Systems biology surveillance decrypts pathological transcriptome remodeling

BackgroundPathological cardiac development is precipitated by dysregulation of calreticulin, an endoplasmic reticulum (ER)-resident calcium binding chaperone and critical contributor to cardiogenesis and embryonic viability. However, pleiotropic phenotype derangements induced by calreticulin deficiency challenge the identification of specific downstream transcriptome elements that direct proper cardiac formation. Here, differential transcriptome navigation was used to diagnose high priority calreticulin domain-specific gene expression changes and decrypt complex cardiac-specific molecular responses elicited by discrete functional regions of calreticulin.MethodsWild type (WT), calreticulin-deficient (CALR−/−), and calreticulin truncation variant (CALR−/−-NP and CALR−/−-PC) pluripotent stem cells were used to investigate molecular remodeling underlying a model of cardiopathology. Bioinformatic deconvolution of isolated transcriptomes was performed to identify predominant expression trends, gene ontology prioritizations, and molecular network features characteristic of discrete cell types.ResultsStem cell lines with wild type (WT), calreticulin-deficient (CALR−/−) genomes, as well as calreticulin truncation variants exclusively expressing either the chaperoning (CALR−/−-NP) or the calcium binding (CALR−/−-PC) domain exhibited characteristic molecular signatures determined by unsupervised agglomerative clustering. Kohonen mapping of RNA expression changes identified transcriptome dynamics that segregated into 12 discrete gene expression meta-profiles which were enriched for regulation of Eukaryotic Initiation Factor 2 (EIF2) signaling. Focused examination of domain-specific gene ontology remodeling revealed a general enrichment of Cardiovascular Development in the truncation variants, with unique prioritization of “Cardiovascular Disease” exclusive to the cohort of down regulated genes of the PC truncation variant. Molecular cartography of genes that comprised this cardiopathological category revealed uncharacterized and novel gene relationships, with identification of Pitx2 as a critical hub within the topology of a CALR−/− compromised network.ConclusionsDiagnostic surveillance, through an algorithm that integrates pluripotent stem cell transcriptomes with advanced high throughput assays and computational bioinformatics, revealed collective gene expression network changes that underlie differential phenotype development. Stem cell transcriptomes provide a deep collective molecular index that reflects ad hoc robustness of the pluripotent gene network. Remodeling events such as monogenic lesions provide a background by which high priority candidate disease effectors and regulators can be identified, demonstrated here by a molecular profiling algorithm that decrypts pluripotent wild type versus disrupted genomes.

[1]  M. Michalak,et al.  Coping with endoplasmic reticulum stress in the cardiovascular system. , 2013, Annual review of physiology.

[2]  A. Terzic,et al.  Bioinformatic Primer for Clinical and Translational Science , 2008, Clinical and translational science.

[3]  T. Kundu,et al.  Gene regulatory networks and epigenetic modifications in cell differentiation , 2014, IUBMB life.

[4]  Leif Hove-Madsen,et al.  PITX2 Insufficiency Leads to Atrial Electrical and Structural Remodeling Linked to Arrhythmogenesis , 2011, Circulation. Cardiovascular genetics.

[5]  J. Murray,et al.  Mutations in PITX2 may contribute to cases of omphalocele and VATER‐like syndromes , 2004, American journal of medical genetics. Part A.

[6]  M. Michalak,et al.  Calreticulin: non‐endoplasmic reticulum functions in physiology and disease , 2010, FASEB journal : official publication of the Federation of American Societies for Experimental Biology.

[7]  T. Ke,et al.  Mutation in Nuclear Pore Component NUP155 Leads to Atrial Fibrillation and Early Sudden Cardiac Death , 2008, Cell.

[8]  M. Michalak,et al.  Calcium binding chaperones of the endoplasmic reticulum. , 2009, General physiology and biophysics.

[9]  L. Hood,et al.  Molecular profiling of stem cells. , 2007, Clinica chimica acta; international journal of clinical chemistry.

[10]  J. Grosskreutz,et al.  Calcium-dependent protein folding in amyotrophic lateral sclerosis. , 2013, Cell calcium.

[11]  R. Albert Scale-free networks in cell biology , 2005, Journal of Cell Science.

[12]  A. Terzic,et al.  Metabolic plasticity in stem cell homeostasis and differentiation. , 2012, Cell stem cell.

[13]  Andre Terzic,et al.  Somatic oxidative bioenergetics transitions into pluripotency-dependent glycolysis to facilitate nuclear reprogramming. , 2011, Cell metabolism.

[14]  R. Rosli,et al.  Calreticulin and Cancer , 2013, Pathology & Oncology Research.

[15]  Melanie I. Stefan,et al.  Molecules for memory: modelling CaMKII , 2007, BMC Systems Biology.

[16]  Jody Groenendyk,et al.  Biology of endoplasmic reticulum stress in the heart. , 2010, Circulation research.

[17]  D K Arrell,et al.  Interpreting Networks in Systems Biology , 2013, Clinical pharmacology and therapeutics.

[18]  Inki Kim,et al.  Ribosomal protein L19 overexpression activates the unfolded protein response and sensitizes MCF7 breast cancer cells to endoplasmic reticulum stress-induced cell death. , 2014, Biochemical and biophysical research communications.

[19]  Marek Michalak,et al.  Calreticulin Differentially Modulates Calcium Uptake and Release in the Endoplasmic Reticulum and Mitochondria* , 2002, The Journal of Biological Chemistry.

[20]  J. Martín,et al.  Regulation of left-right asymmetry by thresholds of Pitx2c activity. , 2001, Development.

[21]  B. Gersh,et al.  Cell therapy for cardiac repair—lessons from clinical trials , 2014, Nature Reviews Cardiology.

[22]  Timothy J. Nelson,et al.  Decoded Calreticulin‐Deficient Embryonic Stem Cell Transcriptome Resolves Latent Cardiophenotype , 2010, Stem cells.

[23]  A. Terzic,et al.  Genomic chart guiding embryonic stem cell cardiopoiesis , 2008, Genome Biology.

[24]  Tal Geva,et al.  Atrial septal defects , 2014, The Lancet.

[25]  John Calvin Reed,et al.  ER stress-induced cell death mechanisms. , 2013, Biochimica et biophysica acta.

[26]  J. Hoffman,et al.  Incidence of congenital heart disease: I. Postnatal incidence , 1995, Pediatric Cardiology.

[27]  S. Dedhar,et al.  Heart, brain, and body wall defects in mice lacking calreticulin. , 2000, Experimental cell research.

[28]  Giovanni Scardoni,et al.  Analyzing biological network parameters with CentiScaPe , 2009, Bioinform..

[29]  Howard S. Fox,et al.  Transcriptome meta-analysis reveals a central role for sex steroids in the degeneration of hippocampal neurons in Alzheimer’s disease , 2013, BMC Systems Biology.

[30]  T H SELLORS,et al.  Atrial septal defects. , 1961, Proceedings of the Royal Society of Medicine.

[31]  Tetsurou Yamamoto,et al.  Arrhythmia induced by spatiotemporal overexpression of calreticulin in the heart. , 2007, Molecular genetics and metabolism.

[32]  K. Krause,et al.  Functional specialization of calreticulin domains , 2001, The Journal of cell biology.

[33]  J. McClintick,et al.  Selective mRNA translation during eIF2 phosphorylation induces expression of IBTKα , 2014, Molecular biology of the cell.

[34]  J. Hoffman,et al.  Incidence of congenital heart disease: II. Prenatal incidence , 1995, Pediatric Cardiology.

[35]  M. Michalak,et al.  ignaling networks in focus alreticulin signaling in health and disease , 2012 .

[36]  Lei Guo,et al.  Calreticulin in the heart , 2004, Molecular and Cellular Biochemistry.

[37]  R. Paro,et al.  Dissection of gene regulatory networks in embryonic stem cells by means of high-throughput sequencing , 2009, Biological chemistry.

[38]  D. L. Weeks,et al.  Pitx2c attenuation results in cardiac defects and abnormalities of intestinal orientation in developing Xenopus laevis. , 2003, Developmental biology.

[39]  L. Larsen,et al.  Of mice and men: molecular genetics of congenital heart disease , 2013, Cellular and Molecular Life Sciences.

[40]  K. Shakesheff,et al.  Directed differentiation of human embryonic stem cells to interrogate the cardiac gene regulatory network. , 2011, Molecular therapy : the journal of the American Society of Gene Therapy.

[41]  D. Franco,et al.  The role of Pitx2 during cardiac development. Linking left-right signaling and congenital heart diseases. , 2003, Trends in cardiovascular medicine.

[42]  J. Hoffman,et al.  The incidence of congenital heart disease. , 2002, Journal of the American College of Cardiology.

[43]  E. Olson,et al.  Mending broken hearts: cardiac development as a basis for adult heart regeneration and repair , 2013, Nature Reviews Molecular Cell Biology.

[44]  H. Duff,et al.  Complete heart block and sudden death in mice overexpressing calreticulin. , 2001, The Journal of clinical investigation.

[45]  B. Göttgens,et al.  Transcriptional mechanisms of cell fate decisions revealed by single cell expression profiling , 2014, BioEssays : news and reviews in molecular, cellular and developmental biology.

[46]  Karl-Heinz Krause,et al.  Calreticulin reveals a critical Ca2+ checkpoint in cardiac myofibrillogenesis , 2002, The Journal of cell biology.

[47]  Andre Terzic,et al.  Systems proteomics for translational network medicine. , 2012, Circulation. Cardiovascular genetics.

[48]  Michael D. Schneider,et al.  Myocardial Pitx2 Differentially Regulates the Left Atrial Identity and Ventricular Asymmetric Remodeling Programs , 2008, Circulation research.