Synergistic activation of RARß and RARγ nuclear receptors restores cell specialization during stem cell differentiation by hijacking RARα-controlled programs.

How cells respond to different external cues to develop along defined cell lineages to form complex tissues is a major question in systems biology. Here, we investigated the potential of retinoic acid receptor (RAR)-selective synthetic agonists to activate the gene regulatory programs driving cell specialization during nervous tissue formation from embryonic carcinoma (P19) and mouse embryonic (E14) stem cells. Specifically, we found that the synergistic activation of the RARß and RARγ by selective ligands (BMS641 or BMS961) induces cell maturation to specialized neuronal subtypes, and to astrocytes and oligodendrocyte precursors. Using RAR isotype knockout lines exposed to RAR-specific agonists, interrogated by global transcriptome landscaping and in silico modeling of transcription regulatory signal propagation, revealed major RARα-driven gene programs essential for optimal neuronal cell specialization and hijacked by the synergistic activation of the RARß and RARγ receptors. Overall, this study provides a systems biology view of the gene programs accounting for the previously observed redundancy between RARs, paving the way toward their potential use for directing cell specialization during nervous tissue formation.

3D single cell migration driven by temporal correlation between oscillating force dipoles.

Directional cell locomotion requires symmetry breaking between the front and rear of the cell. In some cells, symmetry breaking manifests itself in a directional flow of actin from the front to the rear of the cell. Many cells, especially in physiological 3D matrices, do not show such coherent actin dynamics and present seemingly competing protrusion/retraction dynamics at their front and back. How symmetry breaking manifests itself for such cells is therefore elusive. We take inspiration from the scallop theorem proposed by Purcell for micro-swimmers in Newtonian fluids: self-propelled objects undergoing persistent motion at low Reynolds number must follow a cycle of shape changes that breaks temporal symmetry. We report similar observations for cells crawling in 3D. We quantified cell motion using a combination of 3D live cell imaging, visualization of the matrix displacement, and a minimal model with multipolar expansion. We show that our cells embedded in a 3D matrix form myosin-driven force dipoles at both sides of the nucleus, that locally and periodically pinch the matrix. The existence of a phase shift between the two dipoles is required for directed cell motion which manifests itself as cycles with finite area in the dipole-quadrupole diagram, a formal equivalence to the Purcell cycle. We confirm this mechanism by triggering local dipolar contractions with a laser. This leads to directed motion. Our study reveals that these cells control their motility by synchronizing dipolar forces distributed at front and back. This result opens new strategies to externally control cell motion as well as for the design of micro-crawlers.

Reconstructed cell fate-regulatory programs in stem cells reveal hierarchies and key factors of neurogenesis.

Cell lineages, which shape the body architecture and specify cell functions, derive from the integration of a plethora of cell intrinsic and extrinsic signals. These signals trigger a multiplicity of decisions at several levels to modulate the activity of dynamic gene regulatory networks (GRNs), which ensure both general and cell-specific functions within a given lineage, thereby establishing cell fates. Significant knowledge about these events and the involved key drivers comes from homogeneous cell differentiation models. Even a single chemical trigger, such as the morphogen all-trans retinoic acid (RA), can induce the complex network of gene-regulatory decisions that matures a stem/precursor cell to a particular step within a given lineage. Here we have dissected the GRNs involved in the RA-induced neuronal or endodermal cell fate specification by integrating dynamic RXRA binding, chromatin accessibility, epigenetic promoter epigenetic status, and the transcriptional activity inferred from RNA polymerase II mapping and transcription profiling. Our data reveal how RA induces a network of transcription factors (TFs), which direct the temporal organization of cognate GRNs, thereby driving neuronal/endodermal cell fate specification. Modeling signal transduction propagation using the reconstructed GRNs indicated critical TFs for neuronal cell fate specification, which were confirmed by CRISPR/Cas9-mediated genome editing. Overall, this study demonstrates that a systems view of cell fate specification combined with computational signal transduction models provides the necessary insight in cellular plasticity for cell fate engineering. The present integrated approach can be used to monitor the in vitro capacity of (engineered) cells/tissues to establish cell lineages for regenerative medicine.

Modulation of Retinoic Acid Receptor Subtypes by 5- and 8-Substituted (Naphthalen-2-yl)-based Arotinoids.

Retinoid receptors (RARs and RXRs) transduce the signals of their natural and synthetic ligands (retinoids and rexinoids) to cellular transcriptional machinery to induce gene programs that control diverse biological and physiological effects on organisms. All-trans-retinoic acid, the natural ligand for RARs, is used therapeutically for the treatment of acute promyelocytic leukemia (APL), whereas the synthetic rexinoid bexarotene (a representative member of the aromatic retinoids or arotinoids) is approved for the treatment of cutaneous T-cell lymphoma (CTCL). Other retinoids have found applications in the topical treatment of skin disorders. In continuation of previous work on the naphthalene-based arotinoid scaffold, we synthesized a new series of (3-halo)benzoic acids connected to C5- or C8-substituted naphthyl rings via (E)-ethenyl and amide and, for the C5 series, (E)-chalcone linkers. These compounds were evaluated as RAR modulators in comparison with previously described dihydronaphthalene arotinoids with the same substitution pattern. Transactivation studies in this series revealed an absence of synergy between small halogen atoms (F, Cl) at C3 and the groups at C5 or C8, as had been observed on some of the dihydronaphthalene analogues. Instead, non-halogenated 4-(2-naphthamido)benzoic acid derivatives transactivated toward the RARß subtype in preference to the paralogues. The derivatives with bulkier substituents at C8 were characterized as dual RARß/RARα antagonists, and (E)-4-[(8-(phenylethynyl)naphthalene-2-yl)ethenyl]benzoic acid (11 c), with an ethenyl connector, was shown to be a potent antagonist of RARα.

Dual RXR Agonists and RAR Antagonists Based on the Stilbene Retinoid Scaffold.

Arotinoids containing a C5,C8-diphenylnaphthalene-2-yl ring linked to a (C3-halogenated) benzoic acid via an ethenyl connector (but not the corresponding naphthamides), which are prepared by Horner-Wadsworth-Emmons reaction of naphthaldehydes and benzylphosphonates, display the rather unusual property of being RXR agonists (15-fold induction of the RXR reporter cell line was achieved at 3- to 10-fold lower concentration than 9-cis-retinoic acid) and RAR antagonists as shown by transient transactivation studies. The binding of such bulky ligands suggests that the RXR ligand-binding domain is endowed with some degree of structural elasticity.

A functional genetic screen identifies retinoic acid signaling as a target of histone deacetylase inhibitors.

Understanding the pathways that are targeted by cancer drugs is instrumental for their rational use in a clinical setting. Inhibitors of histone deacetylases (HDACI) selectively inhibit proliferation of malignant cells and are used for the treatment of cancer, but their cancer selectivity is understood poorly. We conducted a functional genetic screen to address the mechanism(s) of action of HDACI. We report here that ectopic expression of two genes that act on retinoic acid (RA) signaling can cause resistance to growth arrest and apoptosis induced by HDACI of different chemical classes: the retinoic acid receptor alpha (RARalpha) and preferentially expressed antigen of melanoma (PRAME), a repressor of RA signaling. Treatment of cells with HDACI induced RA signaling, which was inhibited by RARalpha or PRAME expression. Conversely, RAR-deficient cells and PRAME-knockdown cells show enhanced sensitivity to HDACI in vitro and in mouse xenograft models. Finally, a combination of RA and HDACI acted synergistically to activate RA signaling and inhibit tumor growth. These experiments identify the RA pathway as a rate-limiting target of HDACI and suggest strategies to enhance the therapeutic efficacy of HDACI.

HDAC inhibitors induce apoptosis in glucocorticoid-resistant acute lymphatic leukemia cells despite a switch from the extrinsic to the intrinsic death pathway.

Inhibitors of histone deacetylases (HDACi's) are promising novel tools for cancer therapy. We have compared the growth inhibitory and apoptogenic potential of the pan-HDACi SAHA and the sub-class I selective HDAC inhibitor MS275, as well as valproic acid (VPA) on glucocorticoid sensitive and resistant B (B-ALL) and T (T-ALL) cell acute lymphoblastic leukemia cells and patients blasts. In contrast, to our previous results with U937 acute myeloid leukemia (AML) cells which showed a similar activity of MS275 and SAHA in growth inhibition and apoptosis induction, both B and T-ALL cells were much more efficiently killed by SAHA and VPA than by MS275. The same relative potency was observed with some patient ALL blasts treated ex vivo. SAHA displayed similar efficacy on glucocorticoid-sensitive and insensitive ALL cells but did not synergize with dexamethasone. In studying mediators of apoptosis we found that the TRAIL receptor DR5 is constitutively expressed in glucocorticoid-sensitive CEM-C7 cells which are also TRAIL sensitive. In contrast, glucocorticoid-insensitive CEM-C1 cells do not express DR5 and are insensitive to TRAIL. However, SAHA induces, in addition to p21(WAF1/CIP1) also re-expression of DR5. Importantly, SAHA-induced apoptosis of CEM-C7 cells operates through initiator caspase 10, while it induces apoptosis of CEM-C1 cells through the intrinsic, as well as through caspase-independent death pathways. Our data suggest that the generation of resistance to glucocorticoids has dramatically altered death signaling in these cells and that SAHA overcomes these restrictions by inducing alternative death pathways.