Vitamin B3 Controls Important Life Processes by Changing Shape in Response to Oxygen Level

Vitamin B3 Controls Important Life Processes by Changing Shape in Response to Oxygen Level
Rex protein in action

(PhysOrg.com) -- Scientists have obtained the first images of a common molecular signal, vitamin B3, which plays a role in making some bacteria potent and some men impotent.

For the first time, researchers have captured three-dimensional images of a protein in the act of responding to oxygen levels by sensing vitamin B3. Vitamin B3, also known as niacin, is essential to convert the food we eat into energy. Since vitamin B3 carries electrons from metabolized food to oxygen, it serves as a sensitive indicator of oxygen levels in cells. Vitamin B3 also regulates a variety of processes, including erectile dysfunction, aging and sleep patterns in people. The findings, published in the journal Molecular Cell, could guide future development of antibiotics, and in the long term, new treatments for erectile dysfunction.

The research team at the University of Rochester Medical Center used specialized instruments to show how the bacterial protein ‘Rex’ tracks the oxidation state of vitamin B3, which gains electrons when oxygen levels are low. Under normal oxygen conditions, Rex binds both vitamin B3 and the genetic material DNA; there, Rex blocks gene activity. When the oxygen levels decrease, Rex remains bound to the electron-rich state of vitamin B3, but undergoes a massive change in shape. The shape change releases Rex from the DNA, thereby freeing genetic information to cope with the limited oxygen supply. This transformation is central to how proteins use vitamin B3 to sense oxygen levels and alter accordingly.

Rex proteins are prevalent among that cause anthrax infections, toxic shock syndrome, and pneumonia. Understanding how these proteins influence cell signaling offers scientists a new way to try to stop the microbes that cause such infections. In humans, an analogous vitamin B3 sensing system is involved in producing nitric oxide neurotransmitters essential for the erectile process.

“Vitamin B3 has been the focus of intense interest since its role as a signaling molecule was discovered, yet no one knew how proteins, the molecular machines of the cell, could sense the slight differences between the oxidized and reduced forms,” said Clara Kielkopf, Ph.D., associate professor in theDepartment of Biochemistry and Biophysics at the University of Rochester Medical Center and lead study author. “An exciting implication of our findings is that antibiotics could be developed to change the shape of Rex-like proteins and turn off genes needed for a bacterial infection.”

The work has implications for research beyond toxic pathogens and impotence. Many organisms are responding to changing oxygen levels constantly, and understanding how they do so is crucial. In people, for instance, a lack of oxygen leads to arrested cell division and ultimately cell death, while excess oxygen levels can damage cellular building blocks and contribute to a variety of diseases including cancer, diabetes, cardiovascular disease and neurodegenerative disorders.

“It’s amazing to think that less than 10 years ago no one knew the Rex pathway existed, and now we have obtained detailed structural snapshots of the Rex protein in action that allow us to understand how cells can respond to low oxygen levels,” said Krystle McLaughlin, a doctoral student responsible for determining the Rex structures in this study. “This knowledge lays the foundation for new ways to manipulate harmful bacterial pathogens and also facilitates our understanding of similar pathways in the human body.”

In the next phase of the research, the team will analyze differences between Rex and other vitamin B3 sensing proteins. Although very similar to the Rex protein investigated here, subtle differences in the Rex proteins that cause anthrax and other pathogens are likely to be important for drug development. Research will also focus on several human proteins that sense signals. Detailed three-dimensional shapes of these molecules responding to the oxidized versus reduced forms are needed both to understand human aging and metabolism and to guide the design of specific antibiotics.

“This is an elegant example of how modern structural biology can reveal molecules that assume alternate shapes, and how those shapes control important life functions and response to infection,” said Robert Bambara, Ph.D., chair of the Department of Biochemistry and Biophysics at the Medical Center.


Explore further

Vitamin D protects cells from stress that can lead to cancer

More information: Journal paper: www.cell.com/molecular-cell/ab … -2765%2810%2900368-0
Citation: Vitamin B3 Controls Important Life Processes by Changing Shape in Response to Oxygen Level (2010, June 7) retrieved 21 July 2019 from https://phys.org/news/2010-06-vitamin-b3-important-life-response.html
This document is subject to copyright. Apart from any fair dealing for the purpose of private study or research, no part may be reproduced without the written permission. The content is provided for information purposes only.
0 shares

Feedback to editors

User comments

Jun 07, 2010
Well done to the researchers - a lot of hard work obviously went into this.

Now, let me see - the body doesn't make B3[ or does it?] so it has to come from the outside. Yet it's essential for life. The question then arises - just how did this particular dependence on B3 evolve? Or, how did the body evolve independently of B3? If it didn't then what are the chances of the two evolving simultaneously but independently?
Is that at all possible? How could the body survive without B3 whilst it [B3] was in the forming stage, i.e. not quite vitamin B3 yet? Same applies for all the other vitamins - how did the body survive without it?
Oh, of course, the vitamins evolved BEFORE the human body. Just a lucky coincidence for the body that vitamins evolved before the body needed it.
But why did vitamins evolve in the first place. It's so much as if it was anticipating the presence of the body in a far distant future?


Jun 08, 2010
Now, let me see - the body doesn't make B3[ or does it?] so it has to come from the outside.
The human liver biosynthesizes this compound.
Yet it's essential for life. The question then arises - just how did this particular dependence on B3 evolve? Or, how did the body evolve independently of B3? If it didn't then what are the chances of the two evolving simultaneously but independently?
Chances of something happening that actually happened, 1 in 1.

Is that at all possible? How could the body survive without B3 whilst it [B3] was in the forming stage, i.e. not quite vitamin B3 yet?

This is a poor attempt at trying to say "Irreducably complex". What you're completely missing in your ignorance of evolution is the fact that evolution demands irreducable complexity.

Gene A produces Protein A
Gene B evolves to produce a protein (B) that breaks down into Protein A.
Gene A goes dormant, but the organism survives as Protein B replaced direct need for Prot A.

Please sign in to add a comment. Registration is free, and takes less than a minute. Read more