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SUPPLEMENTARY MATERIALThe T-cell leukemia associated ribosomal RPL10 R98S mutation enhances JAK-STAT signaling
Tiziana Girardi1*, Stijn Vereecke1*, Sergey O. Sulima1*, Yousuf Khan2, Laura Fancello1, Joseph W. Briggs2 , Claire Schwab3, Joyce Op de Beeck1, Jelle Verbeeck1, Jonathan Royaert1, Ellen Geerdens4,5, Carmen Vicente4,5, Simon Bornschein4,5, Christine J. Harrison3, Jules P. Meijerink6, Jan Cools4,5, Jonathan D. Dinman2, Kim R. Kampen1, Kim De Keersmaecker1
1 KU Leuven - University of Leuven, Department of Oncology, LKI - Leuven Cancer Institute, Leuven, Belgium2 Department of Cell Biology and Molecular Genetics, University of Maryland, College Park MD, USA3 Leukaemia Research Cytogenetics Group, Northern Institute for Cancer Research,Newcastle University, Newcastle-upon-Tyne, United Kingdom 4 VIB Center for Cancer Biology, Leuven, Belgium5 KU Leuven - University of Leuven, Center for Human Genetics, LKI - Leuven Cancer Institute, Leuven, Belgium6 Princess Máxima Center for pediatric oncology, Utrecht, the Netherlands
* These authors contributed equally to this work
Supplementary Methods
Quantitative proteomicsCells derived from 3 monoclonal Ba/F3 cultures expressing either WT or R98S RPL10 were lysed in
lysis buffer (Cell Signaling Technology) with addition of 5 mM Na3VO4 and protease inhibitors
(Complete, Roche). Twenty µg of protein as determined by the Bradford method was run through a
12% SDS-PAGE (Bio-Rad) and Coomassie stained using Simply Blue Safe Stain (Invitrogen). Entire
SDS–PAGE gel lanes were sliced into pieces and proteins were reduced-alkylated before overnight
digestion using Trypsin/LysC Mix (Promega). The resulting peptides were extracted and vacuum dried.
Peptides were desalted on C18 StageTips and each sample was fractionated using SCX StageTips.
All fractions were again vacuum dried prior to mass spectrometric analysis. For LC MS/MS analysis,
peptides were resuspended and separated by reversed-phase chromatography on a Dionex Ultimate
3000 RSLC nanoUPLC system in-line connected with an Orbitrap Q Exactive Mass-Spectrometer
(Thermo Fischer Scientific). Database searching was performed using Mascot 2.3 (Matrix Science),
MS-Amanda and SEQUEST in Proteome Discoverer v.1.4 against a homemade database consisting
of the human RL10 R98S protein (Uniprot Accession: P27635) and in the mouse reference proteome
(UniProt release 2015_04; 45182 sequences). All searches were performed with trypsin cleavage
specificity, up to 2 missed cleavages were allowed, and ion mass tolerance of 10 ppm for the
precursor and 0.05 Da for the fragments. Carbamidomethylation was set as a fixed modification,
whereas oxidation (M), acetylation (Protein N-term), phosphorylation (STY) were considered as
variable modifications. Data are available via ProteomeXchange with identifier PXD005995. Further
processing of mass spectrometry data was performed in Scaffold 4 software (Proteome Software),
using the quantitative value (normalized total spectra) setting. Unsupervised average-linkage
hierarchical clustering was performed in IBM SPSS 23.0 with Euclidean distance as similarity metric.
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The entire list of identified proteins was ranked according to log2 fold changes and used as input for
GSEA against the MSigDB C2 KEGG gene sets.1,2 Only GSEA results with a FDR q-value <0.25 were
considered.
Rpl10 R98S conditional knock-in mouse model Generation of a conditional Rpl10 R98S knock-in mouse line (Rpl10cKI R98S) was performed by the
company Polygene AG (Rümlang, Switzerland). In this model, the wild type genomic region of Rpl10
encompassing exons 5 up to 7 was flanked with loxP sites. Downstream of this cassette, a mutant
version of exon 5 encoding the R98S mutation was placed (Figure S2, targeted allele (Rpl10 cKI R98S)). In
this configuration, prior to Cre recombinase mediated recombination, the wild type gene containing its
wild type introns including Snora70 is expressed. After Cre recombination, the genomic configuration
is identical to wild type with the exception of a remaining loxP site, and the introduced R98S point
mutation (Figure S2, bottom).
To generate the targeting vector, the homology arms from a C57Bl/6-derived BAC were subcloned,
and a synthetic 1293 bp loxP-flanked cassette containing the Rpl10 genomic sequence encompassing
exons 5-7 spiked with 3 silent changes was used. Upstream of the upstream loxP site, an FRT-flanked
neomycin selection cassette was added for selection in cell culture. The homologous arms had sizes
of 2.5 and 3.2 kbp. Targeting of C57Bl/6N-derived ES cells (PolyGene AG) yielded 8 out of 388 clones
with correct configuration verified by PCR and Southern hybridization. Blastocyst microinjection of
these clones into C57Bl/6grey-derived embryos (PolyGene AG) resulted in chimeric mice that
transmitted to germ line after mating with C57Bl/6grey Flp deleter mice. Neo-less correct heterozygous
F1 genotypes were verified by PCR.
Animal experiments were approved by the local ethics committee (P161/2012). Rpl10 R98S
conditional knock-in mice were crossed to Mx1-Cre C57Bl/6 mice (B6.Cg-Tg(Mx1-cre)1Cgn/J strain
Jackson Laboratories). For the described experiments, lineage negative cells were isolated (EasySep
Mouse Hematopoietic Progenitor Cell enrichment kit, Stemcell Technologies) from 6-8 weeks old male
mice carrying the conditional Rpl10 R98S allele together with an Mx1-Cre allele (Mx1-Cre Rpl10cKI R98S)
and from conditional Rpl10 R98S controls (Rpl10cKI R98S). Cells were plated at 2000 cells/ml in
Methocult GF M3534 medium (Stemcell Technologies) containing 1250 units/ml of IFNβ (R&D
systems) to induce recombination of the conditional Rpl10 R98S allele. After 10-15 days, cells were
collected and lysed in lysis buffer (Cell Signaling Technology) with addition of 5 mM Na3VO4 and
protease inhibitors (Complete, Roche) and analyzed via immunoblotting. Expression of the R98S
mutation upon Cre recombination was confirmed by Sanger sequencing of cDNA of the region
encoding Rpl10 R98.
Programmed -1 ribosomal frameshifting (-1 PRF) assays Dual luciferase assays (Promega), and statistical calculations were performed as previously
described.3-5 Briefly, Hek293T or Ba/F3 cells were transfected with plasmids harboring the in frame
control, the out of frame control, or a -1 PRF signal between the upstream renilla and downstream
firefly luciferase open reading frames (Figure S3). The -1 PRF signals that were tested are reported in
Table S9.
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For Hek293T assays, cells were seeded into 24-well plates (8×104 cells per well) and grown for 24
hours prior to transfection. Cells were transfected with dual luciferase plasmids using 2 µl of FuGene
HD (Promega) in 25 µl total of DMEM. 600 ng of plasmid was used per well and incubated for 15
minutes at room temperature. 48 hours post-transfection, dual luciferase assays were performed using
the standard dual luciferase protocol (Promega) with slight modifications using a Promega GloMax
Multidetection System plate reader. Changes to the standard protocol are as follows: lysates were
resuspended in 100 μl 1× lysis buffer before reading using 30 μl lysate per well, and 50 μl of each
reagent per well were used with a 50-s integration and 2-s pause between reads.
For Ba/F3 cell assays, three million cells were electroporated with 15 µg of each plasmid in 400 µl
serum-free medium in 4 mm cuvettes using an exponential decay protocol (300V, 950 µF), and
immediately transferred to 4 mL of pre-warmed recovery medium (10% FBS, IL3, sodium pyruvate and
MEM non-essential amino acids). Twenty-four hours later, cells were lysed in 100 µl lysis buffer, and
luciferase readings were collected in 96 well half-area white plates (10 µl of lysate per read) on an
EnSpire plate reader with two injectors (PerkinElmer). The percentage of frameshifting was
determined by dividing the firely/renilla signal ratio in cells containing a -1 PRF construct or the out of
frame control by the firefly/renilla signal ratio in the corresponding cells containing the in frame control
construct.
Polysomal and total mRNA sequencingUp to three polysomal and total RNA sequencing libraries were generated for each of the 3
monoclonal Ba/F3 cultures expressing either WT or R98S RPL10. An amount of 15x106 cells were
pelleted by centrifugation (5 min, 1500 rpm) and were lysed in ice-cold 100mM KCl, 20 mM Hepes
(Life technologies), 10 mM MgCl2, 1 mM DTT, 1% sodium deoxycholate, 1% NP-40 (Tergitol solution,
Sigma-Aldrich), 100 µg ml-1 cycloheximide, 1% Phosphatase Inhibitor Cocktail 2 (Sigma-Aldrich), 1%
Phosphatase Inhibitor Cocktail 3 (Sigma-Aldrich), 1% Protease Inhibitor Cocktail (Sigma-Aldrich), 100
U ml-1 RNasin (Promega). After 10 minutes incubation on ice, lysates were centrifuged 5 minutes at
13,000 rpm and the resulting supernatant was loaded onto 10-60% sucrose density gradients (100
mM KCl, 20 mM Hepes, 10 mM MgCl2). Gradients were then centrifuged in a SW40Ti rotor (Beckman
Coulter) at 37,000 rpm for 150 minutes and polysomal fractions were monitored through a live OD254
nm measurement on a BioLogic LP System (Bio-Rad). Polysomal fractions were collected on a
fraction collector 2110 (Bio-Rad), followed by addition of proteinase K (50 µg/ml) and incubation for 30
min at 37°C. NaOAc 3M, pH5.5 (1/10 volume) was added followed by RNA extraction using the
phenol/chloroform method with inclusion of an extra washing step with 70% ethanol. Next generation
sequencing libraries were generated from total RNA and polysomal RNA using the TruSeq Stranded
mRNA Sample Prep Kit (Illumina) and were sequenced on a NextSeq instrument (Illumina) using a 50-
bp single read protocol. Ribosomal RNA and tRNA contamination were computationally removed and
the remaining reads were aligned by Tophat v2.0.11 to the to the mm10 mouse reference genome
(GRCm38) using the transcriptome defined by Mus_musculus.GRCm38.76.6 Only reads mapping
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uniquely and with high quality (mapqual>10) were retained for further analyses. Gene expression was
estimated from exon-mapped reads, which were counted using HTSeq-count in union mode.7
The DESeq2 R package8 was applied on total RNA to identify significant differences in transcription
between R98S and WT conditions (FDR<0.1).
Translational efficiency (TE) was estimated, for each gene and within each condition, as the ratio
between polysome-associated mRNA counts and total mRNA counts. Differences in TE between
R98S and WT conditions were calculated as a TE(R98S)-to-TE(WT) ratio. The Babel R package9 was
used to estimate the statistical significance of detected TE differences between the R98S and WT
condition. This method builds a regression model of polysome mRNA counts and total mRNA counts
to identify genes whose polysome mRNA levels are not sufficiently explained by their total mRNA
levels.
ImmunoblottingCells were lysed in lysis buffer (Cell Signaling Technology) with addition of 5mM Na3VO4 and protease
inhibitors (Roche). Proteins were separated on 4–15% Criterion TGX Precast protein gels (Bio-Rad)
and transferred to PVDF membranes using a Trans-Blot Turbo system (Bio-Rad). Antibodies used for
immunodetections are listed in supplementary Table S2. Blots were imaged on an Azure C600 (Azure
Biosystems) and blot intensities were quantified using Image Studio Lite software (LI-COR). Obtained
values were normalized to a housekeeper gene (alfa-tubulin or beta-actin).
Quantitative PCR (qPCR)RNA was extracted with RNeasy mini kit (Qiagen) and 500-1000ng was reverse transcribed with
GoScript Reverse Transcription System (Promega). qPCR reactions were performed using GoTaq
qPCR Master Mix (Promega) on a LightCycler-384 (Roche). Used RT-qPCR primers are listed in
supplementary Table S3. Data analysis was performed using qBase+ 2.6 software (Biogazelle).
Flow cytometry Human PTPRC (= hCD45) membrane expression levels were analyzed in peripheral blood samples
from NSG mice grafted with human T-ALL samples. Red cell lysis was performed on collected
peripheral blood samples, followed by staining with human CD45 antibody (ebioscience) for 30 min
and washing.
The cells were analyzed using a MACSQuant VYB (Miltenyi) and data analysis was performed using
FlowJo software.
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genes involved in oxidative phosphorylation are coordinately downregulated in human diabetes.
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in the yeast Saccharomyces cerevisiae. RNA 2003; 9: 1019–1024.
4 Grentzmann G, Ingram JA, Kelly PJ, Gesteland RF, Atkins JF. A dual-luciferase reporter system for
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Bioinformatics 2009; 25: 1105–1111.
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Supplementary Figures
Figure S1. RNA Sanger sequences showing Rpl10 WT and R98S expression in Ba/F3 cells. Representative Sanger chromatogram of cDNA obtained from RPL10 WT (A) or R98S (B) expressing
Ba/F3 cells.
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Figure S2. Schematic representation of the conditional Rpl10cKI R98S mouse model
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Figure S3. Validation of -1 PRF signals by dual luciferase assays. A) Schematic representation of the dual luciferase constructs. All data are normalized for the in frame
control, encoding a renilla-firefly luciferase fusion protein. In the out of frame reporter (OOF) negative
control, firefly luciferase lies in the -1 reading frame with respect to the renilla luciferase open reading
frame, indicating the levels of background firefly signal. In the -1 PRF constructs, a computationally
predicted -1 PRF signal is cloned in between the renilla and firefly luciferase sequences. The firefly
open reading frame lies in the -1 frame with respect to renilla, and the production of the firefly
luciferase protein is dependent on a -1 PRF event. -1 PRF percentages are calculated by dividing the
ratio of firefly to renilla luciferase reads by the firefly/renilla ratio of the in frame control. B) Results from
dual luciferase reporter assays in Hek293T cells testing -1 PRF levels on the indicated mouse and
human PRF signals. Error bars denote standard errors. **p<0.01 compared to the out of frame (OOF)
control (T-test).
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Figure S4. . Mass spectrometry screen for proteins shows altered levels of Jak-Stat signaling components in RPL10 R98S expressing cells.A) Unsupervised hierarchical clustering analysis of the differential proteome results of the three
analyzed RPL10 Wild type (WT#29, WT#36 and WT#28) and RPL10 R98S mutant (R98S#13,
R98S#35 and R98S#11) cell clones. B) GSEA plot illustrating enrichment of JAK-STAT pathway
proteins in the proteins upregulated in RPL10 R98S cells. FDR: false discovery rate. C) Volcano plot
of the Jak-Stat signaling mediators identified by mass spectrometry. The dashed line illustrates the
cut-off for significance (p<0.05; T-test). Red dots represent proteins that are significantly upregulated
in the R98S samples, green dots correspond to proteins that are significantly downregulated in the
R98S cells.
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Figure S5. RPL10 R98S cells express altered mRNA levels of Jak-Stat signaling components.Quantification of JAK-STAT mRNA levels in RPL10 WT versus R98S expressing Ba/F3 cells. Results
were obtained by mRNA sequencing on 3 RPL10 WT versus R98S Ba/F3 clones. The represented
RNA levels are DESeq2-normalized counts relative to the WT. Significant changes (FDR<0.1) in RNA
levels between R98S and WT were estimated using the DESeq R package. *p<0.05, ***p<0.001.
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Figure S6. Phospho-Tyrosine detection upon cytokine stimulation. Immunoblot analysis of tyrosine-phosphorylated proteins in RPL10 R98S versus WT expressing cells
at different time points after addition of 1 ng/ml of IL3. The figure shows a representative blot of 3
independent experiments.
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Figure S7. IFNγ stimulation causes elevated JAK-STAT activation in RPL10 R98S mutant cells. A) Immunoblot analysis of phosphorylation of JAK kinases and STAT3 in R98S versus WT Ba/F3 cells
at the indicated time points after addition of 5 ng/ml IFN. The figure shows a representative blot of 3
independent experiments. B) Quantification of the immunoblots of panel (A). Phospho-levels were
quantified by dividing the phospho-signal by the signal of the loading control. The quantification
represents the average +/- standard deviation of a representative experiment. P-values were
calculated using a T-test. *p<0.05, **p<0.01.
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Figure S8. RPL10 R98S cells are not sensitized to Tofacitinib and CI-1040. Relative proliferation of RPL10 WT and R98S Ba/F3 cells treated with the JAK3 inhibitor tofacitinib and
the MEK inhibitor CI-1040. Proliferation was assessed using the ATPlite luminescence assay
(PerkinElmer). The panel shows the average +/- standard deviation of a representative experiment
comparing 4 biologically independent RPL10 WT versus 4 independent R98S cell clones. P-values
were calculated using a T-test *p<0.05.
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Figure S9. PTPRC expression levels are reduced in RPL10 R98S positive versus RPL10 WT T-ALL xenograft samples. Flow cytometry analysis of human PTPRC (= hCD45) membrane
expression levels in peripheral blood samples from NSG mice grafted with RPL10 WT (X9, X10 and
X12) or RPL10 R98S (X13, X14, X15 and XB41) human T-ALL samples. The graph shows the
average median fluorescent intensity of the human PTPRC signal within the population of human
PTPRC positive cells detected in these blood samples. Standard deviations result from multiple mice
that were analyzed. P-values were calculated using a T-test ***p<0.001
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Figure S10. Pimozide treatment of primary T-ALL xenograft samples does not induce apoptosis.Primary xenograft samples were cultured in the presence of DMSO or 5 µM pimozide for 72 hours.
The graph shows the percentage of induction of annexin V positive cells in the pimozide treated
samples as compared to the DMSO treated samples.
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Figure S11. RPL10 R98S mouse hematopoietic cells show upregulation of immunoproteasome subunits. A) Left: immunoblot analysis of protein expression levels of the specific subunits Psmb9
and Psmb10 of the immunoproteasome in three independent Ba/F3 cell clones expressing RPL10
R98S versus WT cells. Right: quantification of the immunoblots. B) Left: representative immunoblots
showing protein expression levels of Psmb10 and Psmb9 in hematopoietic cells derived from Rpl10cKI
R98S (labeled as WT in the figure) and MX-Cre Rpl10cKI R98S (labeled as R98S in the figure) mice. Right:
quantification of the immunoblots. ***p<0.001.
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Figure S12. RPL10 R98S mutant cells do not show altered poly-ubiquitination. A) Immunoblot analysis of poly-ubiquitinated proteins in RPL10 R98S versus WT expressing Ba/F3
cells. The figure shows a representative blot of 3 independent experiments. B) Quantification of the
immunoblots of panel (A). The plot shows the average +/- st dev.
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Figure S13. Stability of Stat proteins remained unchanged within 150 minutes of CHX-chase. Immunoblots illustrating protein stability as assessed by cycloheximide (CHX) chase assays.