Abstract
The RIG-like receptors (RLRs) are related proteins that identify viral RNA in the cytoplasm and activate cellular immune responses, primarily through direct protein-protein interactions with the signal transducer, IPS1. Although it has been well established that the RLRs, RIG-I and MDA5, activate IPS1 through binding between the twin caspase activation and recruitment domains (CARDs) on the RLR and a homologous CARD on IPS1, it is less clear which specific RLR CARD(s) are required for this interaction, and almost nothing is known about how the RLR-IPS1 interaction evolved. In contrast to what has been observed in the presence of immune-modulating K63-linked polyubiquitin, here we show that—in the absence of ubiquitin—it is the first CARD domain of human RIG-I and MDA5 (CARD1) that binds directly to IPS1 CARD, and not the second (CARD2). Although the RLRs originated in the earliest animals, both the IPS1 gene and the twin-CARD domain architecture of RIG-I and MDA5 arose much later in the deuterostome lineage, probably through a series of tandem partial-gene duplication events facilitated by tight clustering of RLRs and IPS1 in the ancestral deuterostome genome. Functional differentiation of RIG-I CARD1 and CARD2 appears to have occurred early during this proliferation of RLR and related CARDs, potentially driven by adaptive coevolution between RIG-I CARD domains and IPS1 CARD. However, functional differentiation of MDA5 CARD1 and CARD2 occurred later. These results fit a general model in which duplications of protein-protein interaction domains into novel gene contexts could facilitate the expansion of signaling networks and suggest a potentially important role for functionally-linked gene clusters in generating novel immune-signaling pathways.
Highlights
The evolution of novel molecular interactions can have profound implications for the organism, including changing how it develops, responds to environmental challenges and interacts with symbionts and pathogens
Analyses of cellular immune-signaling in mammals have demonstrated convincingly that the twin N-terminal caspase activation and recruitment domains (CARDs) domains of the RIG-like receptors (RLRs), RIG-I and MDA5, interact directly with the N-terminal CARD domain of IPS1 to initiate antiviral immune responses [5, 6]
In the absence of polyubiquitin, we found that RIG-I and MDA5 CARD1 and CARD1 +2 domains bound to IPS1 CARD with high affinity, whereas CARD2 domains did not (Fig 1B and S2 Fig)
Summary
The evolution of novel molecular interactions can have profound implications for the organism, including changing how it develops, responds to environmental challenges and interacts with symbionts and pathogens. Understanding how new molecular interactions arise, establish themselves as distinct from existing interactions, and change over evolutionary time provides a reductionist foundation from which to begin answering fundamental questions regarding the evolution of organsimal complexity and novelty [1]. The RIG-like receptors (RLRs) RIG-I and MDA5 are cytoplasmic proteins that identify viral RNA and initiate cellular immune responses by interacting with the signal-transducing protein, IPS1 [2,3,4]. The third RLR, LGP2, lacks CARD signaling domains and appears to regulate antiviral immune responses through various mechanisms [7,8,9]
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