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Naturally fluorescent molecules may serve as cancer biomarker
April 03, 2009Excess amounts of a naturally fluorescent molecule found in all living cells could serve as a natural biomarker for cancer, according to bioengineers.
NADH, or nicotinamide adenine dinucleotide, is a key coenzyme -- a non-protein molecule necessary for the functioning of an enzyme -- found mostly in the inner membrane of a cell's power plant, or mitochondria. It fuels a series of biochemical reactions that involve various enzymes to produce ATP, the major energy source in cells. In the event of disease or a metabolic disorder, these enzymes and their related reactions can become disabled, causing a buildup of unused NADH.
"Dysfunctional enzymes in the mitochondria are known to be associated with serious health problems such as cancer and neurodegenerative diseases," said Ahmed Heikal, associate professor of bioengineering, Penn State. "By detecting the level of NADH and its distribution inside living cells, we should be able to monitor the mitochondrial activity and thus the integrity of any given cell, without adding potentially toxic dyes or actually destroying the cell."
According to Heikal, one of the main challenges in cancer diagnosis is the ability to differentiate cancer cells from normal ones at the early stages of tumor progression.
To tease apart the critical difference between normal and cancerous cells, the researchers used the fluorescence of natural NADH. Using a combination of state-of-the-art spectroscopy and microscopy techniques, the researchers were able to convert such fluorescence into an accurate measure of NADH concentration in live cells. Heikal and Yu, graduate student, bioengineering, have found that the average concentration of NADH in breast cancer cells is about twice that in normal breast cells.
"If we are given two live cells, one normal and the other cancerous, we could differentiate between the two with confidence," said Heikal, whose team's findings appear today (April 2) in the Journal of Photochemistry and Photobiology B: Biology. "For the first time, we have been able to quantify the concentration of NADH in both live breast cells and breast cancer cells."
The researchers also looked at the amounts of NADH in the cell that is free and how much is bound to other enzymes. These amounts are different in normal and cancer cells.
"We realized that the fluorescence intensity not only depends upon the concentration of NADH but also on its structure -- free or enzyme-bound -- as well as its place inside the cell -- in the cytoplasm (non-nucleus part of the cell) or in mitochondria," explained Heikal. "Since a free NADH molecule would rotate -- tumble -- faster than enzyme-bound NADH, we were able to develop a technique called rotational diffusion imaging to establish a direct measure of the concentrations of free and enzyme-bound NADH throughout a living cell, whether in the cytosol (cell fluid) or the mitochondria."
To confirm their findings that disruption of chemical reactions that produce ATP can lead to an increase in NADH, Heikal and Yu exposed normal breast cells to potassium cyanide, a known inhibitor of some of these critical mitochondrial enzymes.
The researchers found that the NADH concentration in the normal cells increased when exposed to potassium cyanide. The relative amounts of NADH in the mitochondria also rose significantly.
Other researchers have previously measured the amount of NADH in cells using conventional biochemical techniques that require destroying the cells. However, Heikal believes measurements of dead cells provide no information about NADH distribution in the cells and may not be accurate or relevant for diagnostic or clinical use.
"The advantage of our non-destructive approach is that the NADH location in a cell relates to its function in cell survival," explained Heikal. "When you destroy the cell, you do not know where the NADH molecules existed inside the cell and what role they might have played in cell survival. For accurate diagnosis, you need to have the cellular context to better understand the problem."
According to the Penn State researcher, the ability to accurately measure NADH levels in a cell without killing it could have potential implications for related research on human health and drug delivery.
"Our technique is not limited to detecting cancer. Other neurodegenerative diseases related to mitochondrial anomalies can also be detected with our method," Heikal said. "We can also use our approach to quantify the efficiency of a new drug on manipulating the activities of mitochondrial enzymes associated with energy production in cells."
Penn State
According to Heikal, one of the main challenges in cancer diagnosis is the ability to differentiate cancer cells from normal ones at the early stages of tumor progression.
To tease apart the critical difference between normal and cancerous cells, the researchers used the fluorescence of natural NADH. Using a combination of state-of-the-art spectroscopy and microscopy techniques, the researchers were able to convert such fluorescence into an accurate measure of NADH concentration in live cells. Heikal and Yu, graduate student, bioengineering, have found that the average concentration of NADH in breast cancer cells is about twice that in normal breast cells.
"If we are given two live cells, one normal and the other cancerous, we could differentiate between the two with confidence," said Heikal, whose team's findings appear today (April 2) in the Journal of Photochemistry and Photobiology B: Biology. "For the first time, we have been able to quantify the concentration of NADH in both live breast cells and breast cancer cells."
The researchers also looked at the amounts of NADH in the cell that is free and how much is bound to other enzymes. These amounts are different in normal and cancer cells.
"We realized that the fluorescence intensity not only depends upon the concentration of NADH but also on its structure -- free or enzyme-bound -- as well as its place inside the cell -- in the cytoplasm (non-nucleus part of the cell) or in mitochondria," explained Heikal. "Since a free NADH molecule would rotate -- tumble -- faster than enzyme-bound NADH, we were able to develop a technique called rotational diffusion imaging to establish a direct measure of the concentrations of free and enzyme-bound NADH throughout a living cell, whether in the cytosol (cell fluid) or the mitochondria."
To confirm their findings that disruption of chemical reactions that produce ATP can lead to an increase in NADH, Heikal and Yu exposed normal breast cells to potassium cyanide, a known inhibitor of some of these critical mitochondrial enzymes.
The researchers found that the NADH concentration in the normal cells increased when exposed to potassium cyanide. The relative amounts of NADH in the mitochondria also rose significantly.
Other researchers have previously measured the amount of NADH in cells using conventional biochemical techniques that require destroying the cells. However, Heikal believes measurements of dead cells provide no information about NADH distribution in the cells and may not be accurate or relevant for diagnostic or clinical use.
"The advantage of our non-destructive approach is that the NADH location in a cell relates to its function in cell survival," explained Heikal. "When you destroy the cell, you do not know where the NADH molecules existed inside the cell and what role they might have played in cell survival. For accurate diagnosis, you need to have the cellular context to better understand the problem."
According to the Penn State researcher, the ability to accurately measure NADH levels in a cell without killing it could have potential implications for related research on human health and drug delivery.
"Our technique is not limited to detecting cancer. Other neurodegenerative diseases related to mitochondrial anomalies can also be detected with our method," Heikal said. "We can also use our approach to quantify the efficiency of a new drug on manipulating the activities of mitochondrial enzymes associated with energy production in cells."
Penn State
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When Charles Darwin visited the Falkland Islands during the voyage of the Beagle in 1835, he saw a wolf-like species, wrote about it in his diaries and correctly commented that it was being hunted in such large numbers that it would soon become extinct.
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Age-related hearing loss is the most common sensory disorder among the elderly. But scientists are still trying to figure out what cellular processes govern or contribute to the loss.
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Individuals with weaker muscles appear to have a higher risk for Alzheimer's disease and declines in cognitive function over time, according to a report in the November issue of Archives of Neurology, one of the JAMA/Archives journals.
Hydrogen Peroxide's Link to Living Cells
If a circadian rhythm is like an orchestra - the united expression of the rhythms of millions of cells - a common chemical may serve as the conductor, or at least as the baton.
Developmental drug may help bone fractures heal after radiation exposure
A drug currently under development by the University of Pittsburgh School of Medicine may help bone fractures heal more quickly after radiation exposure, according to a study by Pitt researchers.
Chemosensitivity of cancer cells depends on their protein dependency
Two different anti-apoptotic proteins support cancer cell survival via an identical mechanism, yet differ in their sensitivity to chemotherapeutic drugs, report Brunelle et al. The study will be published online October 26, 2009 and in the November 2, 2009 print issue of the Journal of Cell Biology (JCB).
Too much of a good thing? Scientists explain cellular effects of vitamin A overdose and deficiency
If a little vitamin A is good, more must be better, right? Wrong! New research published online in the FASEB Journal shows that vitamin A plays a crucial role in energy production within cells, explaining why too much or too little has a complex negative effect on our bodies.
How mitochondrial gene defects impair respiration, other major life functions
Researchers are delving into abnormal gene function in mitochondria, structures within cells that power our lives. Mitochondria are the place where energy is generated from the most basic molecules of food. Because this function is essential to life, defects in mitochondria may affect a wide range of organ systems in humans and animals.
Can an over-the-counter vitamin-like substance slow the progression of Parkinson's disease?
Rush University Medical Center is participating in a large-scale, multi-center clinical trial in the U.S. and Canada to determine whether a vitamin-like substance, in high doses, can slow the progression of Parkinson's disease, a neurodegenerative disorder that affects about one million people in the United States.
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