Research interest
The research focus within our group is to develop and apply computational approaches to exploit a wide variety of data sources in order to improve our understanding of cancer. We work in close collaboration with a large number of groups with the institute. The computational problems we address are frequently inspired by the particular problems encountered in the collaborations.
Extracting oncogenes and oncogenic pathways from insertional mutagenesis screens
An effective method for identifying candidate oncogenic loci is retroviral insertion mutagenesis.
Within a large set of tumors induced by retroviral infection, a subset of viral insertions from independent tumors that map to the same genomic locus is referred to as a Common Insertion Site (CIS). CISs often represent lesions that have been selected for during tumorigenesis. To automatically detect CISs we have developed a computational approach, the kernel convolution framework. This approach finds CISs using a predefined significance level while controlling the family-wise error and takes bias stemming from preferential viral insertion sites into account. In contrast to existing approaches, our method operates at any biologically relevant scale, providing new insights in the behavior of CISs across multiple scales. To find oncogenic lesions which are collaborating events in tumorigenesis, we extended the kernel convolution framework to detect the occurrence of multiple independent insertions within one tumor at a higher frequency than expected by chance. A novel, biclustering algorithm which finds subsets of tumors with similar insertion profiles will also be employed to extract pathway structures from the insertion data.
Prioritizing candidate oncogenes based on genomic data
Gene expression data of tumor series have been extensively employed to predict outcome and response to therapy in breast cancer. To uncover the underlying mechanisms that drive these expression signatures, comparative genomic hybridization and microarray gene expression data from the same sample set is analyzed jointly. We developed SIRAC, a computational approach which detects genomic regions that are significantly enriched for BAC clones highly correlated with a particular outcome variable, such as a molecular subtype or outcome. We also developed KC-SMART, an adaptation of the kernel convolution framework to detect genomic regions that are significantly frequently aberrated in a set of tumors. In contrast to SIRAC, this approach is unsupervised, i.e. it does not require a labeling of the tumor set according to subtypes. Both approaches employ expression data to prioritize genes in a given aberrated region. Application of KC-SMART to a set of p53 deficient mouse tumors resulted in the detection of well-known oncogenes such as c-Met as well as promising new candidates.
Knowledge-based approaches for outcome prediction
Algorithms which exploit biological knowledge, such as the functional grouping of genes, could lead to more accurate predictors and enlarge the possibility of generating novel insights in the disease. Over-fitting can also be overcome by constructing larger datasets by collecting related gene expression data sets in a compendium. We employed an unsupervised approach to derive a set of modules (groups of functionally related genes with coordinated expression across a subset of tumors). By employing the module activity as input for training breast cancer outcome predictors, we revealed functional modules associated with breast cancer outcome. We studied modules extracted from several compendia, and performed extensive validation of these classifiers on datasets originating from different institutions. Modules derived from a single breast cancer dataset and a cancer specific compendium performs better compared to those derived from a human cancer compendium. A functional analysis of the modules revealed general processes involved in cancer, as well as very specific modules that are predictive across multiple datasets.
Mass spectrometry-based response prediction
Poly(ADP-ribose) polymerase (PARP)-inhibitors in combination with the DNA cross-linker, cisplatin, have recently been shown to have great potential as a treatment for patients carrying germline BRCA1 or BRCA2 mutations. The research questions we address include whether we are able to find markers for “BRCAness” and PARP-inhibitor treatment response. We are doing so by following an incremental procedure. First, we performed a comprehensive comparison of currently used, as well as novel mass spectrometry normalization approaches involving six mass spectrometry datasets, three classification approaches and 17 normalization techniques. Based on the results of this comparison, we constructed a computational workflow to process mass spectra. Next, using SELDI-TOF mass spectrometry, we study the proteomic contents of cell lysates and growth media of both BRCA(1,2)/p53-/- and p53-/- cell lines. When appropriate biomarkers have been identified, we will also analyze cell lysates from spontaneous tumors from BRCA1 and BRCA2 deficient mouse models. Simultaneously, we will study sera from these tumor bearing mice, to investigate the relationship between the markers obtained from tumor tissue and markers present in serum. If all these steps have been successfully completed, the approach can be tested on human tissue from BRCA1 and BRCA2 carriers. In addition to this, we hope to gain a better understanding of the pathways affected by PARP-inhibitors by integrating proteomic data with transcriptomic data, yielded by microarray expression profiling.
Key publications
De Ridder, J., Uren, A., Kool, J., Wessels, L.F.A., Reinders, M.J.T. (2007) Co-occurrence analysis of insertional mutagenesis data reveals cooperating oncogenes, Bioinformatics. Accepted for publication.
Van Berlo, R., L.F.A.Wessels, de Ridder, D., Reinders, M.J.T., (2007) Protein complex prediction using an integrative bioinformatics approach, Journal of Bioinformatics and Computational Biology. Accepted for publication.
Theodorou, V., Kimm, M., Boer, M., Wessels, L.F.A., Theelen, W., Jonkers, J. and Hilkens, J. (2007) Identification of novel genes, gene families and pathways involved in mammary cancer by MMTV insertional mutagenesis, Nature Genetics. Accepted for publication.
De Ridder, J., Uren, A., Kool, J., Reinders, M.J.T., Wessels, L.F.A., Detecting Statistically Significant Common Insertion Sites in Retroviral Insertional Mutagenesis Screens, PLoS Comput Biol. 2006 December; 2(12): e166.
Glas, A.M., Floore, A., Delahaye, L.J.M.J., Witteveen, A.T., Pover, R. C. F., Bakx, N., Lahti-Domenici, J. S.T., Bruinsma, T.J., Warmoes, M.O., Bernards, R., Wessels, L.F.A. and van 't Veer, L. J., Converting a breast cancer microarray signature into a high-throughput diagnostic test, BMC Genomics 2006, 7:278 (30 Oct 2006)
Fan, C., Oh, D.S., Wessels, L.F.A., Weigelt, B., Nuyten, D.S.A., Nobel, A.B., van‘t Veer, L.J. and Perou, C.M. (2006). Different gene expression-based predictors for breast cancer patients are concordant, N Engl J Med 2006;355:560-9.
Van Houwelingen, H.C., Bruinsma, T., Hart, A.A.M., Van ‘t Veer, L.J., Wessels, L.F.A. (2006). Cross-validated Cox-regression on microarray gene expression data. Stat Med, vol. 25, (18) 3201-3216.
Lai C, Reinders M.J.T., van't Veer L.J. and Wessels L.F.A. (2006). A comparison of univariate and multivariate gene selection techniques for classification of cancer datasets, BMC Bioinformatics, 7:235
Weigelt, B., Wessels, L.F.A., Bosma, A., Glas, A., Nuyten, D., He, Y., Dai,H., Peterse, J., Van ‘ t Veer, L.J. (2005) Lymph node metastases display gene expression profiles of their primary breast carcinomas. Br J Cancer 93, 924-932.
Wessels, L.F.A., Reinders, M.J.T., Hart, A.A.M., Veenman, C.J., Dai, H., He, Y.D., Van ‘t Veer, L.J. (2005). A protocol for building and evaluating predictors of disease state based on microarray data. Bioinformatics 21, 3755-3762.
More publications by Lodewyk Wessels on PubMed
Biographic sketch
Lodewyk Wessels received his M.Sc.(1990) and Ph.D.(1997) both from the Department of Electronic and Computer Engineering, Universtity of Pretoria, South Africa. From 1993 to 1997 he was a member of the Center for Spoken Language Understanding at the Oregon Graduate School of Science and Technology, initially as graduate student and later as post-doctoral fellow. In 1997 he joined the Faculty of electrical Engineering, Mathematics and Computer Science at the Delft University of Technology, initially as postdoc and later as assistant professor. In 1997 he became a faculty member and head of the Bioinformatics and Statistics group at the Netherlands Cancer Institute in Amsterdam, The Netherlands. He still holds a position as adjunct assistant professor in bioinformatics at the Delft University of Technology.
Group members
Nicola Armstrong PhD Academic staff
Michael Hauptmann PhD Academic staff
Miranda Mandjes PhD Post-doc
Carmen Lai MSc Graduate student
Wouter Meuleman MSc Graduate student
Jeroen de Ridder MSc Graduate student
Martin van Vliet MSc Graduate student
Jorma de Ronde MSc Research Programmer
Cor Lieftink BSc Research Programmer
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