Reverse-engineering the genetic circuitry of a cancer cell with predicted intervention in chronic lymphocytic leukemia

Cellular behavior is sustained by genetic programs that are progressively disrupted in pathological conditions—notably, cancer. High-throughput gene expression profiling has been used to infer statistical models describing these cellular programs, and development is now needed to guide orientated modulation of these systems. Here we develop a regression-based model to reverse-engineer a temporal genetic program, based on relevant patterns of gene expression after cell stimulation. This method integrates the temporal dimension of biological rewiring of genetic programs and enables the prediction of the effect of targeted gene disruption at the system level. We tested the performance accuracy of this model on synthetic data before reverse-engineering the response of primary cancer cells to a proliferative (protumorigenic) stimulation in a multistate leukemia biological model (i.e., chronic lymphocytic leukemia). To validate the ability of our method to predict the effects of gene modulation on the global program, we performed an intervention experiment on a targeted gene. Comparison of the predicted and observed gene expression changes demonstrates the possibility of predicting the effects of a perturbation in a gene regulatory network, a first step toward an orientated intervention in a cancer cell genetic program.

[1]  Claudio Cobelli,et al.  Function-Based Discovery of Significant Transcriptional Temporal Patterns in Insulin Stimulated Muscle Cells , 2012, PloS one.

[2]  Miguel A. Juárez,et al.  Inferring the time-invariant topology of a nonlinear sparse gene regulatory network using fully Bayesian spline autoregression. , 2011, Biostatistics.

[3]  J. Gribben,et al.  A unique proteomic profile on surface IgM ligation in unmutated chronic lymphocytic leukemia. , 2011, Blood.

[4]  J. Slotine,et al.  Controllability of complex networks , 2011, Nature.

[5]  A. Regev,et al.  Impulse Control: Temporal Dynamics in Gene Transcription , 2011, Cell.

[6]  Andrea Califano,et al.  Rewiring makes the difference , 2011, Molecular systems biology.

[7]  G. Marti,et al.  The lymph node microenvironment promotes B-cell receptor signaling, NF-kappaB activation, and tumor proliferation in chronic lymphocytic leukemia. , 2011, Blood.

[8]  Lei Liu,et al.  Using GeneReg to construct time delay gene regulatory networks , 2010, BMC Research Notes.

[9]  D. Floreano,et al.  Revealing strengths and weaknesses of methods for gene network inference , 2010, Proceedings of the National Academy of Sciences.

[10]  Qing Nie,et al.  Incorporating Existing Network Information into Gene Network Inference , 2009, PloS one.

[11]  Michael Hecker,et al.  Gene regulatory network inference: Data integration in dynamic models - A review , 2009, Biosyst..

[12]  D. Baltimore,et al.  The stability of mRNA influences the temporal order of the induction of genes encoding inflammatory molecules , 2009, Nature Immunology.

[13]  Brad T. Sherman,et al.  Bioinformatics enrichment tools: paths toward the comprehensive functional analysis of large gene lists , 2008, Nucleic acids research.

[14]  S. Chiaretti,et al.  BCR ligation induced by IgM stimulation results in gene expression and functional changes only in IgV H unmutated chronic lymphocytic leukemia (CLL) cells. , 2008, Blood.

[15]  U. Alon Network motifs: theory and experimental approaches , 2007, Nature Reviews Genetics.

[16]  J. Gribben,et al.  Temporal genetic program following B-cell receptor cross-linking: altered balance between proliferation and death in healthy and malignant B cells. , 2007, Blood.

[17]  D. di Bernardo,et al.  How to infer gene networks from expression profiles , 2007, Molecular systems biology.

[18]  Korbinian Strimmer,et al.  An empirical Bayes approach to inferring large-scale gene association networks , 2005, Bioinform..

[19]  Chris Wiggins,et al.  ARACNE: An Algorithm for the Reconstruction of Gene Regulatory Networks in a Mammalian Cellular Context , 2004, BMC Bioinformatics.

[20]  M. Gerstein,et al.  Genomic analysis of regulatory network dynamics reveals large topological changes , 2004, Nature.

[21]  Steven L. Allen,et al.  Multiple Distinct Sets of Stereotyped Antigen Receptors Indicate a Role for Antigen in Promoting Chronic Lymphocytic Leukemia , 2004, The Journal of experimental medicine.

[22]  Z. Oltvai,et al.  Network biology: understanding the cell's functional organization , 2004, Nature Reviews Genetics.

[23]  J. Collins,et al.  Inferring Genetic Networks and Identifying Compound Mode of Action via Expression Profiling , 2003, Science.

[24]  H. Kitano Systems Biology: A Brief Overview , 2002, Science.

[25]  C. Li,et al.  Model-based analysis of oligonucleotide arrays: expression index computation and outlier detection. , 2001, Proceedings of the National Academy of Sciences of the United States of America.

[26]  T J Hamblin,et al.  Unmutated Ig V(H) genes are associated with a more aggressive form of chronic lymphocytic leukemia. , 1999, Blood.

[27]  Gary D. Stormo,et al.  Modeling Regulatory Networks with Weight Matrices , 1998, Pacific Symposium on Biocomputing.

[28]  Michele Ceccarelli,et al.  articleTimeDelay-ARACNE : Reverse engineering of gene networks from time-course data by an information theoretic approach , 2010 .

[29]  James Long,et al.  Synthetic microarray data generation with RANGE and NEMO , 2008, Bioinform..

[30]  Darlene R Goldstein,et al.  A Laplace mixture model for identification of differential expression in microarray experiments. , 2006, Biostatistics.

[31]  G. Packham,et al.  Chronic lymphocytic leukemia : revelations from the B-cell receptor , 2004 .

[32]  Nicola J. Rinaldi,et al.  Supporting online material for : Transcriptional Regulatory Networks in Saccharomyces cerevisiae , 2002 .