The economic life of cells
Theory from microeconomics used to predict how biological systems respond
to environmental change
Date:
July 13, 2023
Source:
University of Tokyo
Summary:
A team has combined economic theory with biology to understand
how natural systems respond to change. The researchers noticed a
similarity between consumers' shopping behavior and the behavior
of metabolic systems, which convert food into energy in our
bodies. The team focused on predicting how different metabolic
systems might respond to environmental change by using an economic
tool called the Slutsky equation. Their calculations indicated
that very different metabolic systems actually share previously
unknown universal properties, and can be understood using tools
from other academic fields. Metabolic processes are used in drug
development, bioengineering, food production and other industries,
so being able to predict how such systems will respond to change
can offer many benefits.
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FULL STORY ==========================================================================
A team from the University of Tokyo has combined economic theory
with biology to understand how natural systems respond to change. The researchers noticed a similarity between consumers' shopping behavior and
the behavior of metabolic systems, which convert food into energy in our bodies. The team focused on predicting how different metabolic systems
might respond to environmental change by using an economic tool called
the Slutsky equation. Their calculations indicated that very different metabolic systems actually share previously unknown universal properties,
and can be understood using tools from other academic fields. Metabolic processes are used in drug development, bioengineering, food production
and other industries, so being able to predict how such systems will
respond to change can offer many benefits.
Where do you get your energy from? Perhaps a long night's sleep, or a
good breakfast and some exercise? These activities can all help as they
support a healthy metabolism, the chemical processes by which our bodies convert food and drink into energy. Understanding how individual metabolic reactions behave and predicting how they may change under different circumstances is a big challenge. There are thousands of different
reactions which enable us to move, think, grow -- in short, to live. In
recent years, it has become possible to predict some reactions through numerical simulations, but this requires large amounts of data. However, researchers at the University of Tokyo have derived previously unknown universal properties of metabolic systems by applying microeconomic
theory to their data.
"Until this research, we thought that metabolic systems varied so much
among species and cell types that there were no common properties among
them," explained Assistant Professor Tetsuhiro Hatakeyama from the
Graduate School of Arts and Sciences. "However, we were very excited to demonstrate that all metabolic systems have universal properties, and
that these properties can be expressed by very simple laws."According to
the researchers, this theory does not require as much detailed background
data to be collected as other methods.
It can also be effectively applied whether you are trying to understand
the behavior of all metabolic processes in a cell or focusing on just
one part - - say, for example, how much oxygen it is using.
Hatakeyama, a biophysicist, was looking at some metabolic system diagrams
when he noticed a striking similarity to diagrams used in economics. This realization inspired him to try an interdisciplinary approach and
apply economic theory, which he had briefly studied, to his biology
research. Along with co-author Jumpei Yamagishi, a graduate student in
the same lab, he decided to explore how both consumers and cells optimize
their "spending" to maximize gain: Whereas we as consumers spend money,
cells "spend" nutrients. They reasoned if there were similarities in this
way, then perhaps the same theories that are used to identify patterns in consumer behavior under changing financial situations could also identify patterns in cellular metabolic behavior under changing environments.
More specifically, the researchers focused on the Slutsky equation,
which is used to understand changes in consumer demand. In particular,
it is used to understand so-called Giffen goods, which counterintuitively
go up in demand when the price increases and go down in demand when the
price decreases.
According to Hatakeyama, this is similar to cellular metabolic behavior
in response to a disturbance. For example, respiration demand (the Giffen
goods in this case) in cancer cells goes up, counterintuitively, with
increased drug dosage (the "price"), even though this is not beneficial
to the growth rate of the cancer. The outcome was that the team uncovered
a universal law for how metabolic systems respond to change.
One of the key benefits of this law is that it can be used to understand metabolic systems about which few details are known. "Disturbances in
metabolic systems lead to a variety of diseases, and our research could be
used to propose new treatment strategies for diseases for which treatments
are not fully understood," said Hatakeyama. "In addition, many foods and medicines are made using the metabolic systems of organisms. By applying
the simple equation found in this study, we can know how to increase
the output of products made with these systems." Hatakeyama hopes that
through further interdisciplinary research, more universal laws might
be discovered that will lead to a variety of useful applications.
* RELATED_TOPICS
o Health_&_Medicine
# Fitness # Diet_and_Weight_Loss # Staying_Healthy
o Plants_&_Animals
# Biotechnology_and_Bioengineering # Veterinary_Medicine
# New_Species
o Computers_&_Math
# Mathematical_Modeling # Communications # Robotics
* RELATED_TERMS
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Computer_simulation o Global_climate_model
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========================================================================== Journal Reference:
1. Jumpei F. Yamagishi, Tetsuhiro S. Hatakeyama. Linear Response
Theory of
Evolved Metabolic Systems. Physical Review Letters, 2023; 131 (2)
DOI: 10.1103/PhysRevLett.131.028401 ==========================================================================
Link to news story:
https://www.sciencedaily.com/releases/2023/07/230713141932.htm
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