 |
|
CSHL scientists discover specific small RNA pathways protect germ line from transposons
May 06, 2009In the fruit fly ovary, germ line and somatic cells use different piRNA pathways in transposon defense
Cold Spring Harbor, N.Y. - Cells of higher organisms are in a constant struggle against some of their own DNA - repeated bits of DNA sequence called transposons that have infiltrated host genomes over the eons. Transposons damage the rest of the genome when they copy themselves and jump into new genomic sites.
To protect themselves from these genetic parasites, animal germ line cells such as sperm and eggs, whose mission is to pass on undamaged DNA to the next generation, have developed a molecular immune system. This system is operated by an army of small RNA molecules called Piwi-interacting RNAs (piRNAs) and a set of proteins belonging to the Piwi family.
In a new study appearing in the May 1 issue of Cell, Professor Gregory Hannon, Ph.D., of Cold Spring Harbor Laboratory (CSHL), and his team, report that in the ovaries of fruit flies, non-germ line, or "somatic cells" that surround germ line cells have also developed an anti-transposon defense system.
The piRNAs and protein components of this somatic system, however, are distinct from their counterparts within germ line cells, the researchers show. The system that defends somatic cells specifically guards against a particular class of transposon called gypsy elements. These bits of DNA mobilize themselves for attacks in a way that differs from that used by transposons active in germ cells.
Two distinct piRNA pathways in the ovary
Many transposons propagate themselves by first getting copied or transcribed into RNA, which in turn gets copied back into a new DNA segment. That new segment is then inserted into a new genomic location. Gypsy elements similarly begin to mobilize by first converting into RNA, but are then processed into virus-like particles that propagate by infecting neighboring cells. "But the step in which the transposon is transcribed to RNA is also an Achilles heel," notes Hannon. "Cells are able to defend themselves by targeting the transposons during this intermediate RNA step."
The cell's counter-response is a form of defense called RNA interference, in which piRNAs partner with members of the Piwi protein family - called Argonaute3 (AGO3), Aubergine (Aub) and Piwi - to "silence" transposons. These three proteins act as molecular "scissors" that slice up transposon RNA that their piRNA "guides" lead them to.
While all three Piwi proteins - AGO3, Aub and Piwi - are found in germ cells, Hannon and the CSHL team found only the Piwi protein in somatic cells that surround germ line cells. This suggested to them possible differences in the architecture of the piRNA pathway between the two cell types.
Separating germ line and somatic cells
But how to separate RNA and protein components of the germ cells from that of the surrounding somatic cells? "We simply exploited the fruit fly's natural biology to do this," says Colin Malone, a graduate student in the Hannon lab who led the current study. When fruit fly germ cells develop into embryos, they shed the surrounding somatic cells. A newly laid egg thus includes RNA and protein components that are present only in the germ line, and not the ovary's somatic tissue.
By comparing piRNAs in embryos to those in the ovary, then, the CSHL team discovered that while germ cells contained piRNAs targeted to a variety of transposons, the somatic piRNA fraction utilizes only the Piwi protein to selectively suppress gypsy transposons.
The somatic cells therefore appear to make use of a simplified form of the piRNA "scaffold," employing only one Piwi protein and particular piRNAs to defend against a single class of transposons - the gypsy elements, which might try to gain access to adjacent germ cells through their ability to package themselves like a virus.
Somatic cells are defended by the flamenco piRNA cluster
piRNAs arise from so-called 'transposon graveyards' in the genome, where transposon remnants that can no longer jump are clustered. Scientists speculate that these clusters persist in genomes to provide host cells with a "memory" of previous transposon exposure.
"Once a transposon jumps into a piRNA cluster, that transposon's future is grim," says Malone. The cell will immediately make piRNAs that target this transposon, so that any future activity is immediately blocked.
Hannon's lab had previously found that piRNAs generated from most clusters get amplified in number via a "ping-pong" mechanism - reciprocal cycles of cleavage of RNA molecules by pairs of Piwi-family proteins. They now find that only germ cells use this mechanism to generate and amplify their piRNA stockpile.
In somatic cells, however, the scientists found that the piRNAs utilized by the sole Piwi protein arise from a single cluster called flamenco. This cluster, the authors suggest, appears to be conserved - unchanged over evolutionary time - in most Drosophila species. This in fact represents tens of millions of years of evolution.
The significance of the finding
"The gypsy family may have evolved their own mobilization strategy in the soma to evade the extensive anti-transposon surveillance system already in place in the neighboring germ cells," explains Malone. "The somatic cells, in turn, might have adapted a distinct piRNA pathway, centered on Piwi and the flamenco cluster, as a counter-evolutionary move to cope with this unique threat."
Over the years, fruit fly researchers have uncovered a number of genomic mutations that lead to sterility and abnormal development. Since these defects could have been caused by unchecked transposon activity, mutant flies are a good experimental resource to uncover exactly how piRNA pathways work and how they might get disrupted.
The Hannon team has analyzed eight such mutants, showing how the genes disrupted in each mutant impact the piRNA pathway and how it alters the type and number of piRNAs that cells are able to generate.
"We are beginning to paint a broad picture of how the piRNA pathway has been genetically stitched together," says Hannon. "This work brings decades of research into a cohesive model that can be used as the starting point to understand how each gene that contributes to a fly's biological phenotype is acting at the molecular level."
Cold Spring Harbor Laboratory
In a new study appearing in the May 1 issue of Cell, Professor Gregory Hannon, Ph.D., of Cold Spring Harbor Laboratory (CSHL), and his team, report that in the ovaries of fruit flies, non-germ line, or "somatic cells" that surround germ line cells have also developed an anti-transposon defense system.
The piRNAs and protein components of this somatic system, however, are distinct from their counterparts within germ line cells, the researchers show. The system that defends somatic cells specifically guards against a particular class of transposon called gypsy elements. These bits of DNA mobilize themselves for attacks in a way that differs from that used by transposons active in germ cells.
Two distinct piRNA pathways in the ovary
Many transposons propagate themselves by first getting copied or transcribed into RNA, which in turn gets copied back into a new DNA segment. That new segment is then inserted into a new genomic location. Gypsy elements similarly begin to mobilize by first converting into RNA, but are then processed into virus-like particles that propagate by infecting neighboring cells. "But the step in which the transposon is transcribed to RNA is also an Achilles heel," notes Hannon. "Cells are able to defend themselves by targeting the transposons during this intermediate RNA step."
The cell's counter-response is a form of defense called RNA interference, in which piRNAs partner with members of the Piwi protein family - called Argonaute3 (AGO3), Aubergine (Aub) and Piwi - to "silence" transposons. These three proteins act as molecular "scissors" that slice up transposon RNA that their piRNA "guides" lead them to.
While all three Piwi proteins - AGO3, Aub and Piwi - are found in germ cells, Hannon and the CSHL team found only the Piwi protein in somatic cells that surround germ line cells. This suggested to them possible differences in the architecture of the piRNA pathway between the two cell types.
Separating germ line and somatic cells
But how to separate RNA and protein components of the germ cells from that of the surrounding somatic cells? "We simply exploited the fruit fly's natural biology to do this," says Colin Malone, a graduate student in the Hannon lab who led the current study. When fruit fly germ cells develop into embryos, they shed the surrounding somatic cells. A newly laid egg thus includes RNA and protein components that are present only in the germ line, and not the ovary's somatic tissue.
By comparing piRNAs in embryos to those in the ovary, then, the CSHL team discovered that while germ cells contained piRNAs targeted to a variety of transposons, the somatic piRNA fraction utilizes only the Piwi protein to selectively suppress gypsy transposons.
The somatic cells therefore appear to make use of a simplified form of the piRNA "scaffold," employing only one Piwi protein and particular piRNAs to defend against a single class of transposons - the gypsy elements, which might try to gain access to adjacent germ cells through their ability to package themselves like a virus.
Somatic cells are defended by the flamenco piRNA cluster
piRNAs arise from so-called 'transposon graveyards' in the genome, where transposon remnants that can no longer jump are clustered. Scientists speculate that these clusters persist in genomes to provide host cells with a "memory" of previous transposon exposure.
"Once a transposon jumps into a piRNA cluster, that transposon's future is grim," says Malone. The cell will immediately make piRNAs that target this transposon, so that any future activity is immediately blocked.
Hannon's lab had previously found that piRNAs generated from most clusters get amplified in number via a "ping-pong" mechanism - reciprocal cycles of cleavage of RNA molecules by pairs of Piwi-family proteins. They now find that only germ cells use this mechanism to generate and amplify their piRNA stockpile.
In somatic cells, however, the scientists found that the piRNAs utilized by the sole Piwi protein arise from a single cluster called flamenco. This cluster, the authors suggest, appears to be conserved - unchanged over evolutionary time - in most Drosophila species. This in fact represents tens of millions of years of evolution.
The significance of the finding
"The gypsy family may have evolved their own mobilization strategy in the soma to evade the extensive anti-transposon surveillance system already in place in the neighboring germ cells," explains Malone. "The somatic cells, in turn, might have adapted a distinct piRNA pathway, centered on Piwi and the flamenco cluster, as a counter-evolutionary move to cope with this unique threat."
Over the years, fruit fly researchers have uncovered a number of genomic mutations that lead to sterility and abnormal development. Since these defects could have been caused by unchecked transposon activity, mutant flies are a good experimental resource to uncover exactly how piRNA pathways work and how they might get disrupted.
The Hannon team has analyzed eight such mutants, showing how the genes disrupted in each mutant impact the piRNA pathway and how it alters the type and number of piRNAs that cells are able to generate.
"We are beginning to paint a broad picture of how the piRNA pathway has been genetically stitched together," says Hannon. "This work brings decades of research into a cohesive model that can be used as the starting point to understand how each gene that contributes to a fly's biological phenotype is acting at the molecular level."
Cold Spring Harbor Laboratory
Cold Spring Harbor Scientists Are Part of Consortium That Sequences Platypus Genome, Unlocking Secrets of Evolution
By any account, the platypus is an odd creature. It's got a broad, rubbery bill that brings to mind a duck-.but it swims more like a beaver-.yet it lays eggs and can inject poisonous venom, like a reptile.
More RNA Pathways Current Events and RNA Pathways News Articles
 |
RNA Interference (Current Topics in Microbiology and Immunology) by Patrick J. Paddison (Author), Patrick J. Paddison (Editor), Peter K. Vogt (Editor) In the last few years the major effect that RNAi has had in invertebrate systems like C.elegans and drosophila is beginning to take hold in mammalian systems through both single gene knockdown experiments and genome-scale screens. In the next decade, there will no doubt be both notable successes and failures as we attempt to apply this genetic tool to various biological problems for the first time in academia and industry. Through the introduction of RNAi, mammalian systems have finally gained admittance to the pantheon of model genetic systems. |
 |
RNA Turnover in Eukaryotes: Analysis of Specialized and Quality Control RNA Decay Pathways, Volume 449 (Methods in Enzymology) by Lynne E. Maquat (Editor), Megerditch Kiledjian (Editor) Specific complexes of protein and RNA carry out many essential biological functions, including RNA processing, RNA turnover, RNA folding, as well as the translation of genetic information from mRNA into protein sequences. Messenger RNA (mRNA) decay is now emerging as an important control point and a major contributor to gene expression. Continuing identification of the protein factors and cofactors, and mRNA instability elements responsible for mRNA decay allow researchers to build a comprehensive picture of the highly orchestrated processes involved in mRNA decay and its regulation. * Covers the nonsense-mediated mRNA decay (NMD) or mRNA surveillance pathway * Expert researchers introduce the most advanced technologies and techniques... |
![The ATM-related kinase, hSMG-1, bridges genome and RNA surveillance pathways [An article from: DNA Repair]](http://ecx.images-amazon.com/images/I/51FZ3K9Y7XL._SL160_.jpg) |
The ATM-related kinase, hSMG-1, bridges genome and RNA surveillance pathways [An article from: DNA Repair] by R.T. Abraham (Author) 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: Recent studies have identified, hSMG-1 as the newest member of the phosphoinositide 3-kinase(PI3-kinase)-related kinase (PIKK) family. The protein kinase activity of hSMG-1 resembles that of the related PIKK, ATM, both in terms of substrate specificity and its sensitivity to inhibition by the fungal metabolite wortmannin. hSMG-1 is the ortholog of a Caenorhabditis elegans protein, CeSMG-1, which has been genetically linked to a critical mRNA surveillance pathway termed nonsense-mediated decay (NMD). The function of NMD is... |
 |
RNA Turnover in Eukaryotes: Nucleases, Pathways and Analysis of mRNA Decay, Volume 448 (Methods in Enzymology) by Lynne E. Maquat (Editor), Megerditch Kiledjian (Editor) Specific complexes of protein and RNA carry out many essential biological functions, including RNA processing, RNA turnover, RNA folding, as well as the translation of genetic information from mRNA into protein sequences. Messenger RNA (mRNA) decay is now emerging as an important control point and a major contributor to gene expression. Continuing identification of the protein factors and cofactors, and mRNA instability elements, responsible for mRNA decay allow researchers to build a comprehensive picture of the highly orchestrated processes involved in mRNA decay and its regulation. The control of biological processes, such as cellular growth and differentiation, is dependent on how the genetic material within a cell is expressed. The cellular physiology of mRNA-including mRNA... |
 |
Nuclear pre-mRNA Processing in Plants (Current Topics in Microbiology and Immunology) by A. S. N. Reddy (Author), A. S. N. Reddy (Editor), Maxim V. Golovkin (Editor) In recent years nuclear pre-mRNA processing has taken center stage as an important regulator of gene expression and ultimately growth and development. Large-scale genome and cDNA sequencing projects together with bioinformatic analyses of these sequences have revealed that alternative splicing of pre-mRNAs contributes greatly to transcriptome and proteome complexity in eukaryotes. During the last few years, tremendous progress has been made in understanding various aspects of pre-mRNA processing including alternative splicing and its importance in plant growth and development as well as in plant responses to hormones and stresses. This book, with contributions from leading scientists in this area, summarizes recent advances in nuclear pre-mRNA processing in plants. It provides... |
|
|
New insights for understanding the transcription-coupled repair pathway [An article from: DNA Repair] by A. Sarasin (Author), A. Stary (Author) This digital document is a journal article from DNA Repair, 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: Transcription-coupled repair (TCR) is a sub-pathway of nucleotide excision repair (NER) able to remove bulky DNA lesions located on the transcribed strands of active genes more rapidly than those located on the non-transcribed genomic DNA. Two recently published reports try to dissect the molecular mechanisms of TCR using simplified in vitro assays. A third report shows in vivo data that confirmed the in vitro ones and extends them to the role of other TCR factors such as those involved in chromatin remodeling. These... |
 |
The Metabolic Pathway Engineering Handbook: Tools and Applications (v. 2) by Christina Smolke (Editor) This second volume of the Metabolic Engineering Handbook delves into evolutionary tools as well as. gene expression tools for metabolic pathway engineering. It covers applications of emerging technologies including recent research genome-wide technologies, DNA and phenotypic microarrays, and proteomics. tools for experimentally determining flux through pathways. This volume also looks at emerging applications for producing fine chemicals, drugs, and alternative fuels. Christine Smolke, who recently developed a novel way to churn out large quantities of drugs from genetically modified brewer’s yeast, is regarded as one of the most brilliant new minds in biomedical engineering. In this handbook, she brings together pioneering scientists from dozens of disciplines to provide a... |
| © 2009 BrightSurf.com |