Adaptive duplication and functional diversification of Protein kinase R contribute to the uniqueness of bat-virus interactions

Jacquet, Stéphanie; Culbertson, Michelle; Zang, Chi; Filali, Adil El; Mory, Clement De La Myre; Pons, Jean-Baptiste; Filippi‐Codaccioni, Ondine; Lauterbur, M. Elise; Ngoubangoye, Barthélémy; Duhayer, Jeanne; Verez, Clément; Park, Chorong; Dahoui, Clara; Carey, Clayton M.; Brennan, Greg; Enard, David; Cimarelli, Andrea; Rothenburg, Stefan; Elde, Nels C.; Pontier, Dominique; Etienne, Lucie

doi:10.1101/2022.06.28.497829

Cited by 2 publications

(4 citation statements)

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“…Screening pairs of variant alleles first required the generation of single, nonsynonymous variants of both PKR and K3L . For PKR , we designed all variants accessible with a single nucleotide polymorphism (SNP) in four windows of interest (Figure 2A); these windows contain residues in the tertiary structure that interface with eIF2a and residues under positive selection (Figure 2B) (Elde et al, 2009; Jacquet et al, 2022; Rothenburg et al, 2009). These windows of interest are defined as Window 1: G255-F278, Window 2: K371-R385, Window 3: S448-M455, and Window 4: E480-I506.…”

Section: Resultsmentioning

confidence: 99%

“…This phenomenon is underpinned by the ‘Red Queen Hypothesis’, stating that constant adaptation between antagonistic interacting proteins is necessary to sustain their respective functions (Van Valen, 1973). Here we investigate an ongoing evolutionary arms race between a component of our immune system, Protein Kinase R (PKR), and a vaccinia virus (VACV) pseudo-substrate antagonist, K3, both of which are under positive selection (Elde et al, 2009; Jacquet et al, 2022; Rothenburg et al, 2009). Prior studies have characterized individual residue variants in both proteins that alter their interaction (Dar & Sicheri, 2002; Kawagishi-Kobayashi et al, 1997; Seo et al, 2008).…”

Section: Introductionmentioning

confidence: 99%

“…Previous work has found both PKR and K3 to be under positive selection, with specific residues highlighted throughout PKR that are rapidly evolving (Elde et al, 2009; Jacquet et al, 2022; Rothenburg et al, 2009). Others have identified single-residue variants of PKR and K3 that alter their interaction (Kawagishi-Kobayashi et al, 1997; Seo et al, 2008).…”

Section: Introductionmentioning

confidence: 99%

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Systematic characterization of the local evolutionary space available to human PKR and vaccinia virus K3

Chambers,

Scobell,

Sadhu

2023

Preprint

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The interfaces between host and viral proteins can be dynamic spaces in which genetic variants are continually pursued, giving rise to evolutionary arms races. One such scenario is found between the mammalian innate immunity protein PKR (protein kinase R) and the poxvirus antagonist K3. Once activated, PKR phosphorylates the natural substrate eIF2α, which halts protein synthesis within the cell and prevents viral replication. K3 acts as a pseudosubstrate antagonist against PKR by directly antagonizing this halt in protein synthesis, enabling poxviruses to replicate in the cell. Exploring the impact of genetic variants in both PKR and K3 is necessary not only to highlight residues of evolutionary constraint and opportunity but also to elucidate the mechanism by which human PKR is able to subvert a rapidly evolving viral antagonist. To systematically explore this dynamic interface, we have generated a combinatorial library of PKR and K3 missense variants to be co-expressed and characterized in a high-throughput yeast selection assay. This assay allows us to characterize hundreds of thousands of unique PKR-K3 genetic combinations in a single pooled experiment. Our results highlight specific missense variants available to PKR that subvert the K3 antagonist. We find that improved PKR variants are readily available at sites under positive selection, with limited opportunity at sites interfacing with K3 and eIF2α. Additionally, we find many variants that improve and disable K3 antagonism, suggesting a pliable interface. We reason that this approach can be leveraged to explore the evolutionary plasticity of many other host-virus interfaces.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Systematic characterization of the local evolutionary space available to human PKR and vaccinia virus K3

Chambers,

Scobell,

Sadhu

2023

Preprint

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“…K3 competitively inhibits eIF2α from binding PKR through its sequence and structural similarity to eIF2α (17,(19)(20)(21). Vertebrate PKR homologs have many sites under positive selection, which suggests an evolutionary arms race between PKR and its inhibitors (22)(23)(24). Surprisingly, this includes PKR residues at its binding surface with eIF2α (Figure 1C) even though this interface is essential to PKR function (22,23), which could reflect evolutionary pressure from viral pseudosubstrate inhibitors.…”

Section: Introductionmentioning

confidence: 99%

Systematic genetic characterization of the human PKR kinase domain highlights its functional malleability to escape a poxvirus substrate mimic

Chambers,

Scobell,

Sadhu

2024

Preprint

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Evolutionary arms races can arise at the contact surfaces between host and viral proteins, producing dynamic spaces in which genetic variants are continually pursued. However, the sampling of genetic variation must be balanced with the need to maintain protein function. A striking case is given by protein kinase R (PKR), a member of the mammalian innate immune system. PKR detects viral replication within the host cell and halts protein synthesis to prevent viral replication by phosphorylating eIF2α, a component of the translation initiation machinery. PKR is targeted by many viral antagonists, including poxvirus pseudosubstrate antagonists that inhibit PKR by interacting with the same binding surface as eIF2α. Remarkably, PKR has several rapidly evolving residues at this interface, suggesting it is engaging in an evolutionary arms race, despite the surface’s critical role in phosphorylating eIF2α. To systematically explore the evolutionary opportunities available at this dynamic interface, we generated and characterized a library of 426 SNP-accessible nonsynonymous variants of human PKR for their ability to escape inhibition by the model pseudosubstrate inhibitor K3 from vaccinia virus. We identified key sites in the PKR kinase domain that harbor K3-resistant variants, as well as critical sites where variation leads to loss of function. We find K3-resistant variants are readily available throughout the interface and are enriched at sites under positive selection. Moreover, variants beneficial against K3 were also beneficial against an enhanced variant of K3, indicating resilience to viral adaptation. Overall, we find that the eIF2α-binding surface of PKR is highly malleable, potentiating its evolutionary ability to combat viral inhibition.

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Adaptive duplication and functional diversification of Protein kinase R contribute to the uniqueness of bat-virus interactions

Cited by 2 publications

References 100 publications

Systematic characterization of the local evolutionary space available to human PKR and vaccinia virus K3

Systematic characterization of the local evolutionary space available to human PKR and vaccinia virus K3

Systematic genetic characterization of the human PKR kinase domain highlights its functional malleability to escape a poxvirus substrate mimic

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