The Scientist: NewsBlog:
New role for righty molecules
Posted by Katherine Bagley
[Entry posted at 17th September 2009 06:03 PM GMT]
Researchers have identified a role for rare, right-handed versions of amino acids. This so-called D-form of nature's building blocks allows bacterial cell walls to adapt to changes in the environment, says a study in Science this week -- marking one of the few times the D-aminos have been linked to biological function.
Nineteen of the 20 amino acids found in nature come in two forms, mirror images in structural composition, but until recently it seemed life on Earth used only one of them. L-amino acids were viewed as the building blocks of life, leaving researchers perplexed as to the function of their D-amino siblings. Over the past 20 years, though, studies have gradually begun to identify important roles for D-amino acids as, for example, key components of antibiotics, immunosuppressive drugs, and antitumor agents, and as neurotransmitters in the brain. Hubert Lam and colleagues from Harvard Medical School and Brigham and Women's Hospital stumbled upon the discovery while researching whether the shape of Vibrio cholerae, the bacteria responsible for diarrhea-inducing cholera, could influence its virulence, said Matthew Waldor, a coauthor of the study. Lam's group was working with cells in which proteins controlling cell shape had been mutated. The researchers noticed that the D-forms but not the L-forms of four amino acids stimulated the bacteria to transition from a rod to a spherical shape. So they joined forces with the chemists Jon Clardy and Dong-Chan Oh, to determine what exactly was happening to the cell. As the mutant V. cholerae cells transitioned between exponential growth as rods to a stationary stage as spheres, the researchers found, L-amino acids got converted into D-amino acids by enzymes called racemases, which alter a molecule's structure around the central carbon. To determine where in the cell wall the suddenly plentiful D-amino acids were doing their remodeling job, the researchers compared wild-type cells to cells further mutated to lack racemases (which were therefore equipped with fewer D-amino acids). In these cells, they found, the elastic polymer peptidoglycan, the main component of cell walls, was thicker but weaker -- evidence that D-aminos had the ability to alter the composition, amount, and strength of a critical cell wall component. The group then set out to test their results on another bacterium. "We chose Bacillus subtilis, Gram-positive bacteria, because it is extremely far from V. cholerae evolutionarily," said Waldor. "But it was also because Bacillus is one of the most studied model microorganisms, and therefore there is a wealth of information on it." As with Vibrio, D-amino acids in B. subtilis affected peptidoglycan synthesis and regulated cell wall structure. The righty molecules, the researchers theorized, may be able to slow metabolic activity in any bacteria cell when resources become scarce or environmental conditions stressful. There are still many unanswered questions about the role of D-amino acids in biological functions. Waldor and his colleagues are working to understand the mechanics of how the D-amino acids are affecting peptidoglycan activity and how these previously unappreciated building blocks might be incorporated into new antibiotics. Both Waldor and Blanke are interested in how racemases convert L- into D-amino acids. "We certainly didn't start on the path of studying amino acids," said Waldor, "but we're excited about what we've uncovered." Related stories: [16th March 2009] [15th August 2003] [30th July 2001] |
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Roles For d-Amino Acids
by Dov Henis
[Comment posted 2009-09-21 01:44:21]
[Comment posted 2009-09-21 01:44:21]
Roles For d-Amino Acids
d = dextrorotatory, and l = levorotatory, enantiomers
d = dead-end, and l = life, metabolic functionality
A. Quotes from "New role for righty molecules"
LINK
Quote: "The researchers noticed that the D-forms but not the L-forms of four amino acids stimulated Vibrio cholerae to transition from a rod to a spherical shape."
I reckon that a plain deprivation of one or more essential l-amino acids of these four would have the same effect-result.
Quote: "This so-called D-form of nature's building blocks allows bacterial cell walls to adapt to changes in the environment"
By plain common sense, my best scientific approach, I reckon that d-amino acids were selected by evolution for the bacterial monocell wall plainly and simply for survival, being a dead-end for metabolism by other organisms.
Quote: "The righty molecules, the researchers theorized, may be able to slow metabolic activity in any bacteria cell when resources become scarce, or environmental conditions stressful."
I reckon that when resources become scarce, or environmental conditions stressful, the bacteria cell is capable of adapting without the aid of the d-amino acid.
B. Historically,
d-amino acids are found in some proteins produced by exotic sea-dwelling organisms, such as cone snails.
The presence and function of d-amino acids in other organisms have not been studied, except in the cell walls of microorganisms, as comopnents of the peptidoglycan cell wall.
They are also found in various living "higher" organisms in the form of free amino acids, peptides, and proteins. Free d-aspartate and d-serine are present, and may have physiological functions, in mammals. IMO their presence in mammals, including humans, are related either to protection of tissue from biometabolism or in conjunction with advanced-age-related increase of racemases activity, of enzymes active in racemization.
C. On life's amino acids chirality
From "Genes Are Organisms, Earth'S Primal Organisms"
LINK
Darwinian evolution started at life's day one, with the genesis of the first organisms, the replicating oligomers, pre-archaea genes. It started under yet-unknown energetic conditions, by a serendipitous accident, with oligomeric (RNA?) conformations, in a soup containing all their essential molecular progenitors. These conformations happened to absorb the amounts of energy enabling their polymerization to lengths precipitated as determined by the nature and conditions of the soup.
The sugars and the nitrogen-based compounds that, together with the phosphates, are the components of the genes organisms, are chiral. There probably is an energetic advantage in homochirality and in chiral homogeneity for the self-replication of biopolymers.
This serendipitous accident set up a matrix-field of energy with a potential extended between its source, sun's radiation, and the precipitating organisms. This was the genesis of the ongoing formation and maintenance of Earth's biosphere.
And since thus the biosphere started it could only evolve in more favorable energetic directions and towards stabler components. Survival. Chiral organism survival. After all this was already into the process of life's evolution...
Dov Henis
(Comments From The 22nd Century)
Updated Life's Manifest May 2009
LINK
Implications Of E=Total[m(1 + D)]
LINK
d = dextrorotatory, and l = levorotatory, enantiomers
d = dead-end, and l = life, metabolic functionality
A. Quotes from "New role for righty molecules"
LINK
Quote: "The researchers noticed that the D-forms but not the L-forms of four amino acids stimulated Vibrio cholerae to transition from a rod to a spherical shape."
I reckon that a plain deprivation of one or more essential l-amino acids of these four would have the same effect-result.
Quote: "This so-called D-form of nature's building blocks allows bacterial cell walls to adapt to changes in the environment"
By plain common sense, my best scientific approach, I reckon that d-amino acids were selected by evolution for the bacterial monocell wall plainly and simply for survival, being a dead-end for metabolism by other organisms.
Quote: "The righty molecules, the researchers theorized, may be able to slow metabolic activity in any bacteria cell when resources become scarce, or environmental conditions stressful."
I reckon that when resources become scarce, or environmental conditions stressful, the bacteria cell is capable of adapting without the aid of the d-amino acid.
B. Historically,
d-amino acids are found in some proteins produced by exotic sea-dwelling organisms, such as cone snails.
The presence and function of d-amino acids in other organisms have not been studied, except in the cell walls of microorganisms, as comopnents of the peptidoglycan cell wall.
They are also found in various living "higher" organisms in the form of free amino acids, peptides, and proteins. Free d-aspartate and d-serine are present, and may have physiological functions, in mammals. IMO their presence in mammals, including humans, are related either to protection of tissue from biometabolism or in conjunction with advanced-age-related increase of racemases activity, of enzymes active in racemization.
C. On life's amino acids chirality
From "Genes Are Organisms, Earth'S Primal Organisms"
LINK
Darwinian evolution started at life's day one, with the genesis of the first organisms, the replicating oligomers, pre-archaea genes. It started under yet-unknown energetic conditions, by a serendipitous accident, with oligomeric (RNA?) conformations, in a soup containing all their essential molecular progenitors. These conformations happened to absorb the amounts of energy enabling their polymerization to lengths precipitated as determined by the nature and conditions of the soup.
The sugars and the nitrogen-based compounds that, together with the phosphates, are the components of the genes organisms, are chiral. There probably is an energetic advantage in homochirality and in chiral homogeneity for the self-replication of biopolymers.
This serendipitous accident set up a matrix-field of energy with a potential extended between its source, sun's radiation, and the precipitating organisms. This was the genesis of the ongoing formation and maintenance of Earth's biosphere.
And since thus the biosphere started it could only evolve in more favorable energetic directions and towards stabler components. Survival. Chiral organism survival. After all this was already into the process of life's evolution...
Dov Henis
(Comments From The 22nd Century)
Updated Life's Manifest May 2009
LINK
Implications Of E=Total[m(1 + D)]
LINK
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