Essential Role of Hrs in Endocytic Recycling of Full-length TrkB Receptor
but Not Its Isoform
TrkB.T1 |
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Authors: | Shu-Hong Huang Ling Zhao Zong-Peng Sun Xue-Zhi Li Zhao Geng Kai-Di Zhang Moses V Chao and Zhe-Yu Chen |
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Institution: | ‡Department of Neurobiology, Key Laboratory of Medical Neurobiology, School of Medicine, and ¶Key Laboratory of Cardiovascular Remodeling and Function Research, Chinese Ministry of Education and Chinese Ministry of Health, Qilu Hospital, Shandong University, Jinan, Shandong 250012, China and the §Departments of Cell Biology, Physiology, and Neuroscience and Psychiatry, New York University School of Medicine, New York, New York 10016 |
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Abstract: | Brain-derived neurotrophic factor (BDNF) signaling through its receptor,
TrkB, modulates survival, differentiation, and synaptic activity of neurons.
Both full-length TrkB (TrkB-FL) and its isoform T1 (TrkB.T1) receptors are
expressed in neurons; however, whether they follow the same endocytic pathway
after BDNF treatment is not known. In this study we report that TrkB-FL and
TrkB.T1 receptors traverse divergent endocytic pathways after binding to BDNF.
We provide evidence that in neurons TrkB.T1 receptors predominantly recycle
back to the cell surface by a “default” mechanism. However,
endocytosed TrkB-FL receptors recycle to a lesser extent in a hepatocyte
growth factor-regulated tyrosine kinase substrate (Hrs)-dependent manner which
relies on its tyrosine kinase activity. The distinct role of Hrs in promoting
recycling of internalized TrkB-FL receptors is independent of its
ubiquitin-interacting motif. Moreover, Hrs-sensitive TrkB-FL recycling plays a
role in BDNF-induced prolonged mitogen-activated protein kinase (MAPK)
activation. These observations provide evidence for differential postendocytic
sorting of TrkB-FL and TrkB.T1 receptors to alternate intracellular
pathways.Brain-derived neurotrophic factor
(BDNF)3 has been shown
to play critical roles in vertebrate nervous system development and function
(1–3).
The actions of BDNF are dictated by two classes of cell surface receptors, the
TrkB receptor and the p75 neurotrophin receptor. BDNF binding to TrkB
receptors activates several signaling cascades, including phosphatidylinositol
3-kinase, phospholipase C, and Ras/mitogen-activated protein kinase (MAPK)
pathways, that mediate growth and survival responses to BDNF
(1,
4,
5). It has been established
that upon binding neurotrophins, Trk receptors are rapidly endocytosed in a
clathrin-dependent manner (6,
7). Postendocytic sorting of
Trk receptors to diverse pathways after ligand binding has a significant
impact on the physiological responses to neurotrophins because they also
determine the strength and duration of intracellular signaling cascades
initiated by activated Trk receptors
(8). Three alternate endocytic
pathways that Trk receptors can follow are trafficking to lysosomes for
degradation, recycling back to the plasma membrane, or being retrogradely
transported
(9–13).
The degradative pathway to lysosomes is characterized by down-regulation of
the total number of receptors at the cell surface and a decreased response to
ligand. Conversely, recycling of receptors back to the plasma membrane can
lead to functional resensitization and prolongation of cell surface-specific
signaling events. A recent study has shown that recycled and re-secreted BDNF
plays an important role in mediating the maintenance of long term potentiation
in hippocampal slices, which suggests a potential role of TrkB recycling in
long term potentiation regulation
(14).Different TrkB isoforms, including the full-length TrkB (TrkB-FL) and three
truncated isoforms named TrkB.T1, TrkB.T2, and TrkB.T-Shc, exist in the
mammalian central nervous system because of alternative splicing
(15–17).
Truncated TrkB.T1 receptor lacks the kinase domain but contains short
isoform-specific cytoplasmic domain in its place
(15,
16). Many neuronal
populations, including hippocampal and cortical neurons, express both
full-length and truncated TrkB receptors
(18,
19). TrkB.T1 is expressed at
low levels in the prenatal rodent brain, but its expression increases
postnatally, ultimately exceeding the level of full-length TrkB in adulthood
(19–22).
The physiological function of the TrkB.T1 receptor remains unclear, but it may
serve as dominant-negative regulator of full-length TrkB receptors
(23–25),
may sequester ligand and limit diffusion
(26,
27), may regulate cell
morphology and dendritic growth
(28,
29), and may even autonomously
activate signaling cascades in a neurotrophin-dependent manner
(30). TrkB-FL and TrkB.T1 are
localized to both somatodendritic and axonal compartments in neurons
(31); however, little is known
about TrkB.T1 endocytic trafficking fate upon BDNF treatment.In this study we conducted an analysis of the postendocytic fates
(degradation and recycling) of TrkB-FL and TrkB.T1 receptors in PC12 cells and
neurons. We have determined that, unlike TrkB-FL, TrkB.T1 receptors recycle
more efficiently in a default pathway to plasma surface after internalization,
which is independent of hepatocyte growth factor-regulated tyrosine kinase
substrate (Hrs). Conversely, Hrs could bind with TrkB-FL in a kinase
activity-dependent manner and regulate TrkB-FL receptors postendocytic
recycling. Hrs was identified as a tyrosine-phosphorylated protein in cells
stimulated with growth factors and cytokines
(32). Hrs is expressed in the
cytoplasm of all cells and is predominantly localized to endosomes
(33). Hrs has also been
proposed to play a role in regulating cell surface receptor postendocytic
trafficking (34). These
observations provide evidence for differential postendocytic sorting to
alternate intracellular pathways between TrkB-FL and TrkB.T1 receptors after
internalization. |
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