Memory dynamics: the cellular architecture of systems memory

Award Number
BB/S013199/1
Programme
Research Grant
Status / Stage
Active
Dates
15 May 2019 -
3 October 2023
Duration (calculated)
04 years 04 months
Funder(s)
BBSRC (UKRI)
Funding Amount
£417,910.00
Funder/Grant study page
BBSRC UKRI
Contracted Centre
University of Bristol
Principal Investigator
Professor Matt Jones
PI Contact
Matt.Jones@bristol.ac.uk
PI ORCID
0000-0001-5396-3108
WHO Catergories
Understanding Underlying Disease
Disease Type
Dementia (Unspecified)

CPEC Review Info
Reference ID753
ResearcherReside Team
Published07/07/2023

Data

Award NumberBB/S013199/1
Status / StageActive
Start Date20190515
End Date20231003
Duration (calculated) 04 years 04 months
Funder/Grant study pageBBSRC UKRI
Contracted CentreUniversity of Bristol
Funding Amount£417,910.00

Plain English Summary

The human brain contains approximately 80 billion nerve cells (neurons). When you learn something new, which of those neurons will be involved in storing that information? Are all neurons equal, or are some more likely than others to store memories? Will a memory always involve the same neurons? Or will the memory trace (known as an ‘engram’) change over time, allowing you to file memories appropriately, remembering the important information and updating the engram with new knowledge? These questions are all very challenging to answer. But if we do not answer them, we can never understand how the brain works, or how to treat memory disorders associated with illnesses such as dementia, depression and schizophrenia. Over the past few years, technology has advanced to the point at which we can – at least in mice – “capture” the groups of neurons involved in learning a specific memory. These neurons are known as ‘engram neurons’, and were first discovered in a part of the brain called the hippocampus, which acts as a central indexing system for memory files in all mammals. We can activate engram neurons (to trigger recall of the memory) or silence them (to delete a memory). These methods have transformed our understanding of memory mechanisms over the past 2 years, but they are very new and evolving rapidly, as is out ability to measure brain activity from hundreds of neurons simultaneously. In this 3-year series of experiments, we will combine capture of engram neurons with recording the activity from large populations of neurons in mouse hippocampus and connected brain regions to translate the algorithms used by engram neurons to learn, process and remember new information. This project would not be possible without the international team of neuroscientists involved, which spans the UK and Japan, uniting complementary expertise in genetics, psychology, computational analyses and electrical engineering. We will also measure, for the first time, the activity of engram neurons during sleep. We have known for 2000 years that sleep supports healthy memory, but we still do not know precisely how. Now we have discovered engram neurons, the answers may be within reach. Given that your entire personality and worldview are products of the many memory engrams stored by your brain, neuroscience of this type remains essential if we are to understand the fundamental biology of life and disease.

Aims

In this 3-year series of experiments, we will combine capture of engram neurons with recording the activity from large populations of neurons in mouse hippocampus and connected brain regions to translate the algorithms used by engram neurons to learn, process and remember new information. This project would not be possible without the international team of neuroscientists involved, which spans the UK and Japan, uniting complementary expertise in genetics, psychology, computational analyses and electrical engineering.