Jeffrey Milbrandt

Resveratrol stimulates AMP kinase activity in neurons

Resveratrol is a polyphenol produced by plants that has multiple beneficial activities similar to those associated with caloric restriction (CR), such as increased life span and delay in the onset of diseases associated with aging. CR improves neuronal health, and the global beneficial effects of CR have been postulated to be mediated by the nervous system. One key enzyme thought to be activated during CR is the AMP-activated kinase (AMPK), a sensor of cellular energy levels. AMPK is activated by increases in the cellular AMP:ATP ratio, whereupon it functions to help preserve cellular energy. In this regard, the regulation of dietary food intake by hypothalamic neurons is mediated by AMPK. The suppression of nonessential energy expenditure by activated AMPK along with the CR mimetic and neuroprotective properties of resveratrol led us to hypothesize that neuronal activation of AMPK could be an important component of resveratrol activity. Here, we show that resveratrol activated AMPK in Neuro2a cells and primary neurons in vitro as well as in the brain. Resveratrol and the AMPK-activating compound 5-aminoimidazole-4-carboxamide-1-β-d-ribofuranoside (AICAR) promoted robust neurite outgrowth in Neuro2a cells, which was blocked by genetic and pharmacologic inhibition of AMPK. Resveratrol also stimulated mitochondrial biogenesis in an AMPK-dependent manner. Resveratrol-stimulated AMPK activity in neurons depended on LKB1 activity but did not require the NAD-dependent protein deacetylase SIRT1 during this time frame. These findings suggest that neuronal activation of AMPK by resveratrol could affect neuronal energy homeostasis and contribute to the neuroprotective effects of resveratrol.

Nerve growth factor induces a gene homologous to the glucocorticoid receptor gene

Nerve growth factor (NGF) is required for the development and survival of sympathetic and neural crest-derived sensory neurons. The mechanism of action of NGF has been extensively studied in the NGF-responsive rat pheochromocytoma cell line, PC12. When treated with NGF, PC12 cells initiate neurite outgrowth and differentiate into cells with a neuronal phenotype. This process is prevented by RNA synthesis inhibitors. NGFI-B is a gene, identified by differential hybridization, that is rapidly, but transiently induced in PC12 cells by NGF. The nucleotide sequence of the NGFI-B gene was determined, and it encodes a 61 kd protein with strong homologies to members of the glucocorticoid receptor gene family. The two regions of homology between NGFI-B and this family of ligand-dependent transcriptional activators are the region corresponding to the DNA-binding domain and the region comprising the ligand-binding domain near the COOH-terminus. NGFI-B, as a possible ligand-dependent transcriptional activator induced by NGF, may play a role in initiating NGF-induced differentiation.

Artemin, a Novel Member of the GDNF Ligand Family, Supports Peripheral and Central Neurons and Signals through the GFRα3–RET Receptor Complex

The glial cell line-derived neurotrophic factor (GDNF) ligands (GDNF, Neurturin [NTN], and Persephin [PSP]) signal through a multicomponent receptor system composed of a high-affinity binding component (GFRalpha1-GFRalpha4) and a common signaling component (RET). Here, we report the identification of Artemin, a novel member of the GDNF family, and demonstrate that it is the ligand for the former orphan receptor GFRalpha3-RET. Artemin is a survival factor for sensory and sympathetic neurons in culture, and its expression pattern suggests that it also influences these neurons in vivo. Artemin can also activate the GFRalpha1-RET complex and supports the survival of dopaminergic midbrain neurons in culture, indicating that like GDNF (GFRalpha1-RET) and NTN (GFRalpha2-RET), Artemin has a preferred receptor (GFRalpha3-RET) but that alternative receptor interactions also occur.

Persephin, a Novel Neurotrophic Factor Related to GDNF and Neurturin

A novel neurotrophic factor named Persephin that is approximately 40% identical to glial cell line-derived neurotrophic factor (GDNF) and neurturin (NTN) has been identified using degenerate PCR. Persephin, like GDNF and NTN, promotes the survival of ventral midbrain dopaminergic neurons in culture and prevents their degeneration after 6-hydroxydopamine treatment in vivo. Persephin also supports the survival of motor neurons in culture and in vivo after sciatic nerve axotomy and, like GDNF, promotes ureteric bud branching. However, in contrast to GDNF and NTN, persephin does not support any of the peripheral neurons that were examined. Fibroblasts transfected with Ret and one of the coreceptors GFRalpha-1 or GFRalpha-2 do not respond to persephin, suggesting that persephin utilizes additional, or different, receptor components than GDNF and NTN.

Luteinizing Hormone Deficiency and Female Infertility in Mice Lacking the Transcription Factor NGFI-A (Egr-1)

The immediate-early transcription factor NGFI-A (also called Egr-1, zif/268, or Krox-24) is thought to couple extracellular signals to changes in gene expression. Although activins and inhibins regulate follicle-stimulating hormone (FSH) synthesis, no factor has been identified that exclusively regulates luteinizing hormone (LH) synthesis. An analysis of NGFI-A-deficient mice derived from embryonic stem cells demonstrated female infertility that was secondary to LH-β deficiency. Ovariectomy led to increased amounts of FSH-β but not LH-β messenger RNA, which suggested a pituitary defect. A conserved, canonical NGFI-A site in the LH-β promoter was required for synergistic activation by NGFI-A and steroidogenic factor-1 (SF-1). NGFI-A apparently influences female reproductive capacity through its regulation of LH-β transcription.

The GDNF family ligands and receptors — implications for neural development

The glial cell line derived neurotrophic factor (GDNF) family has recently been expanded to include four members, and the interactions between these neurotrophic factors and their unique receptor system is now beginning to be understood. Furthermore, analysis of mice lacking the genes for GDNF, neurturin, and their related receptors has confirmed the importance of these factors in neurodevelopment. The results of such analyses reveal numerous similarities and potential overlaps in the way the GDNF and the nerve growth factor (NGF) families regulate development of the peripheral nervous system.

GFRα1-Deficient Mice Have Deficits in the Enteric Nervous System and Kidneys

Abstract Glial cell line–derived neurotrophic factor (GDNF) signals through a receptor complex composed of the Ret tyrosine kinase and a glycosylphosphatidylinositol- (GPI-) anchored cell surface coreceptor, either GDNF family receptor α1 (GFRα1) or GFRα2. To investigate the usage of these coreceptors for GDNF signaling in vivo, gene targeting was used to produce mice lacking the GFRα1 coreceptor. GFRα1-deficient mice demonstrate absence of enteric neurons and agenesis of the kidney, characteristics that are reminiscent of both GDNF- and Ret-deficient mice. Midbrain dopaminergic and motor neurons in GFRα1 null mice were normal. Minimal or no neuronal losses were observed in a number of peripheral ganglia examined, including the superior cervical and nodose, which are severely affected in both Ret- and GDNF-deficient mice. These results suggest that while stringent physiologic pairing exists between GFRα1 and GDNF in renal and enteric nervous system development, significant cross-talk between GDNF and other GFRα coreceptors must occur in other neuronal populations.

TrnR2, a novel receptor that mediates neurturin and GDNF signaling through Ret

Glial cell line-derived neurotrophic factor (GDNF) and neurturin (NTN) comprise a family of TGF-beta-related neurotrophic factors (TRNs), which have trophic influences on a variety of neuronal populations. A receptor complex comprised of TrnR1 (GDNFR alpha) and Ret was recently identified and found to be capable of mediating both GDNF and NTN signaling. We have identified a novel receptor based on homology to TrnR1, called TrnR2, that is 48% identical to TrnR1, and is located on the short arm of chromosome 8. TrnR2 is attached to the cell surface via a GPI-linkage, and can mediate both NTN and GDNF signaling through Ret in vitro. Fibroblasts expressing TrnR2 and Ret are approximately 30-fold more sensitive to NTN than to GDNF treatment, whereas those expressing TrnR1 and Ret respond equivalently to both factors, suggesting the TrnR2-Ret complex acts preferentially as a receptor for NTN. TrnR2 and Ret are expressed in neurons of the superior cervical and dorsal root ganglia, and in the adult brain. Comparative analysis of TrnR1, TrnR2, and Ret expression indicates that multiple receptor complexes, capable of mediating GDNF and NTN signaling, exist in vivo.

Mitofusin 2 is necessary for transport of axonal mitochondria and interacts with the Miro/Milton complex

Mitofusins (Mfn1 and Mfn2) are outer mitochondrial membrane proteins involved in regulating mitochondrial dynamics. Mutations in Mfn2 cause Charcot-Marie-Tooth disease (CMT) type 2A, an inherited disease characterized by degeneration of long peripheral axons, but the nature of this tissue selectivity remains unknown. Here, we present evidence that Mfn2 is directly involved in and required for axonal mitochondrial transport, distinct from its role in mitochondrial fusion. Live imaging of neurons cultured from Mfn2 knock-out mice or neurons expressing Mfn2 disease mutants shows that axonal mitochondria spend more time paused and undergo slower anterograde and retrograde movements, indicating an alteration in attachment to microtubule-based transport systems. Furthermore, Mfn2 disruption altered mitochondrial movement selectively, leaving transport of other organelles intact. Importantly, both Mfn1 and Mfn2 interact with mammalian Miro (Miro1/Miro2) and Milton (OIP106/GRIF1) proteins, members of the molecular complex that links mitochondria to kinesin motors. Knockdown of Miro2 in cultured neurons produced transport deficits identical to loss of Mfn2, indicating that both proteins must be present at the outer membrane to mediate axonal mitochondrial transport. In contrast, disruption of mitochondrial fusion via knockdown of the inner mitochondrial membrane protein Opa1 had no effect on mitochondrial motility, indicating that loss of fusion does not inherently alter mitochondrial transport. These experiments identify a role for mitofusins in directly regulating mitochondrial transport and offer important insight into the cell type specificity and molecular mechanisms of axonal degeneration in CMT2A and dominant optic atrophy.

Expression of Neurturin, GDNF, and GDNF Family-Receptor mRNA in the Developing and Mature Mouse

The GDNF family of neurotrophic factors currently has four members: neurturin (NRTN), glial cell line-derived neurotrophic factor (GDNF), persephin, and artemin. These proteins are potent survival factors for several populations of central and peripheral neurons. The receptors for these factors are complexes that include the Ret tyrosine kinase receptor and a GPI-linked, ligand-binding component called GDNF family receptor alpha 1-4 (GFRalpha1-4). We have used in situ hybridization to study the mRNA expression of NRTN, GDNF, Ret, GFRalpha1, and GFRalpha2 during embryonic development and in the adult mouse. GDNF receptors were prominently expressed during embryonic development in the nervous system, the urogenital system, the digestive system, the respiratory system, and in developing skin, bone, muscle, and endocrine glands. In some regions, incomplete receptor complexes were expressed suggesting that other, as yet unidentified, receptor components exist or that receptor complexes are formed in trans. NRTN and GDNF were expressed in many trigeminal targets during embryonic development including the nasal epithelium, the teeth, and the whisker follicles. NRTN and GDNF were also expressed in the developing limbs and urogenital system. In the embryo, GDNF factors and receptors were expressed at several sites of mesenchyme/epithelial induction, including the kidney, tooth, and submandibular gland. This expression pattern is consistent with the possibility that the GDNF factors function in inductive processes during embryonic development and with the recently discovered role of NRTN as a necessary trophic factor for the development of some parasympathetic neurons. In the mature animal, receptor expression was more limited than in the embryo. In the adult mouse, NRTN was most prominently expressed in the gut, prostate testicle, and oviduct; GDNF was most prominently expressed in the ovary.