Derek van der Kooy

NEURAL STEM CELLS IN THE ADULT MAMMALIAN FOREBRAIN : A RELATIVELY QUIESCENT SUBPOPULATION OF SUBEPENDYMAL CELLS

Dissection of the subependyma from the lateral ventricle of the adult mouse forebrain is necessary and sufficient for the in vitro formation of clonally derived spheres of cells that exhibit stem cell properties such as self-maintenance and the generation of a large number of progeny comprising the major cell types found in the central nervous system. Killing the constitutively proliferating cells of the subependyma in vivo has no effect on the number of stem cells isolated in vitro and induces a complete repopulation of the subependyma in vivo by relatively quiescent stem cells found within the subependyma. Depleting the relatively quiescent cell population within the subependyma in vivo results in a corresponding decrease in spheres formed in vitro and in the final number of constitutively proliferating cells in vivo, suggesting that a relatively quiescent subependymal cell is the in vivo source of neural stem cells.

Direct neural fate specification from embryonic stem cells: a primitive mammalian neural stem cell stage acquired through a default mechanism.

Little is known about how neural stem cells are formed initially during development. We investigated whether a default mechanism of neural specification could regulate acquisition of neural stem cell identity directly from embryonic stem (ES) cells. ES cells cultured in defined, low-density conditions readily acquire a neural identity. We characterize a novel primitive neural stem cell as a component of neural lineage specification that is negatively regulated by TGFbeta-related signaling. Primitive neural stem cells have distinct growth factor requirements, express neural precursor markers, generate neurons and glia in vitro, and have neural and non-neural lineage potential in vivo. These results are consistent with a default mechanism for neural fate specification and support a model whereby definitive neural stem cell formation is preceded by a primitive neural stem cell stage during neural lineage commitment.

Is there a neural stem cell in the mammalian forebrain

Neural precursor cells have been of interest historically as the building blocks of the embryonic CNS and, most recently, as substrates for restorative neurological approaches. The majority of previous in vitro studies of the regulation of neural-cell proliferation by polypeptide growth factors, and in vivo studies of neural lineage, argue for the presence of precursors with limited proliferative or lineage potential in the mammalian CNS. This is in contrast to renewable tissues, such as the blood or immune system, skin epithelium and epithelium of the small intestinal crypts, which contain specialized, self-renewing cells known as stem cells. However, recent in vitro and in vivo studies from our and other laboratories lead us to conclude that neural stem cells, with self-renewal and multilineage potential, are present in the embryonic through to adult mammalian forebrain.

Clonal identification of multipotent precursors from adult mouse pancreas that generate neural and pancreatic lineages

The clonal isolation of putative adult pancreatic precursors has been an elusive goal of researchers seeking to develop cell replacement strategies for diabetes. We report the clonal identification of multipotent precursor cells from the adult mouse pancreas. The application of a serum-free, colony-forming assay to pancreatic cells enabled the identification of precursors from pancreatic islet and ductal populations. These cells proliferate in vitro to form clonal colonies that coexpress neural and pancreatic precursor markers. Upon differentiation, individual clonal colonies produce distinct populations of neurons and glial cells, pancreatic endocrine β-, α- and δ-cells, and pancreatic exocrine and stellate cells. Moreover, the newly generated β-like cells demonstrate glucose-dependent Ca2+ responsiveness and insulin release. Pancreas colonies do not express markers of embryonic stem cells, nor genes suggestive of mesodermal or neural crest origins. These cells represent a previously unidentified adult intrinsic pancreatic precursor population and are a promising candidate for cell-based therapeutic strategies.

Drug reinforcement studied by the use of place conditioning in rat.

Rats display a preference for an environment in which they previously received morphine. The present report provides behavioral and pharmacological data for this simple model of reinforcement produced by opiates and describes an aversion in rats for an environment in which they previously received naloxone. Preferences were produced with intravenous (i.v.) morphine sulfate at doses of 0.08-15 mg/kg and durations of the pairing between environment and morphine of 10 min to 1.5 h. Preferences were also seen with other opiate agonists (etorphine-HCl and levorphanol-tartrate), another route of drug administration (subcutaneous), and after 1-4 administrations of morphine. Cocaine-HCl (i.v.), a non-narcotic drug, known to be self-administered by humans, also produced a place preference. Lithium chloride (i.v.), an agent found to be a punishing stimulus in other situations, produced a place aversion. There was no appreciable preference for an environment paired with dextrorphan-tartrate and naloxone-HCl (2 mg/kg, i.p.) blocked the production of the preference produced by i.v. morphine. In contrast to the effect produced by morphine, aversions were produced with (-)-naloxone-HCl alone at doses of 0.1-45 mg/kg (i.v.). The aversion was not produced at (+)-naloxone. Implantation of rats with a 75 mg morphine pellet 3 days prior to place conditioning potentiated the aversive effect of naloxone. It was concluded that place conditioning produced by morphine and naloxone is mediated by specific opiate receptors and that stimulating and decreasing activity of the endogenous opioid peptide system with systemically administered drugs is positively reinforcing and aversive, respectively. The discussion emphasizes application of the simple and sensitive place conditioning model to drug reinforcement research, including analyses of reinforcement produced by microinjection of opiates into the brain.

Hematopoietic competence is a rare property of neural stem cells that may depend on genetic and epigenetic alterations

The concept of stem-cell plasticity received strong support from a recent observation that extensively passaged, clonally derived neural stem cells could contribute to hematopoiesis. We investigated whether hematopoietic potential was a consistent or unusual feature of neural stem cells, and whether it depended on the extent of in vitro passaging before transplantation. Here we transplanted over 128 × 106 neurosphere cells into 128 host animals; however, we never observed contribution to hematopoiesis, irrespective of the number of passages and despite the use of an assay that could detect the contribution of a single blood stem cell to hematopoietic repopulation. Although extensively cultured neurosphere cells continued to generate neural progeny, marked changes in their growth properties occurred, including changes in growth-factor dependence, cell-cycle kinetics, cell adhesion and gene expression. Our results exclude hematopoietic competence as a consistent property of intravenously infused neural stem cells. However, the consistent changes that occurred during extended passaging are compatible with genetic or epigenetic alterations and suggest that rare transformation events may account for the neural-to-blood fate switch originally reported.

THE NEUROBIOLOGY OF NICOTINE ADDICTION: BRIDGING THE GAP FROM MOLECULES TO BEHAVIOUR

Nicotine, the primary psychoactive component of tobacco smoke, produces diverse neurophysiological, motivational and behavioural effects through several brain regions and neurochemical pathways. Recent research in the fields of behavioural pharmacology, genetics and electrophysiology is providing an increasingly integrated picture of how the brain processes the motivational effects of nicotine. The emerging characterization of separate dopamine- and GABA (γ-aminobutyric acid)-dependent neural systems within the ventral tegmental area (VTA), which can mediate the acute aversive and rewarding psychological effects of nicotine, is providing new insights into how functional interactions between these systems might determine vulnerability to nicotine use.

Developmental expression of a novel murine homeobox gene (Chx10): Evidence for roles in determination of the neuroretina and inner nuclear layer

Few potential regulatory proteins of vertebrate retinal development have been identified. We describe a 39 kDa murine polypeptide (Chx10) with a homeodomain 82% identical to that of the nematode protein ceh-10. In the developing mouse, the Chx10 transcript is expressed throughout the anterior optic vesicle and all neuroblasts of the optic cup. In the mature retina, the Chx10 protein is restricted to the inner nuclear layer, in which its expression decreases from the outer to the inner margin. Chx10 transcripts are also detected in regions of the developing thalamus, hindbrain, and ventral spinal cord. The data suggest that Chx10 plays critical roles in the formation of the neuroretina and in the development and maintenance of the inner nuclear layer.

Stem and progenitor cells: the premature desertion of rigorous definitions

A current disturbing trend in stem cell biology is the abandonment of rigorous definitions of stem and progenitor cells in favor of more ambiguous, all-encompassing concepts. However, recent studies suggest that there are consistent, functional differences in the biology of these two cell types. Admittedly, it can be difficult to harmonize the in vivo and in vitro functional differences between stem and progenitor cells. Nonetheless, these distinctions between cell types should be emphasized rather than ignored, as they can be used to test specific hypotheses in neural stem cell biology.

DREAM Is a Critical Transcriptional Repressor for Pain Modulation

Control and treatment of chronic pain remain major clinical challenges. Progress may be facilitated by a greater understanding of the mechanisms underlying pain processing. Here we show that the calcium-sensing protein DREAM is a transcriptional repressor involved in modulating pain. dream(-/-) mice displayed markedly reduced responses in models of acute thermal, mechanical, and visceral pain. dream(-/-) mice also exhibited reduced pain behaviors in models of chronic neuropathic and inflammatory pain. However, dream(-/-) mice showed no major defects in motor function or learning and memory. Mice lacking DREAM had elevated levels of prodynorphin mRNA and dynorphin A peptides in the spinal cord, and the reduction of pain behaviors in dream(-/-) mice was mediated through dynorphin-selective kappa (kappa)-opiate receptors. Thus, DREAM appears to be a critical transcriptional repressor in pain processing.