Surface resistance to SSVs and SIRVs in pilin deletions of <i>Sulfolobus islandicus</i>

Rowland, Elizabeth F.; Bautista, María A.; Zhang, Changyi; Whitaker, Rachel J.

doi:10.1111/mmi.14435

Cited by 27 publications

(37 citation statements)

References 49 publications

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“…1a, b). Consequently, the filaments appear to serve as the primary receptors for SSRV1 and PFV2, as has been demonstrated for some other archaeal viruses [16][17][18] .…”

Section: Resultsmentioning

confidence: 64%

“…For instance, mass-spectrometry analysis of a crude sample typically yields too many potential candidate proteins for unequivocal identification, whereas some proteins are not amenable to standard tryptic digestion, as has been shown recently for the pili of S. islandicus 26 . Pili appear to be a common receptor for hyperthermophilic archaeal viruses and have been previously shown to be recognized by rudiviruses SIRV2 and SIRV8 16,17 , and turrivirus STIV 18 . Here we have shown that members of yet another family of archaeal viruses, the Tristromaviridae, also bind to the host cells via T4P.…”

Section: Discussionmentioning

confidence: 99%

“…Although the full spectrum of functions played by archaeal T4P is yet to be uncovered, they are known to mediate adhesion to various biotic and abiotic surfaces, and play an important role in DNA exchange, intercellular communication and biofilm formation 14,15 . Furthermore, T4P serve as receptors for certain hyperthermophilic archaeal viruses, including Sulfolobus islandicus rod-shaped viruses 2 and 8 (SIRV2 and SIRV8, respectively; family Rudiviridae) 16,17 and Sulfolobus turreted icosahedral virus (STIV; family Turriviridae) 18 .…”

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confidence: 99%

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The structures of two archaeal type IV pili illuminate evolutionary relationships

Wang

Baquero

et al. 2020

Nat Commun

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We have determined the cryo-electron microscopic (cryo-EM) structures of two archaeal type IV pili (T4P), from Pyrobaculum arsenaticum and Saccharolobus solfataricus, at 3.8 Å and 3.4 Å resolution, respectively. This triples the number of high resolution archaeal T4P structures, and allows us to pinpoint the evolutionary divergence of bacterial T4P, archaeal T4P and archaeal flagellar filaments. We suggest that extensive glycosylation previously observed in T4P of Sulfolobus islandicus is a response to an acidic environment, as at even higher temperatures in a neutral environment much less glycosylation is present for Pyrobaculum than for Sulfolobus and Saccharolobus pili. Consequently, the Pyrobaculum filaments do not display the remarkable stability of the Sulfolobus filaments in vitro. We identify the Saccharolobus and Pyrobaculum T4P as host receptors recognized by rudivirus SSRV1 and tristromavirus PFV2, respectively. Our results illuminate the evolutionary relationships among bacterial and archaeal T4P filaments and provide insights into archaeal virus-host interactions.

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“…1a, b). Consequently, the filaments appear to serve as the primary receptors for SSRV1 and PFV2, as has been demonstrated for some other archaeal viruses [16][17][18] .…”

Section: Resultsmentioning

confidence: 64%

Section: Discussionmentioning

confidence: 99%

mentioning

confidence: 99%

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The structures of two archaeal type IV pili illuminate evolutionary relationships

Wang

Baquero

et al. 2020

Nat Commun

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“…Filamentous surface structures are well known primary anchor points for several viruses infecting bacteria (Poranen et al, 2002;Mäntynen et al, 2019). Recent data suggests that a few crenarchaeal viruses also tether to filamentous surface structures (Quemin et al, 2013;Hartman et al, 2019;Rowland et al, 2020). A hallmark of archaeal surface structures is the widespread similarity to bacterial type IV pili.…”

Section: Pilinsmentioning

confidence: 99%

Cellular and genomic properties ofHaloferax gibbonsiiLR2-5, the host of euryarchaeal virus HFTV1

Tittes

Schwarzer

Pfeiffer

et al. 2020

Preprint

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Hypersaline environments are the source of many viruses infecting different species of halophilic euryarchaea. Information on infection mechanisms of archaeal viruses is scarce, due to the lack of genetically accessible virus-host models. Recently a new archaeal siphovirus, Haloferax tailed virus 1 (HFTV1), was isolated together with its host belonging to the genus Haloferax, but it is not infectious on the widely used model euryarcheon Hfx. volcanii. To gain more insight into the biology of HFTV1 host strain LR2-5, we studied characteristics that might play a role in its virus susceptibility: growth-dependent motility, surface layer, filamentous surface structures and cell shape. Its genome sequence showed that LR2-5 is a new strain of Hfx. gibbonsii. LR2-5 lacks obvious viral defense systems, such as CRISPR-Cas, and the composition of its cell surface is different from Hfx. volcanii, which might explain the different viral host range. This work provides first deep insights into the relationship between the host of halovirus HFTV1 and other members of the genus Haloferax. Given the close relationship to the genetically accessible Hfx. volcanii, LR2-5 has high potential as a new model for virus-host studies in euryarchaea.

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“…This experimental and theoretical evidence for advantages of surface modification may entail strong fitness costs under natural conditions because mutations in surface receptors such as those in flagella or pili can be detrimental for microbial movement and biofilm formation [21]. Investigations of natural populations have indeed shown that surface resistance is costly in the wild [27,28]. These observations underlie the need for complementing experimental approaches by developing theory on the kinds of 'macroscopic', whole system, diversity patterns expected under 'microscopic' CRISPR-induced coevolutionary processes.…”

Section: Introductionmentioning

confidence: 99%

The network structure and eco-evolutionary dynamics of CRISPR-induced immune diversification

Pilosof

Alcalá-Corona

Wang

et al. 2019

Preprint

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As a heritable sequence-specific adaptive immune system, CRISPR-Cas is a powerful force shaping strain diversity in host-virus systems. While the diversity of CRISPR alleles has been explored, the associated structure and dynamics of host-virus interactions has not. We develop theory on the role of CRISPR immunity in mediating the interplay between host-virus interaction structure and eco-evolutionary dynamics in a computational model and three natural systems. We show that the structures of networks describing who infects whom and who is protected from whom are modular and weighted-nested, respectively. The dynamic interplay between these networks influences transitions between dynamical regimes of virus diversification and host control,leading to eventual virus extinction. The three empirical systems exhibit weighted nestedness, a pattern our theory shows is indicative of viral control by hosts. Previously missing from studies of microbial host-pathogen systems, the protection network plays a key role in the coevolutionary dynamics. IntroductionThe structure of complex ecological communities is clearly non-random. It is generally argued that interaction structure affects the stability of communities to perturbations [1-3] and arises from coevolutionary dynamics between interacting partners [4][5][6][7], yet the structure-dynamics nexus remains a long-standing central question in community and network ecology. Host-parasite infection networks, in which interaction structure represents 'who infects whom', have been typically described as modular, nested, or both [8,9]. Modularity concerns patterns of specificity, in which the network is partitioned into modules of hosts and parasites that interact densely with each other but sparsely with those outside the group. Nestedness concerns instead patterns of specialization, and describes a network structure in which specialist hosts are infected by subsets of parasites that in turn also infect the more generalist hosts [8,9].Common to all host-parasite network studies is a dominant focus on patterns of infection. Infection structure should critically depend however on the genetic basis of resistance of hosts to pathogens [10]. The emergence of network structure from immune selection has been shown in pathogens of humans such as Plasmodium falciparum [11, 12]. In particular, strain theory developed for pathogens with multilocus encoding of antigens posits that negative frequency dependent selection, mediated by competition for hosts through cross-immunity, can structure pathogen populations into clusters of strains with limited overlap of antigenic repertoires [11][12][13][14][15]. Parasites with 2 . CC-BY-NC-ND 4.0 International license is made available under a resistance by surface mutation can arise quickly to take over CRISPR or restriction-modification systems in providing immunity. This experimental and theoretical evidence for advantages of surface modification may entail strong fitness costs under natural conditions because mutations in surface receptors such a...

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

Cited by 27 publications

References 49 publications

The structures of two archaeal type IV pili illuminate evolutionary relationships

The structures of two archaeal type IV pili illuminate evolutionary relationships

Cellular and genomic properties ofHaloferax gibbonsiiLR2-5, the host of euryarchaeal virus HFTV1

The network structure and eco-evolutionary dynamics of CRISPR-induced immune diversification

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