Prokaryotic Argonaute Proteins Research Articles

Structural and mechanistic insights into the activation of a short prokaryotic argonaute system from archaeon Sulfolobus islandicus.

Prokaryotic Argonaute proteins (pAgos) defend the host against invading nucleic acids, including plasmids and viruses. Short pAgo systems confer immunity by inducing cell death upon detecting invading nucleic acids. However, the activation mechanism of the SiAgo system, comprising a short pAgo from the archaeon Sulfolobus islandicus and its associated proteins SiAga1 and SiAga2, remains largely unknown. Here, we determined the cryo-electron microscopy structures of the SiAgo-Aga1 apo complex and the RNA-DNA-bound SiAgo-Aga1 complex at resolutions of 2.7 and 3.0 Å, respectively. Our results revealed that a positively charged pocket is generated from the interaction between SiAgo and SiAga1, exhibiting an architecture similar to APAZ-pAgo of short pAgo systems and accommodating the nucleic acids. Further investigation elucidated the conserved mechanism of nucleic acid recognition by SiAgo-Aga1. Both the SiAgo-Aga1 interaction and nucleic acid recognition by the complex are essential for antiviral defense. Biochemical and structural analyses demonstrated that SiAgo-Aga1 undergoes extensive conformational changes upon binding to the RNA-DNA duplex, thereby licensing its interaction with the effector SiAga2 to trigger the immune response. Overall, our findings highlight the evolutionary conservation of Agos across phylogenetic clades and provide structural insights into the activation mechanism of the SiAgo system.

A gate-clamp mechanism for ssDNA translocation by DdmD in Vibrio cholerae plasmid defense.

The DdmDE antiplasmid system, consisting of the helicase-nuclease DdmD and the prokaryotic Argonaute (pAgo) protein DdmE, plays a crucial role in defending Vibrio cholerae against plasmids. Guided by DNA, DdmE specifically targets plasmids, disassembles the DdmD dimer, and forms a DdmD-DdmE handover complex to facilitate plasmid degradation. However, the precise ATP-dependent DNA translocation mechanism of DdmD has remained unclear. Here, we present cryo-EM structures of DdmD bound to single-stranded DNA (ssDNA) in nucleotide-free, ATPγS-bound, and ADP-bound states. These structures, combined with biochemical analysis, reveal a unique"gate-clamp" mechanism for ssDNA translocation by DdmD. Upon ATP binding, arginine finger residues R855 and R858 reorient to interact with the γ-phosphate, triggering HD2 domain movement. This shift repositions the gate residue Q781, causing a flip of the 3' flank base, which is then clamped by residue F639. After ATP hydrolysis, the arginine finger releases the nucleotide, inducing HD2 to return to its open state. This conformational change enables DdmD to translocate along ssDNA by one nucleotide in the 5' to 3' direction. This study provides new insights into the ATP-dependent translocation of DdmD and contributes to understanding the mechanistic diversity within SF2 helicases.

A mobile genetic element-derived primase-polymerase harbors multiple activities implicated in DNA replication and repair.

Primase-polymerases (PrimPols) play divergent functions from DNA replication to DNA repair in all three life domains. In archaea and bacteria, numerous and diverse PPs are encoded by mobile genetic elements (MGEs) and act as the replicases for their MGEs. However, their varying activities and functions are not fully understood. In this study, we characterized a group of PrimPols that are genetically associated with prokaryotic argonaute proteins (pAgos). The pAgo-associated PrimPol (AgaPP) is likely derived from a MGE. AgaPP has polymerase and primase activities and physically interacts with a helicase encoded by its downstream gene, suggesting that they constitute a functional replication module. Further, AgaPP performs translesion DNA synthesis, terminal transfer and microhomology-mediated end joining (MMEJ), showing striking similarity to human DNA repair polymerase θ. AgaPP can promote the MMEJ repair of Cas9-induced double-stranded DNA breaks and increase cell survival post DNA damage in Escherichia coli. In addition, the MMEJ activity of AgaPP can be repurposed to assist DNA assembly in vitro. Together, the findings reveal dual role of AgaPP in both DNA replication and repair.

A prokaryotic Argonaute protein recruits a helicase-nuclease to degrade invading plasmids

A prokaryotic Argonaute protein recruits a helicase-nuclease to degrade invading plasmids

Fusion of FokI and catalytically inactive prokaryotic Argonautes enables site-specific programmable DNA cleavage

Site-specific nucleases are crucial for genome engineering applications in medicine and agriculture. The ideal site-specific nucleases are easily reprogrammable, highly specific in target site recognition, robust in nuclease activities. Prokaryotic Argonaute (pAgo) proteins have received much attention as biotechnological tools due to their ability to recognize specific target sequences without a protospacer adjacent motif (PAM), but their lack of intrinsic double-stranded DNA (dsDNA) unwinding activity limits their utility in key applications such as gene editing. Recently, we developed a pAgo-based system for site-specific DNA cleavage at physiological temperatures independently of the DNA form, using peptide nucleic acids (PNAs) to facilitate unwinding dsDNA targets. Here, we fused catalytically dead pAgos with the nuclease domain of the restriction endonuclease FokI and named this modified platform PNA-assisted FokI-(d)pAgo (PNFP) editors. In the PNFP system, catalytically inactive pAgo recognizes and binds to a specific target DNA sequence based on a programmable guide DNA sequence; upon binding to the target site, the FokI domains dimerize and introduce precise dsDNA breaks. We explored key parameters of the PNFP system including the requirements of PNA and guide DNAs, the specificity of PNA and guide DNA on target cleavage, the optimal concentration of different components, reaction time for invasion and cleavage and ideal temperature and reaction buffer, to ensure efficient DNA editing in vitro. The results demonstrated robust site-specific target cleavage by PNFP system at optimal conditions in vitro. We envision that the PNFP system will provide higher editing efficiency and specificity with fewer off-target effects in vivo.

Molecular mechanism of plasmid elimination by the DdmDE defense system.

Seventh-pandemic Vibrio cholerae strains contain two pathogenicity islands that encode the DNA defense modules DdmABC and DdmDE. In this study, we used cryogenic electron microscopy to determine the mechanistic basis for plasmid defense by DdmDE. The helicase-nuclease DdmD adopts an autoinhibited dimeric architecture. The prokaryotic Argonaute protein DdmE uses a DNA guide to target plasmid DNA. The structure of the DdmDE complex, validated by in vivo mutational studies, shows that DNA binding by DdmE triggers disassembly of the DdmD dimer and loading of monomeric DdmD onto the nontarget DNA strand. In vitro studies indicate that DdmD translocates in the 5'-to-3' direction, while partially degrading the plasmid DNA. These findings provide critical insights into the mechanism of DdmDE systems in plasmid elimination.

Comprehensive Analysis of Antiphage Defense Mechanisms: Serovar-Specific Patterns.

Leptospirosis is a major zoonotic disease caused by pathogenic spirochetes in the genus Leptospira, affecting over a million people annually and causing approximately 60,000 deaths. Leptospira interrogans, a key causative agent, likely possesses defense systems against bacteriophages (leptophages), yet these systems are not well understood. We analyzed 402 genomes of L. interrogans using the DefenseFinder tool to identify and characterize the antiphage defense systems. We detected 24 unique systems, with CRISPR-Cas (Clustered Regularly Interspaced Short Palindromic Repeats and CRISPR-associated proteins), PrrC, Borvo, and Restriction-Modification (R-M) being the most prevalent. Notably, Cas were identified in all strains, indicating their central role in phage defense. Furthermore, there were variations in the antiphage system distribution across different serovars, suggesting unique evolutionary adaptations. For instance, Retron was found exclusively in the Canicola serovar, while prokaryotic Argonaute proteins (pAgo) were only detected in the Grippotyphosa serovar. These findings significantly enhance our understanding of Leptospira's antiphage defense mechanisms. They reveal the potential for the development of serovar-specific phage-based therapies and underscore the importance of further exploring these defense systems.

Mn2+-induced structural flexibility enhances the entire catalytic cycle and the cleavage of mismatches in prokaryotic argonaute proteins.

Prokaryotic Argonaute (pAgo) proteins, a class of DNA/RNA-guided programmable endonucleases, have been extensively utilized in nucleic acid-based biosensors. The specific binding and cleavage of nucleic acids by pAgo proteins, which are crucial processes for their applications, are dependent on the presence of Mn2+ bound in the pockets, as verified through X-ray crystallography. However, a comprehensive understanding of how dissociated Mn2+ in the solvent affects the catalytic cycle, and its underlying regulatory role in this structure-function relationship, remains underdetermined. By combining experimental and computational methods, this study reveals that unbound Mn2+ in solution enhances the flexibility of diverse pAgo proteins. This increase in flexibility through decreasing the number of hydrogen bonds, induced by Mn2+, leads to higher affinity for substrates, thus facilitating cleavage. More importantly, Mn2+-induced structural flexibility increases the mismatch tolerance between guide-target pairs by increasing the conformational states, thereby enhancing the cleavage of mismatches. Further simulations indicate that the enhanced flexibility in linkers triggers conformational changes in the PAZ domain for recognizing various lengths of nucleic acids. Additionally, Mn2+-induced dynamic alterations of the protein cause a conformational shift in the N domain and catalytic sites towards their functional form, resulting in a decreased energy penalty for target release and cleavage. These findings demonstrate that the dynamic conformations of pAgo proteins, resulting from the presence of the unbound Mn2+ in solution, significantly promote the catalytic cycle of endonucleases and the tolerance of cleavage to mismatches. This flexibility enhancement mechanism serves as a general strategy employed by Ago proteins from diverse prokaryotes to accomplish their catalytic functions and provide useful information for Ago-based precise molecular diagnostics.

Sensing of DNA modifications by pAgo proteins in vitro

Many prokaryotic Argonaute (pAgo) proteins act as programmable nucleases that use small guide DNAs for recognition and cleavage of complementary target DNA. Recent studies suggested that pAgos participate in cell defense against invader DNA and may also be involved in other genetic processes, including DNA replication and repair. The ability of pAgos to recognize specific targets potentially make them an invaluable tool for DNA manipulations. Here, we demonstrate that DNA-guided DNA-targeting pAgo nucleases from three bacterial species, DloAgo from Dorea longicatena, CbAgo from Clostridium butyricum and KmAgo from Kurthia massiliensis, can sense site-specific modifications in the target DNA, including 8-oxoguanine, thymine glycol, ethenoadenine and pyrimidine dimers. The effects of DNA modifications on the activity of pAgos strongly depend on their positions relative to the site of cleavage and are comparable to or exceed the effects of guide-target mismatches at corresponding positions. For all tested pAgos, the strongest effects are observed when DNA lesions are located at the cleavage position. The results demonstrate that DNA cleavage by pAgos is strongly affected by DNA modifications, thus making possible their use as sensors of DNA damage.

Auto-inhibition and activation of a short Argonaute-associated TIR-APAZ defense system.

Short prokaryotic Ago accounts for most prokaryotic Argonaute proteins (pAgos) and is involved in defending bacteria against invading nucleic acids. Short pAgo associated with TIR-APAZ (SPARTA) has been shown to oligomerize and deplete NAD+ upon guide-mediated target DNA recognition. However, the molecular basis of SPARTA inhibition and activation remains unknown. In this study, we determined the cryogenic electron microscopy structures of Crenotalea thermophila SPARTA in its inhibited, transient and activated states. The SPARTA monomer is auto-inhibited by its acidic tail, which occupies the guide-target binding channel. Guide-mediated target binding expels this acidic tail and triggers substantial conformational changes to expose the Ago-Ago dimerization interface. As a result, SPARTA assembles into an active tetramer, where the four TIR domains are rearranged and packed to form NADase active sites. Together with biochemical evidence, our results provide a panoramic vision explaining SPARTA auto-inhibition and activation and expand understanding of pAgo-mediated bacterial defense systems.

Prokaryotic Argonaute Proteins: A New Frontier in Point-of-Care Viral Diagnostics.

The recent pandemic of SARS-CoV-2 has underscored the critical need for rapid and precise viral detection technologies. Point-of-care (POC) technologies, which offer immediate and accurate testing at or near the site of patient care, have become a cornerstone of modern medicine. Prokaryotic Argonaute proteins (pAgo), proficient in recognizing target RNA or DNA with complementary sequences, have emerged as potential game-changers. pAgo present several advantages over the currently popular CRISPR/Cas systems-based POC diagnostics, including the absence of a PAM sequence requirement, the use of shorter nucleic acid molecules as guides, and a smaller protein size. This review provides a comprehensive overview of pAgo protein detection platforms and critically assesses their potential in the field of viral POC diagnostics. The objective is to catalyze further research and innovation in pAgo nucleic acid detection and diagnostics, ultimately facilitating the creation of enhanced diagnostic tools for clinic viral infections in POC settings.

Programmable site-specific DNA double-strand breaks via PNA-assisted prokaryotic Argonautes.

Programmable site-specific nucleases promise to unlock myriad applications in basic biology research, biotechnology and gene therapy. Gene-editing systems have revolutionized our ability to engineer genomes across diverse eukaryotic species. However, key challenges, including delivery, specificity and targeting organellar genomes, pose barriers to translational applications. Here, we use peptide nucleic acids (PNAs) to facilitate precise DNA strand invasion and unwinding, enabling prokaryotic Argonaute (pAgo) proteins to specifically bind displaced single-stranded DNA and introduce site-specific double-strand breaks (DSBs) independent of the target sequence. We named this technology PNA-assisted pAgo editing (PNP editing) and determined key parameters for designing PNP editors to efficiently generate programable site-specific DSBs. Our design allows the simultaneous use of multiple PNP editors to generate multiple site-specific DSBs, thereby informing design considerations for potential in vitro and in vivo applications, including genome editing.

Oligomerization-mediated activation of a short prokaryotic Argonaute.

Although eukaryotic and long prokaryotic Argonaute proteins (pAgos) cleave nucleic acids, some short pAgos lack nuclease activity and hydrolyse NAD(P)+ to induce bacterial cell death1. Here we present a hierarchical activation pathway for SPARTA, a short pAgo consisting of an Argonaute (Ago) protein and TIR-APAZ, an associated protein2. SPARTA progresses through distinct oligomeric forms, including a monomeric apo state, a monomeric RNA-DNA-bound state, two dimeric RNA-DNA-bound states and a tetrameric RNA-DNA-bound active state. These snapshots together identify oligomerization as a mechanistic principle of SPARTA activation. The RNA-DNA-binding channel ofapoinactiveSPARTA is occupied by an auto-inhibitory motif in TIR-APAZ. After the binding of RNA-DNA, SPARTA transitions from a monomer to a symmetricdimer and then an asymmetric dimer, in which two TIR domains interact through charge and shape complementarity. Next, two dimers assemble into a tetramer with a central TIR cluster responsible for hydrolysing NAD(P)+. In addition, we observe unique features of interactions between SPARTA and RNA-DNA, including competition between the DNA 3' end and the auto-inhibitory motif, interactions between the RNA G2 nucleotide and Ago, and splaying of the RNA-DNA duplex by two loops exclusive to short pAgos. Together, our findings provide a mechanistic basis for the activation of short pAgos, a large section of the Ago superfamily.

Structural insights into mechanisms of Argonaute protein-associated NADase activation in bacterial immunity

Nicotinamide adenine dinucleotide (NAD+) is a central metabolite in cellular processes. Depletion of NAD+ has been demonstrated to be a prevalent theme in both prokaryotic and eukaryotic immune responses. Short prokaryotic Argonaute proteins (Agos) are associated with NADase domain-containing proteins (TIR-APAZ or SIR2-APAZ) encoded in the same operon. They confer immunity against mobile genetic elements, such as bacteriophages and plasmids, by inducing NAD+ depletion upon recognition of target nucleic acids. However, the molecular mechanisms underlying the activation of such prokaryotic NADase/Ago immune systems remain unknown. Here, we report multiple cryo-EM structures of NADase/Ago complexes from two distinct systems (TIR-APAZ/Ago and SIR2-APAZ/Ago). Target DNA binding triggers tetramerization of the TIR-APAZ/Ago complex by a cooperative self-assembly mechanism, while the heterodimeric SIR2-APAZ/Ago complex does not assemble into higher-order oligomers upon target DNA binding. However, the NADase activities of these two systems are unleashed via a similar closed-to-open transition of the catalytic pocket, albeit by different mechanisms. Furthermore, a functionally conserved sensor loop is employed to inspect the guide RNA–target DNA base pairing and facilitate the conformational rearrangement of Ago proteins required for the activation of these two systems. Overall, our study reveals the mechanistic diversity and similarity of Ago protein-associated NADase systems in prokaryotic immune response.

Thermus thermophilus Argonaute-Based Isothermal Amplification Assay for Ultrasensitive and Specific RNA Detection.

Recent advances in prokaryotic Argonaute proteins (pAgos) as potential genome-editing tools have provided new insights into the development of pAgos-based nucleic acid detection platforms. However, pAgos-based isothermal detection remains challenging. Here, we report a true isothermal amplification strategy, termed Thermus thermophilus Argonaute-based thermostable exponential amplification reaction (TtAgoEAR), to detect RNA with ultrasensitivity and single-nucleotide resolution at a constant temperature of 66 °C. We demonstrate the reliable detection of lncRNA, mRNA, and virus RNA with attomolar sensitivity and that TtAgoEAR can be applied to detect RNA targets in in cell lines, saliva, and tissues. We utilize this assay to distinguish pancreatic cancer cells carrying the mutation from wild-type cells with as little as 2 ng of RNA material. We also show that TtAgoEAR is easily adaptable to a lateral-flow-based readout. These results demonstrate that TtAgoEAR has great potential to facilitate reliable and easy RNA detection in point-of-care diagnosis and field analysis.

Bacterial Argonaute Proteins Aid Cell Division in the Presence of Topoisomerase Inhibitors in Escherichia coli.

Prokaryotic Argonaute (pAgo) proteins are guide-dependent nucleases that function in host defense against invaders. Recently, it was shown that TtAgo from Thermus thermophilus also participates in the completion of DNA replication by decatenating chromosomal DNA. Here, we show that two pAgos from cyanobacteria Synechococcus elongatus (SeAgo) and Limnothrix rosea (LrAgo) are active in heterologous Escherichia coli and aid cell division in the presence of the gyrase inhibitor ciprofloxacin, depending on the host double-strand break repair machinery. Both pAgos are preferentially loaded with small guide DNAs (smDNAs) derived from the sites of replication termination. Ciprofloxacin increases the amounts of smDNAs from the termination region and from the sites of genomic DNA cleavage by gyrase, suggesting that smDNA biogenesis depends on DNA replication and is stimulated by gyrase inhibition. Ciprofloxacin enhances asymmetry in the distribution of smDNAs around Chi sites, indicating that it induces double-strand breaks that serve as a source of smDNA during their processing by RecBCD. While active in E. coli, SeAgo does not protect its native host S. elongatus from ciprofloxacin. These results suggest that pAgo nucleases may help to complete replication of chromosomal DNA by promoting chromosome decatenation or participating in the processing of gyrase cleavage sites, and may switch their functional activities depending on the host species. IMPORTANCE Prokaryotic Argonautes (pAgos) are programmable nucleases with incompletely understood functions in vivo. In contrast to eukaryotic Argonautes, most studied pAgos recognize DNA targets. Recent studies suggested that pAgos can protect bacteria from invader DNA and counteract phage infection and may also have other functions including possible roles in DNA replication, repair, and gene regulation. Here, we have demonstrated that two cyanobacterial pAgos, SeAgo and LrAgo, can assist DNA replication and facilitate cell division in the presence of topoisomerase inhibitors in Escherichia coli. They are specifically loaded with small guide DNAs from the region of replication termination and protect the cells from the action of the gyrase inhibitor ciprofloxacin, suggesting that they help to complete DNA replication and/or repair gyrase-induced breaks. The results show that pAgo proteins may serve as a backup to topoisomerases under conditions unfavorable for DNA replication and may modulate the resistance of host bacterial strains to antibiotics.

Bacterial Argonaute nucleases reveal different modes of DNA targeting in vitro and in vivo.

Prokaryotic Argonaute proteins (pAgos) are homologs of eukaryotic Argonautes (eAgos) and are also thought to play a role in cell defense against invaders. However, pAgos are much more diverse than eAgos and little is known about their functional activities and target specificities in vivo. Here, we describe five pAgos from mesophilic bacteria that act as programmable DNA endonucleases and analyze their ability to target chromosomal and invader DNA. In vitro, the analyzed proteins use small guide DNAs for precise cleavage of single-stranded DNA at a wide range of temperatures. Upon their expression in Escherichia coli, all five pAgos are loaded with small DNAs preferentially produced from plasmids and chromosomal regions of replication termination. One of the tested pAgos, EmaAgo from Exiguobacterium marinum, can induce DNA interference between homologous sequences resulting in targeted processing of multicopy plasmid and genomic elements. EmaAgo also protects bacteria from bacteriophage infection, by loading phage-derived guide DNAs and decreasing phage DNA content and phage titers. Thus, the ability of pAgos to target multicopy elements may be crucial for their protective function. The wide spectrum of pAgo activities suggests that they may have diverse functions in vivo and paves the way for their use in biotechnology.

Strong temperature effects on the fidelity of target DNA recognition by a thermophilic pAgo nuclease

Prokaryotic Argonaute (pAgo) proteins are programmable nucleases with great promise in genetic engineering and biotechnology. Previous studies identified several DNA-targeting pAgo nucleases from mesophilic and thermophilic prokaryotic species that are active in various temperature ranges. However, the effects of temperature on the specificity of target recognition and cleavage by pAgos have not been studied. Here, we describe a thermostable pAgo nuclease from the thermophilic bacterium Thermobrachium celere, TceAgo. We show that TceAgo preferentially uses 5′-phosphorylated small DNA guides and can perform specific cleavage of both single-stranded and double-stranded DNA substrates in a wide range of temperatures. Single-nucleotide mismatches between guide and target molecules differently change the reaction efficiency depending on the mismatch position, with the fidelity of target recognition greatly increased at elevated temperatures. Thus, TceAgo can serve as a tool to allow specific detection and cleavage of DNA targets in a temperature-dependent manner. The results demonstrate that the specificity of programmable nucleases can be strongly affected by the reaction conditions, which should be taken into account when using these nucleases in various in vitro and in vivo applications.

Prokaryotic Argonaute Proteins as a Tool for Biotechnology

Programmable nucleases are the most important tool for manipulating the genes and genomes of both prokaryotes and eukaryotes. Since the end of the 20th century, many approaches were developed for specific modification of the genome. The review briefly considers the advantages and disadvantages of the main genetic editors known to date. The main attention is paid to programmable nucleases from the family of prokaryotic Argonaute proteins. Argonaute proteins can recognize and cleave DNA sequences using small complementary guide molecules and play an important role in protecting prokaryotic cells from invading DNA. Argonaute proteins have already found applications in biotechnology for targeted cleavage and detection of nucleic acids and can potentially be used for genome editing.

A bacterial Argonaute from Tepiditoga spiralis with the ability of RNA guided plasmid cleavage

The eukaryotic Argonaute proteins (eAgos) play an important role in the RNA interference pathway. The function and mechanism of prokaryotic Argonaute proteins (pAgos) in vivo are still unclear although the structure of pAgos and eAgos are highly homologous. Most of the reported pAgos have a preference for 5′P-gDNA, but MpAgo originated from bacteria Marinitoga piezophila preferentially uses 5′OH-gRNA to target DNA and RNA. To enrich our knowledge of this type of Argonaute proteins, here we report an Argonaute protein derived from Tepiditoga spiralis (TsAgo). Like MpAgo, TsAgo has a preference for 5′OH-gRNA. Meanwhile, TsAgo has DNA and RNA cleavage activity in presence of Mn2+ and Mg2+, and TsAgo has catalytic activity at 37–70 °C. In addition, TsAgo can tolerate mismatches in the 5′-end and 3′-tail regions of guides but is sensitive to mismatches in the 5′-seed and central regions of guides, especially the central region. Furthermore, the EMSA assay reveals that TsAgo exhibits a stronger binding affinity for 5′OH-gRNA than 5′P-gRNA which is consistent with its cleavage activity. Moreover, the structural modeling analysis demonstrates that like MpAgo, TsAgo has an ordered α5 at the C terminus of the PIWI domain which may hinder to binding of 5′ phosphate. Importantly, we find that TsAgo can target and cut plasmid DNA in vitro at 60 °C under the direction of RNA guides. These studies broaden our understanding of pAgos, and demonstrate that TsAgo can be regarded as an RNA-guided programmable nuclease for cleaving plasmids.