Background: A critical step in uncovering rules of RNA processing is to study the in vivo regulatory networks of RNA binding proteins (RBPs). Crosslinking and immunoprecipitation (CLIP) methods enable mapping RBP targets transcriptome-wide, but methodological differences present challenges to large-scale analysis across datasets. The development of enhanced CLIP (eCLIP) enabled the mapping of targets for 150 RBPs in K562 and HepG2, creating a unique resource of RBP interactomes profiled with a standardized methodology in the same cell types. Results: Our analysis of 223 eCLIP datasets reveals a range of binding modalities, including highly resolved positioning around splicing signals and mRNA untranslated regions that associate with distinct RBP functions. Quantification of enrichment for repetitive and abundant multicopy elements reveals 70% of RBPs have enrichment for non-mRNA element classes, enables identification of novel ribosomal RNA processing factors and sites, and suggests that association with retrotransposable elements reflects multiple RBP mechanisms of action. Analysis of spliceosomal RBPs indicates that eCLIP resolves AQR association after intronic lariat formation, enabling identification of branch points with single-nucleotide resolution, and provides genome-wide validation for a branch point-based scanning model for 3′ splice site recognition. Finally, we show that eCLIP peak co-occurrences across RBPs enable the discovery of novel co-interacting RBPs. Conclusions: This work reveals novel insights into RNA biology by integrated analysis of eCLIP profiling of 150 RBPs with distinct functions. Further, our quantification of both mRNA and other element association will enable further research to identify novel roles of RBPs in regulating RNA processing.
The N6-methyladenosine (m6A) modification is the most prevalent post-transcriptional mRNA modification, regulating mRNA decay and splicing. It plays a major role during normal development, differentiation, and disease progression. The modification is regulated by a set of writer, eraser, and reader proteins. The YTH domain family of proteins consists of three homologous m6A-binding proteins, Ythdf1, Ythdf2, and Ythdf3, which were suggested to have different cellular functions. However, their sequence similarity and their tendency to bind the same targets suggest that they may have overlapping roles. We systematically knocked out (KO) the Mettl3 writer, each of the Ythdf readers, and the three readers together (triple-KO). We then estimated the effect in vivo in mouse gametogenesis, postnatal viability, and in vitro in mouse embryonic stem cells (mESCs). In gametogenesis, Mettl3-KO severity is increased as the deletion occurs earlier in the process, and Ythdf2 has a dominant role that cannot be compensated by Ythdf1 or Ythdf3, due to differences in readers’ expression pattern across different cell types, both in quantity and in spatial location. Knocking out the three readers together and systematically testing viable offspring genotypes revealed a redundancy in the readers’ role during early development that is Ythdf1/2/3 gene dosage-dependent. Finally, in mESCs there is compensation between the three Ythdf reader proteins, since the resistance to differentiate and the significant effect on mRNA decay occur only in the triple-KO cells and not in the single KOs. Thus, we suggest a new model for the Ythdf readers function, in which there is profound dosage-dependent redundancy when all three readers are equivalently coexpressed in the same cell types.
15The N6-methyladenosine (m 6 A) modification is the most prevalent post-transcriptional mRNA 16 modification, regulating mRNA decay, translation and splicing. It plays a major role during normal 17 development, differentiation, and disease progression. The modification is dynamically regulated 18 by a set of writer, eraser and reader proteins. The YTH-domain family of proteins: Ythdf1, Ythdf2, 19and Ythdf3, are three homologous m 6 A binding proteins, which have different cellular functions. 20However, their sequence similarity and their tendency to bind the same targets suggest that they 21 may have overlapping roles. We systematically knocked out (KO) the Mettl3 writer for each of 22 E7.5, and to embryonic lethality. By using systematic genotyping of viable offspring, we found 81 that in early development there is compensation between the readers, which is dosage-82 dependent, i.e. Ythdf2-hetrozygouse mice need to have at least one functional copy of another 83Ythdf reader to escape mortality. Furthermore, we used mESCs to analyze the function of each 84Ythdf reader separately, and together. We found that only triple-KO mESCs are not able to 85 differentiate properly, and present a prolonged mRNA degradation rate, similar to the effect 86shown in Mettl3-KO, while no significant effect is seen in the single-KOs. This suggests that just 87 like in early development, in mouse ESCs, a system in which all the readers are expressed in the 88 same cells and compartment, there is a redundancy between Ythdf readers, which enables 89 compensation in the absence of the other. 90 91Results 92 93Mettl3 writer plays an essential role in oogenesis and spermatogenesis 94 95We started by systematically testing the three readers in a specific system in-vivo, focusing on 96 spermatogenesis and oogenesis. m 6 A writers Mettl3 and Mettl14 and m 6 A erasers FTO and 97ALKBH5 were found to be essential for proper gametogenesis in mouse. Their KO typically leads 98to defective maturation of sperm or ova, and hypofertility (Xu et al.
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