Abstract
Maternal RNA degradation is critical for embryogenesis and is tightly controlled by maternal RNA-binding proteins. Fragile X mental-retardation protein (FMR1) binds target mRNAs to form ribonucleoprotein (RNP) complexes/granules that control various biological processes, including early embryogenesis. However, how FMR1 recognizes target mRNAs and how FMR1-RNP granule assembly/disassembly regulates FMR1-associated mRNAs remain elusive. Here we show that Drosophila FMR1 preferentially binds mRNAs containing m6A-marked “AGACU” motif with high affinity to contributes to maternal RNA degradation. The high-affinity binding largely depends on a hydrophobic network within FMR1 KH2 domain. Importantly, this binding greatly induces FMR1 granule condensation to efficiently recruit unmodified mRNAs. The degradation of maternal mRNAs then causes granule de-condensation, allowing normal embryogenesis. Our findings reveal that sequence-specific mRNAs instruct FMR1-RNP granules to undergo a dynamic phase-switch, thus contributes to maternal mRNA decay. This mechanism may represent a general principle that regulated RNP-granules control RNA processing and normal development.
Highlights
Maternal RNA degradation is critical for embryogenesis and is tightly controlled by maternal RNA-binding proteins
Because the proper degradation of maternal RNAs is critical for embryogenesis, we sought to ask whether the m6A plays a role in normal embryogenesis
We report that a subset of m6A-modified messenger RNA (mRNA) instructs Fragile X mental retardation protein[1] (FMR1)–RNP granules to undergo a dynamic phase-switch, contributing to maternal RNA degradation during early embryogenesis
Summary
Maternal RNA degradation is critical for embryogenesis and is tightly controlled by maternal RNA-binding proteins. The high-affinity binding largely depends on a hydrophobic network within FMR1 KH2 domain This binding greatly induces FMR1 granule condensation to efficiently recruit unmodified mRNAs. The degradation of maternal mRNAs causes granule de-condensation, allowing normal embryogenesis. Our findings reveal that sequence-specific mRNAs instruct FMR1-RNP granules to undergo a dynamic phase-switch, contributes to maternal mRNA decay. This mechanism may represent a general principle that regulated RNP-granules control RNA processing and normal development. Our findings reveal the mechanism by which a subset of m6A-modified mRNAs regulates the dynamics of RNA-granules, contributing to the decay of target RNAs and ensuring normal development
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