Colorectal Cancer Clinical Trial
Official title:
Aberrant Splicings Due to Microsatellite Instability in Colorectal Cancer : Physiopathological and Clinical Impact (MICROSPLICOTHER)
MSI (Microsatellite Instability) colorectal cancer (CRC) show improved survival, are less
prone to metastasis and show poor response to chemotherapy (compared to MSS tumors). The
underlying reasons for these characteristics are still not understood and no specific
therapeutic approach for MSI colon tumours (15% of CRC overall) has yet been developed.
The MSI process is oncogenic when it affects DNA repeat sequences that have a functional
role, e.g. Small Coding Repeats (SCR). MSI also frequently affects Long Non-Coding Repeats
(LNCR) in tumour DNA. In contrast to SCR, only a few LNCR are endowed with biological
activity. Consequently, this area has received very little attention. Our group recently
identified HSP110 mutant chaperone protein in MSI CRC that was generated by somatic deletion
of a LNCR. Of interest, HSP110 mutant (due to exon skipping) have anti-oncogenic properties
and the survival of MSI CRC patients receiving chemotherapy is positively associated with
HSP110 mutations in tumour DNA.
The aim of the current project is to identify additional clinically relevant MSI-associated
splicing aberrations due to mutations in LNCR located in splice acceptor sites. The four main
steps are as follows:
1. To identify exon/intron sites affected by aberrant splicing events due to MSI in CRC .
All RNASeq data will be exploited to identify recurrent splicing aberrations (mostly
exon skipping) that occur specifically in MSI colon tumours;
2. To investigate for possible functional links between MSI and any detected aberrant
splicing events . All specific aberrant splicing events detected by RNAseq in MSI CRC
samples will be first confirmed (quantitative RT-PCR) in order to eliminate false
positive cases. For validated exon candidates, the allelic profiles of adjacent intronic
LNCR will be analysed (PCR and fluorescence genotyping) in CRC cell lines and primary
tumours (MSI and MSS), as well as in matching normal mucosa samples in order to assess
their polymorphic status;
3. To identify splicing events and LNCR mutations with clinical relevance in MSI CRC
patients . All LNCR with a confirmed role in gene splicing in MSI CRC will be analysed.
The clinical relevance of candidate genes will be assessed using multivariate survival
regression models for Relapse- Free Survival, with interaction terms (response to
chemotherapy);
4. To initiate functional studies on a limited number of clinically relevant,
cancer-related genes whose splicing is perturbed in MSI cancer cells, and to develop
biological tools to simplify screening in future clinical assays Similar to HSP110, we
will focus on 4 or 5 mutant proteins that are promising drug therapeutic targets.
Functional assays will be developed to further elucidate their role in the
pathophysiology of MSI tumours. We also aim to develop biological tools for these
candidate genes, such as the detection of wild-type or mutant proteins by
immunohistochemistry.
WP1 - To identify exon/intron junctions that are specifically affected by aberrant splicing
events in MSI CRC. Sequences will first be evaluated at CNG using Illumina's Pipeline CASAVA
(Consensus Assessment of Sequence And Variation) software. This program converts intensity
scores into base calls, quality scored alignments and additional formats for downstream
analysis, thus rapidly transforming data into biologically relevant information. The filtered
data will then be transferred to the CIT platform (Carte d'Identité des Tumeurs;
http://cit.ligue-cancer.net, dir: A. de Reynies) to be analysed by our bio-informatics
expert. The Cufflinks workflow will be used to quantify transcript expression levels in MSI
tumours. This allows transcript assembly, discovery and differential expression measures at
transcript-level resolution. Because the standard Cufflinks workflow does not support gene
fusion discovery or quantification, several new features will be incorporated into it.
Firstly, SoapFuse will be used to detect fusion break points and to predict fusion junction
sequences. These will be integrated into the human reference genome and gene annotation from
the Gencode project to provide a comprehensive, integrated annotation of gene features for
mapping of splicing reads. The integration INCa - PRTK 2014 17/51 process will abide by
several rules to minimise the potential to disturb the quantification of expression level in
forthcoming analyses. With the help of our customised reference genome and annotation,
TopHat, an aligner that supports splice junction and gene fusion mapping will be used for
RNASeq mapping. Cufflinks will then be used to find new splice variants, including new exon
skipping isoforms.
These will be integrated into the annotation using Cuffmerge. Depending on the alignment
results obtained with TopHat, several filters will be applied to remove low quality
candidates for splice variation and gene fusion, as well as candidates that are incompatible
with existing annotated transcripts. Where necessary, reads will be assembled by AbySS and
then aligned onto the reference genome by BLAT to provide more information for refining the
annotation. This will produce a transcriptome assembly containing high confidence gene fusion
and exon skipping events. Identification of these events will then be performed in individual
samples. Cuffdiff will be used to analyse the mapping result, also based on this
transcriptome assembly, for calling differentially expressed genes and transcripts and for
detecting differential splicing changes. Finally, CummeRbund will be used to interpret and
visualise the results.
The reliability of RNA-seq analysis will be verified by searching for aberrantly spliced
transcripts already reported in MSI cancers (eg. MRE11 and HSP110) and for point mutations in
the coding sequences of target genes for MSI (eg.TGFBR2, IGF2R, TCF7L2, AXIN2, PTEN, RIZ) and
in other cancer-related genes that serve as internal positive controls (eg. KRAS, BRAF, TP53,
PIK3CA). It is worth noting this project is part of several others developed jointly with
CIT-Ligue and that are aimed at characterizing MSI CRC using Omics technologies. Importantly,
this data is already available for a significant number of samples and could therefore be
exploited if required.
Data from the RNASeq cohort of patients will be comprehensively analysed to identify
recurrent splicing aberrations (expected to be mostly exon skipping) that occur specifically
in MSI colon tumours compared to MSS CRCs and matching normal colonic mucosa. Amongst these,
the study will focus on splicing aberrations that are due to MSI and that affect exons with a
flanking upstream intron containing a ≥ 15 bp LNCR that is located ≤ 6 bp from the
intron-exon junction (splice acceptor site) (RNASeqMSI-exon pre-list). As stated above, about
2,000 human genes contain at least one intron with a LNCR very close to the AG splice
acceptor site at the intron-exon junction. Approximately 100 human genes could be affected by
recurrent and specific aberrant splicing events due to MSI in CRC (mostly exon skipping;
deduced from experiments performed in a limited series of CRC cell lines and primary tumours
using exon arrays; preliminary and unpublished results).
WP2 - To investigate for functional links between MSI and aberrant splicing events.
Following the RNASeq analysis, confirmation of the aberrant splicing events due to MSI will
be required using another methodological approach in order to eliminate false positive
events. This will be achieved with real-time quantitative INCa - PRTK 2014 18/51 RT-PCR using
internal, specific probes (Applied biosystems). For each skipped exon in the RNASeqMSI-exon
pre-list, a common pair of forward and reverse primers located in the flanking exons will be
designed.
Two internal probes will be designed, located either within the skipped exons or spanning the
flanking exons at their junction in order to detect normal or aberrantly spliced mRNA in a
competitive manner, respectively. It is highly sensitive and also avoids false positive
signals due to contamination with genomic DNA. Candidate exons that will be retained are
those that display aberrant and recurrent skipping in MSI CRC cell lines and primary tumors
as compared to MSS CRC controls.
In line with our working hypothesis, the study will then determine whether each confirmed
splicing aberration is MSI-driven. This will be achieved as described earlier for T17
deletions in intron 8 of HSP110 that were identified specifically in MSI CRC and lead to exon
9 skipping. Briefly, allelic profiles of adjacent intronic LNCR (see above) will be analyzed
using fluorescence-based genotyping in the panel of MSI and MSS CRC cell lines, as well as in
the complete series of MSI primary tumors from the RNASeq patient cohort and paired normal
mucosa (in order to assess polymorphic status). This will be performed using the same method
developed earlier in our laboratory for analysis of the HSP110 T17 DNA repeat. Following
migration of PCR products on an ABI 3100 Genetic Analyzer with GS400HD ROX size standards and
POP-7 polymer (Applied Biosystems), GeneMapper V4.0 software (Applied Biosystems) will be
used to analyze LNCR traces, with application of an AFLP (Amplified Fragment Length
Polymorphism) method. Traces will be considered acceptable when the peak amplitudes are
between 100 and 6,000 fluorescence units. An MSI Perl script has been developed to
automatically compare LNCR traces in normal and tumour samples, thus allowing detection of
aberrant LNCR peaks that fall outside of the polymorphic zone observed in the normal
population. As with HSP110, it is expected (i) to detect somatic deletions/insertions in some
of the candidate LNCRs using this approach, and (ii) to identify those whose somatic
alterations due to MSI are significantly associated with exon skipping-related events at the
RNA level (MSI exon final list).
WP3 - To identify splicing events and/or LNCR mutations with clinical relevance in MSI CRC
patients. The clinical relevance of candidate genes (MSI exon final list) will be assessed
using multivariate survival regression models for RFS (Relapse-Free Survival). The number of
candidate splicing events and/or LNCR mutations is approximately 100 (see WP1 and WP2 above)
and INCa - PRTK 2014 19/51 other known clinical determinants such as stage, treatment and age
at diagnosis will be considered in the multivariate models. False positives are one of the
major pitfalls in identifying potentially relevant markers amongst dozens of candidates. As
the number (p) of covariates to be considered will be of the same order as the number of
individuals, the "high-dimensional setting" will be reached. Consequently, the usual
algorithms for survival regression models (e.g. coxph in R) will fail to estimate the
parameters and to identify events with clinical relevance. In our analysis, three main
methodological issues require special attention, particularly at the algorithmic level.
WP3 will be divided into two main steps, the first of which concerns comparisons and the
development of statistical algorithms. Once tuned, the algorithms will be run to identify a
prognostic biomarker(s) that involves splicing events and/or LNCR mutations with clinical
relevance.
High-dimensional regression models and lasso algorithms. In the first step only splicing
mutations and clinical determinants in the survival regression models will be considered. In
this case, variable selection and parameter estimation will be conducted with a lasso (or
elastic net) algorithm (see Simon et al. for the Cox model, and Gaiffas et al. for Aalen
model, both implemented in R).
In previous publications it was demonstrated that cut-point values resulted in maximal
survival differences between patient groups with large or small deletions in the HSP110 T17
LNCR, and with high or low expression of mutant HSP110 mRNA due to exon 9 skipping at the
INCa - PRTK 2014 20/51 mRNA level. Since other splicing events could present with the same
threshold effect, the cut-points for up to 100 candidate splicing events will be carefully
determined. Even in classical statistics, cut-point determination is a known difficulty
because of overdetection. As recently proposed in a related context, the "lasso with
pre-screening algorithm" could be adapted to incorporate the cut-point determination into the
main algorithm.
Other points. Missing data will be handled by multiple imputations from nearest-neighbour or
regression methods. The study will consider possible interactions with the use of
chemotherapy. As a final step, estimations will be run on the training cohort (Saint-Antoine)
to derive a prognostic biomarker that will include splicing events and/or LNCR mutations with
clinical relevance. This biomarker will be validated on the test cohort (multi-centre).
Bootstrap analysis will be conducted to ascertain the biomarker.
WP4 - To initiate functional studies on a limited number of clinically relevant, cancer
related genes whose splicing is highly perturbed in MSI cancer cells, and to develop
biological tools to simplify screening in future clinical assays. As stated earlier, A
preliminary study has been performed using exon arrays in a small series of MSI CRC cell
lines and primary tumours (unpublished). This was conducted to evaluate feasibility, time,
cost, adverse factors, effect size (statistical variability) and to improve upon the study
design prior to performing the present full scale research project. The functions of the 100
detected candidate genes (some of which may overlap with those identified from RNAseq
screening) were frequently related to a cancer-related processes such as macromolecular
synthesis (30%), cell proliferative capacity or cell death (20%), drug resistance (10%) and
others (WNT pathway, metastatic process, changes in chromosome structure). The present
project expect to identify several robust MSI-driven splice mutants that are clinically
relevant (see WP2 and WP3 above). These mutants could have either oncogenic or antioncogenic
functions, given that some (such as HSP110) may be produced at high levels even though they
have negative impacts on the tumour cell (see our functional hypothesis above concerning the
expected detrimental influence of MSI at LNCR in CRC). In this context, in vitro functional
studies will be designed to characterize the oncogenic impact of a small number (n=5) of
putative clinically relevant mutants. These experiments will be based on transient silencing
or overexpression using siRNA or plasmids and ad hoc biological read-out in CRC cellular
models already available in our laboratory.
Depending on the results obtained, further investigations could then be planned using stably
transfected CRC models xenografted into nude mice. In addition, the study plan to validate
biological tools (e.g. Antibodies) to optimize the future screening of patients using routine
assays, similar to our work with HSP110 and the HSP110DE9 mutant. Tissue Microarrays (TMAs)
will be constructed from routinely prepared, formalin-fixed and paraffin-embedded blocks
collected INCa - PRTK 2014 21/51 retrospectively from the Pathology Department of
Saint-Antoine hospital. Neoplastic tissue will be sampled, including the tumour invasive
front (3 to 6 samples of 0.6 mm diameter tissue cores). When available, paired lymph node
metastasis will also be sampled. Immunohistochemistry with antibodies generated specifically
(subcontracting) to recognize wild-type or mutant candidate proteins will be performed on
TMAs. Exon skipping events are frameshift in 2/3 of cases and thus generate truncated
proteins that have immunogenic, aberrant C-terminal tails. Correlations between protein
expression and clinico-pathological features will be evaluated, as well as their prognostic
and predictive values. TMA slide images will be captured as high-resolution digital files and
evaluation of each staining will be done by two pathologists.
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