José M. Frade

MICROGLIA-DERIVED NERVE GROWTH FACTOR CAUSES CELL DEATH IN THE DEVELOPING RETINA

While nerve growth factor (NGF) is best known for its trophic functions, recent experiments indicate that it can also cause cell death during development by activating the neurotrophin receptor p75. We now identify microglial cells as the source of NGF as a killing agent in the developing eye. When the retina is separated from the surrounding tissue before colonization by microglial cells, no NGF can be detected, and cell death is dramatically reduced. It is restored by the addition of microglial cells, an effect that is blocked by NGF antibodies. NGF adsorbed at the surface of beads, but not soluble NGF, mimics the killing action of microglial cells. These results indicate an active role for macrophages in neuronal death.

NERVE GROWTH FACTOR : TWO RECEPTORS, MULTIPLE FUNCTIONS

Nerve growth factor (NGF) was characterized over 4 decades ago, and like the other neurotrophins subsequently discovered, it is best known for its trophic role, including the prevention of programmed cell death in specific populations of neurones in the peripheral nervous system. This property can be accounted for by the activation of a tyrosine kinase receptor. NGF also regulates neuronal function, as illustrated by its role in pain and inflammation, and in synaptic plasticity. Finally, NGF recently was shown to activate the neurotrophin receptor p75 (p75NTR), a receptor with no intrinsic catalytic activity and with similarities to members of the tumor necrosis factor receptor family. During normal development, the activation of p75NTR by NGF actually kills cells in the central nervous system. One remarkable property of NGF is then that it controls cell numbers in opposite ways in the developing nervous system, a result of its unique ability to activate two different receptor types. BioEssays 20:137–145, 1998.

The zinc finger protein NRIF interacts with the neurotrophin receptor p75NTR and participates in programmed cell death

NRIF (neurotrophin receptor interacting factor) is a ubiquitously expressed zinc finger protein of the Krüppel family which interacts with the neurotrophin receptor p75NTR. The interaction was first detected in yeast and then biochemically confirmed using recombinant GST–NRIF fusions and p75NTR expressed by eukaryotic cells. Transgenic mice carrying a deletion in the exon encoding the p75NTR‐binding domain of NRIF display a phenotype which is strongly dependent upon genetic background. While at the F2 generation there is only limited (20%) embryonic lethality, in a congenic BL6 strain nrif−/− mice cannot survive beyond E12, but are viable and healthy to adulthood in the Sv129 background. The involvement of NRIF in p75NTR/NGF‐mediated developmental cell death was examined in the mouse embryonic neural retina. Disruption of the nrif gene leads to a reduction in cell death which is quantitatively indistinguishable from that observed in p75NTR−/− and ngf−/− mice. These results indicate that NRIF is an intracellular p75NTR‐binding protein transducing cell death signals during development.

Neurotrophin receptors TrkA and TrkC cause neuronal death whereas TrkB does not

Neurons of the peripheral nervous system have long been known to require survival factors to prevent their death during development. But why they selectively become dependent on secretory molecules has remained a mystery, as is the observation that in the central nervous system, most neurons do not show this dependency. Using engineered embryonic stem cells, we show here that the neurotrophin receptors TrkA and TrkC (tropomyosin receptor kinase A and C, also known as Ntrk1 and Ntrk3, respectively) instruct developing neurons to die, both in vitro and in vivo. By contrast, TrkB (also known as Ntrk2), a closely related receptor primarily expressed in the central nervous system, does not. These results indicate that TrkA and TrkC behave as dependence receptors, explaining why developing sympathetic and sensory neurons become trophic-factor-dependent for survival. We suggest that the expansion of the Trk gene family that accompanied the segregation of the peripheral from the central nervous system generated a novel mechanism of cell number control.

Interkinetic nuclear movement may provide spatial clues to the regulation of neurogenesis

During the transition from S phase to mitosis, vertebrate neuroepithelial cells displace their nuclei and subsequently migrate from the basal membrane to the apical surface of the neuroepithelium, a phenomenon termed interkinetic nuclear movement (INM). Here we provide evidence that cycling neuroepithelial cells pass through a neurogenic state in which they are situated apically, as defined by the capacity to express Notch1, Delta1, and Neurogenin2 (Ngn2). Based on this scenario, we have developed a mathematical model to analyze the influence of INM on neurogenesis. In the absence of INM, the model predicted an increase in the rate of neurogenesis due to the reduction in the influence of inhibitory signals on cells in the neurogenic state. This exacerbation in neurogenesis led to the diminished growth of the neuroepithelium and a reduction in the later production of neurons. Pharmacological perturbation of the stereotypical distribution of precursors along the orthogonal axis of the neuroepithelium resulted in an excess of neurogenesis, as seen by the expression of Ngn2, and of the neuronal marker RA4 in the retina. These findings suggest that INM might be important for the efficient and continued production of neurons in G0, since it is involved in defining a proneural cluster in the ventricular part of the neuroepithelium that contains precursors at stages of the mitotic cycle compatible with neuronal differentiation.

Role of neurotrophins in the control of neural development: Neurotrophin-3 promotes both neuron differentiation and survival of cultured chick retinal cells

The effects of neurotrophins brain-derived neurotrophic factor and neurotrophin-3 on cultured dissociated cells from chick retina were studied at several embryonic ages from day 4 to day 13. Precursor cells from days 4-7 retinas proliferated in vitro and, after 20 h in culture, a proportion of them underwent spontaneous differentiation, as judged by both [3H]thymidine uptake and acquisition of neuronal morphology and neuron-specific markers. Brain-derived neurotrophic factor did not affect neuronal differentiation, although this factor supports survival of differentiated retinal ganglion cells [Rodríguez-Tébar et al. (1989) Devl Biol. 136, 296-303]. However, in cultures from young undifferentiated retinas, neurotrophin-3 produced up to a 2.5-fold increase in the number of [3H]thymidine-positive neurons, i.e. those that in vitro replicated their DNA. Moreover, in older retinas, neurotrophin-3, like brain-derived neurotrophic factor, supported the survival of differentiated retinal ganglion cells over a short developmental period. This effect was negligible at embryonic day 5, maximal at day 9, decreased at day 11 and was absent at embryonic day 13. Neurotrophin-3 also supported the survival of a population of amacrine neurons. This effect was modest at embryonic day 9, and increased at days 11 and 13. Our results show that, whereas the action of brain-derived neurotrophic factor is restricted to differentiated neurons, neurotrophin-3 exerts two distinct successive actions on retinal cells in vitro: first, this factor promotes either differentiation of neuroepithelial cells or maturation of recently differentiated neurons, and later in development, this factor supports the survival of differentiated retinal ganglion and amacrine cells but only during a discrete post-differentiation period.

Nuclear Translocation of the p75 Neurotrophin Receptor Cytoplasmic Domain in Response to Neurotrophin Binding

The intracellular domain of the p75 neurotrophin receptor (p75ICD) can be released by γ-secretase in response to the previous activation of α-secretase by phorbol esters. However, ligand-dependent release of p75ICD has yet to be described. We show here that nerve growth factor can induce the release of p75ICD and facilitate its translocation to the nucleus in a γ-secretase-dependent manner. This effect was observed in RN22 schwannoma cells cultured under serum-free conditions, as well as in Schwann cells, and it was mimicked by other neurotrophins, such as brain-derived neurotrophic factor or neurotrophin-3. Unlike other known examples of regulated intramembrane proteolysis, ligand-dependent release of p75ICD did not need the previous activation of α-secretase. These results suggest that nuclear translocation of p75ICD may represent a novel neurotrophin-mediated signaling pathway.

Neurotrophins and other growth factors in the generation of retinal neurons.

The generation of neurons in the vertebrate retina, as in other areas of the developing nervous system, largely depends on extracellular signals. Of the known signaling molecules, neurotrophins play decisive, defined, and distinct roles. The three neurotrophins identified in the chick, namely, neurotrophin‐3 (NT‐3), brain‐derived neurotrophic factor (BDNF), and nerve growth factor (NGF), are expressed in either the pigment epithelium (NT‐3 and BDNF) or in the neural retina (NGF) at the onset of neuron birth. In addition, trkC and trkB, receptors for NT‐3 and BDNF, respectively, together with p75, the low‐affinity neurotrophin receptor, are expressed in the retina at the same developmental period. The role of these three neurotrophins in the differentiation of neurons in the chick retina has been elucidated by a combination of in vitro and in vivo experiments. Thus, NT‐3 promotes the conversion of neuroepithelial cells into neurons, whereas BDNF and NGF control the programmed cell death (apoptosis) that affects early postmitotic neuroblasts. BDNF, acting via its trkB receptor, is a survival factor for these cells, whereas NGF, binding to p75 receptor, acts as a killing factor, thereby controlling the provisional number of newly generated neurons. Microsc. Res. Tech. 45:243–251, 1999. 

Neuronal cell cycle: the neuron itself and its circumstances

Neurons are usually regarded as postmitotic cells that undergo apoptosis in response to cell cycle reactivation. Nevertheless, recent evidence indicates the existence of a defined developmental program that induces DNA replication in specific populations of neurons, which remain in a tetraploid state for the rest of their adult life. Similarly, de novo neuronal tetraploidization has also been described in the adult brain as an early hallmark of neurodegeneration. The aim of this review is to integrate these recent developments in the context of cell cycle regulation and apoptotic cell death in neurons. We conclude that a variety of mechanisms exists in neuronal cells for G1/S and G2/M checkpoint regulation. These mechanisms, which are connected with the apoptotic machinery, can be modulated by environmental signals and the neuronal phenotype itself, thus resulting in a variety of outcomes ranging from cell death at the G1/S checkpoint to full proliferation of differentiated neurons.

Somatic tetraploidy in specific chick retinal ganglion cells induced by nerve growth factor

A subset of neurons in the normal vertebrate nervous system contains double the normal amount of DNA in their nuclei. These neurons are all thought to derive from aberrant mitoses in neuronal precursor cells. Here we show that endogenous NGF induces DNA replication in a subpopulation of differentiating chick retinal ganglion cells that express both the neurotrophin receptor p75 and the E2F1 transcription factor, but that lack the retinoblastoma protein. Many of these neurons avoid G2/M transition and remain alive in the retina as tetraploid cells with large cell somas and extensive dendritic trees, and most of them express β2 nicotinic acetylcholine receptor subunits, a specific marker of retinal ganglion cells innervating lamina F in the stratum-griseum-et-fibrosum-superficiale of the tectal cortex. Tetraploid neurons were also observed in the adult mouse retina. Thus, a developmental program leading to somatic tetraploidy in specific retinal neurons exists in vertebrates. This program might occur in other vertebrate neurons during normal or pathological situations.