 |
|
UC Riverside Researchers Discover Model Organism For Studying Viruses that Affect Humans
August 18, 2005Simple nematode has similar virus-fighting mechanism as humans and can be used in research
RIVERSIDE, Calif. - www.ucr.edu - Researchers at the University of California, Riverside have discovered that a simple worm, called C. elegans, makes an excellent experimental host for studying some of the most virulent viruses that infect humans.
The researchers published their findings in the Aug. 18 issue of the journal Nature in a paper titled, Animal virus replication and RNAi-mediated antiviral silencing in C. elegans.
UCR Professor of Plant Pathology Shou-Wei Ding co-authored the paper with Morris Maduro, assistant professor of biology; Feng Li, a graduate student in microbiology; Rui Lu and Hongwei Li, postdoctoral researchers in Ding's laboratory; and research specialists Gina Broitman-Maduro and Wan-Xiang Li. Lu and Maduro are co-first authors of this Nature paper. The National Institutes of Health and the U.S. Department of Agriculture supported the research.
The paper reflects a major step forward in the study of how some of the world's most virulent viruses, such as West Nile, SARS, Ebola and Hepatitis C interact with their hosts.
"All these viruses are very dangerous and are traditionally studied in animal models, so large-scale genetic studies of the host-virus interaction is very hard to do," said Ding, who works in the Center for Plant Cell Biology at UCR's Institute for Integrative Genome Biology. "Needless to say, we are all very excited to find that this little worm can be used to understand how hosts genetically control viruses."
For years researchers throughout the world have studied C. elegans because many aspects of its biology, such as genetics, development and the workings of neurons, mirror the biology of humans. However, no viruses were known to infect the millimeter-long roundworm so it was not used as a model for studying viral infections.
The Nature paper now shows that UC Riverside researchers have developed a strain of the worm, C. elegans, in which an animal virus could replicate, allowing them to map the delicate dance of action and reaction between virus and host.
The UCR team has shown that virus replication in the worm triggers an antiviral response known as RNA silencing or RNA interference (RNAi). RNAi specifically breaks down the virus' RNA. Virus RNA creates proteins that allow the virus to function. The virus responds by producing a protein acting as a suppressor of RNAi to shut down the host's antiviral response. Virus infection did not occur when the viral RNAi suppressor was made inactive by genetic mutations in the host system.
C. elegans' RNAi system is considered a "blanket system," meaning that it has parallels in humans, making the worm model discovered by Ding and his colleagues a valuable tool in studying the way viruses interact with hosts. This tool may speed the discovery of treatments for virus-caused diseases that plague humans.
"The RNAi machinery is very similar between humans and C. elegans, and human viruses such as Influenza A virus and HIV are known to produce RNAi suppressors," Ding said. "So now, the question is can we treat human viral diseases using chemical inhibitors of viral RNAi suppressors?"
The methods outlined in the Nature paper are now being used to generate additional C. elegans strains for screening chemical compounds that inactivate RNAi suppressors associated with avian flu, HIV and others.
University of California, Riverside
UCR Professor of Plant Pathology Shou-Wei Ding co-authored the paper with Morris Maduro, assistant professor of biology; Feng Li, a graduate student in microbiology; Rui Lu and Hongwei Li, postdoctoral researchers in Ding's laboratory; and research specialists Gina Broitman-Maduro and Wan-Xiang Li. Lu and Maduro are co-first authors of this Nature paper. The National Institutes of Health and the U.S. Department of Agriculture supported the research.
The paper reflects a major step forward in the study of how some of the world's most virulent viruses, such as West Nile, SARS, Ebola and Hepatitis C interact with their hosts.
"All these viruses are very dangerous and are traditionally studied in animal models, so large-scale genetic studies of the host-virus interaction is very hard to do," said Ding, who works in the Center for Plant Cell Biology at UCR's Institute for Integrative Genome Biology. "Needless to say, we are all very excited to find that this little worm can be used to understand how hosts genetically control viruses."
For years researchers throughout the world have studied C. elegans because many aspects of its biology, such as genetics, development and the workings of neurons, mirror the biology of humans. However, no viruses were known to infect the millimeter-long roundworm so it was not used as a model for studying viral infections.
The Nature paper now shows that UC Riverside researchers have developed a strain of the worm, C. elegans, in which an animal virus could replicate, allowing them to map the delicate dance of action and reaction between virus and host.
The UCR team has shown that virus replication in the worm triggers an antiviral response known as RNA silencing or RNA interference (RNAi). RNAi specifically breaks down the virus' RNA. Virus RNA creates proteins that allow the virus to function. The virus responds by producing a protein acting as a suppressor of RNAi to shut down the host's antiviral response. Virus infection did not occur when the viral RNAi suppressor was made inactive by genetic mutations in the host system.
C. elegans' RNAi system is considered a "blanket system," meaning that it has parallels in humans, making the worm model discovered by Ding and his colleagues a valuable tool in studying the way viruses interact with hosts. This tool may speed the discovery of treatments for virus-caused diseases that plague humans.
"The RNAi machinery is very similar between humans and C. elegans, and human viruses such as Influenza A virus and HIV are known to produce RNAi suppressors," Ding said. "So now, the question is can we treat human viral diseases using chemical inhibitors of viral RNAi suppressors?"
The methods outlined in the Nature paper are now being used to generate additional C. elegans strains for screening chemical compounds that inactivate RNAi suppressors associated with avian flu, HIV and others.
University of California, Riverside
C Elegans Current Events and C Elegans News RSSWorm genome offers clues to evolution of parasitism
The genome of a humble worm that dines on the microbial organisms covering the carcasses of dead beetles may provide clues to the evolution of parasitic worms, including those that infect humans, say scientists at Washington University School of Medicine in St. Louis and the Max-Planck Institute for Developmental Biology in Germany.
Mate or hibernate? That's the question worm pheromones answer
If worms could talk, they might tell potential suitors, "I like the way you wriggle," complete with that telltale come slither look.
Bloodless Worm Sheds Light on Human Blood, Iron Deficiency
Using a lowly bloodless worm, University of Maryland researchers have discovered an important clue to how iron carried in human blood is absorbed and transported into the body. The finding could lead to developing new ways to reduce iron deficiency, the world's number one nutritional disorder.
Snoozing worms help Penn researchers explain the evolution of sleep
The roundworm C. elegans, a staple of laboratory research, may be key in unlocking one of the central biological mysteries: why we sleep. Researchers at the University of Pennsylvania School of Medicine report in this week's advanced online edition of Nature that the round worm has a sleep-like state, joining most of the animal kingdom in displaying this physiology.
Executable biology -- Computer science sheds light on animal development
By applying the techniques of computer engineering to a mechanistic diagram describing the development of the Nematode C. elegans, a group of researchers in Switzerland has been able to tease out what laboratory experiments have not - how and when the crucial cross-talk between cellular signaling pathways takes place in order to determine the fates of individual cells.
Don't move a muscle: Evolutionary insight into myogenesis
In a paper released online ahead of its scheduled December 15th publication date, Dr. Michael Krause (NIH) and colleagues detail the transcription network that drives muscle development in the roundworm C. elegans, and make a strong argument for an evolutionarily conserved program of myogenesis in all animals.
New clues to how sex evolves
Sex is a boon to evolution; it allows genetic material from parents to recombine, giving rise to a unique new genome. But how did sex itself evolve\\\
Tiny worm provides model for the genetics of nicotine dependence
The unassuming C. elegans nematode worm, a 1-millimeter workhorse of the genetics lab, is quite similar to human beings in its genetic susceptibility to nicotine dependence.
U. of Colorado team solves mystery of carcinogenic mothballs
Chemical compounds in household products like mothballs and air fresheners can cause cancer by blocking the normal process of "cell suicide" in living organisms, according to a new study spearheaded by the University of Colorado at Boulder.
Biologists develop genome-wide map of miRNA-mRNA interactions
Researchers at New York University's Center for Comparative Functional Genomics and the University of California, Berkeley have used computational analyses to predict a genome-wide map of microRNA (miRNA) targets in the animal model organism, Caenorhabditis elegans (C. elegans).
More C Elegans Current Events and C Elegans News Articles
 | C. elegans: Methods and Applications (Methods in Molecular Biology) Nonmammalian model organisms have become a cornerstone of systems biology research. Like the Rosetta Stone, which enabled modern scholars to decode ancient Egyptian hieroglyphics, model organisms enable biologists to decipher the genetic code underlying the complex physiological processes common to all life. C. elegans provides a particularly striking example of the experimental utility of... |
 | C. Elegans II : Monograph 33 (Cold Spring Harbor Monograph Series,33) (Cold Spring Harbor Monograph) by Donald L. Riddle Studies of the cells and genes of the nematode C. elegans have become a cornerstone of current biology. A classic 1988 Cold Spring Harbor monograph, The Nematode Caenorhabditis elegans, described the basic genetics, anatomy and development of the organism. Now, in that authoritative tradition, comes C. elegans II -- not a second edition but a book that breaks new ground and defines the ... |
 | The Neurobiology of C. elegans, Volume 69 The Neurobiology of C. elegans assembles together a series of chapters describing the progress researchers have made toward solving some of the major problems in neurobiology with the use of this powerful model organism. The first chapter is an introduction to the anatomy of the C. elegans nervous system. This chapter provides a useful introduction to this system and will help the reader who is... |
 | C. elegans Atlas by David H. Hall Derived from the acclaimed online "WormAtlas," C. elegans Atlas is a large-format, full-color atlas of the hermaphroditic form of the model organism C. elegans, known affectionately as "the worm" by workers in the field. Prepared by the editors of the WormAtlas Consortium, David H. Hall and Zeynep F. Altun, this book combines explanatory text with copious, labeled, color illustrations and... |
 | C. elegans: A Practical Approach (Practical Approach Series) Caenorhabditis Elegans has been a popular model organism for biological research for over thirty years and has been used to investigate many aspects of animal development, for example apoptosis, the Hox genes, signal transduction pathways, and the development of the nervous system. It has recently taken on new importance with the publication of its entire genome sequence in 1998. This book... |
 | RNA Interference in Practice: Principles, Basics, and Methods for Gene Silencing in C.elegans, Drosophila, and Mammals by Ute Schepers This hands-on guide to RNA interference brings the power of targeted gene silencing to any laboratory with the basic equipment for handling nucleic acids. In easy-to-follow, step-by-step protocols you will learn: How RNAi works in worms, flies and mammals How to design the most efficient RNAi constructs How to achieve transient, stable and conditional RNAi in cell cultures ... |
 | AYs Neuroanatomy of C Elegans for Computation by Theodore B. Achacoso, William S. Yamamoto AY's Neuroanatomy of C. elegans for Computation provides the neural circuitry database of the nematode Caenorhabditis elegans, both in printed form and in ASCII files on 5.25-inch diskettes (for use on IBM® and compatible personal computers, Macintosh® computers, and higher level machines). Tables of connections among neuron classes, synapses among individual neurons, gap junctions among... |
 | C. elegans FANCD2 responds to replication stress and functions in interstrand cross-link repair [An article from: DNA Repair] by S.J. Collis, L.J. Barber, J.D. Ward, J.S. Martin This digital document is a journal article from DNA Repair, published by Elsevier in 2006. The article is delivered in HTML format and is available in your Amazon.com Media Library immediately after purchase. You can view it with any web browser.Description: One of the least well understood DNA repair processes in cells is the repair of DNA interstrand cross-links (ICLs) which present a major... |
 | Single and double metallothionein knockout in the nematode C. elegans reveals cadmium dependent and independent toxic effects on life history traits [An article from: Environmental Pollution] by S. Hughes, S.R. Sturzenbaum This digital document is a journal article from Environmental Pollution, published by Elsevier in 2007. The article is delivered in HTML format and is available in your Amazon.com Media Library immediately after purchase. You can view it with any web browser.Description: The genome of the nematode Caenorhabditis elegans contains two metallothionein genes, both involved in metal homeostasis and/or... |
| The C. elegans gene pme-5: molecular cloning and role in the DNA-damage response of a tankyrase orthologue [An article from: DNA Repair] by C. Gravel, L. Stergiou, S.N. Gagnon, S. Desnoyers This digital document is a journal article from DNA Repair, published by Elsevier in 2004. The article is delivered in HTML format and is available in your Amazon.com Media Library immediately after purchase. You can view it with any web browser.Description: Tankyrases are recently identified proteins characterized by ankyrin repeats and a poly(ADP-ribose) polymerase (PARP) signature motif. In... |
| © 2008 BrightSurf.com |