 |
|
New and sharper X-rays of cell's ribosome could lead to better antibiotics
November 04, 2005Berkeley - A new, sharper picture of the nano-machine that translates our genetic program into proteins promises to help researchers explain how some types of antibiotics work and could lead to the design of better ones.
The high-resolution snapshots of the bacterial ribosome were captured by scientists at the University of California, Berkeley, and Lawrence Berkeley National Laboratory (LBNL) with the lab's Advanced Light Source, which generates intense beams of X-rays that can reveal unprecedented structural detail of such large and complex molecules.
The new, high-resolution data on the intact ribosome allows researchers to build more detailed and more realistic models of the ribosome that until now were impossible with the "fuzzy pictures" available.
While sharp images of the two main pieces of the ribosome have already provided great insight into how specific antibiotics work, many antibiotics, such as the aminoglycosides, only interfere with the entire, fully assembled molecular machine.
"Many antibiotics target only the intact machine, disrupting messenger RNA decoding or movement," said lead author Jamie Cate, assistant professor of chemistry and of molecular and cell biology at UC Berkeley and a staff scientist in the Physical Biosciences Division at LBNL. "We are now in a position to look at some of these drugs and discover things that haven't been known before."
Cate, a member of the California Institute for Quantitative Biomedical Research (QB3) at UC Berkeley, and his colleagues report the detailed structure of the ribosome from Escherichia coli, the common intestinal bacteria, in the Nov. 4 issue of Science.
The ribosome, about 21 to 25 nanometers across, is the original nanomachine, taking genetic information relayed by messenger RNA, decoding it and spitting out proteins. Ribosomes are dispersed in the hundreds of thousands throughout the cell, and in some highly active cells, ribosomes are responsible for producing millions of proteins per minute.
Ribosomes are found in all organisms, ranging from bacteria to humans, and probably arose nearly 2 billion years ago. They have changed so little through evolution that a bacterial ribosome can often translate human genes into protein. Some people suspect that ribosomes, which at their core consist of ribonucleic acid (RNA), a sister of the DNA that comprises our genes, arose when RNA, not DNA, carried our genetic dowry.
Because of its importance to life, and the fact that important drugs target the ribosome, it has received lots of attention. Only four years ago, Cate was part of a team that published a picture of the ribosome with a resolution of 5.5 Angstroms, where an Angstrom, about the size of a hydrogen atom, is one-tenth of a nanometer. The new images have a resolution of 3.5 Angstroms, allowing Cate and his colleagues to see the individual nucleotides in the RNA strands of the ribosome and the amino-acid backbones of the proteins that surround the RNA core.
Both the old and new images were obtained through X-ray crystallography using Advanced Light Source beamlines, which provide extremely bright X-ray sources. Having the light source in his backyard, Cate said, has made it easier to get the best crystallographic picture with the sharpest three-dimensional detail. He and his laboratory colleagues grow crystals of ribosomes, check their quality in the light source, then tweak the crystals and try again.
"We've burned through thousands of crystals in the last five years," he said.
The researchers obtained two high-resolution snapshots of the intact E. coli ribosome and compared them with a wide range of conformations of other ribosomes. These other data came from lower-resolution X-ray crystallographyic images of Thermus thermophilus and E. coli ribosomes, plus electron microscopy of E. coli, yeast and mammalian ribosomes. Together, they yielded what Cate calls "global snapshots" and allowed him and his colleagues to deduce how individual parts of the ribosome function during the translocation process.
What the new structure shows so far is how the two large pieces of the ribosome bend, ratchet and rotate as the ribosome goes through the repetitive process of protein manufacturing.
The "small" subunit of the ribosome first recognizes and latches onto the messenger RNA (mRNA), which contains a copy of part of the chromosomal DNA. Once the small subunit finds the start position, the "large" subunit moves in and latches on, clamping the mRNA between them. The combined machine slides along the mRNA, reading each three-letter codon, matching this code to the appropriate amino acid, and then adding that amino acid-one of 20 possible building blocks-to the lengthening protein chain.
As this translation takes place, transfer RNA (tRNA) constantly brings in amino acid building blocks, while energy-supplying molecules in the form of GTP (guanosine triphosphate) cycle through.
They found that after the bond-called a peptide bond-forms between the growing chain and the newly added amino acid, the small subunit ratchets with respect to the large subunit. Then the head of the small subunit swivels in preparation for shifting the mRNA forward by one codon. At the same time, a groove opens that allows the mRNA to actually move and the tRNA, depleted of its amino acid, to float away.
Then, the small subunit reverses its motions, resets, and is ready to add the next amino acid. This picture of translocation-ratcheting, swiveling, opening the groove, then reversing these three steps-is repeated 10 to 20 times each second in bacteria.
Based on the researchers' analysis of the new data, Cate said that it appears, also, that the helical RNA in the ribosome acts as a spring to withstand the stress of these reversible swivels. Also, the ribosome harbors an astounding number of positive magnesium ions-hundreds in all-that apparently neutralize the highly negative charge of the RNA. Without these magnesium ions, Cate said, the repulsion of the RNA's negative charge would blow the ribosome apart. Some of the magnesium ions form a salty liquid at the interface between the large and small subunits of the ribosome, perhaps lubricating the machine.
These and other hypotheses need further exploration, he said.
"All the interactions we see have been seen before at lower resolution, but it was not clear how to interpret them," he said. "It took these high-resolution studies to coalesce our ideas."
University of California-Berkeley
While sharp images of the two main pieces of the ribosome have already provided great insight into how specific antibiotics work, many antibiotics, such as the aminoglycosides, only interfere with the entire, fully assembled molecular machine.
"Many antibiotics target only the intact machine, disrupting messenger RNA decoding or movement," said lead author Jamie Cate, assistant professor of chemistry and of molecular and cell biology at UC Berkeley and a staff scientist in the Physical Biosciences Division at LBNL. "We are now in a position to look at some of these drugs and discover things that haven't been known before."
Cate, a member of the California Institute for Quantitative Biomedical Research (QB3) at UC Berkeley, and his colleagues report the detailed structure of the ribosome from Escherichia coli, the common intestinal bacteria, in the Nov. 4 issue of Science.
The ribosome, about 21 to 25 nanometers across, is the original nanomachine, taking genetic information relayed by messenger RNA, decoding it and spitting out proteins. Ribosomes are dispersed in the hundreds of thousands throughout the cell, and in some highly active cells, ribosomes are responsible for producing millions of proteins per minute.
Ribosomes are found in all organisms, ranging from bacteria to humans, and probably arose nearly 2 billion years ago. They have changed so little through evolution that a bacterial ribosome can often translate human genes into protein. Some people suspect that ribosomes, which at their core consist of ribonucleic acid (RNA), a sister of the DNA that comprises our genes, arose when RNA, not DNA, carried our genetic dowry.
Because of its importance to life, and the fact that important drugs target the ribosome, it has received lots of attention. Only four years ago, Cate was part of a team that published a picture of the ribosome with a resolution of 5.5 Angstroms, where an Angstrom, about the size of a hydrogen atom, is one-tenth of a nanometer. The new images have a resolution of 3.5 Angstroms, allowing Cate and his colleagues to see the individual nucleotides in the RNA strands of the ribosome and the amino-acid backbones of the proteins that surround the RNA core.
Both the old and new images were obtained through X-ray crystallography using Advanced Light Source beamlines, which provide extremely bright X-ray sources. Having the light source in his backyard, Cate said, has made it easier to get the best crystallographic picture with the sharpest three-dimensional detail. He and his laboratory colleagues grow crystals of ribosomes, check their quality in the light source, then tweak the crystals and try again.
"We've burned through thousands of crystals in the last five years," he said.
The researchers obtained two high-resolution snapshots of the intact E. coli ribosome and compared them with a wide range of conformations of other ribosomes. These other data came from lower-resolution X-ray crystallographyic images of Thermus thermophilus and E. coli ribosomes, plus electron microscopy of E. coli, yeast and mammalian ribosomes. Together, they yielded what Cate calls "global snapshots" and allowed him and his colleagues to deduce how individual parts of the ribosome function during the translocation process.
What the new structure shows so far is how the two large pieces of the ribosome bend, ratchet and rotate as the ribosome goes through the repetitive process of protein manufacturing.
The "small" subunit of the ribosome first recognizes and latches onto the messenger RNA (mRNA), which contains a copy of part of the chromosomal DNA. Once the small subunit finds the start position, the "large" subunit moves in and latches on, clamping the mRNA between them. The combined machine slides along the mRNA, reading each three-letter codon, matching this code to the appropriate amino acid, and then adding that amino acid-one of 20 possible building blocks-to the lengthening protein chain.
As this translation takes place, transfer RNA (tRNA) constantly brings in amino acid building blocks, while energy-supplying molecules in the form of GTP (guanosine triphosphate) cycle through.
They found that after the bond-called a peptide bond-forms between the growing chain and the newly added amino acid, the small subunit ratchets with respect to the large subunit. Then the head of the small subunit swivels in preparation for shifting the mRNA forward by one codon. At the same time, a groove opens that allows the mRNA to actually move and the tRNA, depleted of its amino acid, to float away.
Then, the small subunit reverses its motions, resets, and is ready to add the next amino acid. This picture of translocation-ratcheting, swiveling, opening the groove, then reversing these three steps-is repeated 10 to 20 times each second in bacteria.
Based on the researchers' analysis of the new data, Cate said that it appears, also, that the helical RNA in the ribosome acts as a spring to withstand the stress of these reversible swivels. Also, the ribosome harbors an astounding number of positive magnesium ions-hundreds in all-that apparently neutralize the highly negative charge of the RNA. Without these magnesium ions, Cate said, the repulsion of the RNA's negative charge would blow the ribosome apart. Some of the magnesium ions form a salty liquid at the interface between the large and small subunits of the ribosome, perhaps lubricating the machine.
These and other hypotheses need further exploration, he said.
"All the interactions we see have been seen before at lower resolution, but it was not clear how to interpret them," he said. "It took these high-resolution studies to coalesce our ideas."
University of California-Berkeley
Ribosome Current Events and Ribosome News RSSComputational microscope peers into the working ribosome
Two new studies reveal in unprecedented detail how the ribosome interacts with other molecules to assemble new proteins and guide them toward their destination in biological cells.
Study reveals why certain drug combinations backfire
Combination drug therapy has become a staple for treating many infections. For instance, doctors treat extensively drug resistant forms of tuberculosis with one drug that breaks down the pathogen's protective barriers and opens the door for another to deliver the deathblow.
2-pronged protein attack could be source of SARS virulence
Ever since the previously unknown SARS virus emerged from southern China in 2003, University of Texas Medical Branch at Galveston virologists have focused on finding the source of the pathogen's virulence - its ability to cause disease.
Scientists visualize assembly line gears in ribosomes, cell's protein factory
Even as research on the ribosome, one of the cell's most basic machines, is recognized with a Nobel Prize, scientists continue to achieve new insights on the way ribosomes work.
National Science Foundation congratulates Nobel Laureates in medicine/physiology, chemistry and economics
The National Science Foundation (NSF) congratulates the 2009 Nobel laureates, particularly those who have received NSF funding over the years: Jack W. Szostak, who shared the prize in physiology or medicine; Thomas A. Steitz, who shared the prize in chemistry; and Elinor Ostrom and Oliver E. Williamson who earned the Sveriges Riksbank Prize in economic sciences in memory of Alfred Nobel 2009.
What are the characteristics of clarithromycin-resistant Helicobacter pylori?
Clarithromycin is currently one of the antibiotics used for eradication of Helicobacter pylori. However, reports of H. pylori resistance to this antibiotic are increasing worldwide.
Scripps research scientists observe human neurodegenerative disorder in fruit flies
A team of scientists from The Scripps Research Institute, Katholeike Universiteit Leuven, and the University of Antwerp, Belgium, among other institutions, has created a genetically modified fruit fly that mimics key features of Charcot-Marie-Tooth disease, a common neurodegenerative disorder that strikes about one out of every 2,500 people in the United States.
NIST researchers 'all aglow' over new test of toxin strength
A new National Institute of Standards and Technology (NIST) assay using a "glow or no glow" technique may soon help the U.S. Department of Homeland Security (DHS) defend the nation against a spectrum of biological weapons that could be used in a terrorist attack.
Genetic switch potential key to new class of antibiotics
Researchers have determined the structure of a key genetic mechanism at work in bacteria, including some that are deadly to humans, in an important step toward the design of a new class of antibiotics.
Researchers study signaling networks that set up genetic code
In a new study, researchers at the University of Illinois have identified and visualized the signaling pathways in protein-RNA complexes that help set the genetic code in all organisms.
More Ribosome Current Events and Ribosome News Articles
 |
The Ribosome: Structure, Function, Antibiotics, and Cellular Interactions b |
 |
The Ribosome: Cold Spring Harbor Symposia on Quantitative Biology, Volume LXVI by Cold Spring Harbor Laboratory (Author) This is the first book to contain the newly published findings on the structure of the ribosome and discuss their meaning for our understanding of how proteins are made and processed inside the cell. With over 60 contributions from the worldÂ’s most innovative ribosome biology laboratories, this is the latest volume in the annual series that for over 60 years has provided analysis and interpretation of the most interesting problems in biology. |
 |
Metabolic (Ribosome Edit) Jakt (Primary Contributor) |
|
Pleasure or Pain Tracks are: 1. Do You Remember? 2. Pleasure Or Pain 3. Tango 4. Never Change 5. Average Guy 6. Chairman 7. Sweet Jane 8. Reckless Lover 9. Slide Aside 10. Slide Aside (Uncensored Mix) | |
 |
Protein Synthesis and Ribosome Structure: Translating the Genome by Knud H. Nierhaus (Editor), Daniel N. Wilson (Editor) Based on more than 30 years of ribosome research and incorporating the most recent structural evidence, this book presents a uniform picture of the largest enzyme complex found in living cells, shedding light on many decades-old questions in molecular biology. From the contents: Structure of the Ribosome Ribosome Assembly tRNA and Synthetases mRNA Degradation Initiation and Elongation Termination and Ribosome Recycling Regulation of Ribosome Biosynthesis Inhibition of the Translational Apparatus by Antibiotics A premier resource for anyone with an interest in ribosomal protein synthesis, whether in the context of molecular biology, biotechnology, pharmacology or molecular medicine. |
|
Ribosome inactivation for preservation: concepts and reservations.: An article from: Science Progress by Walid El- M. Sharoud (Author) This digital document is an article from Science Progress, published by Science Reviews Ltd. on September 22, 2004. The length of the article is 6391 words. The page length shown above is based on a typical 300-word page. The article is delivered in HTML format and is available in your Amazon.com Digital Locker immediately after purchase. You can view it with any web browser. Citation Details Title: Ribosome inactivation for preservation: concepts and reservations. Author: Walid El- M. Sharoud Publication: Science Progress (Refereed) Date: September 22, 2004 Publisher: Science Reviews Ltd. Volume: 87 Issue: 3 Page: 137(16) Distributed by Thomson... | |
 |
Ribosomes Kenny Cambre (Primary Contributor) |
 |
Ribosomes (Cellular Organelles) by Alexander S. Spirin (Author) Dr. Spirin is a world authority on ribosomes and has published two earlier books in this area in English. He is one of the best possible people who could write this book. This text is for advanced undergraduates and beginning graduate students and will cover the structure, function, and biosynthesis of ribosomes. Ribosomes are important in protein synthesis, which is currently a hot topic in many different areas of research. |
 |
Ribosomes Kenny Cambre (Primary Contributor) |
|
Messenger RNA and Ribosomes in Protein Synthesis (Biochemical Society Symposia) by C.F. Phelps (Author), H.R.V. Arnstein (Author) |
| © 2009 BrightSurf.com |