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SAMD9L autoinflammatory or ataxia pancytopenia disease mutations activate cell-autonomous translational repression

Amanda J. Russell, Paul Gray, John B. Ziegler, Yae Jean Kim, Sandy Smith, William A. Sewell, Christopher C. Goodnow

2021Proceedings of the National Academy of Sciences32 citationsDOIOpen Access PDF

Abstract

mutations, p.Asn885Thrfs*6 and p.Lys878Serfs*13. These frameshift mutations truncate the SAMD9L protein within a domain a region of homology to the nucleotide-binding and oligomerization domain (NOD) of APAF1, ∼80 amino acids C-terminal to the Walker B motif. Single-cell analysis of human cells expressing green fluorescent protein (GFP)-SAMD9L fusion proteins revealed that enforced expression of wild-type SAMD9L repressed translation of red fluorescent protein messenger RNA and globally repressed endogenous protein translation, cell autonomously and in proportion to the level of GFP-SAMD9L in each cell. The children's truncating mutations dramatically exaggerated translational repression even at low levels of GFP-SAMD9L per cell, as did a missense Arg986Cys mutation reported recurrently as causing ataxia pancytopenia syndrome. Autoinflammatory disease associated with SAMD9L truncating mutations appears to result from an interferon-induced translational repressor whose activity goes unchecked by the loss of C-terminal domains that may normally sense virus infection.

Topics & Concepts

BiologyFrameshift mutationGeneticsMutationGeneinterferon and immune responsesImmune Response and InflammationRNA regulation and disease
SAMD9L autoinflammatory or ataxia pancytopenia disease mutations activate cell-autonomous translational repression | Litcius