The influence of the copy number of invader on the fate of bacterial host cells in the antiviral defense by CRISPR-Cas10 DNases

Type Ⅲ CRISPR-Cas10 systems employ multiple immune activities to defend their hosts against invasion from mobile genetic elements(MGEs),including DNase and cyclic oligoadenylates(cOA)synthesis both of which are hosted by the type-specific protein Cas10.Extensive investigations conducted for the activation of Cas accessory proteins by cOAs have revealed their functions in the type Ⅲ immunity,but the function of the Cas10 DNase in the same process remains elusive.Here,Lactobacillus delbrueckii subsp.Bulgaricus type Ⅲ-A(Ld)Csm system,a type Ⅲ CRISPR system that solely relies on its Cas10 DNase for providing immunity,was employed as a model to investigate the DNase function.Interference assay was conducted in Escherichia coli using two plasmids:pCas carrying the LdCsm system and pTarget producing target RNAs.The former functioned as a de facto“CRISPR host element”while the latter,mimicking an invading MGE.We found that,upon induction of immune responses,the fate of each genetic element was determined by their copy numbers:plasmid of a low copy number was selectively eliminated from the E.coli cells regardless whether it represents a de facto CRISPR host or an invader.Together,we reveal,for the first time,that the immune mechanisms of Cas10 DNases are of two folds:the DNase activity is capable of removing low-copy invaders from infected cells,but it also leads to abortive infection when the invader copy number is high.

The archaeal KEOPS complex possesses a functional Gon7 homolog and has an essential function independent of the cellular t^(6)A modification level

Kinase,putative Endopeptidase,and Other Proteins of Small size(KEOPS)is a multisubunit protein complex conserved in eukaryotes and archaea.It is composed of Pcc1,Kae1,Bud32,Cgi121,and Gon7 in eukaryotes and is primarily involved in N^(6)-threonylcarbamoyl adenosine(t^(6)A)modification of transfer RNAs(tRNAs).Recently,it was reported that KEOPS participates in homologous recombination(HR)repair in yeast.To characterize the KEOPS in archaea(aKEOPS),we conducted genetic and biochemical analyses of its encoding genes in the hyperthermophilic archaeon Saccharolobus islandicus.We show that aKEOPS also possesses five subunits,Pcc1,Kae1,Bud32,Cgi121,and Pcc1-like(or Gon7-like),just like eukaryotic KEOPS.Pcc1-like has physical interactions with Kae1 and Pcc1 and can mediate the monomerization of the dimeric subcomplex(Kae1-Pcc1-Pcc1-Kae1),suggesting that Pcc1-like is a functional homolog of the eukaryotic Gon7 subunit.Strikingly,none of the genes encoding aKEOPS subunits,including Pcc1 and Pcc1-like,can be deleted in the wild type and in a t^(6)A modification complementary strain named TsaKI,implying that the aKEOPS complex is essential for an additional cellular process in this archaeon.Knock-down of the Cgi121 subunit leads to severe growth retardance in the wild type that is partially rescued in TsaKI.These results suggest that aKEOPS plays an essential role independent of the cellular t^(6)A modification level.In addition,archaeal Cgi121 possesses dsDNA-binding activity that relies on its tRNA 3ʹCCA tail binding module.Our study clarifies the subunit organization of archaeal KEOPS and suggests an origin of eukaryotic Gon7.The study also reveals a possible link between the function in t^(6)A modification and the additional function,presumably HR.

Genetic technologies for extremely thermophilic microorganisms of Sulfolobus, the only genetically tractable genus of crenarchaea

Archaea represents the third domain of life, with the information-processing machineries more closely resembling those of eukaryotes than the machineries of the bacterial counterparts but sharing metabolic pathways with organisms of Bacteria, the sister prokaryotic phylum. Archaeal organisms also possess unique features as revealed by genomics and genome comparisons and by biochemical characterization of prominent enzymes. Nevertheless, diverse genetic tools are required for in vivo experiments to verify these interesting discoveries. Considerable efforts have been devoted to the development of genetic tools for archaea ever since their discovery, and great progress has been made in the creation of archaeal genetic tools in the past decade. Versatile genetic toolboxes are now available for several archaeal models, among which Sulfolobus microorganisms are the only genus representing Crenarchaeota because all the remaining genera are from Euryarchaeota. Nevertheless, genetic tools developed for Sulfolobus are probably the most versatile among all archaeal models, and these include viral and plasmid shuttle vectors, conventional and novel genetic manipulation methods, CRISPR-based gene deletion and mutagenesis, and gene silencing, among which CRISPR tools have been reported only for Sulfolobus thus far. In this review, we summarize recent developments in all these useful genetic tools and discuss their possible application to research into archaeal biology by means of Sulfolobus models.

CRISPR-Cas adaptive immune systems in Sulfolobales:genetic studies and molecular mechanisms

CRISPR-Cas systems provide the small RNA-based adaptive immunity to defend against invasive genetic elements in archaea and bacteria.Organisms of Sulfolobales,an order of thermophilic acidophiles belonging to the Crenarchaeotal Phylum,usually contain both type I and typeⅢCRISPR-Cas systems.Two species,Saccharolobus solfataricus and Sulfolobus islandicus,have been important models for CRISPR study in archaea,and knowledge obtained from these studies has greatly expanded our understanding of molecular mechanisms of antiviral defense in all three steps:adaptation,expression and crRNA processing,and interference.Four subtypes of CRISPR-Cas systems are common in these organisms,including I-A,I-D,Ⅲ-B,andⅢ-D.These cas genes form functional modules,e.g.,all genes required for adaptation and for interference in the I-A immune system are clustered together to form aCas and i Cas modules.Genetic assays have been developed to study mechanisms of adaptation and interference by different CRISPR-Cas systems in these model archaea,and these methodologies are useful in demonstration of the protospacer-adjacent motif(PAM)-dependent DNA interference by I-A interference modules and multiple interference activities byⅢ-B Cmr systems.Ribonucleoprotein effector complexes have been isolated for SulfolobalesⅢ-B andⅢ-D systems,and their biochemical characterization has greatly enriched the knowledge of molecular mechanisms of these novel antiviral immune responses.

Deletion of the topoisomeraseⅢgene in the hyperthermophilic archaeon Sulfolobus islandicus results in slow growth and defects in cell cycle control

Topoisomerase III （topo III）, a type IA topoisomerase, is widespread in hyperthermophilic archaea. In order to interrogate the in vivo role of archaeal topo III, we constructed and characterized a topo III gene deletion mutant of Sulfolobus islandicus. The mutant was ,viable but grew more slowly than the wild-type strain, especially in a nutrient-poor medium. Flow cytometry analysis revealed changes of the mutant in growth cycle characteristics including an increase in proportion of cells containing either more than two genome equivalents or less than one genome equivalent in exponentially-growing cultures. As shown by fluorescence microscopy, a fraction of mutant cells in the cultures were drastically enlarged, and at least some of the enlarged cells were apparently capable of resuming cell division. The mutant also shows a different tran- scriptional profile from that of the wild-type strain. Our results suggest that the enzyme may serve roles in chromosomal segregation and control of the level of supercoiling in the cell.

Genome editing from Cas9 to IscB:Backwards and forwards towards new breakthroughs

In a very recent article published in Science,Altae-Tran et al.recon-structed the evolution of CRISPR-Cas9 systems and traced their ances-tors to unique groups of transposons(Altae-Tran et al.,2021).These transposable elements encode RNA-guided nucleases that show strong potential for developing novel biotechnologies.Structural domains of these nucleases serve as useful building blocks for engineering novel RNA-guided nucleases via synthetic biology to strongly inspire the de-velopment of novel and precision genome-editing tools.

Rational design of unrestricted pRN1 derivatives and their application in the construction of a dual plasmid vector system for Saccharolobus islandicus

Saccharolobus islandicus REY15A represents one of the very few archaeal models with versatile genetic tools,which include efficient genome editing,gene silencing,and robust protein expression systems.However,plasmid vectors constructed for this crenarchaeon thus far are based solely on the pRN2 cryptic plasmid.Although this plasmid coexists with pRN1 in its original host,early attempts to test pRN1-based vectors consistently failed to yield any stable host-vector system for Sa.islandicus.We hypothesized that this failure could be due to the occurrence of CRISPR immunity against pRN1 in this archaeon.We identified a putative target sequence in orf904 encoding a putative replicase on pRN1(target N1).Mutated targets(N1a,N1b,and N1c)were then designed and tested for their capability to escape the host CRISPR immunity by using a plasmid inter-ference assay.The results revealed that the original target triggered CRISPR immunity in this archaeon,whereas all three mutated targets did not,indicating that all the designed target mutations evaded host immunity.These mutated targets were then incorporated into orf904 individually,yielding corresponding mutated pRN1 backbones with which shuttle plasmids were constructed(pN1aSD,pN1bSD,and pN1cSD).Sa.islandicus transformation revealed that pN1aSD and pN1bSD were functional shuttle vectors,but pN1cSD lost the capability for replication.These results indicate that the missense mutations in the conserved helicase domain in pN1c inactivated the replicase.We further showed that pRN1-based and pRN2-based vectors were stably maintained in the archaeal cells either alone or in combination,and this yielded a dual plasmid system for genetic study with this important archaeal model.