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Alternative mRNA processing and modification

The Lai lab uses an integrated approach to study selected topics in mRNA processing and modification, including alternative polyadenylation, circularization and RNA methylation.

Tissue specific alternative polyadenylation (APA)

As a core member of the modENCODE project, we were deeply involved in reannotating the transcriptome of Drosophila melanogaster, including its short RNAs and conventional transcriptome. One of the surprises of the latter effort was the realization that hundreds of genes utilized unannotated 3’ UTR extensions in the nervous system, and/or shorter 3’ UTRs in the testis. These tissue-specific alternative polyadenylation (APA) programs radically change how we view the post-transcriptional landscape of different settings in the animal. In recent efforts, we have extended this perspective by generating dozens of 3’-seq libraries across development, tissues, and cell lines, and across multiple Drosophila species. These data provide an unprecedented view into

What mechanisms drive tissue-specific APA programs, in cis and in trans? We are analyzing this using bioinformatic queries of our extensive datasets, coupled with molecular genetic screening using the Drosophila model. We are also quite interested to understand the biological imperatives for tissue specific APA. Presumably this reflects needs to alter post-transcriptional regulatory networks. We are examining whether this has impact on specific miRNAs that we have genetic knowledge of. Perhaps more interesting is the genetic perturbation of 3’ UTRs in vivo using CRISPR engineering, to reveal potential phenotypes upon their deletion.

Figure 1. Tissue specific APA of mei-P26. (Left) The mei-P26 gene exhibits an extraordinarily extended 3'UTR in the CNS of 18.5kb, the longest documented in Drosophila, an intermediate length 3'UTR in ovary, and a short 3'UTR in testi. (Right) Northern blotting using universal (uni) and extension (ext) probes confirms that the RNA-seq signals correspond to full-length transcripts in the head (arrowhead).


RNA circularization

Circularization was recently recognized to broadly expand transcriptome complexity.  We exploited massive Drosophila total RNA-sequencing data (>5 billion paired-end reads from >100 libraries covering diverse developmental stages, tissues and cultured cells) to rigorously annotate >2500 fruitfly circular RNAs (Figure 2). These mostly derive from back-splicing of protein-coding genes and lack poly(A) tails, and circularization of hundreds of genes is conserved across multiple Drosophila species. We elucidate structural and sequence properties of Drosophila circular RNAs, which preferentially derive from neural genes and exhibit enhanced accumulation in neural tissues. Interestingly, circular isoforms increase dramatically relative to linear isoforms during CNS aging, and constitute a novel aging biomarker. We are interested to analyze more about the mechanisms of circularization and potential biological activities. 

Figure 2. RNA circularization. (Top) Example of RNA circularization formed by backsplicing of an exon flanked by long introns. (Bottom) Circular RNAs preferentially accumulate in neural total RNA-seq libraries.


RNA methylation

Of the ~100 post-transcriptional chemical modifications to RNA known, N6-methyladenosine (m6A) is the most prevalent modification in mRNA. Although described over 40 years ago, understanding the biological roles of m6A during most of this time was limited by lack of knowledge of molecular mechanisms that generate and interpret this modification, uncertainty on identities of methylated transcripts, and paucity of genetic mutants in specific m6A pathway components that could reveal in vivo requirements of this nucleoside modification. However, recent years have witnessed remarkable progress on all of these fronts, and the realization that m6A is a major epitranscriptomic modification.

            Since most studies of this pathway have been conducted in cultured cells, we established the Drosophila as a powerful system that can combine genetics, biochemistry, and genomics to elucidate in vivo biology of RNA methylation. We used miCLIP to map m6A across embryogenesis, characterize its m6A “writer” complex and YTH readers, and used CRISPR/Cas9 to mutate all the m6A factors. While m6A factors with additional roles in splicing are lethal, m6A-specific mutants are viable but present certain developmental and behavioral defects. Notably, we find that m6A working through the nuclear reader YT521-B facilitates sex-specific splicing of the master female determinant Sxl (Figure 3). In the future, we are interested to use these molecular and genetic toolkit to elucidate other aspects of in vivo m6A biology.

Figure 3. Drosophila m6A pathway. (A) m6A writers and readers. (B) Mapping of m6A modifications (miCLIP track) relative to mRNA-seq identifies extensive modification in the intronic regions (CIMS, nt-precision m6A sites) flanking the sex-specifically alternatively spliced exon of Sxl, the master female determinant. (C) rt-PCR tests reveal accumulation of the male isoform of Sxl in various m6A mutant females. (D) m6A mutant females exhibit lethality when made heterozygous for Sxl, indicating failure of the Sxl autoregulatory program.


Kan, L., A. V. Grozhik, J. Vedanayagam, D. P. Patil, N. Pang, K.-S. Lim, Y.-C. Huang, B. Joseph, C.-J. Lin, V. Despic, J. Guo, D. Yan, S. Kondo, W.-M. Deng, P. C. Dedon, S. R. Jaffrey and E. C. Lai (2017). The m6A pathway facilitates sex determination in Drosophila. Nature Communications 8:15737, 1-16.

Sanfilippo, P., P. Miura, and E. C. Lai (2017). Genome-wide profiling of the 3’ ends of polyadenylated RNAs. Methods S1046-2023(17) 30137-8.

Westholm, J. O., P. Miura, S. Olson, S. Shenker, B. Joseph, P. Sanfilippo, S. E. Celniker, B. R. Graveley and E. C. Lai (2014). Genomewide analysis of Drosophila circular RNAs reveals their structural and sequence properties and age-dependent neural accumulation. Cell Reports 9: 1966-1980.

Miura, P., S. Shenker, P. Sanfilippo and E. C. Lai (2014). Alternative polyadenylation in the nervous system: to what lengths will 3’ UTR extensions take us? Bioassays 8:766-77.

Miura, P., S. Shenker, J. O. Westholm, C. Andreu-Agullo and E. C. Lai (2013). Widespread and extensive lengthening of 3’ UTRs in the mammalian brain. Genome Research 23: 812-825.

Smibert, P., P. Miura, J. O. Westholm, S. Shenker, G. May, M. O. Duff, D. Zhang, B. D. Eads, J. Carlson, B. Brown, R. C. Eisman, J. Andrews, T. Kaufman, P. Cherbas, S. E. Celniker, B. R. Graveley, and E. C. Lai (2012). Global patterns of tissue-specific alternative polyadenylation in Drosophila. Cell Reports 1: 277-289.