REVIEW doi:10.1038/naturel5386 CRISPR-Cas immunity in prokaryotes Luciano A. Marraffini1 Prokaryotic organisms are threatened by a large array of viruses and have developed numerous defence strategies. Among these, only clustered, regularly interspaced short palindromic repeat (CRISPR) -Cas systems provide adaptive immunity against foreign elements. Upon viral injection, a small sequence of the viral genome, known as a spacer, is integrated into the CRISPR locus to immunize the host cell. Spacers are transcribed into small RNA guides that direct the cleavage of the viral DNA by Cas nucleases. Immunization through spacer acquisition enables a unique form of evolution whereby a population not only rapidly acquires resistance to its predators but also passes this resistance mechanism vertically to its progeny. Prokaryotic viruses (bacteriophages or phages) are the most abundant life form, outnumbering their hosts by a factor of 10 (refs 1, 2). Since the beginning of the study of phages in the laboratory3,4, investigators isolated and characterized bacteria that were resistant to phage infection". This led to the discovery of many different antiviral defence mechanisms (Box 1). CRISPR loci and CRISPR-associated (cas) genes encode a unique defence mechanism that provides rapid and robust adaptation to the rapidly evolving viruses (primarily double-stranded (ds)DNA viruses and other foreign DNA) of archaea and bacteria. CRISPR loci consist of an array of short (approximately 30-40 base pairs (bp)) and partially palindromic, repetitive sequences interspaced by equally short 'spacer' sequences (Fig. 1) from viral or plasmid origin. Spacers are at the centre of CRISPR defence as they specify immunity against phages or plasmids that contain a complementary sequence8,9. The acquisition and utilization of spacer sequences constitute the two main stages of CRISPR immunity (Fig. 1). In the first stage, also known as 'adaptation' or 'spacer acquisition' (Fig. la), sequences from the viral genome are integrated into the CRISPR array (that is, the host is immunized). The second stage, where immunity is executed, can be further divided into two phases (Fig. lb). First, in the guide RNA biogenesis phase, the CRISPR array is transcribed and processed to generate short RNAs containing one spacer sequence. Second, in the targeting phase, the spacer sequences in these RNAs are used as guides to direct the cleavage of the viral genome by the Cas endonucleases. As is the case with other major antiviral defence systems (Box 1), phages can escape CRISPR immunity through mutations in the target region that prevent its recognition and/or cleavage10,11. However, in contrast to the other defence systems, the rapid acquisition of new spacers endows CRISPR-Cas loci with an in-built mechanism to counterattack these phage 'escapers'10,12-14. This distinctive property makes CRISPR-Cas immunity a unique form of heritable and adaptive immunity. Discovery of CRISPR-Cas immune systems CRISPR- cas loci and their function in antiviral and antiplasmid defence were first analysed in silico. The first description of CRISPR loci appeared in 1987, after the sequencing of the iap gene of Escherichia coli15. An 'unusual' repeat cluster was found downstream of this gene but due to the lack of homology to other known sequences the authors concluded that "the biological significance of these sequences is not known". The first comprehensive report of CRISPR sequences was only possible after the accumulation of prokaryote genomes in GenBank16, and established CRISPR loci as common clusters of repetitive sequences in bacteria and archaea. In 2002, the isolation and sequencing of small non-coding RNA species of Archaeoglobus fulgidus revealed that CRISPR loci are transcribed into small RNAs17. Also in 2002, the cas genes were identified as a gene family associated with CRISPR loci18. Sequence homology indicated that many of the Cas proteins participate in chemical reactions involving nucleic acids. In 2005 it was discovered that spacers match sequences present in phages and plasmids19-21, and that the more spacers present in Streptococcus thermophilus strains, the fewer phages that were able to infect them19. These findings suggested a role for CRISPR-Cas systems in the prevention of phage infection and plasmid conjugation. All these data were incorporated into a model for CRISPR-Cas immunity reminiscent of RNA interference in eukaryotes, in which small CRISPR RNAs (crRNAs) had an antisense function against phage or plasmid transcripts, thereby preventing the propagation of these genetic elements20,22, with the Cas proteins functioning as the effectors of the immunity mechanism22. The initial experimental work on CRISPR-Cas systems concentrated on testing this model. Three foundational studies uncovered the basic features of CRISPR-Cas immunity: adaptation, the role of crRNA guides and the targeting of the invading nucleic acid (Fig. 1). The first study demonstrated the suspected function of CRISPR-Cas in the prevention of phage infection in S. thermophilus8. The work demonstrated a fundamental aspect of CRISPR-Cas immunity that was not foreseen in the models: that immunity is adaptive. To test for an involvement of CRISPR- cas loci in antiphage defence, Barrangou and colleagues infected S. thermophilus with phage and examined the CRISPR locus of the phage-resistant bacteria8. They observed that the resistant mutants harboured one or more new spacer sequences that perfectly matched a region of the genome of the infecting phage, which showed that new spacers (and immunity) are acquired during infection. This study also implicated the cas genes in CRISPR-mediated defence. A second study (Brouns and colleagues23) demonstrated the requirement of crRNAs for immunity that was proposed in the early models. Brouns and colleagues discovered a Cas ribonucleoprotein complex harbouring the RNase responsible for the generation of small (mature) crRNAs in E. coli23. Disruption of the complex or mutation of the catalytic residues of the RNase subunit prevented the accumulation of crRNAs and at the same time abrogated CRISPR immunity against phages. A third study demonstrated the role of CRISPR-Cas systems in the prevention of plasmid conjugation9. Marraffini and Sontheimer showed that a spacer present in the CRISPR locus of Staphylococcus epidermidis, which matched a region of the nickase gene of staphylococcal plasmids, prevented the conjugative transfer of such plasmids. The study also revealed laboratory of Bacteriology, The Rockefeller University, 1230 York Avenue, New York, New York 10065, USA. 1 OCTOBER 2015 I VOL 526 I NATURE ©2015 Macmillan Publishers Limited. All rights reserved RESEARCH BOX I Mechanisms of antiviral defence in prokaryotes A common mechanism of defence against phage is the prevention of phage adsorption and/or genome injection. Bacteria can switch on or off the expression of phage receptors105,106 or secrete polysaccharides that limit the access to the receptor107. Bacterial hosts can also express membrane proteins that prevent injection of the viral genetic material into the cell108. Abortive infection is another common antiviral strategy in which the infected host cell sacrifices itself to prevent phage propagation109. In most of the cases studied to date, phage infection is detected by a sensor protein that activates a cell death mechanism such as membrane depolarization110 or inhibition of bacterial translation111. Other abortive infection mechanisms work through a phage-triggered activation of toxin-antitoxin systems that kills the host112,113. Restriction-modification is the best studied defence system of prokaryotes and confers protection by cleaving the invading viral genome114. This system utilizes nucleases that recognize and cleave short DNA motifs. The target sequences of restriction nucleases are present in both the viral and host genome, but the bacterial chromosome is protected through methylation of the target DNA sequence. Therefore, restriction-modification systems display both endonuclease and methylase activities with the same sequence specificity. Other defence systems recently discovered, and less well characterized, are the bacteriophage exclusion (BREX) system, which blocks phage replication115, and the prokaryotic Argonaute pathway, which attacks foreign nucleic acid elements116,117. As expected from the highly dynamic virus-host interactions that occur in prokaryotic ecosystems, phages have evolved several counter-defence strategies to overcome host defences118. Phages can adapt to use different receptors119 or produce degrading enzymes to eliminate the extracellular polysaccharides that occlude receptors120. Mutations in the viral proteins that trigger abortive infection allow phages to bypass this resistance mechanism109, and when methylation of the invading phage DNA occurs faster than its cleavage by restriction endonucleases, the infecting phage can overcome this barrier and rapidly propagate throughout the whole host population114. To adapt to phage evasion strategies the host population needs to restore the lost mechanism of defence, in most cases through the selection of infrequent (and sometimes costly) mutations. By contrast, the acquisition of spacer sequences into CRISPR-Cas loci constitutes an in-built mechanism that provides a rapid and efficient response against phages that escape immunity through the introduction of mutations in the target site10-12-14 Immunization that as opposed to the proposed RNA-interference-like mechanism, CRISPR-Cas systems provide immunity by targeting DNA, rather than RNA. To show this, a self-splicing intron was placed in the nickase target sequence, creating a scenario in which the DNA target was interrupted but the RNA target was intact after splicing. Immunity to conjugation was lost, demonstrating the requirement of an intact DNA, but not RNA, target for CRISPR-Cas function. These results also suggested the existence of crRNA-guided, programmable Cas DNA nucleases, opening up the possibility for the development of CRISPR-based DNA manipulation tools24. Molecular mechanisms of CRISPR-Cas immunity All CRISPR-Cas systems harbour the casl and cas2 genes, which are central to the immunization stage of the pathway (see below). However, based on the accessory cas gene content, each system can be classified into three different types25. While all types use the same basic molecular mechanism to achieve immunity, that is, through crRNA-guided Immunity Figure 1 | Stages of CRISPR-Cas immunity. CRISPR loci are a cluster of short DNA repeats (white boxes) separated by equally short spacer sequences of phage and plasmid origin (coloured, numbered boxes). This repeat/spacer array is flanked by an operon of CRISPR-associated (cas) genes (blue-tone arrows) that encode the machinery for the immunization and immunity stages of the system. The CRISPR array is preceded by a leader sequence (grey box) containing the promoter for its expression, a, In the immunization stage, spacer sequences are captured upon entry of the foreign DNA into the cell and integrated into the first position of the CRISPR array, b, In the immunity stage the spacer is used to target invading DNA that carries a cognate sequence for destruction. Spacers are transcribed and processed into small CRISPR RNAs (crRNAs) in the 'crRNA biogenesis' phase. These small RNAs act as antisense guides for Cas RNA-guided nucleases (which usually form a complex) that locate and cleave the target sequence (black arrowhead) in the invader's genome during the 'targeting' phase. nucleases, they differ in the biogenesis of crRNAs and the targeting requirements. Type I CRISPR-Cas immunity is mediated by the Cascade complex and the Cas3 nuclease (Fig. 2a)23. One of the subunits of Cascade, Cas6e, is a repeat-specific endoribonuclease that cleaves the precursor crRNA that is generated by transcription of the full CRISPR array23,26. This cleavage produces short crRNAs that remain associated with Cascade and that are used by the complex to locate a complementary sequence in the target DNA23,27,28, known as the protospacer. Another subunit, Cas8 (also known as CasA or Csel), recognizes a short sequence motif located immediately upstream of the target sequence recognized by the crRNA29. Sequence motifs adjacent to the targets specified by CRISPR spacers were first identified in type II systems11,19,30 and subsequently named as 'protospacer adjacent motif, or PAM31. PAM recognition is required for type I CRISPR-Cas immunity32, and the absence of a PAM in the repeat sequences prevents the targeting of the spacers within the CRISPR array by their complementary crRNAs; that is, it prevents an autoimmune reaction. The presence of a PAM promotes Cascade binding to its target29,33,34 and the formation of an R-loop between the crRNA spacer sequence and the dsDNA3"7. The first 8 bp at the 5' end of the crRNA-DNA duplex are critical for immunity and define a 'seed' sequence within the target28,32. Mutant viruses containing mutations in this region can escape type I CRISPR immunity in E. coif2. An exception is mutations in the sixth nucleotide of the seed, which do not affect CRISPR immunity. The recent crystal structure of the interaction between a guide crRNA and its cognate 56 I NATURE I VOL 5 2 6 I 1 OCTOBER 2015 ©2015 Macmillan Publishers Limited. All rights reserved |^^^ RESEARCH a be Cascade Pre_crRNA Cas9tracrRNA Cas6 -J_ I V^T^X Pro.nrOMi X Pre-crRNA I Pre-crRNA I Cas10 complex PAM PAM Type I Transcript Type I Type I Figure 2 Immunity mechanisms of the different CRISPR-Cas types. a, Type I systems. A Cas protein complex known as Cascade cleaves at the base of the stem-loop structure of each repeat in the long precursor crRNA (pre-crRNA, black arrowheads), which generates short crRNA guides. The Cascade-crRNA complex scans the target DNA for a matching sequence (known as protospacer), which is flanked by a protospacer-adjacent motif (PAM, in green). Annealing of the crRNA to the target strand forms an R-loop; the Cas3 nuclease is recruited and cleaves the target downstream of the PAM (red arrowhead) and also degrades the opposite strand, b, Type II systems. These systems encode another small RNA known as trans-encoded crRNA (tracrRNA) which is bound by Cas9 and has regions of complementarity to the repeat sequences in the pre-crRNA. The repeat/tracrRNA dsRNA is cleaved by RNase III to generate crRNA guides for the Cas9 nuclease (black arrowheads). This nuclease cleaves both strands of the protospacer/crRNA R-loop (red arrowhead). A PAM (in green) is located downstream of the target sequence, c, Type III systems. Cas6 is a repeat-specific endoribonuclease that cleaves the pre-crRNA at the base of the stem-loop structure of each repeat (black arrowhead). The crRNA is loaded into the Cas 10 complex where it is further trimmed at the 3' end to generate a mature crRNA (white arrowhead). The CaslO complex requires target transcription to cleave the non-template strand of the protospacer DNA and it is also capable of crRNA-guided transcript cleavage (red arrowheads). single-stranded (ss)DNA target within the Cascade complex showed that the crRNA-ssDNA interaction forms a non-canonical ribbon structure in which every sixth nucleotide is rotated out of the double helix and therefore not engaged in the formation of a base pair3840. Finally, target recognition by Cascade triggers the recruitment and activity of Cas3, a nuclease that introduces ssDNA breaks into the target virus or plasmid33,41-44 to initiate their degradation. Type II CRISPR-Cas systems require only one cas gene, cas9, to execute immunity in the presence of an existing targeting spacer sequence (Fig. 2b)45. However, as opposed to the other CRTSPR types, two small RNAs are needed for immunity: the crRNA and the trans-encoded crRNA (tracrRNA)46. The tracrRNA forms a secondary structure that mediates its association with Cas9 (refs 47-49) but also has a region that is complementary to the repeat sequences of the CRTSPR array46. The dsRNA formed between the tracrRNA and the precursor crRNA is cleaved by RNase III, resulting in the cleavage of each repeat and the processing of the long CRTSPR transcript into small crRNA guides46. Type II immunity also requires a PAM, and mutations in this motif are the most common mechanism of escape from CRTSPR immunity by the targeted viruses11. In contrast to type I, the PAM is located immediately downstream of the target sequence1119 and is recognized by a PAM-binding domain present in Cas9 (refs 47-49). Type II CRISPR-Cas immunity results in the introduction of crRNA-specific dsDNA breaks in the invading DNA50 that require two nuclease domains: HNH and RuvC45. Each of these domains cleaves one DNA strand of the protospacer sequence51,52 and the tracrRNA is absolutely required for cleavage52. The first step in target recognition is the transient binding of Cas9 to PAM sequences within the target DNA, which promotes the melting of the two DNA strands immediately upstream of the PAM53. A productive interaction in this region of the target, between 6-8 bases of the spacer sequence of the crRNA guide and the melted DNA (the 'seed' sequence of type II systems11,54), triggers the formation of an R-loop and target cleavage37,53. In type III CRISPR-Cas systems, the precursor crRNA is cleaved by a repeat-specific endoribonuclease, Cas6, which is not part of a complex55. As a result of this processing, 8 nucleotides of the repeat sequence remain at the 5' end of the spacer sequence in the crRNA55,56, a sequence known as the crRNA tag. By an as yet unknown mechanism, the small crRNAs generated after Cas6 cleavage are transferred to a larger complex57, the CaslO-Csm or CaslO-Cmr complex for type III-A or III-B systems, respectively. Within these complexes the crRNAs undergo a process of maturation whereby the 3' end is trimmed at 6-nucleotide intervals58-60. As opposed to type I and II systems, in which targeting relies strictly on the recognition of DNA sequences, type III CRISPR-Cas immunity also requires target transcription61,62 and a crRNA complementary to the non-template strand of the DNA target and to the transcript62. Both DNA9,61-63 and RNA63-68 are targeted by type III CRISPR-Cas systems, resulting in the co-transcriptional crRNA-guided cleavage of the target DNA and its transcripts63,69. The CaslO complex contains both nucleolytic activities: the palm domain of CaslO is required for cleavage of the non-template DNA strand63, and backbone subunits Csm3 (refs 63, 65) or Cmr4 (ref. 66), for type III-A or III-B systems, respectively, are responsible for cleavage of the RNA transcripts. To date, no PAM requirements have been observed for type III CRISPR-Cas targeting. To avoid targeting of the CRTSPR locus, type III systems rely on the differential base pairing between the crRNA tag and the sequences flanking the protospacer56. Whereas the absence of complete complementarity between these sequences licenses DNA targeting, full complementarity between the crRNA tag and the repeat sequence in the CRTSPR locus prevents DNA targeting56,63,67 and thus autoimmunity. The biological significance of this elaborate targeting mechanism is beginning to be elucidated. The transcription requirement for targeting offers the possibility of immunological tolerance of mobile genetic elements with non-transcribed regions, such as prophages with the potential to provide a fitness advantage to the host62. Moreover, when the prophage re-activates and enters the lytic cycle, its genome is transcribed and type III targeting resumes, resulting in clearance of the infection and preventing the death of the host cell. Studies have shown that RNA cleavage can protect against RNA viruses66; however, the role of RNA targeting in immunity against DNA elements and possibly regulation of gene expression remains to be determined. CRISPR immunization The mechanisms by which new spacer sequences are added to the CRTSPR locus to immunize the host are beginning to be understood. This process can be divided into two stages: the selection of protospacer sequences from the invader DNA and their integration into the CRTSPR array (Fig. 3). With a few exceptions, the spacer acquisition mechanism has been studied in detail in the E. coli type I CRISPR-Cas system. This is because an early report showed that overexpression of type I Casl and Cas2 is sufficient for the expansion of the E. coli CRTSPR array of this organism and thus established a very simple and elegant experimental system to study this phenomenon70. Central to the mechanism of selection of new spacer sequences is the prevention of autoimmunity; that is, the ability of the acquisition machinery to distinguish self (chromosomal) from non-self (invading) DNA. Failure to do so leads to the death of the host, a scenario that has been tested and exploited for the use of CRISPR-Cas systems as genome editing tools of bacteria54,71-73 and as antimicrobials74-76. Applying the Casl-Cas2 overexpression system—in which autoimmunity is avoided 1 OCTOBER 2015 I VOL 5 2 6 I NATURE I 57 ©2015 Macmillan Publishers Limited. All rights reserved RESEARCH a Spacer sampling b Spacer integration Figure 3 | Mechanism of CRISPR immunization, a, The first step of CRISPR immunization is the sampling of the spacer sequences. These are believed to be generated from non-specific DNA breaks that occur during replication of the virus or plasmid. The fragments generated are captured by the Casl-Cas2 complex, with the participation of the targeting machinery for the recognition of DNA sequences carrying a functional PAM. b, The Casl-Cas2 complex catalyses the integration of the spacer into the first position of the CRISPR array. Casl performs two concerted cleavage-ligation reactions whereby the 5' end of each repeat strand is cleaved (blue arrowhead) and ligated to the 3' ends of the spacer. This mechanism generates two ssDNA gaps on the repeat sequences that flank the inserted spacer, which presumably are filled by DNA polymerase (dotted arrow). L, leader; Rj, first repeat; R2, second repeat; Rnew, new repeat; Si, first spacer; Snew, new spacer. by using an E. coli strain that lacks the Cascade and Cas3 immunity machinery—several studies determined that there is a strong preference for the integration of plasmid over chromosomal spacer sequences70,77,78. Recently, it has been shown that Chi sites, 8-nucleotide motifs present approximately once every 5 kb in the E. coli genome, limit the acquisition of chromosomal sequences79. Chi sites are over-represented in the E. coli chromosome80; therefore, this mechanism favours the acquisition of spacer sequences from foreign elements. The origin of the substrates for CRISPR adaptation is not yet known. In E. coli, the overexpression of Cas 1 -Cas2 in the absence of immunity leads to the acquisition of spacer sequences derived from regions limited by Chi sites on one side and by Ter sites on the other79. There are two Ter sites in the E. coli genome, TerA and TerC, which are diametrically opposed from the origin of replication to stall a faster replication fork and ensure proper chromosomal decatenation at the end of a round of DNA replication81. Replisome stalling at either Ter site leads to chromosome breaks that are processed by the RecBCD exonuclease complex, generating 3'OH overhang ends for RecA-mediated homologous recombination repair of the DNA lesion82. To avoid excessive DNA degradation, RecBCD activity is inhibited by Chi sequences83. Therefore, the chromosomal acquisition data obtained in E. coli (ref. 79) suggest that the nucleolytic processing of dsDNA breaks generated during replication is the source of new spacer sequences for the CRISPR-Cas acquisition machinery. This model is supported by a reduction in spacer acquisition from the host chromosome when DNA replication is chemically inhibited and in mutants that lack the RecBCD machinery79. Although not directly tested, this work predicts that the DNA degradation that follows the formation of spontaneous breaks during viral or plasmid replication produces DNA fragments that are captured by the Cas adaptation machinery for their incorporation as non-self spacers into the CRISPR array (Fig. 3a). A second aspect of spacer selection relates to the PAM requirement for targeting: how does the acquisition machinery ensure that a new spacer will match a protospacer flanked by the correct PAM? Recently it was revealed that Cas9, which has the ability to recognize the PAM, is used to select new spacers with the correct PAM sequence84 (Fig. 3a). Genetic studies showed that Cas9 is absolutely required for type II CRISPR-Cas adaptation84,85. While the nuclease activity does not con- tribute to the role of Cas9 in spacer acquisition84,85, mutation of the PAM-binding domain results in the incorporation of new spacers that match DNA targets but without conservation of their flanking sequences; that is, without a PAM84. Supporting a role for Cas9 in the acquisition of functional spacer sequences it was shown that this nuclease forms a complex with Casl, Cas2 and Csn2, proteins exclusively involved in CRISPR adaptation, and that swapping cas9 alleles that recognize different PAM sequences results in the incorporation of spacers with PAMs corresponding to the cas9 allele used84. Casl and Cas2, without Cascade, are sufficient for E.coli type I spacer acquisition. However, it is not clear whether the new spacers acquired in the absence of Cascade display an absolute conservation of the PAM sequence—AAG for this CRISPR-Cas system70,86,87. Interestingly, the first (5' end) nucleotide of E. coli spacer sequences is invariably G; that is, the last nucleotide of the PAM88-90. Therefore it is possible that, similarly to Cas9 in type II systems, the PAM recognition feature of the Cascade complex is involved in the selection of functional spacers. Although this remains to be tested, studies have found another role for Cascade in type I adaptation, in a phenomenon known as 'priming'86. It has been shown that the presence of pre-existing (priming) spacers with partial homology (and therefore unable to provide full immunity) to the ssDNA phage M13 increases the rate of spacer acquisition by several orders of magnitude86. In addition, new spacers acquired in the presence of a priming spacer have a strong strand bias, producing a crRNA guide that matches the same strand matched by the priming spacer86,87. Primed acquisition facilitates adaptation against invaders that are related in sequence to previous invaders (that have partial matches to pre-existing spacers) and also against escapers (that is, phage containing target mutations that prevent CRISPR-Cas immunity). The mechanism of primed acquisition is yet to be resolved. Primed adaptation requires the Cascade complex86, and the partial match between the crRNA-target sequences that trigger this process results in a distinct mode of Cascade binding to the target DNA35. It is believed that this binding results in a low incidence of target cleavage that, similarly to the DNA breaks that occur at replication stall sites79, would generate the substrates for spacer acquisition. Interestingly, primed acquisition reveals a coupling between the immunity and immunization stages of CRISPR defence. In the second stage of CRISPR immunization, after the selection of the spacer by the acquisition machinery, spacers are integrated into the CRISPR array in a reaction that resembles retroviral integration (Fig. 3b). Recently, it was shown that E. coli Casl and Cas2 perform the spacer integration reaction. Studies using the Casl-Cas2 overexpression system demonstrated the presence of integration intermediates in vivo91. Using specific probes for Southern blot assays it was demonstrated that each strand of the first repeat sequence is separated and ligated to the 3' end of the new spacer sequence. This reaction is catalysed by the Casl-Cas2 complex, which is composed of two Casl-Cas2 units, and mutations that prevent the interaction between these proteins78 or eliminate Casl nuclease activity70,78,91 abrogate spacer acquisition. The complex binds to E. coli CRISPR sequences in vitro78 and, when incubated with a 33-nucleotide dsDNA substrate (which mimics a captured spacer sequence), it mediates the covalent addition of this dsDNA into plasmids harbouring the CRISPR array92. This reaction requires free 3' OH ends on the 33-nucleotide spacer substrate, which presumably perform a direct nucleophilic attack on the phosphodiester bond between the first repeat and spacer sequences92 (Fig. 3b). Importantly, deep sequencing of the reaction products revealed a strong bias for the integration of spacers with a C nucleotide at the 3' end (that is, the complementary base to the first (5' end) G of the spacer sequence92). Collectively, these results indicate that the Casl-Cas2 complex provides the orientation specificity of the integration reaction, which probably occurs by two consecutive 3' OH attacks on opposite sides of the repeat sequence, with the first nucleophilic attack by the 3'-end C of the spacer sequence on the 5' end of the bottom strand of the repeat. After the repair of the repeat gaps that result from this reaction, a new repeat-spacer unit is added into the CRISPR array. This mechanism 58 I NATURE I VOL 5 2 6 I 1 OCTOBER 2015 ©2015 Macmillan Publishers Limited. All rights reserved |^^^ RESEARCH is consistent with early work that demonstrated that the additional repeat is derived from the first repeat of the CRISPR array70. This study showed that a 'labelling' mutation introduced in the first, but not the second, repeat sequence is incorporated into the new repeat after spacer acquisition. Perspectives An extensive body of work has established the function of CRISPR-Cas systems as the adaptive immune system of prokaryotes, which function in protection against viral infection and plasmid invasion. One intriguing aspect is the role of these systems in the regulation of horizontal gene transfer (HGT) between microorganisms. HGT is fundamental for the generation of the genetic diversity required for prokaryotic evolution and is achieved through three major routes: phage transduction, plasmid conjugation and DNA transformation93. In addition to the activity of CRISPR-Cas against phages, it has been experimentally demonstrated that CRISPR-Cas systems can prevent plasmid conjugation9 and the transformation of naturally competent bacteria94,95. Therefore, in principle, CRISPR immunity can prevent the major routes of HGT and therefore have an important role in limiting the evolution of bacteria and archaea. This drawback of CRISPR-Cas systems has often been considered a cause for the inconsistent distribution of these loci96,97, which are present in only ~50% of bacterial and ~90% of archaeal genomes98. A recent study investigated the relationship between the number of spacer sequences (an indicator of CRISPR activity) and the estimated number of HGT transfer events for all the genomes present in GenBank". If CRISPR immunity limits HGT, a negative correlation between these two values is expected. Since this correlation was not evident, the study suggests that there is no impact of CRISPR-Cas on gene transfer among prokaryotes over evolutionary timescales. Future work should determine the effects of CRISPR-Cas immunity on HGT at the population level as well as other potential disadvantages of the system, such as a high incidence of autoimmunity and/or off-target effects, which could impact on its distribution among prokaryotic organisms. Another puzzling aspect of CRISPR-Cas systems is their high diversity25100. For each of the three CRISPR types there are many subtypes encoding divergent sets of Cas proteins. The biological significance of this diversity is not known. A driving force for the diversification of CRISPR-Cas systems could be imposed by phage-encoded anti-CRISPR mechanisms. It has been shown that phages encode small proteins that specifically inhibit type I-F CRISPR immunity101, which could conceivably lead to the evolution of another type or subtype to overcome the inhibition of the existing CRISPR-Cas system. In this hypothetical scenario CRISPR-Cas systems would diversify as a result of the arms race with the viruses they target. It is also possible that the mechanistic differences between types and subtypes provide advantages for different CRISPR-Cas systems in different conditions imposed by the lifestyle or the environment of the host. An example of this is the type III systems, which tolerate untranscribed or inert mobile genetic elements62. Different conditions where this tolerance is beneficial or detrimental will determine the selection of type III systems in different hosts. Similarly, mechanistic differences between other types or subtypes that have an impact on the fitness of the host could have a role in the distribution of the CRISPR systems. Furthermore, additional functions of particular CRISPR subtypes could explain their diversification. For example, the type II-C CRISPR-Cas system of the bacterial pathogen Francisella novicida harbours a tracrRNA with sequence homology to an endogenous lipoprotein gene102 103. When complexed with Cas9, the tracrRNA associates with another small RNA, the small CRISPR-assoc-iated RNA (scaRNA), to mediate the silencing of the lipoprotein gene during F. novicida infection. Another example is the RNA cleavage feature of type III (CaslO) complexes, which offers the possibility of regulation of gene expression by these systems67 104 that could lead to the preferential selection of these systems over other types that cannot perform this function. Similarly to restriction-modification systems, the possibilities to manipulate DNA sequences in a predictable manner by CRISPR-Cas immunity have led to numerous applications in molecular biology, most notably the genetic engineering of a range of different cell types24. This highlights the importance of the study of basic biological problems, particularly the interactions between prokaryotes and the mobile genetic elements that invade them, for the development of innovative biotech-nological applications. In this context it is exciting to consider the different mechanisms of immunity present in the understudied (or even presently undiscovered) CRISPR-Cas systems, as well as the many uncharacterized prokaryotic defence systems carried by the archaeal and bacterial domains of life that inhabit every corner of our planet. Received 29 May 2015; accepted 7 August 2015. 1. Bergh, 0., Borsheim, K. Y., Bratbak, G. & Heldal, M. High abundance of viruses found in aquatic environments. Nature 340, 467^68 (1989). 2. Chibani-Chennoufi, S., Bruttin, A., Dillmann, M. L. & Brussow, H. Phage-host interaction: an ecological perspective. J. Bacteriol. 186, 3677-3686 (2004). 3. d'Herelle, F. Sur un microbe invisible antagoniste des bacilles dysenteriques. CR. Acad. Sei. Paris 165,373-375 (1917). 4. Twort, F. W. An investigation on the nature of ultra-microscopic viruses. Lancet 186,1241-1243(1915). 5. Burnet, F. M. Further observations on the nature of bacterial resistance to bacteriophage. J. Pathol. 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