedings of the National Academy of Sciences of the United States of America. 92 (24): 11095–9. Bibcode:1995PNAS...9211095K. doi: 10.1073/pnas.92.24.11095 . PMC   40578 . PMID   7479944.
  44. Sternberg SH, Redding S, Jinek M, Greene EC, Doudna JA (March 2014). "DNA interrogation by the CRISPR RNA-guided endonuclease Cas9". Nature. 507 (7490): 62–7. Bibcode:2014Natur.507...62S. doi:10.1038/nature13011. PMC   4106473 . PMID   24476820.
  45. 1 2 3 4 5 6 Bikard D, Jiang W, Samai P, Hochschild A, Zhang F, Marraffini LA (August 2013). "Programmable repression and activation of bacterial gene expression using an engineered CRISPR-Cas system". Nucleic Acids Research. 41 (15): 7429–37. doi:10.1093/nar/gkt520. PMC   3753641 . PMID   23761437.
  46. Heintze J, Luft C, Ketteler R (2013). "A CRISPR CASe for high-throughput silencing". Frontiers in Genetics. 4: 193. doi: 10.3389/fgene.2013.00193 . PMC   3791873 . PMID   24109485.
  47. 1 2 Gilbert LA, Horlbeck MA, Adamson B, Villalta JE, Chen Y, Whitehead EH, Guimaraes C, Panning B, Ploegh HL, Bassik MC, Qi LS, Kampmann M, Weissman JS (October 2014). "Genome-Scale CRISPR-Mediated Control of Gene Repression and Activation". Cell. 159 (3): 647–61. doi:10.1016/j.cell.2014.09.029. PMC   4253859 . PMID   25307932.
  48. O'Connell MR, Oakes BL, Sternberg SH, East-Seletsky A, Kaplan M, Doudna JA (December 2014). "Programmable RNA recognition and cleavage by CRISPR/Cas9". Nature. 516 (7530): 263–6. Bibcode:2014Natur.516..263O. doi:10.1038/nature13769. PMC   4268322 . PMID   25274302.

Further reading

This page is based on this Wikipedia article
Text is available under the CC BY-SA 4.0 license; additional terms may apply.
Images, videos and audio are available under their respective licenses.