Abstract
In contrast to the extensively studied rewiring of epigenetic and transcriptional programs required for cell reprogramming, the dynamics of post-transcriptional changes and their associated regulatory mechanisms remain poorly understood. Here we have studied the dynamics of alternative splicing (AS) changes occurring during efficient reprogramming of mouse B cells into induced pluripotent stem (iPS) cells. These changes, generally uncoupled from transcriptional regulation, significantly overlapped with splicing programs reported during reprogramming of mouse embryonic fibroblasts (MEFs). Correlation between gene expression of potential regulators and specific clusters of AS changes enabled the identification and subsequent validation of CPSF3 and hnRNP UL1 as facilitators, and TIA1 as repressor of MEFs reprogramming. These RNA-binding proteins control partially overlapping programs of splicing regulation affecting genes involved in developmental and morphogenetic processes. Our results reveal common programs of splicing regulation during reprogramming of different cell types and identify three novel regulators of this process.
Introduction
Alternative splicing (AS) is a widespread mechanism of gene regulation that generates multiple mRNA isoforms from a single gene, dramatically diversifying the transcriptome (and proteome) of eukaryotic cells. 95% of multi-exonic mammalian genes undergo AS, producing mRNA isoforms which often differ in coding capacity, stability or translational efficiency, and that can be translated into proteins with distinct structural and functional properties (Pan et al. 2008; E. T. Wang et al. 2008). AS contributes to the regulation of many biological processes in multicellular eukaryotes, including embryonic development and tissue specification (reviewed in Baralle and Giudice, 2017). During the last decade, progress has been made to understand the role of post-transcriptional regulation (including AS) in the maintenance of cellular pluripotency and cell fate decisions, discovering genes differentially spliced between stem cells and differentiated cells and splicing regulators that control these choices (G. W. Yeo et al. 2009; Salomonis et al. 2010; Gabut et al. 2011; Han et al. 2013; Venables et al. 2013; Lu et al. 2014; Yamazaki et al. 2018; Solana et al. 2016a).
During reprogramming into induced pluripotent stem (iPS) cells, somatic cells revert to a pluripotent state after overexpression of the transcription factors OCT4, SOX2, KLF4 and MYC (OSKM) (Takahashi and Yamanaka 2006). Substantial progress has been made to understand the process at the transcriptional and epigenetic level, such as by identifying numerous roadblocks and some facilitators, but comparatively little is known about how posttranscriptional regulation impacts cell fate decisions. Recent work has revealed the functional relevance and conservation of splicing regulation during reprogramming (Han et al. 2013; Ohta et al. 2013; Toh et al. 2016; Kanitz et al. 2019; reviewed in Zavolan and Kanitz, 2018). Previously, a conserved functional splicing program associated with pluripotency and repressed in differentiated cells by the RNAbinding proteins MBNL1 and MBNL2 was previously reported (Han et al. 2013). This splicing program includes a mutually exclusive exon event in the transcription factor FOXP1: a switch in inclusion of Foxp1 exons 16/16b modulates the functions of the transcription factor between pluripotent and differentiated cells (Gabut et al. 2011). Illustrating the complexity of such splicing program, dynamic changes of AS during cell reprogramming of mouse embryonic fibroblasts (MEFs) revealed sequential waves of exon inclusion and skipping in reprogramming intermediates and the functional role of splicing regulators in modulating reprogramming, in particular during the initial mesenchymal-to-epithelial transition (MET) phase (Cieply et al. 2016). Given the limited efficiency of cell reprogramming in this system, subpopulations of reprogramming intermediates had to be isolated through the expression of a pluripotency marker, biasing studies to the most prevalent and dominant factors.
Here we took advantage of the rapid, highly efficient and largely synchronous reprogramming of pre-B cells (hereafter referred to as “B cell reprogramming”), obtained by a pulse of the transcription factor C/EBPα followed by induced OSKM expression (Di Stefano et al. 2014, 2016) to study the dynamics of AS during this transition. The essentially homogeneous reprogramming of the cells in this system allowed detailed temporal transcriptome analyses of the bulk population, without the need of selecting for reprogramming intermediates. We established clusters of temporal regulation and compared these changes with the ones differentially spliced in MEF reprogramming (Cieply et al. 2016). Analyzing the dynamic expression of RNA-binding proteins (RBPs) during reprogramming, we inferred potential AS regulators, of which three were studied in detail. Characterization of these factors, namely CPSF3, hnRNP UL1 and TIA1, by perturbation experiments demonstrated their role as AS regulators in the induction of pluripotency.
Results
Dynamics of alternative splicing in C/EBPα-enhanced B cell reprogramming occur independently from gene expression changes
To study the dynamics of changes in alternative splicing (AS) during cell reprogramming, primary mouse pre-B cells (hereafter referred to as “B cells”) were reprogrammed as previously described (Di Stefano et al. 2016; Stadhouders et al. 2018; Di Stefano et al. 2014). Briefly, B cells were isolated from bone marrow of reprogrammable mice, containing a doxycycline-inducible OSKM cassette and an OCT4-GFP reporter. These cells were infected with a retroviral construct containing an inducible version of C/EBPα fused to the estrogen receptor ligand-binding domain (ER). Infected cells were selected and re-plated on a feeder layer of inactivated mouse embryonic fibroblasts (MEFs). This was followed by a 18h-long pulse of β-estradiol, triggering the translocation of C/EBPα-ER to the nucleus and poising the B cells for efficient and homogeneous reprogramming (Di Stefano et al. 2016, 2014). After washout of β-estradiol, reprogramming was induced by growing the cells for 8 days in reprogramming medium containing doxycycline (see Methods and Stadhouders et al. 2018). RNA was isolated every other day from duplicates and subjected to paired-end sequencing (RNA-seq), resulting in high coverage (more than 100 million reads per sample) (Figure 1A). As positive controls, mouse embryonic stem (ES) cells and induced pluripotent stem (iPS) cells were also sequenced.
AS analysis was performed using vast-tools (Tapial et al. 2017), an event-based software that quantifies Percent Spliced-In (PSI) values of annotated AS events and constitutive exons in all samples. These analyses revealed more than 14000 AS changes during the entire reprogramming time course (for any possible pair of conditions: minimum absolute ΔPSI of 10 between PSI averages and minimum difference of 5 between any individual replicates across conditions) and a gradual increase in the number of differentially spliced events when comparing B cells to progressive stages of somatic cell reprogramming (Figures 1B and S1A). Different classes of AS events were detected, with similar relative proportions at the various time points: 31-47% cassette exons, 5-11% alternative 3’ splice sites and 6-11% alternative 5’ splice sites, and 33-57% retained introns (Figure 1B).
To classify the dynamics of AS changes during reprogramming, we selected cassette exon (CEx) events differentially spliced in at least one comparison (4556 exons) and performed a fuzzy c-means clustering analysis on their scaled PSI values (Mfuzz; Kumar and Futschik, 2007). This analysis revealed diverse kinetics of exon inclusion occurring during B cell reprogramming (Figures 1C and S1B-C, Table S1). Six major clusters of AS dynamic profiles were detected: 1) exons that become included already after the C/EBPα pulse; 2) and 3) exons that are regulated either towards increased inclusion or skipping early after OSKM induction (day 2); 4) and 5) exons that display changes in inclusion at middle stages of reprogramming (day 4 onwards); 6) a cluster of exons only included at the latest steps of reprogramming (day 8 onwards) (Figure 1C). Each of these clusters consisted of 300-500 exons. The inclusion levels of examples of exons belonging to different cluster types were validated by semi-quantitative RT-PCR (Figure 1D). For reference, changes in the PSI values of Grhl1 exon 6 and Dnmt3B exon 10, previously described to be associated with reprogramming and pluripotency (Gopalakrishnan et al. 2009; Gopalakrishna-Pillai and Iverson 2011; Cieply et al. 2016) were also quantified and found to follow similar inclusion patterns in B cell reprogramming, compared to the ones previously described in other systems (Figure 1E).
We next sought to compare general AS and gene expression dynamics during reprogramming. Gene expression was analyzed using the edgeR package (Robinson et al. 2009) and the level of similarity between each pair of conditions was estimated using a Pearson correlation coefficient on the cpm (counts per million) values of the most variable genes (3rd quartile coefficient of variation, n=2961). In addition, Pearson correlation coefficient was calculated based on the PSI values from the most variable cassette exons (3rd quartile coefficient of variation, n=1140). Both analyses showed pronounced switches between days 4 and 6 post-OSKM induction (Figure 1F). Over-all, however, most clusters displayed matching profiles in gene expression and AS of any included exon in less than 10% of the genes, reaching a maximum of 20% in a subset of AS clusters (Figures 1G and S1D-E). These results argue, as observed before in a variety of other systems (e.g. Pan et al. 2004), that global programs of regulation of gene expression and AS are uncoupled from each other.
Interestingly, a larger proportion of exons included (or skipped) at early stages of reprogramming are predicted to disrupt the open reading frame (ORF) of the transcripts upon exon skipping (or inclusion, respectively), compared to middle/late exons and to the general distribution of mapped alternative exons (Figure 1H, classification as described in Tapial et al. 2017). This suggests a higher impact of AS-mediated on/off regulation of the corresponding protein expression via nonsense-mediated decay (NMD), and a switch to expression of full-length proteins during early steps of reprogramming. Middle clusters, instead, contain more exons predicted to preserve the coding potential of their transcripts, implying modulation of the functions of their encoded protein isoforms rather than on/off switches (Figure 1H). Consistent with these concepts, while PSI values of cassette exons tend to increase throughout reprogramming (Figure 1B, blue bars), intron retention – generally leading to NMD – tends to decrease in the course of reprogramming (Figure 1B, grey bars).
AS changes at intermediate reprogramming stages show commonalities with MEF reprogramming
As a first step to identify key AS events and potential regulators important for reprogramming, we compared our transcriptome analysis of B cell reprogramming with that of MEF reprogramming (Cieply et al. 2016). The two datasets differ in the experimental design and time frame (compare Figures 1A and 2A). Specifically, the MEF system required sorting of cells undergoing reprogramming using the SSEA1 surface marker, while this was not necessary for B cell reprogramming due to its efficiency. To facilitate the comparison between the two transcriptome datasets, vast-tools analysis was applied to the MEF dataset (Cieply et al. 2016), which yielded 843 cassette exons differentially spliced (|ΔPSI| ≥10, range ≥ 5) between any pair of samples of the MEF reprogramming dataset. Despite differences in the experimental set up, 79% of these exons (669 out of 843) were also found to be differentially spliced in B cell reprogramming (Figure S2A, Table S2). A similar level of overlap was also observed at the level of other AS events (72% of AS events in general, Figure S2A). The overlap between differentially spliced exons in the two systems was higher for middle and late AS clusters than for early clusters of B cell reprogramming (Figure 2B), as might be expected from the convergence on a common program of AS related to pluripotency.
To further compare the two datasets, we performed a Principal Component Analysis (PCA) on the gene expression of the most variable genes in both datasets (3rd quartile coefficient of variation, n=2679) separating the stages into four distinct groups by k-means clustering (Figure 2C). These groups clearly distinguish between starting cells, early and late stages of reprogramming and pluripotent cells. The PCA allowed us to outline a “reprogramming pseudotime” which was subsequently used to select AS exons and regulators for functional characterization. It also further highlighted the transition between days 4 and 6 in B cell reprogramming, juxtaposing them with days 7/10 in MEF reprogramming. A heatmap displaying the scaled PSI values of the 669 common differentially spliced exons of the two datasets at the different steps of the reprogramming process shows substantial similarities in exon inclusion (Figure 2D).
In contrast to the similarities in AS profiles between the two reprogramming systems, the observed that expression profiles of RNA-binding proteins (RBPs) differed significantly between the two datasets. Specifically, we analyzed the expression of RBPs previously associated with pluripotency, somatic cell reprogramming and/or development (Cieply et al. 2016; Han et al. 2013; Lu et al. 2014; Ohta et al. 2013) and presumably mechanistically linked to different aspects of post-transcriptional regulation (Figure 2E). Despite these more divergent profiles, hierarchical clustering captured three known functional groups, with cluster a) containing factors with higher expression in iPS/ES samples (fold change > 0 and high rank score according to Han et al. 2013, right panel) and known to promote pluripotency/reprogramming, such as U2af1 or Srsf2/3 (Lu et al. 2014; Ohta et al. 2013). In contrast, cluster b) contains factors with higher expression in the starting somatic cells, which includes known repressors of reprogramming such as Mbnl1/2, Celf2 and Zcchc24 (Cieply et al. 2016; Han et al. 2013; Solana et al. 2016b). Finally, cluster c) contains factors with more variegated expression patterns at early and intermediate reprogramming steps (and mildly repressed in iPS/ES cells), including Esrp1/2 (Cieply et al. 2016; Kanitz et al. 2019) (Figure 2E).
Taken together, our analyses revealed widespread AS changes during B cell reprogramming, which significantly overlapped with those of MEF reprogramming, especially at intermediate phases of the process.
Predicted regulators of alternative splicing during somatic cell reprogramming
To infer potential regulators of exons differentially spliced during B cell reprogramming, we extracted gene expression profiles of 507 RBPs (as annotated in the Uniprot database), which were detectably expressed (cpm ≥ 5 in at least 33% of samples) and featured a minimum of variation across the B cell reprogramming dataset (coefficient of variation ≥ 0.2). Using the membership function of the Mfuzz package, we correlated (positively or negatively) the scaled gene expression profile of each RBP to each AS cluster centroid. This allowed us to derive a list of potential regulators whose changes in levels of expression correlate (or anti-correlate) with the profiles of AS changes in each cluster (membership > 0.3) (Figures 3 and S3, Table S3). In line with previous work (Han et al. 2013; Ohta et al. 2013; Solana et al. 2016), our analysis identified known AS regulators involved in the induction or repression of pluripotency/developmental decisions, such as Mbnl1/2, Celf2 (both potential negative regulators of pulse/late clusters 1/6) and U2af1 (potential positive regulator of middle cluster 4) (Figure 3). Importantly, additional RBPs and splicing factors without previously known functions in reprogramming emerged as possible regulators.
To further define such regulators, we focused on RBPs that change their expression after the C/EBPα pulse or at early stages of reprogramming, as we speculated that these could drive the inclusion/skipping of both early and intermediate AS exons during the reprogramming of C/EBPα-poised B cells. We selected CPSF3, a top predicted positive regulator of very early events whose expression increases during B cell and MEF reprogramming, for functional validation during the induction of pluripotency (positive predicted regulator of cluster 1, Figure 3A). We also chose two predicted negative regulators of cluster 1, namely TIA1, a well-described AS regulator with roles in cell proliferation and development (see below), and hnRNP UL1, a member of the heterogeneous ribonucleoprotein (hnRNP) family whose involvement in splicing regulation is largely unexplored (Figure 3B). Due to experimental diffculties in genetic manipulation of the B cell reprogramming system (see Discussion), we modulated their expression at early stages of MEF reprogramming (Stadtfeld et al. 2010) and examined the consequences on the dynamics of pluripotency induction and on relevant AS alterations.
Knockdowns of CPSF3 or hnRNP UL1 repress MEF reprogramming
The Cleavage and Polyadenylation Specificity Factor (CPSF) complex is primarily involved in mRNA polyadenylation, but a number of its components, including CPSF3, have been shown to also play a role in splicing (Kyburz et al. 2006; Larson et al. 2016; Misra et al. 2014, 2015). Cpsf3 expression increased early during reprogramming of both B cells and MEFs (Figures 3A and 4A). The expression of Hnrnpul1, an hnRNP whose function in RNA metabolism is poorly understood, decreases in B cells after the C/EBPα pulse and then stabilizes at levels similar to those observed throughout MEF reprogramming (Figures 3B and 4B).
To test their effects on MEF reprogramming, two different short hairpin RNAs (shRNAs) for each factor were cloned into lentiviral vectors containing a GFP reporter. The protocol used is summarized in Figure S4A. Briefly, early passage MEFs isolated from reprogrammable mice were transduced with constructs bearing the shRNAs and the cells treated with doxycycline to activate OSKM (day 0). GFP+ cells were FACS-sorted 48 hours post-infection and seeded on inactivated MEFs serving as feeder layers, to proceed with reprogramming for up to 14 days. Cells were harvested every other day and samples analyzed by RT-qPCR for the expression of the shRNAs target and of pluripotency markers, and by flow cytometry to quantify the proportion of cells expressing the early pluripotency cell surface marker SSEA1 (appearing around day 5-6) and the later pluripotency marker EPCAM1 (appearing around day 8, J. M. Polo et al. 2012). At day 14, two days after removing doxycycline, cultures were stained for alkaline phosphatase (AP) activity to identify iPS colonies and to assess the efficiency of reprogramming.
Cells infected with shRNAs targeting Cpsf3 and Hnrnpul1 were compared with non-infected (NI) cells, as well as with cells transduced with a scrambled control shRNA (shSCR). Knockdown efficiency, quantified by RT-qPCR (Figures 4C and D), showed a 51% and 58% reduction in Cpsf3 at day 6 post-infection with shCPSF3#1 and #2, respectively, becoming slightly less efficient during reprogramming (Figure 4C). Similarly, knockdown of Hnrnpul1 resulted in 81% and 76% reduction of mRNA levels at day 6 post-infection with shUL1#1 and #2, respectively (Figure 4D). The increase in the mRNA levels of endogenous Pou5f1 (encoding OCT4) and Nanog pluripotency markers was delayed in both Cpsf3 and Hnrnpul1 knockdown cells (compare for example values at day 8 in Figures 4E and S4B), suggesting slower reprogramming kinetics. Consistent with these observations, knockdown of Cpsf3 and Hnrnpul1 reduced the percentage of cells expressing SSEA1 at day 6 (Figure 4F) and cells expressing both SSEA1 and EPCAM1 at days 10-12 (Figures 4G and S4C). Survival of cells during reprogramming did not seem to be affected in the knockdowns because no significant increase in the proportion of DAPI-stained cells was observed throughout reprogramming (Figure S4D). Finally, we counted the number of AP positive colonies at day 14 and found that the amount was significantly reduced in cells infected with either the shRNAs targeting Cpsf3 or those targeting Hnrnpul1 (Figure 4H).
Taken together, these data show that the knockdown of Cpsf3 or Hnrnpul1 reduces the MEF to iPS reprogramming efficiency, therefore arguing that both RBPs contribute to the induction of pluripotency.
Overexpression of TIA1 represses MEF reprogramming
TIA1 is an RBP and AS regulator (Förch et al. 2000, 2002; Izquierdo et al. 2005). Tia1 mRNA levels decrease early during B cell reprogramming (Figures 3B and 5A), compatible with a potential role as a repressor of cell reprogramming in this system. Because depletion of TIA1 induces mouse embryonic lethality and the protein is important for MEF proliferation, cell cycle progression, autophagy and numerous signaling pathways (Sánchez-Jiménez and Izquierdo, 2013), we decided to test the effects of TIA1 overexpression during MEF reprogramming. For this purpose, primary MEFs were infected at day 0 (concomitantly with the induction of reprogramming), with retroviral constructs containing a T7-tagged Tia1 cDNA and a GFP reporter to allow sorting of the transduced cells (Figure S4A). Levels of Tia1 were quantified by RT-qPCR (24-fold increase compared to cells transduced with an empty vector, Figure 5B). Consistent with our prediction from its expression profile in B cell reprogramming, overexpression of Tia1 repressed the induction of endogenous Pou5f1 and Nanog genes (Figures 5C and S4E) and led to a reduction of early SSEA1+EPCAM1-cells and of late reprogramming intermediates (SSEA1+EPCAM1+ cells) compared to empty vector and non-infected controls (Figures 5D-E and S4F). In addition, it significantly reduced the count of AP+ colonies at day 14 post-OSKM induction compared to controls (Figure 5F), without substantially affecting the viability of reprogramming cells (Figure S4G). Of note, overexpression of Tia1 delayed the gradual skipping of Lef1 exon 6, a conserved AS event between B cell and MEF reprogramming (Figure 5G), which might partially explain the observed reduction in reprogramming efficiency.
Taken together, the observed reduced expression of TIA1 during B cell reprogramming and its impairment of MEF reprogramming when overexpressed suggest that it functions as a general repressor of pluripotency induction.
CPSF3, hnRNP UL1 and TIA1 regulate alternative splicing during reprogramming
To assess the effects of CPSF3, hnRNP UL1 and TIA1 manipulation on AS during reprogramming, RNA-seq analyses were carried out with RNAs isolated from MEFs at 0 and at 12 days post-OSKM induction, comparing the effects of Cpsf3/Hnrnpul1 knockdown (two different shRNAs for each factor) or Tia1 overexpression with those of the corresponding shSCR/empty vector controls (Figure 6A). Quantification of gene expression of Tia1, Cpsf3 and Hnrnpul1 at the two timepoints is shown in Figures S6A-B.
To determine the impact of these per tur bations on AS we calculated differentially spliced events between day 0 and day 12 in each condition as described before (|ΔPSI(day12-day0)| ≥ 10, range ≥ 5). TIA1-dependent events were defined as those changing during reprogramming only in the control or the overexpression condition, with |ΔΔPSI(TIA1-Empty)| ≥ 10 (colored dots in Figure 6B). Similarly, CPSF3-dependent and UL1-dependent events were defined as those with |ΔΔPSI(average shRNAs-shSCR)| ≥ 10 (only events selected by both specific shRNAs were considered, 54% and 60% overlap respectively, colored dots in Figures 6C and S6C). For each RBP, control events, changing during reprogramming but not affected by TIA1, CPSF3 or hnRNP UL1 manipulation, were classified as those differentially spliced between days 0 and 12, either in control or knockdown/overexpression conditions (|ΔPSI(day12-day0)| ≥ 10, range ≥ 5), that display minimal differences between the ΔPSI values in the two conditions (e.g. |ΔΔPSI(TIA1-Empty)| < 2) (grey dots in Figures 6B-C and S6C). All sets are summarized in Table S4.
We thus identified 387 TIA1-dependent events and 558 TIA1-independent events. Similarly, we identified 357 CPSF3-dependent and 298 UL1-dependent events (as well as 429 CPSF3-independent and 662 UL1-independent events). Interestingly, CPSF3-dependent and UL1-dependent events showed a significant overlap (e.g. 70% of UL1-dependent events were also CPSF3-dependent events, of which 98% changed in the same direction) whereas little overlap was observed with TIA1-dependent events (Figure 6D, left panel). As we found no strong evidence for cross-regulation between CPSF3 and hnRNP UL1 factors (either in AS or in gene expression, Figure S6B), these data suggest that CPSF3 and hnRNP UL1 contribute to a common program of AS changes relevant for cell reprogramming. Moreover, TIA1-, CPSF3- and UL1-dependent events detected in MEFs showed high overlap with events that were also differentially spliced during B cell reprogramming, suggesting that these factors regulate AS events that generally contribute to the induction of pluripotency (Figure 6D, right panel).
Focusing on cassette exon events, TIA1-dependent exons (but not TIA1-independent exons) displayed significantly higher PSI values at day 12 compared to day 0 of reprogramming, as well as a relative increase in exons displaying intermediate PSI values (Figures 6E-F and S6E). These effects are altered by TIA1 overexpression (Figure 6E), suggesting that in this system, the typical role of TIA1 is to repress exon inclusion.
Analysis of sequence features associated with TIA1-regulated exons performed using Matt (Gohr and Irimia, 2018) revealed weaker 5′ splice sites, shorter median length of the flanking downstream introns and a larger difference in GC content between the alternative exons and their flanking upstream introns (Figure 6G), suggestive of a strong dependence of these exons on the process of exon definition (Amit et al. 2012). Notably, an enrichment in putative TIA1 binding motifs was detected about 100 nucleotides upstream of the distal 3′ splice site (Figure 6H), suggesting that binding of TIA1 to this region might repress inclusion of the alternative exon (or enhance pairing between the distal splice sites), leading to exon skipping.
Gene Ontology (GO) enrichment analysis (GOrilla; Eden et al. 2009) on the set of genes containing TIA1-dependent AS events compared to a background list of all genes containing mapped AS events (n=11132) showed an enrichment in functions related to peptide/ hormone secretion, T-helper cell functions and embryonic development (Figure 6I).
CPSF3- and UL1-dependent exons showed similar inclusion patterns: an increased proportion of intermediate PSIs was observed at day 12 in CPSF3- and UL1-dependent but not in -independent events (Figures 6J-K and S6F). CPSF3- and UL1-dependent exons also showed higher PSI values at day 12 compared to day 0, and an enrichment in exons displaying intermediate PSI values at the end of the reprogramming process (Figures 6J-K and S6F). These effects were attenuated, specifically for CPSF3- and UL1-dependent exons upon knockdown of either of these factors (Figures 6J-K and S6F), supporting the notion that their regulatory programs overlap. Both CPSF3- and UL1-dependent exons displayed weaker 3’ and 5’ splice sites (Figure 6L). GO analyses revealed that CPSF3- and UL1-dependent events belong to genes enriched in functional categories related to the regulation of cell morphogenesis, cell-substrate adhesion and cytoskeleton organization (Figure 6M).
Taken together, these results suggest that the AS regulators TIA1, CPSF3 and hnRNP UL1 function in cell reprogramming through their activities on genes relevant for cell fate decisions. Moreover, CPSF3 and hnRNP UL1 act through a highly overlapping program of splicing changes, while TIA1 affects a different set of AS events.
Discussion
Somatic cell reprogramming holds great promise for fundamental research and medicine. In this study, we have characterized the dynamics of AS changes during the deterministic reprogramming of B cells into iPS cells and have identified three splicing regulators with a role in somatic cell reprogramming, as validated in perturbation experiments performed during MEF reprogramming.
The B cell reprogramming system is a twostep process, in which a pulse of the myeloidspecific transcription factor C/EBPα poises the cells for deterministic reprogramming by the subsequent induction of the OSKM factors, inducing early chromatin opening and epigenetic modifications that silence of the B cell-specific program and induce pluripotency (Di Stefano et al. 2014, 2016; Sardina et al. 2018; Stadhouders et al. 2018). While C/EBPα might not directly impact AS, it remains possible that the pulse of C/EBPα could induce changes in the expression of splicing regulatory factors (e.g. induction of CPSF3 or repression of hnRNP UL1 or TIA1) that trigger a program of post-transcriptional changes that contributes to cell reprogramming, or that C/EBPα could have direct effects on the activity of splicing factors.
We observed widespread changes in AS, whose frequency increased as reprogramming progressed. Clustering analysis of cassette exons revealed groups of exons varying in inclusion at very early stages of B cell reprogramming (including following the C/EBPα pulse), but also at middle and late phases after OSKM induction. Of note, early clusters contain a larger proportion of exons predicted to disrupt open reading frames (ORFs) of isoforms predominantly expressed in the B cells, whereas middle clusters contain more ORF-preserving exons. Together with the observation that the majority of regulated introns tend to be retained (leading to ORF disruption) at early stages and are progressively spliced during reprogramming, these findings suggest that, in the transition from early to late stages, AS acts as a switch towards a gain in coding capacity, while at intermediate stages of reprogramming AS acts more commonly as a switch between isoforms.
The AS switch observed between day 4 and day 6 of B cell reprogramming coincides with a transcriptional switch, although the proportion of genes displaying both gene expression and AS changes is lower than expected (typically 1/3 of alternatively spliced transcripts are controlled at the level of gene expression by nonsense mediated decay, Lewis, Green and Brenner, 2003; Pan et al. 2004, 2008). The transcriptomic changes observed during this transition might be mediated at least in part by the replacement of the culture medium from serum + LIF cell to N2B27-based 2i medium at day 6. Exons changing their inclusion levels during this intermediate period displayed the highest overlap with exons differentially spliced in the reprogramming of MEFs, arguing for the general relevance of these changes in the induction of pluripotency.
Our analysis of changes in expression of RBPs during B cell reprogramming suggested potential regulators of AS, including factors already known to play a role in cell reprogramming such as the pluripotency repressors MBNL1/2 and CELF2 (Han et al. 2013; Solana et al. 2016), which are downregulated during B cell reprogramming, and positive pluripotency regulators such as U2AF1 and hnRNP H1 (Ohta et al. 2013; Yamazaki et al. 2018), which were upregulated during the process, consistent with results described for MEF reprogramming (Cieply et al. 2016). We focused on three candidate regulators of early AS changes, CPSF3, hnRNP UL1 and TIA1 because they could potentially contribute to the reprogramming advantage acquired by B cells poised by C/EBPα and/or to early events occurring during reprogramming. We found that perturbations of each of the three factors impaired the reprogramming of MEFs. CPSF3 plays an important role in mRNA polyadenylation, recognizing the polyadenylation signal (PAS) together with the rest of the CPSF complex. In addition to the well-known intense crosstalk between last intron splicing and 3’ end processing (Kyburz et al. 2006), CPSF2 and the CPSF complex have been shown to influence splicing of internal exons independently of cleavage and polyadenylation (Misra et al. 2014, 2015). Furthermore, mutations of the CPSF3 yeast homolog Brr5/Ysh1 have been shown to strongly affect splicing, suggesting that CPSF3 could also play similar direct regulatory functions (Larson et al. 2016). hnRNP UL1, instead, is a largely uncharacterized RBP known to participate in DNA damage response (Polo et al. 2012b) and identified as a surface marker of human ES cells, although its functions in this context remain unknown (Choi et al. 2011). Recent work in Zebrafish suggest a possible role for Hnrnpul1 in the regulation of AS (Blackwell et al. 2020).
Knockdown of Cpsf3 or Hnrnpul1 (with two independent shRNAs for each gene) caused a general repression or delay in MEF reprogramming, revealing their functions as promoters of somatic cell reprogramming. Sequence analysis of regulated AS events suggest that CPSF3 and hnRNP UL1 favor the definition of exons harboring relatively weak splice sites. Remarkably, the AS targets of CPSF3 and hnRNP UL1 identified by our RNA-seq analyses show a high overlap (without evidence of cross-regulation between the two proteins), suggesting a concerted mechanism of splice site selection, perhaps as components of the same complex. It is unlikely that the overlap is an indirect consequence of reduced/ delayed reprogramming, because TIA1 over-expression also inhibits reprogramming and yet it is accompanied by largely non-overlapping changes in AS. These observations suggest that multiple, separable AS programs contribute to the regulation of cell reprogramming.
TIA1 is a regulator of RNA metabolism influencing mRNA decay and AS implicated in cell proliferation, cell cycle progression, cellular stress, autophagy and programmed cell death (Förch et al. 2000; Izquierdo et al. 2005; Kedersha et al. 1999; Sánchez-Jiménez & Izquierdo 2013) whose depletion induces mouse embryonic lethality (Piecyk et al. 2000).
We found that TIA1 overexpression at early stages of reprogramming represses the induction of pluripotency, as reported for MBNL proteins (Han et al. 2013). Binding of TIA1 to U-rich sequences downstream of weak 5’SS helps to recruit U1 snRNP and facilitates exon definition (Förch et al. 2000, 2002; Izquierdo et al. 2005; Wang et al. 2014), while it can also inhibit the inclusion of alternative exons located at a distance from its binding site (Ule et al. 2010). As expected, TIA1-dependent exons are enriched in weak 5’ splice sites and other features that support a role in exon definition. Interestingly, TIA1-dependent exons in our system feature an enrichment of predicted U-rich TIA1 binding sites approximately 100 nucleotides upstream of the 3’ splice site located in the downstream intron, suggesting that this configuration serves to repress the inclusion of exons that contribute to cell reprogramming. Since GO terms most enriched in genes bearing TIA1-dependent exons include ‘positive regulation of peptide hormone secretion’, we hypothesize that TIA1-regulated transcripts could modulate functions related to the senescence-associated secretory phenotype (SASP), which was shown to promote reprogramming of somatic cells and dedifferentiation in cancer (Brady et al. 2013; Mosteiro et al. 2016; Ritschka et al. 2017). Indeed, 7 out of 23 (30%) of the genes belonging to these GO terms were also found in a list of senescence- or SASP-associated genes (GeneCards database; Stelzer et al. 2016).
The finding that overexpression of TIA1 caused a delay in the conserved gradual skipping of Lef1 exon 6 observed during MEF reprogramming is consistent with a conserved role of the factor in reprogramming, as gradual skipping of this exon was also observed in middle stages of B cell reprogramming, along with a decrease in expression of the gene. LEF1 is a transcription factor with important functions in embryonic and T cell development and activation (Oosterwegel et al. 1993; Travis et al. 1991; Van Genderen et al. 1994; Waterman et al. 1991; Zhou et al. 1995). As Lef1 exon 6 inclusion is promoted by CELF2 during T cell development and activation (Ajith et al. 2016; Mallory et al. 2011, 2015) and Celf2 expression rapidly decreases in both B cell and MEF reprogramming, CELF2 may participate – along with TIA1 – in Lef1 exon 6 regulation during reprogramming. We observed that overexpression of Lef1 at the start of MEF reprogramming improved reprogramming efficiency (observed as an increase of pluripotency markers and percentage of reprogramming intermediates), with overexpression of the iPS-associated Lef1 exon 6-skipping isoform displaying stronger effects than the exon 6-including isoform, suggesting a functional role for this switch in cell reprogramming (Figure S5). We speculate that the gradual skipping of exon 6 affects the interaction of LEF1 with protein partners that either act as coactivators – e.g. ALY (Bruhn et al. 1997) – or corepressors – e.g. Groucho/TLE (Levanon et al. 1998) –, differentially affecting the transcription of target genes. For example, the LEF1inclusion isoform could promote cell proliferation and maintenance of B cell identity – as observed in the C/EBPα-dependent transdifferentiation system and in pancreatic cancer cell lines (Jesse et al. 2010; Rodriguez-Ubreva et al. 2014) –, while gradual skipping of exon 6 might alter its effect on its target genes with the consequence of inducing pluripotency, most probably in a β-catenin independent way.
In summary, our results provide a comparison between AS changes occurring in two very different reprogramming systems and a wealth of information relevant for cell fate decisions and transitions to pluripotency. Furthermore, they demonstrate the functional involvement of the splicing regulators CPSF3, hnRNP UL1 and TIA1 in efficient cell reprogramming. It thus significantly extends previous work on splicing during reprogramming and suggests that AS is required for the entire transition of somatic into pluripotent stem cells. It would be interesting to determine whether the AS changes and regulators identified in our work play similar roles during the specification of pluripotent stem cells in early embryo development.
Materials and Methods
RNA sequencing
For RNA sequencing of B cell reprogramming and MEF reprogramming upon TIA1 overexpression and knockdown of CPSF3 and hnRNP UL1, stranded libraries were prepared from samples and sequenced on an Illumina HiSeq 2500 v4 using a 2×125nt paired-end protocol. Duplicates were sequenced for each condition, with samples pooled in separate lanes. RNA-seq data (triplicates of 2×100nt paired-end sequencing) of MEF reprogramming was downloaded from GEO Database (Cieply et al. 2016).
Data and code accessibility
All scripts and RNA-seq data of MEF reprogramming upon TIA1 overexpression and knockdown of CPSF3 and hnRNP UL1 will be released to public databases when the article is accepted for publication.
Gene expression and alternative splicing analyses
Reads mapping was performed with STAR (Dobin et al. 2013) and gene expression analysis was performed using the edgeR package v3.16.5 (McCarthy et al. 2012; Robinson et al. 2009). A minimum of 5 counts per million (cpm) was required in 33% of both datasets (5 samples for B cell reprogramming, 6 samples for MEF reprogramming) and a minimum coefficient of variation of 0.2 was required.
Alternative splicing (AS) analysis was performed using vast-tools software v2.2.2 (Irimia et al. 2014; Tapial et al. 2017). Strand-specific mapping was performed and only events with a minimum of 10 actual reads per sample were considered (VLOW quality score). PSI values for single replicates were quantified for all types of alternative events, including simple and complex cassette exons (S, C1, C2, C3), microexons (MIC), alternative 5′ and 3′ splice sites (Alt5, Alt3) and retained introns (IR-S, IR-C). For cassette exon events (referred to as CEx), PSI values of all annotated exons were also quantified with vast-tools (Annotation module ANN). For both B cell and MEF reprogramming, all possible pairwise comparisons between samples were performed, selecting differentially spliced events with a |ΔPSI| ≥ 10 and a minimum range of 5 between samples.
For TIA1 overexpression experiments, TIA1-dependent events were defined as events with |ΔΔPSI| ≥ 10, where ΔΔPSI = (ΔPSI TIA1_day12 – NI_day0) - (ΔPSI Empty_day12 – NI_day0). TIA1-independent events were instead defined as events changing in any of the two conditions (|ΔPSI| TIA1_day12 – NI_day0 ≥ 10) or (|ΔPSI| Empty_day12 – NI_day0 ≥ 10) and having minimal difference between the two conditions (|ΔΔPSI| < 2).
Similarly, CPSF3- or UL1-dependent events were events for which in both shRNAs |ΔΔPSI| ≥ 10, where ΔΔPSI = (ΔPSI shC/U#1/2_day12 – NI_day0) - (ΔPSI shSCR_day12 – NI_day0). CPSF3- or UL1-independent events were instead defined as events changing in any of the knockdown or control conditions (|ΔPSI| shC/ U#1/2_day12 – NI_day0 ≥ 10) or (|ΔPSI| shSCR_day12 – NI_day0 ≥ 10) and having minimal difference between the two conditions (|ΔΔPSI| < 2).
Clustering analysis of alternatively spliced exons and correlation of gene expression profiles
PSI values of exons differentially spliced in at least one pair of B cell reprogramming samples (n=4556) were scaled and centered (referred to as ‘scaled PSI’ values). Fuzzy c-means clustering analysis was carried out using the R package Mfuzz (Futschik & Carlisle 2005; Kumar & Futschik 2007) on the scaled PSI values. The optimal number of clusters (12) was selected on the basis of the minimum distance to the cluster centroid. A membership value was assigned to correlate gene expression profiles to each AS clusters, either of genes containing the AS exons of each cluster or of genes encoding RBPs. To each scaled cpm values vector, we attributed a membership value to the centroid of each cluster or to its negative.
Correlation of B cell reprogramming stages
Pearson correlation coefficient for B cell reprogramming stages was calculated on the most variable expressed genes (cpm ≥ 5 in at least 5 samples and coefficient of variation ≥ 0.73864, corresponding to the 3rd quartile, n=2961) or the most variable exons (differentially spliced in at least one pairwise comparison and coefficient of variation ≥ 0.4107, corresponding to the 3rd quartile, n=1139).
Prediction of the protein impact of alternative exons
Alternative exons detected by vast-tools were classified as described in vastDB v2.2.2 (Tapial et al. 2017). Briefly, following division according to their location in non-coding RNAs, untranslated regions (5’ or 3’UTRs) or open reading frame (ORF), exons were predicted to disrupt the ORF if their inclusion or skipping would induce a frameshift in their ORF or if they would induce a premature stop codon (PTC) predicted to be targeted by nonsense-mediated decay (NMD) or truncating the protein by more than 300 amino acids. The rest of the ORF-mapping events are predicted to preserve the transcript coding-potential.
Principal Component Analysis (PCA) and comparison between B cell and MEF reprogramming
Gene expression values were filtered for minimum variation (coefficient of variation ≥ 0.66, corresponding to the 3rd quartile, n=2679), scaled and centered (referred to as ‘scaled cpm’ values). Principal Component Analysis (PCA) was performed on scaled cpm values of the most variable genes expressed in both B cell and MEF reprogramming. The groups shown were obtained by k-means clustering. For heatmaps representing scaled PSI and scaled cpm values in B cell and MEF reprogramming, hierarchical clustering was performed on values of both datasets using a Ward’s method and Euclidean distance as the distance metric.
Correlation of RNA-binding proteins expression to AS clusters
The lists of Mus musculus RNA-binding proteins (RBPs) and splicing-related proteins were downloaded from the Uniprot database. For RBPs, Uniprot keywords had to match ‘RNA-binding [KW-0694]’, ‘mRNA splicing [KW-0508]’, ‘mRNA processing [KW-0507]’ or ‘Spliceosome [KW-0747]’. Splicing-related RBPs were defined if keywords were matching either ‘mRNA splicing [KW-0508]’ or ‘Spliceosome [KW-0747]’. Filtered gene expression values were scaled as described above and a membership value was attributed to each RBP profiles for each AS cluster centroid and to its negative (RBPs with membership ≥ 0.3 are shown). Word clouds were created with WordArt.com online tool, with the size of each RBP name proportional to the corresponding membership value and colors highlighting splicing-associated RBPs.
Sequence feature analysis and RNA maps
Sequence features of exons and flanking introns were analyzed using Matt software v1.3.0 (Gohr & Irimia 2019). Features of TIA1-, CPSF3- or UL1-dependent exons were compared with the corresponding independent exons and with a set of control Cassette exons, representing alternative exons not changing during reprogramming. Specifically, the union of alternative non-changing exons (AS_NC sets, 10 < average PSI < 90 and ΔPSI ≤ 2) in all conditions of each dataset was generated, TIA1- or CPSF3/UL1-dependent events were excluded and a random set was selected, with a size similar to TIA1- or CPSF3-/UL1-dependent and -independent exon sets. Maximum entropy score is calculated as an approximation of splice site strength (Yeo & Burge 2004). RNA maps for TIA1 M075 motif (Ray et al. 2013) were generated for the first and last 50 nt of exons and the first and last 150nt of introns (sliding window = 31, p value ≤ 0.05 with 1000 permutations).
Statistical analyses and plots
Statistical tests were performed as indicated in figures legends with R (v3.6.1) or GraphPad Prism (version 8). Heatmaps were plotted with ggplot2 package or heatmap.2 function. Venn diagrams were generated with Biovenn (Hulsen et al. 2008).
Gene Ontology enrichment analysis
Genes bearing the differentially spliced exons belonging to each set were analyzed for GO terms enrichment in contrast to all genes containing any mapped AS event. Analysis was carried out with the ‘two unranked lists of genes’ module of GOrilla (Gene Ontology enRIchment anaLysis and visuaLizAtion) tool (Eden et al. 2009) and summarized using REViGO (Supek et al. 2011). Statistical significance was defined with p value < 1e-03. Only enriched terms for GO Process are shown.
Cell culture
Platinum E cells (PlatE), 293T/17 cells, stromal S17 cells and primary MEFs serving as feeder cells for B cell reprogramming were kindly provided by the group of T. Graf and cultured in Glutamax Dulbecco’s modified Eagle’s (DMEM, Life Technologies) medium supplemented with 10% fetal bovine serum (FBS) and penicillin/streptomycin antibiotics (PenStrep, 50 U/ml penicillin; 50 μg/ml streptomycin). All cells were maintained at 37°C under 5% CO2 and routinely tested for mycoplasma.
Lentivirus production
293T/17 cells were seeded on gelatincoated 10 cm plates at a density of 3×106 cells/ plate and incubated overnight. The following day, medium was replaced approximately 2 hours before transfection. For each 10 cm plate, 10 μg of the plasmid of interest, 2.5 μg of VSV-G and 7.5 μg of pΔ8.9 were mixed with 61 μl of CaCl2 2.5 M (Sigma) and endotoxin-free water up to 500 μl. While bubbling, 500 μl of 2x HBS pH7.2 (281 mM NaCl, 100 mM HEP-ES, 1.5 mM Na2HPO4) were added dropwise, and the mix was incubated for 10 min at room temperature (RT). The solution was added dropwise to the 293T/17 cells, followed by incubation for 24 hours at 37°C. The following day, medium was substituted with 6 ml of fresh medium (reprogramming medium for MEF reprogramming). Viral medium was collected 48 and 72 hours after transfection, filtered (0.22 μm pore size) and supplemented as needed.
Retrovirus production
4.5×106 PlatE cells were seeded in gelatin-coated 10cm plates (0.1% gelatin, Millipore) the day before transfection. To improve efficiency, chloroquine was added approximately one hour before transfection to a final concentration of 30 μM. For each plate, 20 μg of plasmid were mixed with 60 μl of CaCl2 2.5 M (Sigma) and endotoxin-free water up to 500 μl. While bubbling, 500 μl of 2x HBS pH 7.2 (281 mM NaCl, 100 mM HEPES, 1.5 mM Na2HPO4) were added dropwise, and the mix was incubated for 10 min at room temperature (RT). The solution was added dropwise to the PlatE cells and transfected cells were incubated for 8-10 hours. Medium was substituted with 6 ml of fresh medium (reprogramming medium for MEF reprogramming). Viral medium was collected the day after transfection and the following one, filtered (0.22 μm filter pore size) and supplemented as needed.
C/EBPα-dependent B cell reprogramming
Primary B cell reprogramming was performed as described in (Di Stefano et al. 2014, 2016; Di Stefano & Graf 2016; Stadhouders et al. 2018).
MEF reprogramming
Primary MEFs (P0), obtained from male embryos of a Collagen-OKSM, M2rtta+, mouse line (Stadtfeld et al. 2010) were cultured on gelatin-coated plates in MEF medium (DMEM, high glucose + Glutamax, FBS 10%, PenStrep 1x, Sodium Pyruvate 1 mM, HEPES 30 mM, NEAA 1x, β-mercaptoethanol 0.1 mM). Primary MEFs were expanded for a maximum of 2 passages before inducing reprogramming. Early passage MEFs were plated in MEF medium on gelatin-coated 6-well plates at a density of 70.000 cells/well. The following day, infection was performed by substituting the medium with the filtered retroviral or lentiviral supernatant (prepared in reprogramming medium), supplemented with LIF and doxycycline to induce reprogramming. Two subsequent infections were performed, 12 hours apart, after which fresh reprogramming medium was added. The following day (day 2) cells were trypsinized and FACS-sorted for GFP expression by flow cytometry. Sorted MEFs were seeded (10.000 cells/well of 12-well plate) on irradiated feeders on gelatin-coated plates (plated the previous day 100.000 cells/well of 12-well plate). Medium was substituted every 2 days starting from day 4. Harvesting was performed every two days with trypsin 0.25% to ensure the complete dissociation of the feeder layer. Doxycycline was withdrawn from the culture at day 12 post-OSKM induction and AP staining was performed at day 14 with the Alkaline Phosphatase Kit II (StemGent), according to the manufacturer’s instructions. The number of AP+ colonies was quantified with ImageJ software (colony size between 20-2000 pixels).
Reprogramming medium is composed by DMEM, high glucose + Glutamax, ES-qualified FBS 15%, PenStrep 0.5x, Sodium Pyruvate 1 mM, HEPES 30 mM, NEAA 1x, β-mercaptoethanol 0.1 mM. LIF (1000 U/ml) and doxycycline (1μg/ml) were added freshly.
Flow cytometry analysis
Cells were trypsinized and stained with a mix of antibodies SSEA1-eFluor 660 (MC-480, eBioscience) and EpCAM-PE (G8.8, eBioscience), both at a 1:50 dilution in 100 μl per sample. Staining was carried out by incubating on ice for 20 min, followed by washing and staining with DAPI (Sigma). Flow cytometry analysis was performed with a BD LSR II analyser. Gates and compensation between FITC and PE were adjusted on non-stained controls. 10.000 events (alive cells) per sample were acquired.
Cloning of LEF1 isoforms and TIA1 in retroviral vectors
Lef1 isoforms were amplified from bulk cDNAs of B cells and iPS (RNA-seq samples) and cloned using Gibson technology (Gibson et al. 2009) into a MIG-pMSCV retroviral vector including an IRES-GFP element. Kozak consensus sequences and an N-terminal T7 tag were inserted before the LEF1 ORF to ensure efficient translation and discrimination from endogenous Lef1.
cDNA of mouse Tia1 was purchased from GenScript in pcDNA3.1 vectors (clone ID: OMu08423D) and cloned using a similar Gibson strategy into the MIG-pMSCV retroviral vector bearing the N-terminal T7 and IRES-GFP elements. Gibson reaction master mixes were provided by the CRG Protein Technologies Core Facility.
Short hairpin RNAs
Five MISSION shRNAs specific for each splicing regulator were purchased from Sigma in pLKO lentiviral vectors and their effects were compared with those of SHC002 mammalian non-targeting MISSION shRNA (Sigma). The effect of each shRNA was tested on MEFs and E14 embryonic stem cells, and knockdown efficiency was assessed by RT-qPCR at 72/96h post-infection using primers specific for each target and normalised by the expression of two housekeeping genes (Gapdh and Rplp0). The two shRNAs displaying the largest knockdown effects in both cell lines were selected (sequences shown in Table S6).
RNA extraction and retrotranscription, semi-quantitative RT-PCR and real-time qPCR (RT-qPCR)
RNA extraction and DNAse treatment was performed using Maxwell simplyRNA kit (Promega) or RNeasy Mini kit (Qiagen), following the manufacturers’ instructions.
200 ng of total RNA were reverse-transcribed with Superscript III (Invitrogen) following the manufacturer’s recommendations.
PCR reactions were carried out using Go-Taq enzyme (Promega) with 1 μl of cDNA diluted 1:5. To quantify inclusion of alternatively spliced exons, capillary electrophoresis was performed using a Labchip GX Caliper workstation (Caliper, Perkin Elmer) at the CRG Protein Technologies Core Facility. The nanomolar content of each band was extracted with Lab-Chip GX software and PSI values were calculated as the ratio between the inclusion amplicon and the sum of inclusion and skipping amplicons.
Real Time quantitative PCR (RT-qPCR) was performed on a ViiA7 Real Time PCR System (Applied Biosystems). Reactions in a total volume of 10μl contained 2x SYBR Green Master Mix (Applied Biosystems), primers 400 nM and 1μl of previously synthetized cDNA, diluted 1:5-20. The output Ct values were normalized by the expression of the housekeeping gene GAPDH (unless differently stated) and analysed with ΔCt/ΔΔCt method. All primers sequences are listed in Table S6.
Authors contributions
C.V., T.G., and J.V. conceived the study. C.V., P.P., J.L.S. and J.V. designed experiments and data analyses. C.V. and J.V. wrote the manuscript with input from all authors. C.V. performed the majority of the experimental work and data analyses (RNA-seq analyses, MEF reprogramming and molecular biology experiments). R.S., B.D.S. and C.B. performed the B cell reprogramming experiments for RNA-seq. S.G, A.M. and B.P. provided reprogrammable MEFs. J.V. and T.G. acquired funding.
Declaration of Interests
The authors declare no competing interests.
Supplementary Figures
Supplementary Tables
Table S1. Cassette exon events differentially spliced in B cell reprogramming. This table includes the information about the AS cluster each exon belongs to and the predicted effect on its transcript. Data for other types of events is available upon request.
Table S2. Cassette exon events differentially spliced in MEF reprogramming. This table includes the information about the overlap with B cell reprogramming. Data for other types of events is available upon request.
Table S3. Gene expression levels of RBPs correlating with AS clusters (positive and negative predicted regulators).
Table S4. CPSF3-, UL1- and TIA1-dependent and -independent events. This table includes the sets of control cassette exons (CEx) used for KD (CPSF3- and UL1-dependent CEx) or OE (TIA1-dependent CEx).
Table S5. Gene Ontology terms enriched in CPSF3-, UL1- and TIA1-dependent events. This table includes outputs from GOrilla and REViGO analyses.
Table S6. Sequences of primers and shRNAs used in this study.
Acknowledgements
We thank the CRG Genomics Unit for sequencing; the CRG Tissue Engineering Unit for the inactivated MEF feeders; the CRG/UPF FACS Unit for FACS sorting; Daniel Soronellas for help with the Mfuzz package and Konrad Hochedlinger for the Col-OKSM reprogrammable mouse strain. We thank members of Manuel Irimia’s, T.G.’s and J.V.’s groups for discussions; Manuel Irimia and members of J.V.’s group for critical reading of the manuscript. C.V. was recipient of an FPI-Severo Ochoa Fellowship from the Spanish Ministry of Economy and Competitiveness Work in J.V. laboratory is supported by the European Research Council (ERC AdvG 670146), AGAUR, Spanish Ministry of Economy and Competitiveness (BFU 2017 89308-P) and the Centre of Excellence Severo Ochoa. Work in T.G.’s laboratory was supported by the European Research Council FP7/2007-2013 (ERC Synergy Grant 4D-Genome) the Ministerio de Educación y Ciencia (SAF.2012-37167) and AGAUR.