CRISPR-mediated gene silencing reveals involvement of the archaeal S-layer in cell division and virus infection

Zink, Isabelle Anna; Pfeifer, Kevin; Wimmer, Erika; Sleytr, Uwe B.; Schuster, Bernhard; Schleper, Christa

doi:10.1038/s41467-019-12745-x

Cited by 38 publications

(54 citation statements)

References 72 publications

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“…Previous work has suggested that SSV1 adsorption requires the S‐layer in S. solfataricus P1 (Stedman et al, ; Zink et al, ). We have shown that S. islandicus lacking the outer S‐layer (SlaAB) is viable and contained pili and archaellum, although the archaellum are nonmotile in this strain (Zhang et al, ).…”

Section: Resultsmentioning

confidence: 99%

Surface resistance to SSVs and SIRVs in pilin deletions of Sulfolobus islandicus

Rowland

Bautista

Zhang

et al. 2019

Molecular Microbiology

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Characterizing the molecular interactions of viruses in natural microbial populations offers insights into virus–host dynamics in complex ecosystems. We identify the resistance of Sulfolobus islandicus to Sulfolobus spindle‐shaped virus (SSV9) conferred by chromosomal deletions of pilin genes, pilA1 and pilA2 that are individually able to complement resistance. Mutants with deletions of both pilA1 and pilA2 or the prepilin peptidase, PibD, show the reduction in the number of pilins observed in TEM and reduced surface adherence but still adsorb SSV9. The proteinaceous outer S‐layer proteins, SlaA and SlaB, are not required for adsorption nor infection demonstrating that the S‐layer is not the primary receptor for SSV9 surface binding. Strains lacking both pilins are resistant to a broad panel of SSVs as well as a panel of unrelated S. islandicus rod‐shaped viruses (SIRVs). Unlike SSV9, we show that pilA1 or pilA2 is required for SIRV8 adsorption. In sequenced Sulfolobus strains from around the globe, one copy of each pilA1 and pilA2 is maintained and show codon‐level diversification, demonstrating their importance in nature. By characterizing the molecular interactions at the initiation of infection between S. islandicus and two different types of viruses we hope to increase the understanding of virus–host interactions in the archaeal domain.

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Section: Resultsmentioning

confidence: 99%

Surface resistance to SSVs and SIRVs in pilin deletions of Sulfolobus islandicus

Rowland

Bautista

Zhang

et al. 2019

Molecular Microbiology

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“…Inner face net negatively charged due to an excess of carboxyl groups [7,8,24] Antifouling, non-sticky outer surface [7,11,28] Self-assembly capability in aqueous media, on the air/water interface, on lipid films, and on solid surfaces like metals (gold, silver, platinum, stainless steel), glass, silicon, silicon oxide and nitride, mica, polymers (e.g., polystyrene, polyester, cellulose, polydimethylsiloxane (PDMS), indium tin oxide (ITO), highly oriented pyrolytic graphite (HOPG), and carbon nanotubes [7,9,[28][29][30] S-layer proteins have so far suggested to mediate a broad range of specific biological functions, including protection against (e.g., bdellovibrios, bacteriophages, and phagocytosis) promoters for cell adhesion (e.g., to host enzymes and cells, immune-modulators, surface recognition, molecular sieve, molecule and ion traps, antifouling coatings, and virulence factors in pathogenic organisms) [7,23,31,32]. Moreover, the S-layer lattice is involved in the determination of cell shape and can aid in the cell division process in archaea possessing S-layers as the exclusive envelope component external to the cytoplasmic membrane [32][33][34][35].…”

Section: General Featuresmentioning

confidence: 99%

Electrochemical Biosensors Based on S-Layer Proteins

Damiati

Schuster

2020

Sensors

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Designing and development of electrochemical biosensors enable molecule sensing and quantification of biochemical compositions with multitudinous benefits such as monitoring, detection, and feedback for medical and biotechnological applications. Integrating bioinspired materials and electrochemical techniques promote specific, rapid, sensitive, and inexpensive biosensing platforms for (e.g., point-of-care testing). The selection of biomaterials to decorate a biosensor surface is a critical issue as it strongly affects selectivity and sensitivity. In this context, smart biomaterials with the intrinsic self-assemble capability like bacterial surface (S-) layer proteins are of paramount importance. Indeed, by forming a crystalline two-dimensional protein lattice on many sensors surfaces and interfaces, the S-layer lattice constitutes an immobilization matrix for small biomolecules and lipid membranes and a patterning structure with unsurpassed spatial distribution for sensing elements and bioreceptors. This review aims to highlight on exploiting S-layer proteins in biosensor technology for various applications ranging from detection of metal ions over small organic compounds to cells. Furthermore, enzymes immobilized on the S-layer proteins allow specific detection of several vital biomolecules. The special features of the S-layer protein lattice as part of the sensor architecture enhances surface functionalization and thus may feature an innovative class of electrochemical biosensors.

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“…1) [29][30][31][32][33][34]. Recently, we used this technology to silence the gene encoding an essential translation initiation factor, aIF5A [32], and the S-layer anchor, SlaB [31] in S. solfataricus, enabling a phenotypic analysis of the depletion cultures. Silencing of slaB caused severe growth defects and perturbed cell division, limiting our ability to obtain stable lines with a silence efficiency of greater than 75% [31].…”

Section: Introductionmentioning

confidence: 99%

“…Recently, we used this technology to silence the gene encoding an essential translation initiation factor, aIF5A [32], and the S-layer anchor, SlaB [31] in S. solfataricus, enabling a phenotypic analysis of the depletion cultures. Silencing of slaB caused severe growth defects and perturbed cell division, limiting our ability to obtain stable lines with a silence efficiency of greater than 75% [31]. This indicated that, under the applied growth conditions, SlaB might execute an essential function in S. solfataricus, even though it was shown to be non-essential in S. islandicus [3].…”

Section: Introductionmentioning

confidence: 99%

Comparative CRISPR type III-based knockdown of essential genes in hyperthermophilic Sulfolobales and the evasion of lethal gene silencing

et al. 2020

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CRISPR type III systems, which are abundantly found in archaea, recognize and degrade RNA in their specific response to invading nucleic acids. Therefore, these systems can be harnessed for gene knockdown technologies even in hyperthermophilic archaea to study essential genes. We show here the broader usability of this posttranscriptional silencing technology by expanding the application to further essential genes and systematically analysing and comparing silencing thresholds and escape mutants. Synthetic guide RNAs expressed from miniCRISPR cassettes were used to silence genes involved in cell division (cdvA), transcription (rpo8), and RNA metabolism (smAP2) of the two crenarchaeal model organisms Saccharolobus solfataricus and Sulfolobus acidocaldarius. Results were systematically analysed together with those obtained from earlier experiments of cell wall biogenesis (slaB) and translation (aif5A). Comparison of over 100 individual transformants revealed gene-specific silencing maxima ranging between 40 and 75%, which induced specific knockdown phenotypes leading to growth retardation. Exceedance of this threshold by strong miniCRISPR constructs was not tolerated and led to specific mutation of the silencing miniCRISPR array and phenotypical reversion of cultures. In two thirds of sequenced reverted cultures, the targeting spacers were found to be precisely excised from the miniCRISPR array, indicating a still hypothetical, but highly active recombination system acting on the dynamics of CRISPR spacer arrays. Our results indicate that CRISPR type III-based silencing is a broadly applicable tool to study in vivo functions of essential genes in Sulfolobales which underlies a specific mechanism to avoid malignant silencing overdose.

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CRISPR-mediated gene silencing reveals involvement of the archaeal S-layer in cell division and virus infection

Cited by 38 publications

References 72 publications

Surface resistance to SSVs and SIRVs in pilin deletions of Sulfolobus islandicus

Surface resistance to SSVs and SIRVs in pilin deletions of Sulfolobus islandicus

Electrochemical Biosensors Based on S-Layer Proteins

Comparative CRISPR type III-based knockdown of essential genes in hyperthermophilic Sulfolobales and the evasion of lethal gene silencing

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