WEST LAFAYETTE, Ind., Apr 14, 2009 (ASCRIBE NEWS via COMTEX) -- Researchers
have uncovered new evidence suggesting factors other than genes could cause
obesity, finding that genetically identical cells store widely differing amounts
of fat depending on subtle variations in how cells process insulin.
Learning the precise mechanism responsible for fat storage in cells could lead
to methods for controlling obesity.
"Insights from our study also will be important for understanding the precise
roles of insulin in obesity or Type II diabetes, and to the design of effective
intervention strategies," said Ji-Xin Cheng, an assistant professor in Purdue
University's Weldon School of Biomedical Engineering and Department of
Chemistry.
Findings indicate that the faster a cell processes insulin, the more fat it
stores.
Other researchers have suggested that certain "fat genes" might be associated
with excessive fat storage in cells. However, the Purdue researchers confirmed
that these fat genes were expressed, or activated, in all of the cells, yet
those cells varied drastically - from nearly zero in some cases to pervasive in
others - in how much fat they stored.
The researchers examined a biological process called adipogenesis, using
cultures of a cell line called 3T3-L1, which is often used to study fat cells.
In adipogenesis, these cells turn into fat.
"This work supports an emerging viewpoint that not all biological information in
cells is encoded in the genetic blueprint," said Thuc T. Le, a National
Institutes of Health postdoctoral fellow at Purdue who is working with Cheng.
"We found that the variability in fat storage is dependent on how 3T3-L1 cells
process insulin, a hormone secreted by the pancreas after meals to trigger the
uptake of glucose from the blood into the liver, muscle or fat cells."
The findings are detailed in a research paper appearing online in the journal
PLoS ONE, published by the Public Library of Science, a non- profit organization
of scientists and physicians.
"This varied capability to store fat among genetically identical cells is a
well-observed but poorly understood phenomenon," Cheng said
The researchers determined that these differences in fat storage depend not on
fat-gene expression but on variations in a cascade of events within an
"insulin-signaling pathway." The pathway enables cells to take up glucose from
the blood.
"Only one small variation at the beginning of the cascade can lead to a drastic
variation in fat storage at the end of the cascade," Cheng said.
The researchers conducted "single cell profiling" using a combination of imaging
techniques to precisely compare fat storage in cloned cells having the same fat
genes expressed.
Single cell profiling allows researchers to precisely compare the inner workings
of individual cells, whereas the conventional analytical approach in
biochemistry measures entire populations of cells and then provides data
representing an average.
"In this case, we don't want an average. We need to find out what causes fat
storage at the single-cell level so that we can compare one cell to another, "
Le said. "By profiling multiple events in single cells, we found that
variability in fat storage is due to varied rates of insulin processing among
cells."
The cell culture used in the research contains cloned mice fibroblast cells.
"This particular type of cell culture has been used to study the molecular
control of obesity for the past 35 years," Cheng said. "Researchers have
observed tremendous variability in how much fat is stored in cells with
identical genes, but no one really knows why. Our findings have shed some light
on this phenomenon."
The researchers used a specialized imaging method called coherent anti- Stokes
Raman scattering, or CARS, combined with other techniques, including flow
cytometry and fluorescence microscopy.
"This multimodal imaging system allows us to correlate different events, like
fat storage, gene expression and insulin signaling," Le said. "We can monitor
these different events at the same time, and that's why we can determine the
mechanism at the single-cell level."
Insulin attaches to binding sites on cell membranes, signaling the cells to take
up glucose from the blood. Cells that are said to be resistant to insulin fail
to take up glucose, the primary cause of Type II diabetes, a medical condition
affecting nearly 24 million Americans. About two-thirds of U.S. adults are
overweight, and nearly one-third obese.
The research, which has been funded by the National Institutes of Health, is
ongoing. Future work may seek to pinpoint specific events in the
insulin-signaling cascade that are responsible for fat storage.
- - - -
Writer: Emil Venere, 765-494-4709, venere@purdue.edu
Sources: Ji-Xin Cheng, 765-494-4335, jcheng@purdue.edu
Thuc T. Le, 765-496-9717, let@purdue.edu
NOTE TO JOURNALISTS: An electronic copy of the research paper is available from
Emil Venere, 765-494-4709, venere@purdue.edu. Abstract on the research in this
release is available at:
http://news.uns.purdue.edu/x/2009a/090414ChengFatgenes.html
RELATED WEB SITES:
Ji-Xin Cheng: https://engineering.purdue.edu/BME/research/labs/cheng
Weldon School of Biomedical Engineering: http://www.purdue.edu/BME
PHOTO: A publication-quality photo is available at
http://news.uns.purdue.edu/images/+2009/cheng-fatgenes.jpg
PHOTO CAPTION: Purdue researchers have uncovered new evidence that factors other
than genes could cause obesity, finding that genetically identical cells store
widely differing amounts of fat depending on subtle variations in how cells
process insulin. Here, insulin (green) is present in cells with no fat storage
and absent in cells with fat storage at two days after insulin addition. This
observation indicates faster insulin processing rates in cells with fat storage.
Fluorophore-labeled insulin (green) is visualized with fluorescence imaging, and
fat is visualized withcoherent anti-Stokes Raman scattering - or CARS - imaging
(red/white). (Weldon School of Biomedical Engineering, Purdue University)