Abstract
RNA surveillance by the Nonsense Mediated Decay (NMD) pathway eliminates potentially deleterious transcripts containing Premature Termination Codons (PTCs). The transition from a pioneering round of translation to steady state translation is hypothesized to be a major checkpoint in this process. One hallmark of mRNAs licensed for translation is the exchange of 7-methylguanosine cap binding proteins. However, mRNAs undergoing steady state translation are also NMD substrates, raising mechanistic questions about the NMD checkpoint. To test the role of cap binding proteins in NMD, we modulated the protein composition of cytoplasmic messenger ribonucleoprotein particles (mRNPs) with the naturally occurring macrolide rapamycin. We demonstrate that despite well-documented attenuation of cap-dependent mRNA translation, rapamycin can augment NMD. Rapamycin-treatment significantly reduces the levels of endogenous and exogenous PTC-containing mRNA isoforms in a dose-and UPF1- dependent manner. PTC-containing transcripts exhibit a shorter half-life upon rapamacyin-treatment as compared to non-PTC isoforms. Rapamycin also causes depletion of PTC-containing mRNA isoforms from polyribosomes, suggesting that actively translating ribosomes can transition between low and high NMD states. Importantly, mRNPs show depletion of eIF4E and retention of the nuclear Cap Binding Complex (CBC) in rapamycin-treated cells. Our data demonstrate that rapamycin potentiates pioneer-like mRNP context thereby decreasing NMD evasion.
Introduction
Nonsense Mediated Decay (NMD) is a conserved RNA surveillance system which recognizes and eliminates transcripts containing Premature Termination Codons (PTCs) (Popp and Maquat 2013). The NMD system prevents the synthesis of potentially toxic proteins arising from transcripts containing nonsense mutations, frame shifts and those generated by alternative splicing. NMD is known to regulate the expression of many genes, including those involved in the NMD pathway itself (Ni et al. 2007; Huang et al. 2011).
The constellation of proteins associated with RNA transcripts is dynamic and reflects the diverse cellular landscapes traversed by the mRNA. For example, all newly synthesized mRNAs are bound by the nuclear Cap Binding Complex (CBC), the Exon Junction Complex (EJC) and the nuclear poly(A) binding protein (PABPN1) (Le Hir et al. 2000; Ishigaki et al. 2001; Lejeune et al. 2002). By contrast, mRNAs licensed for translation are depleted of EJC proteins, and have exchanged CBC and PABPN1 at the cap and poly(A) tail for the eukaryotic translation initiation factor 4E (eIF4E) and the cytoplasmic poly(A) binding protein (PABPC), respectively (Dostie and Dreyfuss 2002; Lejeune et al. 2002; Sato et al. 2008). Termination codons located more than 25-35 nt upstream from an Exon Junction Complex (EJC) are strong NMD signals (Lejeune et al. 2003). Following PTC detection by a pioneering ribosome, the SMG1 phosphatidylinositol 3-kinase-related kinase (SMG1) and the EJC protein UP-Frameshift Mutation 1 homolog (UPF1) interact with the translation termination release factor-1 and -3 (eRF1 and eRF3, respectively) to form the SURF complex (Chiu et al. 2004; Kashima et al. 2006). The SURF complex associates with the downstream EJC and triggers SMG1-dependent phosphorylation of UPF1, which is required for inhibition of translation initiation and subsequent nucleolytic decay of the targeted messenger RNA (Ohnishi et al. 2003). Additionally, shorter 3’UTRs are thought to suppress NMD and presence of cis-acting elements in long 3’UTRs can trigger NMD evasion (Eberle et al. 2008; Toma et al. 2015).
NMD efficiency may be linked to the composition of messenger ribonucleoprotein particles (mRNPs). The CBC is displaced by eIF4E in a translation-independent manner (Dias et al. 2009; Sato and Maquat 2009). This exchange mechanism is driven by interactions of CBP80 with the nuclear import receptor Importin b (IMPb) and also presumably by mass action due to the high cytoplasmic concentrations of eIF4E (Sato and Maquat 2009; Rong et al 2008). These rearrangements have important consequences for NMD; for example the interaction of CBC with UPF1 promotes assembly of the SURF complex and is important for activating NMD (Hosoda et al. 2005). Recent observations suggest that NMD in mammalian cells can also occur during eIF4E-initiated translation. This is in contrast to the pioneer round model (Durand and Lykke-Andersen 2013; Rufener and Muhlemann 2013). However these data raise the intriguing hypothesis that NMD efficiency and regulation might differ when triggered in the context of CBC- or eIF4E-bound mRNPs.
The mechanistic Target of Rapamycin Complex 1 (mTORC1) serves as part of a nutrient/stress sensing pathway and is inhibited by the naturally occurring macrolide rapamycin, which promotes autophagy and extends lifespan (Laplante and Sabatini 2012; Kim et al. 2013). One important branch of the mTORC1 signaling pathway modulates initiation of cap-dependent translation through phosphorylation of targets such as 4EBPs (eIF4E-Binding proteins) and S6K1 (40S ribosomal subunit protein S6 protein kinase 1). The 4EBP family functions as inhibitor of cap dependent translation by inducing nuclear sequestration of eIF4E (Rong et al. 2008). Active mTORC1 phosphorylates 4EBPs and counteracts their inhibitory effects on eIF4E (Gingras et al. 2001) thereby stimulating translation. Interestingly, mTORC1 inhibition does not lead to global repression of translation but rather to a regulated inhibition of translation and control of gene expression (Hsieh et al. 2012). Furthermore, eIF4G, a translation initiation factor that is stimulated by mTOR, suppresses NMD (Joncourt et al. 2014). These observations prompted us to hypothesize that mTORC1 inhibition by rapamycin may enhance NMD.
Here we show that rapamycin augments decay of endogenous and exogenous PTC-containing mRNA isoforms in a dose and UPF1-dependent manner. Interestingly, PTC-containing mRNA isoforms accumulate in polyribosomes when mTORC1 is active, but are depleted when cells are treated with rapamycin. Because rapamycin inhibits mTORC1 causing nuclear sequestration of eIF4E, we hypothesized that rapamycin would alter the dynamics of CBC- and eIF4E- cap binding decreasing NMD evasion. Indeed, we observe that rapamycin treatment induces nuclear accumulation of eIF4E. Concomitantly, we show that rapamycin promotes eIF4E depletion from cytosolic mRNPs whilst binding of CBC is moderately increased, suggesting accumulation of pioneer-like mRNPs. Taken together, our results demonstrate that mammalian cells can dynamically regulate NMD efficiency of messenger RNA associated with polyribosomes depending on the cellular needs.
Results and Discussion
Depletion of PTC-containing mRNA isoforms by rapamycin is dose dependent
To assess the effects of rapamycin on NMD substrates we assayed the abundance of NMD sensitive and insensitive mRNA isoforms over a broad rapamycin concentration range by RT-qPCR. As expected, phosphorylation of 4EBP decreases with increasing rapamycin concentrations, suggesting that the activity of the mTORC1 pathway is being modulated in a dose-dependent manner (Figure 1A). We then implemented a previously described RT-qPCR assay (Lareau et al. 2007) and analyzed two different NMD substrates with different modalities of AS-NMD: a) inclusion of exon 3 in the SRSF6 mRNA which introduces a PTC and induces NMD and b) skipping of exon 13 from CCAR1 which leads to a frameshift that triggers NMD (Ni et al. 2007). Figures 1B and 1C show the results of RT-qPCR analysis of PTC-containing and PTC-non-containing (non-PTC) isoforms for SRSF6 and CCAR1 genes, respectively. PTC-containing isoforms of SRSF6 and CCAR1 genes diminish with increasing concentrations of rapamycin. This decrease is statistically significant at the highest doses, 22nM and 2.2nM of rapamycin. We also assayed the levels of total gene expression for SRSF6 and CCAR1 employing primers to amplify constitutive exons in each gene and using SDHA as housekeeper normalizer according to (Lareau et al. 2007). Our data for SRSF6 and CCAR1 suggest that rapamycin causes an overall increase in the total mRNA expression of both genes (Supplemental Figure 1).
To determine the effects of rapamycin in exogenous PTC-containing transcripts we employed a previously developed and validated NMD reporter (Boelz et al. 2006). We co-transfected HEK 293 T cells with a reporter vector containing a wild type -globin open reading frame (WT) or an NMD-triggering mutation -globin (MUT) fused to a renilla luciferase gene (schematics in Figure 1D) together with a normalizer firefly luciferase vector. Transfected cells were then treated with vehicle (Control), 22nM of rapamycin (Rapa) or emetine (Emetine) and chemiluminiscence was measured. We employed emetine as a positive control of NMD inhibition that leads to up-regulation of PTC-containing transcripts (Noensie and Dietz 2001). Figure 1E shows our results as Relative Luminescence Units of the normalized renilla NMD-reporter compared to the normalized WT-reporter (RLU MUT/WT) as in (Boelz et al. 2006). Our data indicate that the expression of the NMD reporter was significantly diminished in cells treated with rapamycin compared to vehicle (compare Rapa to Control). As expected, emetine treatment increased the stability of the NMD reporter. Taken together, our data suggest a widespread mechanism for rapamycin triggering depletion of PTC-containing mRNAs.
Rapamycin affects mRNA stability of PTC-containing mRNA isoforms and requires UPF1
The previous experiments suggested that rapamycin augments NMD activity and decreases levels of PTC-containing isoforms in HEK cells. In order to confirm that the observed change in the ratio of PTC-containing/non-PTC isoforms is due to RNA decay and not merely AS regulation, we assayed the half-life of PTC-containing and non-PTC isoforms of SRSF6 in a rapamycin dependent manner using RT-qPCR. Figure 2A shows that endogenous SRSF6 PTC-containing isoform displayed accelerated decay kinetics in rapamycin-treated cells as compared to the non-PTC isoform, suggestive of an increased rate of NMD rather than regulation of AS.
To test the direct role of NMD machinery in rapamycin effects, we compared the levels of PTC-containing SRSF6 mRNA isoforms in UPF1-depleted HEK cells treated with or without rapamycin. Depletion of UPF1 inhibits NMD in a variety of model systems (Leeds et al. 1991; Hurt et al. 2013). We generated stably transduced HEK cell lines with an inducible Tet-On shRNA against UPF1 or a scramble control (Bulliard et al. 2006) (Figure 2B). As previously observed, rapamycin stimulation decreased the levels of PTC-containing isoforms of endogenous SRSF6 in control cells. However, this effect was attenuated in the UPF1 depleted cells (Figure 2C). These data demonstrate that the depletion of PTC-containing isoforms by rapamycin is dependent on UPF1 and supports our hypothesis that rapamycin enhances NMD.
Rapamycin decreases levels of PTC-containing isoforms bound to polyribosomes
NMD can happen not only during pioneer translation but also during steady translation, given that eIF4E-bound mRNAs are substrates of NMD (Rufener and Muhlemann 2013). Moreover, Durand et al. demonstrated that eIF4F-bound transcripts are susceptible to NMD, even when translation is inhibited (Durand and Lykke-Andersen 2013). A prediction from these experiments is that NMD efficiency of polyribosome-associated mRNAs may be dynamically regulated. Given that NMD in mammals is translation-dependent (Hu et al. 2009; Hu et al. 2010) and that rapamycin is a global translation modulator, we hypothesized that rapamycin-treatment might enhance the decay of polyribosome-bound PTC-containing transcripts. We investigated this hypothesis in cells treated with or without rapamycin. As expected, rapamycin-treatment increased the electrophoretic mobility of 4EBP on SDS-PAGE relative to control cells (Figure 3A), indicative of 4EBP hypophosphorylation. We then isolated polyribosomes from control or rapamycin treated cells. We observed that rapamycin treated cells showed the distinctive characteristics of global translational inhibition when compared to control cells: an increase in the monosomal fraction (80S, peak) and a decrease of the polyribosome fractions (Figure 3B shows a representative polyribosome profile). We then analyzed the presence of PTC-containing and non-PTC isoforms in the polyribosomal fractions. In control cells we observed an enrichment of the SRSF6 PTC-containing isoform in the polyribosome-associated mRNA fraction as compared to total cytoplasmic mRNAs (Figure 3C, compare lanes 1 and 2). Rapamycin-treatment dramatically reduced levels of the PTC-containing SRSF6 isoform in polyribosome-associated mRNA fractions (Figure 3C, compare lanes 2 and 4). To rule out alternative splicing as the underlying cause of PTC-containing isoform depletion from polyribosomes in rapamycin-treated cells, we stimulated cells with both rapamycin and emetine. We expected that if rapamycin effects were splicing dependent, then emetine treatment would not alter the levels of PTC-containing isoforms observed in polyribosomal-bound fractions between control and rapamycin treated cells. As expected, we observed that the effect of rapamycin was attenuated by emetine (compare lanes 6 and 8 in Figure 3C). Taken together these data suggest that rapamycin alters the stability of PTC-containing isoforms in polyribosome complexes rather than the AS of their pre-mRNA.
We further assayed the abundance of PTC-containing and non-PTC isoforms of SRSF6 and CCAR1 in total and polyribosome-bound mRNA fractions at 7h postrapamycin stimulation. Rapamycin significantly diminished the presence of the PTC-containing isoforms in polyribosomal fractions of both SFRS6 and CCAR1 (Supplemental Figure 2) genes whereas the effects were not detectable when comparing the total pool of mRNAs. Together these data suggest that rapamycin diminishes the abundance of PTC-containing transcripts through a translation-dependent mechanism.
Previous studies demonstrated that rapamycin treatment induces nuclear accumulation of eIF4E through de-phosphorylation and de-repression of 4EBP (Dostie et al. 2000; Rong et al. 2008). We confirmed these data in HEK 293 T cells: upon glutamine starvation we observed rapamycin-dependent modest nuclear accumulation of eIF4E whereas it is localized predominantly to the cytoplasm in control cells. In contrast, in rapamycin-treated cells we observed strong accumulation of eIF4E in the nucleus (Supplemental Figure 3). Given our previous results suggesting a role for rapamycin in the degradation of PTC-containing isoforms, and because rapamycin treatment causes nuclear sequestration of eIF4E, we hypothesized that exchange of cap binding proteins on mRNAs may also be abrogated. We thus purified cytoplasmic mRNPs from control or rapamycin-treated cells and assayed eIF4E and CBP80 association in an RNA-dependent manner. Figure 3D shows a representative western blot of eIF4E, CBP80, SF2/ASF, and U2AF65 in whole cell extracts (lanes 1 and 2) and RNase-treated or untreated eluates from oligo dT cellulose affinity chromatography. We observed that rapamycin-treatment increases the electrophoretic mobility of 4EBP, consistent with dephosphorylation. With the exception of U2AF65, which binds directly to oligo dT cellulose, SF2/ASF, CBP80 and eIF4E were all RNase-sensitive, suggesting that their binding to oligo dT cellulose is RNA-dependent. Unlike SF2/ASF protein, which bound to polyA-mRNAs equally in the presence or absence of rapamycin, CBP80 and eIF4E mRNPs levels were inversely correlated (Figure 3D lanes 5-6). Treatment with rapamycin resulted in a decrease of eIF4E association with polyadenylated mRNPs and a modest but reproducible increase in CBP80 association. Together, our data suggests that rapamycin-treatment impairs the normal exchange of CBP80 with eIF4E on cytoplasmic mRNPs, rendering them more susceptible to nonsense mediated decay and subsequent increased degradation of PTC-containing mRNAs.
Little is known about enhancement of NMD, which may have the potential of increasing genomic surveillance by increasing the degradation of potentially deleterious mRNAs. Up to 11 % of genetic inherited diseases are due to deleterious NMD (Mort et al. 2008) underlining the importance of NMD. The accumulation of potentially “toxic” mRNAs can lead to translation of truncated proteins that may be harmful for the cells, especially under stress conditions. As an example, the only hallmark of pancreatic adenosquamous carcinoma is a deficient NMD signature due to mutations in UPF1 (Liu et al. 2014). These data suggest that genomic surveillance is required for a “healthy” cellular environment and the possibility that cells have evolved a mechanism to integrate danger signals coming from mRNAs. It is also plausible to consider the idea that accumulation of “toxic” mRNAs may increase cellular stress (Gardner 2010).
Our data demonstrate a role for rapamycin in augmenting decay of PTC-containing mRNA isoforms. Rapamycin increases the nuclear accumulation of eIF4E (Supplemental Figure 3), which is consistent with arrest of translation initiation (Figure 3B). With eIF4E being predominantly localized to the nucleus upon rapamycin exposure, mRNAs may be pushed towards a pioneer-like mRNP complex in the cytoplasm. This hypothesis is reflected in Figure 3D which strongly suggests that rapamycin impairs the exchange of the CBC component CBP80 for eIF4E favoring an increased ratio of CBC/eIF4E binding. This can in turn lead to an increased opportunity for PTC-containing mRNAs to be flagged for degradation by NMD. It is possible that in addition to this “propioneer round” effect exerted by rapamycin, PTC-containing transcripts bound to eIF4E decrease in abundance due to -the nuclear accumulation of eIF4E and -the decrease of eIF4E binding to polyadenylated mRNAs upon rapamycin stimulation (model in Figure 4). Importantly, both Rufener and Durand studies pose a central role for translation in NMD (Durand and Lykke-Andersen 2013; Rufener and Muhlemann 2013), strongly supporting our observations that PTC-containing isoforms are less abundant in polyribosomes in rapamycin treated cells (Figures 3C and Supplemental Figure 2) and consistent with nonsense-mediated mRNA decay occurring during translation (Hu et al. 2009; Hu et al. 2010).
Rapamycin’s effects on NMD may also rely on post-translational modifications (such as phosphorylation) of NMD factors in addition to augmentation of CBC-binding to mRNPs (Figure 3D). Work by Pal et al. has shown that phosphorylation of UPF1 is sensitive to rapamycin (Pal et al. 2001); however the effect of lowered UPF1 phosphorylation on PTC-containing mRNAs was not tested. Moreover, although rapamycin concentration was similar to our working dose (25nM and 22nM, respectively), cells were only exposed for a short period of time (30min vs 72h in our case). We do not exclude the possibility that prolonged exposure to rapamycin may result in phosphorylation changes in some of NMD factors (or their regulators).
Augmentation of NMD by rapamycin could have broad implications for cell biology and physiology. Given that rapamycin increases lifespan in a wide variety of model systems, including mammals (Harrison et al. 2009; Bjedov et al. 2010), it is tempting to hypothesize that by increasing NMD efficiency, rapamycin may provide a ‘healthier’ transcriptome via degradation of potentially deleterious mRNAs that would otherwise result in cellular toxicity and premature senescence. NMD is effective not only during pioneer-but also during steady-state translation. Cells may then stand a better chance for surveillance and regulation of their transcriptome. For example, a previous study showed that UPF1 levels play a key role in deciding between undifferentiated cells (high UPF1 expression) vs neurogenic cells (UPF1 down-regulated) (Lou et al. 2014). These data may also implicate that NMD efficiency may allow neuronal regeneration, which is depleted in age-related diseases. We believe our study presents novel experimental evidence for the role of rapamycin in NMD that may have a broad impact in ageing and age-related diseases.
Materials and Methods
Cell culture and Rapamycin treatment
Human Embryonic Kidney (HEK) 293 T cells were cultured in DMEM 10%FBS (Santa Cruz Biotech) at 37°C 5% CO2. For rapamycin (Cell Signaling) experiments, cells were starved for 24h in Glutamine deficient media DMEM 10%FBS. Following this, they were incubated in 22nM rapamycin or vehicle (DMSO) for 30min prior to feeding with complete medium containing DMSO or rapamycin. For polyribosome experiments, cells were harvested 8h-post rapamycin stimulation. For dose-response assays cells were harvested 72h at the indicated concentrations diluted in vehicle (DMSO). Actinomycin D was added after 48h rapamycin exposure at a concentration of 5mg/mL and cells harvested at the indicated time points.
Immunofluorescence
HEK 293 T cells were seeded at low density on coverslips overnight. Cells were treated as described above, fixed with 3.2% paraformaldehyde for 15 min at room temperature and permeabilized with 0.1% Triton X-100 in PBS for 3 min. After blocking in 1% BSA+PBS 1h at room temperature they were incubated with eIF4E-FITC primary conjugated antibody (Santa Cruz Biotechnology) overnight at 4°C and washed. After washing 3 times with 0.02% tween PBS, coverslips were mounted using DAPI-mounting media.
Microscopy and quantification
Immunofluorescence was observed using a Leica DM2700 white field microscope at magnification 63X (oil immersion objective). Quantification of fluorescence was performed using ImageJ.
Cell fractionation and polyribosome extraction
Cells were incubated in the presence of 100μg/,mL cycloheximide 10min at 37C, 5%CO2 prior harvesting. Cell lysis was performed in 0.5% NP40, 20mM Tris HCl pH 7.5, 100mM KCl and 10mM MgCl2. Lysates were passed 3 times through a 23G needle and incubated on ice 7min. Extracts were then centrifuged at 10K rpm at 4C 7min. Cytosolic extracts were laid on 15-45% sucrose gradients prepared in 20mM Tris HCl pH 7.5, 100mM KCl and 10mM MgCl2 using a Gradient Station Master (Biocomp). Gradients were ultracentrifuged at 40K rpm 4C for 1h 20min using SW41 rotor in a Beckman Ultracentrifuge. Polyribosome monitoring and extraction of discrete complexes were conducted using the Gradient Station Master (Biocomp).
Western blotting
Cell extracts were prepared in Lysis Buffer as described above. For 4E-BP and P-4E-BP blots, cell extracts were resolved in 12% Bis/acrylamide gels. For CBP80/eIF4E blots, extracts were resolved in 10% Bis/acrylamide gels. Antibodies used were: 4E-BP1 53H11 (Cell Signaling), CBP80 E-7 (Santa Cruz Biotech), iEF4E FL-217 (Santa Cruz Biotech), p-4E-BP1/2/3 (Thr 45)-R (Santa Cruz Biotech) and U2AF65 MC3 (Santa Cruz Biotech).
Cap binding experiments
Cells were stimulated with rapamycin for 24h and extracts prepared in Lysis Buffer as described above. Cell extracts were prepared in Lysis Buffer as described before. Oligo dT cellulose (Ambion) was resuspended in Lysis Buffer twice before incubating it in the presence of cell extracts on a rotating wheel at 4C during 2h. Cellulose-bound extracts were washed 5 times. RNAse treatment was done using 1/100 RNAse A/T1 cocktail (Ambion) at 37C during 13min shaking. Extracts were washed once more and cellulose was pelleted and resuspended in lysis buffer, boiled and loaded onto bis/acrylamide gels for CBP80/eIF4E blotting.
Luciferase assays
HEK 293 T cells were starved for 24h in the absence of glutamine and then cotransfected with a normalizer firefly luciferase vector (pGL3, Promega) and pCl-Renilla/β-globin wt (WT) or NS39 (MUT) kindly gifted by Prof. A.E. Kulozik (Boelz et al. 2006). Transfected cells were then treated with vehicle (Control), 22nM of rapamycin (Rapa) or Emetine and chemiluminiscence was measured using the Dual-Luciferase Reporter (DLR) Assay (Promega) following manufacturer’s instructions.
RT-PCR and Real Time PCR (qPCR)
Total cytoplasmic RNA and polyribosome-bound RNA was extracted using TRIzol LS following manufacturer’s instructions. In the case of polyribosomal-bound RNA (Figure 3), RNA was extracted from discrete (disomes – nonosomes) polyribosomes fractions and then pooled prior to reverse transcription with random hexamers (Applied Biosystems) following manufacturer’s instructions. For actinomycin D experiments, poly-T primers were used in reverse transcription. PCR was performed using Taq Titanium (Clontech). In the case of Total to Polyribosme comparisons of CCAR1 (Supplemental Figure 2) the rate of inclusion was calculated using the following formula %Inclusion= Included/(Skipped+Included) in nmol as determined using an Agilent 2001 Bioanalyzer. Statistics were done using a Mann Whitney one tailed t-test.
For qPCR experiments, Sybr Green qPCR for -PTC and +PTC was done using primers described previously in Lareau et al. 2007. Our primers were designed using the Universal Probe Library System Software (Roche) and blasted in UCSC Genome Browser tool In silico PCR to NCBI36/hg18 assembly:
SRSF6_All_FOR: tgg aag cag atc cag gtc tc
SRSF6_All_REV: gcg act ttt tga gat act tcg ag
CCAR1_All_FOR: CAA AAA GAA GAA CAG AAG GAG TTA GAG
CCAR1_All_REV: TCG TCT TCA GAT TTC CTA TCA TCA
CCAR1_-PTC_FOR: AAC CCT CTC CCG AGG ATA CA
CCAR1_-PTC_REV: TCA TCC TTC TCT TCT TCA TCC TG
CCAR1_+PTC_FOR: TGG ACC AGA CCC AGA AAA AG
CCAR1_+PTC_REV: TTC TTC ATC CAT TGT GTG C.
Levels of each of each isoform (“-PTC” or “+PTC”) were normalized to total transcript levels (“All”) which accounts for the total gene expression of each gene and analyzed using the DDCt method. Total levels of transcript were normalized against SDHA. Statistics were done using a Mann Whitney 2 tailed t-test and calculated as fold rapamycin-treated over control.
Acknowledgements
The authors thank Javier Caceres, Luiz Penalva, Alan Zahler and Aishwarya Griselda Jacob for critical input to the manuscript. This work was supported by grants from the NIH and Ellison Medical Research Foundation to JRS (5R21AG042003 and AG-NS-0623-09, respectively). RTMN was supported by Post-doctoral Career track award from the Faculty of Medicine, University of Southampton.