Paul Stroobant

Platelet-derived growth factor is structurally related to the putative transforming protein p28sis of simian sarcoma virus.

A partial amino acid sequence of human platelet-derived growth factor, the major mitogen in serum for cells of mesenchymal origin, has been determined. A region of 104 contiguous amino acids shows virtual identity with the predicted sequence of p28sis, the putative transforming protein of simian sarcoma virus (SSV). This similarity suggests a mechanism for transformation by SSV and other agents, involving expression of growth factors.

Glial growth factor restricts mammalian neural crest stem cells to a glial fate

Growth factors and cytokines are thought to influence the development of uncommitted progenitor cell populations, but the issue of how these factors act on individual cells remains controversial. Such factors may act simply as selective mitogens or survival factors for cells that undergo lineage restrictions stochastically. Alternatively, they may instruct or bias multipotent cells to choose one lineage at the expense of others. Here we show that glial growth factor (GGF), previously defined as a Schwann cell mitogen, strongly suppresses neuronal differentiation of rat neural crest stem cells while promoting or allowing glial differentiation. Quantitative clonal analysis suggests that the action of GGF is likely to be instructive rather than selective. Taken together with the expression pattern of GGF, these data suggest a lateral signaling model for the diversification of cell types within developing peripheral ganglia.

Correlation network analysis for data integration and biomarker selection.

High-throughput biomolecular profiling techniques such as transcriptomics, proteomics and metabolomics are increasingly being used in in vivo studies to recognize and characterize effects of xenobiotics on organs and systems. Of particular interest are biomarkers of treatment-related effects which are detectable in easily accessible biological fluids such as blood. A fundamental challenge in such biomarker studies is selecting among the plethora of biomolecular changes induced by a compound and revealed by molecular profiling, to identify biomarkers which are exclusively or predominantly due to specific processes. In this work we present a cross-compartment correlation network approach, involving no a priori supervision or design, to integrate proteomic, metabolomic and transcriptomic data for selecting circulating biomarkers. The case study we present is the identification of biomarkers of drug-induced hepatic toxicity effects in a rodent model. Biomolecular profiling of both blood plasma and liver tissue from Wistar Hannover rats administered a toxic compound yielded many hundreds of statistically significant molecular changes. We exploited drug-induced correlations between blood plasma analytes and liver tissue molecules across study animals in order to nominate selected plasma molecules as biomarkers of drug-induced hepatic alterations of lipid metabolism and urea cycle processes.

Glial growth factors I‐III are specific mitogens for glial cells

Recently we identified three novel Schwann cell mitogens named GGF (glial growth factor)‐I (34 kDa), GGF‐II (59 kDa), and GGF‐III (45 kDa), and provided evidence that they are three distinct but structurally related members of a larger family of factors, which includes heregulin, neu differentiation factor, and acetylcholine receptor‐inducing activity (ARIA). We report here the characterization of the mitogenic and trophic activities for all three forms of GGF on rat Schwann cells and several other cell types. GGF‐I, GGF‐II, and GGF‐III are potent mitogens for rat Schwann cells in vitro at nanomolar concentrations, whereas at lower concentrations they promote Schwann cell survival, in the absence of cAMP elevating agents. Forskolin, an adenylate cyclase activator, potently synergizes with the GGFs by an indirect mechanism, possibly involving transcriptional activation of GGF receptor(s). In addition, the GGFs stimulate DNA synthesis in rat glioma C6 cells, and in SK‐BR‐3 cells, which overexpress the p185 neu/erbB2. Fibroblasts obtained from different sources are weakly stimulated by GGFs, whereas PC12 cells are unable to respond under a variety of experimental conditions. These observations are consistent with the proposal that GGF‐I, GGF‐II, and GGF‐III are a set of potent glial cell mitogens and putative ligands of members of the EGF receptor family, namely p185 neu/erbB2, p160/erbB3, and p180/erbB4, which may play important roles in the development, regeneration, and tumor biology of the peripheral nervous system.