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Contact: Phyllis Edelman
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301-634-7302
Genetics Society of America

Genetics Society of America’s GENETICS journal highlights for August 2012

Bethesda, MD—August 9, 2012 – Listed below are the selected highlights for the August 2012 issue of the Genetics Society of America's journal, GENETICS. The August issue is available online at www.genetics.org/content/current. Please credit GENETICS, Vol. 191, AUGUST 2012, Copyright © 2012.

Please feel free to forward to colleagues who may be interested in these articles.

ISSUE HIGHLIGHTS

New negative feedback regulators of Egfr signaling in Drosophila, pp. 1213
Jonathan P. Butchar, Donna Cain, Sathiya N. Manivannan, Andrea D. McCue, Liana Bonanno, Sarah Halula, Sharon Truesdell, Christina L. Austin, Thomas L. Jacobsen, and Amanda Simcox
While much is known about the checks and balances necessary for the precise specification of fly wings, these authors show that we didn't know it all. They report the discovery of two new negative regulators in the Egfr pathway that are conserved in other animals. Because a perfect wing is of critical importance to flies, it is likely that more such controls will be discovered.

On the prospects of whole-genome association mapping in Saccharomyces cerevisiae, pp. 1345
Caitlin F. Connelly and Joshua M. Akey
Genome-wide association (GWA) studies have not caught on for model organisms. One challenge is population structure, which can result in spurious associations. This article shows that indeed, GWA studies in yeast are complicated by complex patterns of population structure that are not easily corrected by existing approaches. The authors expound on how careful study design and empirical tests of the effects of population structure will be necessary for carrying out GWA studies in model organisms.

Suppressors, screens, and genes: An educational primer for use with "A network of genes antagonistic to the LIN-35 retinoblastoma protein of Caenorhabditis elegans", pp. 1031-1035
Elizabeth A. De Stasio
This is the first of a new series of articles in GENETICS — Educational Primers — designed to guide educators in the use of current scientific literature in the classroom (see editorial in this issue). In this Primer, Elizabeth De Stasio explains how Polley and Fay used RNA interference, suppressor screens, and synthetic phenotypes to elucidate the function of the retinoblastoma protein in C. elegans (see article in this issue). Each Primer provides necessary background for students and offers a sample approach to classroom use of the original article, including discussion questions.

A resolution of the mutation load paradox in humans, pp. 1321
Yann Lesecque, Peter D. Keightley, and Adam Eyre-Walker
It has been estimated that each of us receives, on average, at least two new harmful mutations from our parents. Previous theoretical work suggested that this high rate of harmful mutation should result in 88% of individuals failing to have offspring, and each female having to have more than 16 offspring on average, to maintain population size. Fortunately, those calculations are incorrect, as these authors show. They show that humans could tolerate hundreds of new harmful mutations if natural selection acts via competition between individuals.

SNP-ratio mapping (SRM): Identifying lethal alleles and mutations in complex genetic backgrounds by next-generation sequencing, pp. 1381
Heike Lindner, Michael T. Raissig, Christian Sailer, Hiroko Shimosato-Asano, Rémy Bruggmann, and Ueli Grossniklaus
Mutations in essential genes are difficult to identify. Here the authors present a method for quick identification of homozygous-lethal alleles by next-generation sequencing. The authors' method, which can also be used to map second-site modifiers in complex genetic/transgenic backgrounds, can be applied to any genetic organism.

The mRNA decay pathway regulates the expression of the Flo11 adhesin and biofilm formation in Saccharomyces cerevisiae, pp. 1387
Tricia L. Lo, Yue Qu, Nathalie Uwamahoro, Tara Quenault, Traude H. Beilharz, and Ana Traven
The gene encoding the yeast cell-wall adhesin Flo11 offers an excellent platform for learning how gene expression is controlled by extracellular signals and developmental pathways. Regulated expression of the cell-wall adhesins is also relevant to virulence properties of pathogenic fungi and industrial applications with yeasts. These investigators discover a novel mechanism controlling FLO11 expression: the mRNA decay pathway inhibits the expression of transcriptional repressors of FLO11.

Fluctuations of fitness distributions and the rate of Muller's ratchet, pp. 1283
Richard A. Neher and Boris I. Shraiman
Muller's ratchet is relentless, but its quantitative characterization has remained a challenge. This article offers a systematic analysis of the stochastic properties of the deleterious mutation selection-balance, and provides an accurate formula for the rate of Muller's ratchet.

A network of genes antagonistic to the LIN-35 retinoblastoma protein of Caenorhabditis elegans, pp. 1367
Stanley R. G. Polley and David S. Fay
The pRb tumor suppressor of Caenorhabditis elegans (LIN-35) regulates a diverse range of cellular and developmental processes. This article describes genes that were identified as genetic suppressors of phenotypes associated with LIN-35/pRb loss of function in the worm. Because the encoded proteins are highly conserved, these may represent candidate targets for anticancer therapies, as their inactivation alleviates defects associated with a commonly inactivated tumor suppressor in humans.

Transvection is common throughout the Drosophila genome, pp. 1129
David J. Mellert and James W. Truman
We know that cis-regulatory sequence elements can regulate transcription in trans, but what is the prevalence of their action in trans? These investigators show that trans interactions between transgenes inserted into the Drosophila genome is common, and provide insight into possible molecular mechanisms. Because trans interactions between transgenes can confound experimental strategies, the authors propose guidelines for using transgenes inserted via site-specific integration.

and

Comparing enhancer action in cis and in trans, pp. 1143
Jack R. Bateman, Justine E. Johnson, and Melissa N. Locke
Sometimes two chromosomes are close enough that an enhancer on one can communicate in trans with a promoter on its neighbor. How does this "transvection" work? This article describes a transgenic approach to the study of transvection that simplifies sequence manipulation and enables precise quantification of changes to gene expression when enhancers act in cis or trans.

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ABOUT GENETICS: Since 1916, GENETICS (http://www.genetics.org/) has covered high quality, original research on a range of topics bearing on inheritance, including population and evolutionary genetics, complex traits, developmental and behavioral genetics, cellular genetics, gene expression, genome integrity and transmission, and genome and systems biology. GENETICS, a peer-reviewed, peer-edited journal of the Genetics Society of America is one of the world's most cited journals in genetics and heredity.

ABOUT GSA: Founded in 1931, the Genetics Society of America (GSA) is the professional membership organization for scientific researchers, educators, bioengineers, bioinformaticians and others interested in the field of genetics. Its nearly 5,000 members work to advance knowledge in the basic mechanisms of inheritance, from the molecular to the population level. GSA is dedicated to promoting research in genetics and to facilitating communication among geneticists worldwide through its conferences, including the biennial conference on Model Organisms to Human Biology, an interdisciplinary meeting on current and cutting edge topics in genetics research, as well as annual and biennial meetings that focus on the genetics of particular organisms, including C. elegans, Drosophila, fungi, mice, yeast, and zebrafish. GSA publishes GENETICS, a leading journal in the field and an online, open-access journal, G3: Genes|Genomes|Genetics. For more information about GSA, please visit www.genetics-gsa.org. Also follow GSA on Facebook at facebook.com/GeneticsGSA and on Twitter @GeneticsGSA.



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