Jason Aoto

Publications (6)39.97 Total impact

• Source

  Available from: PubMed Central

  Article: Conditional RARα knockout mice reveal acute requirement for retinoic acid and RARα in homeostatic plasticity.

  Federica Sarti, Jessica Schroeder, Jason Aoto, Lu Chen
  [show abstract] [hide abstract]
  ABSTRACT: All-trans retinoic acid (RA) plays important roles in brain development through regulating gene transcription. Recently, a novel post-developmental role of RA in mature brain was proposed. Specifically, RA rapidly enhanced excitatory synaptic transmission independent of transcriptional regulation. RA synthesis was induced when excitatory synaptic transmission was chronically blocked, and RA then activated dendritic protein synthesis and synaptic insertion of homomeric GluA1 AMPA receptors, thereby compensating for the loss of neuronal activity in a homeostatic fashion. This action of RA was suggested to be mediated by its canonical receptor RARα but no genetic evidence was available. Thus, we here tested the fundamental requirement of RARα in homeostatic plasticity using conditional RARα knockout (KO) mice, and additionally performed a structure-function analysis of RARα. We show that acutely deleting RARα in neurons eliminated RA's effect on excitatory synaptic transmission, and inhibited activity blockade-induced homeostatic synaptic plasticity. By expressing various RARα rescue constructs in RARα KO neurons, we found that the DNA-binding domain of RARα was dispensable for its role in regulating synaptic strength, further supporting the notion that RA and RARα act in a non-transcriptional manner in this context. By contrast, the ligand-binding domain (LBD) and the mRNA-binding domain (F-domain) are both necessary and sufficient for the function of RARα in homeostatic plasticity. Furthermore, we found that homeostatic regulation performed by the LBD/F-domains leads to insertion of calcium-permeable AMPA receptors. Our results confirm with unequivocal genetic approaches that RA and RARα perform essential non-transcriptional functions in regulating synaptic strength, and establish a functional link between the various domains of RARα and their involvement in regulating protein synthesis and excitatory synaptic transmission during homeostatic plasticity.
  Frontiers in Molecular Neuroscience 01/2012; 5:16.
• Article: Retinoic acid regulates RARalpha-mediated control of translation in dendritic RNA granules during homeostatic synaptic plasticity.

  Bita Maghsoodi, Michael M Poon, Christine I Nam, Jason Aoto, Pamela Ting, Lu Chen
  [show abstract] [hide abstract]
  ABSTRACT: Homeostatic plasticity is thought to play an important role in maintaining the stability of neuronal circuits. During one form of homeostatic plasticity, referred to as synaptic scaling, activity blockade leads to a compensatory increase in synaptic transmission by stimulating in dendrites the local translation and synaptic insertion of the AMPA receptor subunit GluR1. We have previously shown that all-trans retinoic acid (RA) mediates activity blockade-induced synaptic scaling by activating dendritic GluR1 synthesis and that this process requires RARalpha, a member of the nuclear RA receptor family. This result raised the question of where RARalpha is localized in dendrites and whether its localization is regulated by RA and/or activity blockade. Here, we show that activity blockade or RA treatment in neurons enhances the concentration of RARalpha in the dendritic RNA granules and activates local GluR1 synthesis in these RNA granules. Importantly, the same RNA granules that contain RARalpha also exhibit an accumulation of GluR1 protein but with a much slower time course than that of RARalpha, suggesting that the former regulates the latter. Taken together, our results provide a direct link between dendritically localized RARalpha and local GluR1 synthesis in RNA granules during RA-mediated synaptic signaling in homeostatic synaptic plasticity.
  Proceedings of the National Academy of Sciences 11/2008; 105(41):16015-20. · 9.68 Impact Factor
• Article: Synaptic signaling by all-trans retinoic acid in homeostatic synaptic plasticity.

  Jason Aoto, Christine I Nam, Michael M Poon, Pamela Ting, Lu Chen
  [show abstract] [hide abstract]
  ABSTRACT: Normal brain function requires that the overall synaptic activity in neural circuits be kept constant. Long-term alterations of neural activity lead to homeostatic regulation of synaptic strength by a process known as synaptic scaling. The molecular mechanisms underlying synaptic scaling are largely unknown. Here, we report that all-trans retinoic acid (RA), a well-known developmental morphogen, unexpectedly mediates synaptic scaling in response to activity blockade. We show that activity blockade increases RA synthesis in neurons and that acute RA treatment enhances synaptic transmission. The RA-induced increase in synaptic strength is occluded by activity blockade-induced synaptic scaling. Suppression of RA synthesis prevents synaptic scaling. This form of RA signaling operates via a translation-dependent but transcription-independent mechanism, causes an upregulation of postsynaptic glutamate receptor levels, and requires RARalpha receptors. Together, our data suggest that RA functions in homeostatic plasticity as a signaling molecule that increases synaptic strength by a protein synthesis-dependent mechanism.
  Neuron 11/2008; 60(2):308-20. · 14.74 Impact Factor
• Article: Bidirectional ephrin/Eph signaling in synaptic functions.

  Jason Aoto, Lu Chen
  [show abstract] [hide abstract]
  ABSTRACT: Eph receptors, the largest family of receptor tyrosine kinases, and their membrane bound ligands, the ephrins, are involved in multiple developmental and adult processes within and outside of the nervous system. Bi-directional signaling from both the receptor and the ligand is initiated by ephrin-Eph binding upon cell-cell contact, and involves interactions with distinct subsets of downstream signaling molecules related to specific functions. In the CNS, Ephs and ephrins act as attractive/repulsive, migratory and cell adhesive cues during development and participate in synaptic functions in adult animals. In this review, we will focus on recent findings highlighting the functions of ephrin/Eph signaling in dendritic spine morphogenesis, synapse formation and synaptic plasticity.
  Brain Research 01/2008; 1184:72-80. · 2.73 Impact Factor
• Article: Postsynaptic ephrinB3 promotes shaft glutamatergic synapse formation.

  Jason Aoto, Pamela Ting, Bita Maghsoodi, Nanjie Xu, Mark Henkemeyer, Lu Chen
  [show abstract] [hide abstract]
  ABSTRACT: Excitatory synapses in the CNS are formed on both dendritic spines and shafts. Recent studies show that the density of shaft synapses may be independently regulated by behavioral learning and the induction of synaptic plasticity, suggesting that distinct mechanisms are involved in regulating these two types of synapses. Although the molecular mechanisms underlying spinogenesis and spine synapse formation are being delineated, those regulating shaft synapses are still unknown. Here, we show that postsynaptic ephrinB3 expression promotes the formation of glutamatergic synapses specifically on the shafts, not on spines. Reducing or increasing postsynaptic ephrinB3 expression selectively decreases or increases shaft synapse density, respectively. In the ephrinB3 knock-out mouse, although spine synapses are normal, shaft synapse formation is reduced in the hippocampus. Overexpression of glutamate receptor-interacting protein 1 (GRIP1) rescues ephrinB3 knockdown phenotype by restoring shaft synapse density. GRIP1 knockdown prevents the increase in shaft synapse density induced by ephrinB3 overexpression. Together, our results reveal a novel mechanism for independent modulation of shaft synapses through ephrinB3 reverse signaling.
  Journal of Neuroscience 08/2007; 27(28):7508-19. · 7.11 Impact Factor
• Article: Cell-autonomous notch signaling regulates endothelial cell branching and proliferation during vascular tubulogenesis.

  Richard C A Sainson, Jason Aoto, Martin N Nakatsu, Matthew Holderfield, Erin Conn, Erich Koller, Christopher C W Hughes
  [show abstract] [hide abstract]
  ABSTRACT: The requirement for notch signaling during vascular development is well-documented but poorly understood. Embryonic and adult endothelial cells (EC) express notch and notch ligands; however, the necessity for cell-autonomous notch signaling during angiogenesis has not been determined. During angiogenesis, EC display plasticity, whereby a subset of previously quiescent cells loses polarity and becomes migratory. To investigate the role of notch in EC, we have used a three-dimensional in vitro system that models all of the early steps of angiogenesis. We find that newly forming sprouts are composed of specialized tip cells that guide the sprout and trunk cells that proliferate and rearrange to form intercellular lumens. Furthermore, we find that notch acts cell-autonomously to suppress EC proliferation, thereby regulating tube diameter. In addition, when notch signaling is blocked, tip cells divide, and both daughter cells take on a tip cell phenotype, resulting in increased branching through vessel bifurcation. In contrast, notch signaling is not required for re-establishment of EC polarity or for lumen formation. Thus, notch is used reiteratively and cell-autonomously by EC to regulate vessel diameter, to limit branching at the tip of sprouts, and to establish a mature, quiescent phenotype.
  The FASEB Journal 07/2005; 19(8):1027-9. · 5.71 Impact Factor