TMT proteomic data from mouse cortical neurons

By Odetta Antico, Alban Ordureau, Michael Stevens, Francois Singh, Marek Gierlinski, Erica Barini, Mollie L. Rickwood, Alan Prescott, Rachel Toth, Ian G. Ganley, J. Wade Harper and Miratul Muqit
View Published Dataset

Output Details

Description
TMT proteomic data from mouse cortical neurons
Identifier (DOI)
10.1101/2021.04.01.438131
Tags
  • Cortical
  • In Vitro
  • Mouse
  • Neurons
  • Protein
  • Proteins
  • Proteomics
Team
Team Harper
Program
Collaborative Research Network
Theme
PD Functional Genomics

Meet the Authors

  • User avatar fallback logo

    Odetta Antico

  • User avatar fallback logo

    Alban Ordureau

  • User avatar fallback logo

    Michael Stevens

  • User avatar fallback logo

    Francois Singh

  • User avatar fallback logo

    Marek Gierlinski

  • User avatar fallback logo

    Erica Barini

  • User avatar fallback logo

    Mollie L. Rickwood

  • User avatar fallback logo

    Alan Prescott

  • User avatar fallback logo

    Rachel Toth

  • User avatar fallback logo

    Ian G. Ganley

  • J. Wade Harper

    Lead PI (Core Leadership): Team Harper

    Harvard University

  • Miratul Muqit

    Co-PI (Core Leadership): Team Alessi

    University of Dundee

Related Research

A data-driven single-cell and spatial transcriptomic map of the human prefrontal cortex

A data-driven molecular map of the DLPFC reveals distinct spatial domains and cell populations, offering insights into neuropsychiatric disorders. The study provides a roadmap for implementing spatial clustering approaches in the human brain.

View Article

Datasets and Key Resources Table used in Do, Quyen B. et al. (2023) “Early striatal hyperexcitability in an in vitro human striatal microcircuit model carrying the Parkinson’s GBA-N370S mutation”

The files found here are associated to Do, Q. et al (2023) study and contain: (a) all source and supplementary data, (b) Key Resources Table, and (c) list of primers.

View Dataset

Early deficits in an in vitro striatal microcircuit model carrying the Parkinson’s GBA-N370S mutation

The results highlight the unique utility of modeling striatal neurons in a modular and highly physiological circuit, which is essential to reveal mechanistic insights of the loss of electrical functional integrity in the striata of GBA1 PD patients.

View Article
View More Outputs