David S. Middlemas

trkB, a neural receptor protein-tyrosine kinase: evidence for a full-length and two truncated receptors.

We have screened an adult rat cerebellar cDNA library in search of novel protein tyrosine-kinase (PTK) cDNAs. A cDNA for a putative PTK, trkB, was cloned, and its sequence indicates that it is likely to be derived from a gene for a ligand-regulated receptor closely related to the human trk oncogene. Northern (RNA) analysis showed that the trkB gene is expressed predominantly in the brain and that trkB expresses multiple mRNAs, ranging from 0.7 to 9 kb. Hybridization of cerebral mRNAs with a variety of probes indicates that there are mRNAs encoding truncated trkB receptors. Two additional types of cDNA were isolated, and their sequences are predicted to encode two distinct C-terminally truncated receptors which have the complete extracellular region and transmembrane domain, but which differ in their short cytoplasmic tails.

The neurotrophic factors brain-derived neurotrophic factor and neurotrophin-3 are ligands for the trkB tyrosine kinase receptor

Neurotrophic factors are essential for neuronal survival and function. Recent data have demonstrated that the product of the tyrosine kinase trk proto-oncogene binds NGF and is a component of the high affinity NGF receptor. Analysis of the trkB gene product, gp145trkB, in NIH 3T3 cells indicates that this tyrosine kinase receptor is rapidly phosphorylated on tyrosine residues upon exposure to the NGF-related neurotrophic factors BDNF and NT-3. Furthermore, gp145trkB specifically binds BDNF and NT-3 in NIH 3T3 cells and in hippocampal cells, but does not bind NGF. Thus, the trk family of receptors are likely to be important signal transducers of NGF-related trophic signals in the formation and maintenance of neuronal circuits.

Increased production of the TrkB protein tyrosine kinase receptor after brain insults

The protein-tyrosine kinases Trk, TrkB, and TrkC are signal-transducing receptors for a family of neurotrophic factors known as the neurotrophins. Here we show that seizures induced by hippocampal kindling lead to a rapid, transient increase of trkB mRNA and protein in the hippocampus. TrkB is a component of a high affinity receptor for brain-derived neurotrophic factor (BDNF). No change was detected in mRNAs for Trk or TrkC, components of the high affinity nerve growth factor or neurotrophin-3 receptors, respectively. trkB mRNA was also transiently increased in the dentate gyrus following cerebral ischemia and hypoglycemic coma; these treatments had no effect on trk and trkC mRNAs. The increase in trkB mRNA and protein showed the same time course and distribution as the increase in BDNF mRNA. These data suggest that BDNF and its receptor may play a local role within the hippocampus in kindling-associated neural plasticity and in neuronal protection following epileptic, ischemic, and hypoglycemic insults.

Brain-derived Neurotrophic Factor Promotes Survival and Chemoprotection of Human Neuroblastoma Cells

Brain-derived neurotrophic factor (BDNF) promotes neuronal survival and protection against neuronal damage. We addressed whether BDNF might promote survival and chemoprotection in neuroblastoma (NB) using a drug-sensitive human NB cell line. All-trans-retinoic acid (ATRA) induces a striking phenotypic differentiation of NB1643 cells, and exogenous BDNF treatment promotes survival of these differentiated cells. ATRA induces TRKB expression, and exogenous BDNF stimulates both autophosphorylation of TRKB and induction of the immediate early gene, FOS, in these cells.BDNF mRNA is expressed in NB1643 cells. Because the time course of TRKB induction closely parallels phenotypic differentiation of these cells, it seems probable that ATRA induces differentiation of NB1643 cells by establishing an autocrine loop involving BDNF and TRKB. Exogenous BDNF treatment resulted in a further increase in neurite outgrowth, which again suggests that an autocrine loop is involved in differentiation of NB1643 cells in response to ATRA. We then tested whether BDNF might afford drug resistance in NB and found that BDNF does indeed protect in this NB model against cisplatin, a DNA-damaging agent actually used in the treatment of NB.

Receptor Protein Tyrosine Kinases and Phosphatases

It is clear that the number of receptor PTKs and PTPs encoded by a typical vertebrate genome is rather large. Although the signal pathways activated by the receptor PTKs may in many cases be common, specificity is provided by the ligand-binding domain and the availability of ligand. In addition, the precise spectrum of substrates that bind to and are phosphorylated by each receptor PTK can differ based on the number and nature of the autophosphorylation sites and on the repertoire of SH2-containing proteins and other substrates expressed in each cell type. It is also clear that receptor PTKs can activate multiple independent signaling pathways and that the output of these pathways can be integrated to provide a specific cellular response. The role of receptor PTPs in such integrated signaling networks is not yet obvious. In some cases, they may activate nonreceptor PTKs, whereas in other cases, they may counteract the effects of activated receptor and nonreceptor PTKs by dephosphorylating the PTKs themselves or their substrates. We know very little about the substrate specificity of PTPs, but in part this must be dictated by their subcellular location. It is possible that there are specific pairs of receptor PTKs and PTPs, which act in concert at the cell surface to activate and down-regulate specific signal pathways. Progress in understanding the function of receptor PTPs will depend on identifying ligands for receptor PTPs and then determining how ligand binding influences their activity.

A sleep-inducing peptide from Conus geographus venom

A novel peptide toxin, which causes a sleep-like state upon intracerebral injection in mice, has been purified to homogeneity from the venom of the piscivorous marine snail Conus geographus L. It elicits no obvious effects when injected i.p. into either mice or fish. The purified toxin is a highly acidic heptadecapeptide with no cystine residues (Lys1, Arg1, Asx2, Ser1, Glx7-8, Gly1, Ile1, Leu2). This composition is in marked contrast to those of other conotoxins, which are basic and disulphide-bridged. The N-terminal residue is Gly and the COOH-terminal sequence is Ser-Asn-NH2.

The protein tyrosine phosphatase, Shp2, is required for the complete activation of the RAS/MAPK pathway by brain-derived neurotrophic factor

Brain‐derived neurotrophic factor (BDNF) and other neurotrophins induce a unique prolonged activation of mitogen‐activated protein kinase (MAPK) compared with growth factors. Characterization and kinetic and spatial modeling of the signaling pathways underlying this prolonged MAPK activation by BDNF will be important in understanding the physiological role of BDNF in many complex systems in the nervous system. In addition to Shc, fibroblast growth factor receptor substrate 2 (FRS2) is required for the BDNF‐induced activation of MAPK. BDNF induces phosphorylation of FRS2. However, BDNF does not induce phosphorylation of FRS2 in cells expressing a deletion mutant of TrkB (TrkBΔPTB) missing the juxtamembrane NPXY motif. This motif is the binding site for SHC. NPXY is the consensus sequence for phosphotyrosine binding (PTB) domains, and notably, FRS2 and SHC contain PTB domains. This NPXY motif, which contains tyrosine 484 of TrkB, is therefore the binding site for both FRS2 and SHC. Moreover, the proline containing region (VIENP) of the NPXY motif is also required for FRS2 and SHC phosphorylation, which indicates this region is an important component of FRS2 and SHC recognition by TrkB. Previously, we had found that the phosphorylation of FRS2 induces association of FRS2 and growth factor receptor binding protein 2 (Grb2). Now, we have intriguing data that indicates BDNF induces association of the SH2 domain containing protein tyrosine phosphatase, Shp2, with FRS2. Moreover, the PTB association motif of TrkB containing tyrosine 484 is required for the BDNF‐induced association of Shp2 with FRS2 and the phosphorylation of Shp2. These results imply that FRS2 and Shp2 are in a BDNF signaling pathway. Shp2 is required for complete MAPK activation by BDNF, as expression of a dominant negative Shp2 in cells attenuates BDNF‐induced activation of MAPK. Moreover, expression of a dominant negative Shp2 attenuates Ras activation showing that the protein tyrosine phosphatase is required for complete activation of MAPKs by BDNF. In conclusion, Shp2 regulates BDNF signaling through the MAPK pathway by regulating either Ras directly or alternatively, by signaling components upstream of Ras. Characterization of MAPK signaling controlled by BDNF is likely to be required to understand the complex physiological role of BDNF in neuronal systems ranging from the regulation of neuronal growth and survival to the regulation of synapses.

Brain-derived neurotrophic factor induces phosphorylation of fibroblast growth factor receptor substrate 2.

Brain-derived neurotrophic factor (BDNF) promotes neuronal survival. Gaining an understanding of how BDNF, via the tropomyosin-related kinase B (TRKB) receptor, elicits specific cellular responses is of contemporary interest. Expression of mutant TrkB in fibroblasts, where tyrosine 484 was changed to phenylalanine, abrogated Shc association with TrkB, but only attenuated and did not block BDNF-induced phosphorylation of mitogen-activated protein kinase (MAPK). This suggests there is another BDNF-induced signaling mechanism for activating MAPK, which compelled a search for other TrkB substrates. BDNF induces phosphorylation of fibroblast growth factor receptor substrate 2 (FRS2) in both fibroblasts engineered to express TrkB and human neuroblastoma (NB) cells that naturally express TrkB. Additionally, BDNF induces phosphorylation of FRS2 in primary cultures of cortical neurons, thus showing that FRS2 is a physiologically relevant substrate of TrkB. Data are presented demonstrating that BDNF induces association of FRS2 with growth factor receptor-binding protein 2 (GRB2) in cortical neurons, fibroblasts, and NB cells, which in turn could activate the RAS/MAPK pathway. This is not dependent on Shc, since BDNF does not induce association of Shc and FRS2. Finally, the experiments suggest that FRS2 and suc-associated neurotrophic factor-induced tyrosine-phosphorylated target are the same protein.

The differential regulation of BDNF and TrkB levels in juvenile rats after four days of escitalopram and desipramine treatment.

Major depressive disorder is a major health problem in adults and is now recognized as a substantial problem in children as well. Tricyclic antidepressants, including desipramine (DMI), are no better than placebo in treating childhood and adolescent depression, but are effective in treating adult depression. Several studies have suggested that normal BDNF (brain-derived neurotrophic factor) signaling is necessary for antidepressant drug action. Antidepressant drugs induce several plastic changes in the rodent brain which may be associated with changes in BDNF levels and/or with BDNF function. In the present study we report parallel measurements of BDNF mRNA and protein in the frontal cortex and hippocampus after four days of twice daily treatments with escitalopram, a selective serotonin reuptake inhibitor, and desipramine, a tricyclic antidepressant. Post-natal day 13, 21, 28 and adult rats were used in this study. TrkB (the primary receptor for BDNF) mRNA levels were also examined under the same treatment conditions. BDNF mRNA and protein levels, as well as TrkB mRNA levels, were increased significantly in post-natal day 13 pups after escitalopram treatment as compared to control, but desipramine failed to increase either BDNF or TrkB. The failure of desipramine to increase BDNF and TrkB levels in juvenile rats is consistent with the lack of efficacy of desipramine in children and adolescents. The serotonergic nervous system matures earlier than the noradrenergic system, which may explain why escitalopram, but not desipramine, increases BDNF and TrkB levels.

Brain Derived Neurotrophic Factor Protects Human Neuroblastoma Cells from DNA Damaging Agents

Neurotrophins are required for survival of neurons during development and may act as survival factors to cells undergoing stress. We tested whether brain derived neurotrophic factor (BDNF) protects neuroblastoma (NB) cells from cytotoxic agents using a model NB cell line, NB 1643, which expresses functional tropomyosin related kinase B (TRKB) following treatment with all-trans-retinoic acid. TRKB is the receptor for BDNF. BDNF increases the EC50 values in survival assays for cisplatin, doxorubicin, and topotecan by two to three fold. Thus, BDNF does indeed protect cells drugs that damage DNA. Cisplatin and doxorubicin are used to treat NB. Topotecan is in clinical studies for the treatment of NB. Since these drugs induce DNA damage, we also investigated whether BDNF might afford protection from γ irradiation. BDNF also induces more than a two fold resistance to γ irradiation. Since BDNF protects cells from agents with different mechanisms of damaging DNA and resistance, it seems likely that BDNF may alter a common signaling pathway required for cell death initiation by DNA damaging agents.