 |
|
Researchers develop new way to see single RNA molecules inside living cells
April 07, 2009Biomedical engineers have developed a new type of probe that allows them to visualize single ribonucleic acid (RNA) molecules within live cells more easily than existing methods. The tool will help scientists learn more about how RNA operates within living cells.
Techniques scientists currently use to image these transporters of genetic information within cells have several drawbacks, including the need for synthetic RNA or a large number of fluorescent molecules. The fluorescent probes developed at the Georgia Institute of Technology circumvent these issues.
"The probes we designed shine bright, are small and easy to assemble, bind rapidly to their targets, and can be imaged for hours. These characteristics make them a great choice for studying the movement and location of RNA inside a single cell and the interaction between RNA and binding proteins," said Philip Santangelo, an assistant professor in the Wallace H. Coulter Department of Biomedical Engineering at Georgia Tech and Emory University.
Details of the probe production process and RNA imaging strategy were published online in the journal Nature Methods on April 6. In addition to Santangelo, Georgia Tech graduate student Aaron Lifland, Emory University associate professor Gary Bassell and Vanderbilt University professor James Crowe Jr. also contributed to this research. This research was funded by new faculty support from Georgia Tech.
In the study, the probes - produced by attaching a few small fluorescent molecules called fluorophores to a modified nucleic acid sequence and combining the sequences with a protein - exhibited single-molecule sensitivity and allowed the researchers to target and follow native RNA and non-engineered viral RNA in living cells.
"The great thing about these probes is that they recognize RNA sequences and bind to them using the same base pairing most people are familiar with in regards to DNA," explained Santangelo. "By adding only a few probes that would bind to a region of RNA, we gained the ability to distinguish a targeted RNA molecule from a single unbound probe because the former lit up two or three times brighter."
For their experiments, the team used a bacterial toxin to transport the probes into living cells - a delivery technique that when combined with the high affinity of the probes for their targets, required significantly fewer probes than existing techniques. The toxin created several tiny holes in the cell membrane that allowed the probes to enter the cell's cytoplasm.
The researchers tested the sensitivity of conventional fluorescence microscopy to image individual probes inside a cell. Previous studies showed that these techniques were able to image an accumulation of probes inside a cell, but the current study demonstrated that individual probes without cellular targets could be observed homogenously distributed in the cytoplasm with no localization or aggregation.
With single-molecule sensitivity accomplished, the researchers investigated whether they could visualize individual RNA molecules using the probes. To do this, they simultaneously delivered probes designed to target a human messenger RNA (mRNA) sequence region and a probe designed with no target in the human genome. They were able to image unbound probes of both types as well as individual RNA molecules that had attached to the former probes.
The imaging technique also allowed the researchers to observe a process called dynamic RNA-protein co-localization, which is the joining of RNA molecules and RNA binding proteins in a single cell.
"We observed substantial transient interactions between proteins and viral RNA molecules that I don't think had ever been seen before with non-engineered RNA," noted Santangelo. "We saw one of the proteins move into a viral RNA granule and reside within it for over a minute before it was released, and we also saw another protein that appeared to dock with a viral RNA granule."
Santangelo is currently trying to improve the probes by making them smaller and brighter, while also using them to investigate viral pathogenesis and other biological phenomena.
"We are excited to use this imaging strategy to study how single viral RNAs travel from the nucleus of a cell to a virus assembly site, how mRNAs are regulated by location and time, and RNA trafficking in neurons," added Santangelo.
Georgia Institute of Technology Research News
Details of the probe production process and RNA imaging strategy were published online in the journal Nature Methods on April 6. In addition to Santangelo, Georgia Tech graduate student Aaron Lifland, Emory University associate professor Gary Bassell and Vanderbilt University professor James Crowe Jr. also contributed to this research. This research was funded by new faculty support from Georgia Tech.
In the study, the probes - produced by attaching a few small fluorescent molecules called fluorophores to a modified nucleic acid sequence and combining the sequences with a protein - exhibited single-molecule sensitivity and allowed the researchers to target and follow native RNA and non-engineered viral RNA in living cells.
"The great thing about these probes is that they recognize RNA sequences and bind to them using the same base pairing most people are familiar with in regards to DNA," explained Santangelo. "By adding only a few probes that would bind to a region of RNA, we gained the ability to distinguish a targeted RNA molecule from a single unbound probe because the former lit up two or three times brighter."
For their experiments, the team used a bacterial toxin to transport the probes into living cells - a delivery technique that when combined with the high affinity of the probes for their targets, required significantly fewer probes than existing techniques. The toxin created several tiny holes in the cell membrane that allowed the probes to enter the cell's cytoplasm.
The researchers tested the sensitivity of conventional fluorescence microscopy to image individual probes inside a cell. Previous studies showed that these techniques were able to image an accumulation of probes inside a cell, but the current study demonstrated that individual probes without cellular targets could be observed homogenously distributed in the cytoplasm with no localization or aggregation.
With single-molecule sensitivity accomplished, the researchers investigated whether they could visualize individual RNA molecules using the probes. To do this, they simultaneously delivered probes designed to target a human messenger RNA (mRNA) sequence region and a probe designed with no target in the human genome. They were able to image unbound probes of both types as well as individual RNA molecules that had attached to the former probes.
The imaging technique also allowed the researchers to observe a process called dynamic RNA-protein co-localization, which is the joining of RNA molecules and RNA binding proteins in a single cell.
"We observed substantial transient interactions between proteins and viral RNA molecules that I don't think had ever been seen before with non-engineered RNA," noted Santangelo. "We saw one of the proteins move into a viral RNA granule and reside within it for over a minute before it was released, and we also saw another protein that appeared to dock with a viral RNA granule."
Santangelo is currently trying to improve the probes by making them smaller and brighter, while also using them to investigate viral pathogenesis and other biological phenomena.
"We are excited to use this imaging strategy to study how single viral RNAs travel from the nucleus of a cell to a virus assembly site, how mRNAs are regulated by location and time, and RNA trafficking in neurons," added Santangelo.
Georgia Institute of Technology Research News
RNA Molecules Current Events and RNA Molecules News RSSScripps research scientists find new link between insulin and core body temperature
A team led by scientists at The Scripps Research Institute have discovered a direct link between insulin-a hormone long associated with metabolism and metabolic disorders such as diabetes-and core body temperature.
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.
Advances in lung cancer research announced at conference
Dr. Glen Weiss of the Translational Genomics Research Institute (TGen) and Scottsdale Healthcare this week announced two significant advances in treating lung cancer at an international cancer research conference.
Scripps Research scientists find early evolution maximized the 'spellchecking' of protein sequences
As letters of the alphabet spell out words, when amino acids are linked to one another in a particular order they "spell out" proteins.
Parasites ready to jump
Transposons are mobile genetic elements found in the hereditary material of humans and other organisms. They can replicate and the new copies can insert at novel sites in the genome.
International research team seeks to unravel flatworm regeneration
Planarian flatworms are only a few millimeters up to a few centimeters in length, live in freshwater and are the object of intense research, because they possess the extraordinary ability to regenerate lost tissue with the help of their stem cells (neoblasts) and even grow an entirely new worm out of minute amputated body parts.
LincRNAs serve as genetic air-traffic controllers
Earlier this year, a scientific team from Beth Israel Deaconess Medical Center (BIDMC) and the Broad Institute identified a class of RNA genes known as large intervening non-coding RNAs or "lincRNAs," a discovery that has pushed the field forward in understanding the roles of these molecules in many biological processes, including stem cell pluripotency, cell cycle regulation, and the innate immune response.
Active genes discovered in the developing mammal brain
A study by scientists at Penn State provides new information about the genes that are involved in a mammal's early brain development, including those that contribute to neurological disorders.
Gladstone scientists identify genetic factors that hold promise for treatment of vascular diseases
Researchers at the Gladstone Institute of Cardiovascular Disease (GICD) have discovered a key switch that makes stem cells turn into the type of muscle cells that reside in the wall of blood vessels.
Cancer researchers link DICER1 gene mutation to rare childhood cancer
Research published today in Science Express from the journal Science demonstrates the first definitive link between mutations in the gene DICER1 and cancer.
More RNA Molecules Current Events and RNA Molecules News Articles
 |
DNA and RNA Binders, From Small Molecules to Drugs (2-Volume Set) by Martine Demeunynck (Editor), Christian Bailly (Editor), W. David Wilson (Editor) The development of molecules that selectively bind to nucleic acids has provided many details about DNA and RNA recognition. The range of such substances, such as metal complexes, peptides, oligonucleotides and a wide array of synthetic organic compounds, is as manifold as the functions of nucleic acids. Nucleic acid recognition sequences are often found in the major or minor groove of a double strand, while other typical interactions include intercalation between base pairs or the formation of triple or quadruple helices. One example of a binding mode that has recently been proposed is end stacking on such complex structures as the telomere tetraplex. In this comprehensive book, internationally recognized experts describe in detail the important aspects of nucleic acid binding, and in so... |
 |
Individual DNA and Molecular Model Kit by Carolina Biological Supply Company For one student. Kit contains over 150 plastic, color-coded pieces representing nitrogenous bases (A, T, G, C), hydrogen bonds (flexible), phosphates, and sugars needed to construct a model of a short DNA segment with 8 base pairs. Also included are atoms of carbon, oxygen, nitrogen, hydrogen, and phosphorus, with the covalent bonding pieces needed to construct a DNA or RNA nucleotide. Models are easy to assemble and disassemble; all components are reusable. Includes a student instruction manual. |
|
RNA--marvellous, multi-tasking molecules.: An article from: Canadian Chemical News by Jennifer Gardy (Author) This digital document is an article from Canadian Chemical News, published by Thomson Gale on March 1, 2006. The length of the article is 445 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: RNA--marvellous, multi-tasking molecules. Author: Jennifer Gardy Publication: Canadian Chemical News (Magazine/Journal) Date: March 1, 2006 Publisher: Thomson Gale Volume: 58 Issue: 3 Page: 17(1) Distributed by Thomson... | |
 |
RNA Polymerases as Molecular Motors (RSC Biomolecular Sciences) by Henri Buc (Editor), Terence Strick (Editor) This book, written by expert scientists in the field, analyses how these diverse fields of research interact on a specific example - RNA polymerase. The book concentrates on RNA polymerases because they play a central role among all the other machines operating in the cell and are the target of a wide range of regulatory mechanisms. They have also been the subject of spectacular advances in their structural understanding in recent years, as testified by the attribution of the Nobel prize in chemistry in 2006 to Roger Kornberg. |
 |
Non-Protein Coding RNAs (Springer Series in Biophysics) by Nils G. Walter (Editor), Sarah A. Woodson (Editor), Robert T. Batey (Editor) This book assembles chapters from experts in the Biophysics of RNA to provide a broadly accessible snapshot of the current status of this rapidly expanding field. The 2006 Nobel Prize in Physiology or Medicine was awarded to the discoverers of RNA interference, highlighting just one example of a large number of non-protein coding RNAs. Because non-protein coding RNAs outnumber protein coding genes in mammals and other higher eukaryotes, it is now thought that the complexity of organisms is correlated with the fraction of their genome that encodes non-protein coding RNAs. Essential biological processes as diverse as cell differentiation, suppression of infecting viruses and parasitic transposons, higher-level organization of eukaryotic chromosomes, and gene expression itself are found to... |
|
MicroRNA molecule prevents skin cell proliferation.(RESEARCH NEWS)(ribonucleic acid)(Clinical report): An article from: Dermatology Nursing by Gale Reference Team (Author) This digital document is an article from Dermatology Nursing, published by Jannetti Publications, Inc. on October 1, 2008. The length of the article is 670 words. The page length shown above is based on a typical 300-word page. The article is delivered in HTML format and is available immediately after purchase. You can view it with any web browser. Citation Details Title: MicroRNA molecule prevents skin cell proliferation.(RESEARCH NEWS)(ribonucleic acid)(Clinical report) Author: Gale Reference Team Publication: Dermatology Nursing (Magazine/Journal) Date: October 1, 2008 Publisher: Jannetti Publications, Inc. Volume: 20 Issue: 5 Page: 413(2) Article Type: Clinical report Distributed by Gale, a part of Cengage... | |
|
mall Molecule DNA and RNA Binders, From Synthesis to Nucleic Acid Complexes (2-Volume Set) by Martine Demeunynck (Author) | |
|
Regulating muscle decline: small molecules linked to degenerative diseases.(This Week)(microRNAs, muscular diseases): An article from: Science News by P. Barry (Author) This digital document is an article from Science News, published by Thomson Gale on October 20, 2007. The length of the article is 520 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: Regulating muscle decline: small molecules linked to degenerative diseases.(This Week)(microRNAs, muscular diseases) Author: P. Barry Publication: Science News (Magazine/Journal) Date: October 20, 2007 Publisher: Thomson Gale Volume: 172 Issue: 16 Page: 244(2) Distributed by Thomson... | |
|
Quark files patent application covering chemical modifications to its RNAi molecules.: An article from: BIOTECH Patent News by Gale Reference Team (Author) This digital document is an article from BIOTECH Patent News, published by Thomson Gale on August 1, 2007. The length of the article is 448 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: Quark files patent application covering chemical modifications to its RNAi molecules. Author: Gale Reference Team Publication: BIOTECH Patent News (Newsletter) Date: August 1, 2007 Publisher: Thomson Gale Volume: 21 Issue: 8 Distributed by Thomson... | |
 |
Riboswitches: Methods and Protocols (Methods in Molecular Biology) by Alexander Serganov (Editor) The revolutionary discoveries of RNA interference and bacterial regulatory RNAs led to further breakthroughs such as the identification of riboswitches and related RNA sensors, mRNA regions capable of alternating their conformations in response to the presence of cellular metabolites and other physical or chemical cues. In "Riboswitches: Methods and Protocols", expert researchers provide comprehensive and up-to-date coverage of various methods used to study riboswitches and other RNAs involved in gene expression control. Examining biochemical and modern biophysical techniques, the volume focuses on mRNAs responding to small organic molecules but expands the definition of a riboswitch to incorporate classes of RNA that undergo conformational transitions in response to other stimuli in... |
| © 2009 BrightSurf.com |