New Theory Offered on Memory

X-Message-Number: 26627
From: "Basie" <>
Subject: New Theory Offered on Memory
Date: Fri, 15 Jul 2005 14:53:33 -0400

New Theory Offered on Memory

By Elizabeth Crown

How do you remember your own name? Is it possible ever to forget it? The 
memory trace, or engram, "feels" like it is stored permanently in the brain, 
and it will never be forgotten.

Indeed, the current view of memory is that, at the molecular level, new 
proteins are manufactured in a process known as translation and these newly 
synthesized proteins subsequently stabilize the changes underlying the 
memory. Thus, every new memory results in a permanent representation in the 
brain.

But Northwestern University neuroscientist Aryeh Routtenberg, PhD, has 
presented a provocative new theory that takes issue with that view. Dr. 
Routtenberg, with doctoral student Jerome L. Rekart, outlined the new theory 
on memory storage in the January issue of the journal Trends in 
Neuroscience.

Rather than permanent storage, a "dynamic, meta-stable" process exists, the 
authors said. Our subjective experience of permanence is a result of the 
re-duplication of memories across many different brain networks.

For example, one's name is represented in innumerable neural circuits; thus, 
it is extremely difficult to forget. But each individual component is 
malleable and transient, and as no particular neural network lasts a 
lifetime, it is theoretically possible to forget one's own name. This is 
seen in the most advanced stages of Alzheimer's disease, the researchers 
stated.

The advantage of such a precarious storage mechanism is that it is highly 
flexible, enabling rapid retrieval even of infrequent elements, with great 
advantages over models of permanent storage, said Dr. Routtenberg, professor 
in the Departments of Psychology and Neurobiology and Physiology in the Judd 
A. and Marjorie Weinberg College of Arts and Sciences and a leading 
researcher in the Northwestern University Institute for Neuroscience.

To achieve this high degree of flexibility, Dr. Routtenberg proposes that 
the brain stores long-term memory by rapidly changing the shape of proteins 
already present at those synapses activated by learning.

While it is universally agreed that brain proteins are critical for memory 
storage, Dr. Routtenberg's hypothesis challenges the widely accepted, 
40-year-old model that long-term memories are stabilized only once newly 
synthesized proteins are transported to recently activated synapses.

Indeed, this view is central to the theory of Eric Kandel, who in his Nobel 
Prize address reinforced the central position of this model in forming 
long-term memory.

So does memory form because you make more protein, as most neuroscientists 
believe, or because you change the shape of existing proteins, which are 
known to be strategically located to effect change within milliseconds of 
activation?

Part of the answer to this question lies in the fact that critical 
weaknesses can be found in the prevailing view.

"Enough instances occur of memory storage in the virtual absence of protein 
synthesis to compel consideration of alternative models," said Dr. 
Routtenberg.

The authors noted that most of the evidence supporting the current view was 
obtained by studying the effects of drugs called protein synthesis 
inhibitors on memory, leading to the conclusion that synthesis was 
necessary. The authors outline specific evidence that calls those results 
into question.

For example, synthesis inhibitors that block the production of new proteins 
by more than 90 percent often cause no discernible memory impairments. 
Additionally, protein synthesis inhibitors cause a number of side effects 
that could lead to memory loss caused by something other than protein 
synthesis inhibition.

Dr. Routtenberg agrees that the synapse is modified in response to 
learning-associated activity, a position first articulated by Nobelist Ramon 
y Cajal a century ago. But the difference with the current theory is that he 
and Rekart do not believe that synaptic modification is brought about by 
recently synthesized proteins.

Dr. Routtenberg's theory, derived from extensive, fundamental biochemical 
information, advocates that learning leads to a post-synthesis (or 
post-translational) synaptic protein modification that results in changes to 
the shape, activity, and/or location of existing synaptic proteins. In the 
Routtenberg-Rekart proposal, this is the only mechanism required for 
long-term memory.

To maintain some residue of this modification, Dr. Routtenberg proposes that 
the "spontaneous activity" of the brain acts to "cryptically rehearse" past 
events. So long-term memory storage relies on a positive-feedback rehearsal 
system that continually updates or fine-tunes post-translational 
modification of previously modified synaptic proteins. This model allows for 
the continual modifications of memories.

In the Routtenberg-Rekart model, post-translational modifications within 
cells and synaptic dialog and endogenous activity between cells and networks 
work in concert to perpetuate and update memory representations.

A group of post-translational protein modifications that affect neuronal 
plasticity-present in activated pre-synaptic and post-synaptic elements and 
regulated by proteases, kinases and phosphatases-regulate the efficacy of 
the synapse in response to a learning event.

These modifications are, in turn, maintained via positive feedback between 
cells (dialog), which are regulated by synaptic excitation (for example, via 
the neurotransmitter glutamate) or inhibition (via the neurotransmitter 
GABA).

Thus, the self-sustaining positive feedback system also carries built-in 
control mechanisms that would prevent runaway feedback leading to the 
detonation of one massive memory or "thermonuclear" engram.

Although Dr. Routtenberg's model may represent a radical departure from the 
current view of how long-term memories are stored, he believes that 
scientists need to articulate alternative models other than the prevailing 
one.

A more accurate description will help address issues of memory loss in 
mental retardation, aging, and Alzheimer's disease. Indeed, new hypotheses 
can lead to the development of new chemical agents that would successfully 
target the chemical reactions necessary.

"Enough substance exists both in the concerns raised and in the 
post-translational modification/positive feedback model proposed to energize 
the search for yet more plausible models of long-term memory storage and to 
redirect and reinvigorate the quest to understand the brain substrates of 
information storage," Dr. Routtenberg said.

This research was supported by research grants from the National Institute 
of Mental Health (NIMH) and National Science Foundation and a training grant 
from the NIMH.

http://www.medschool.northwestern.edu/newsworthy/2005L-January/memory.html


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If we are merely the shapes of proteins in the synapses then duplication 
should be easy. On the other hand if memories are constantly rehearsed then 
errors will occur. Thus an eternal identity is impossible. That will make 
the argument whether a copy is real moot. I hope Routtenberg is wrong.

Basie

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