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[
Bioessays,
2008]
Predicting the phenotype of an organism from its genotype is a central question in genetics. Most importantly, we would like to find out if the perturbation of a single gene may be the cause of a disease. However, our current ability to predict the phenotypic effects of perturbations of individual genes is limited. Network models of genes are one tool for tackling this problem. In a recent study, (Lee et al.) it has been shown that network models covering the majority of genes of an organism can be used for accurately predicting phenotypic effects of gene perturbations in multicellular organisms. BioEssays 30:707-710, 2008. (c) 2008 Wiley Periodicals, Inc.
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Genome Res,
1995]
Caenorhabditis elegans, a free-living nematode worm, has proved a particularly useful model organism for studying the anatomy, behavior, genetics, and development of a metazoan. It also has one of the smallest genomes of the higher eukaryotes (100 Mb distributed over six chromosomes), making it an ideal candidate for detailed molecular analysis. The C. elegans genome project began over 10 years ago and is a collaberative effort between two laboratories (St. Louis, MO, USA and Cambridge, UK), with the ultimate aim of mapping and sequencing the whole of the 100-Mb genome. The consortium has now completed the sequence of approximately one-fifth of the genome and plans to have sequenced more than half the genome before the end
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[
1980]
A number of review articles on the nematode cuticle have been published in the last decade. The most recent of these are those of Bird and Lee and Atkinson. These authors, while emphasizing the complexity and variability of nematode cuticles, support the use of a simplified nomenclature of cuticle structure which divides the cuticle into three regions or zones-namely, cortical, median, and basal. It is obvious that many exceptions to this fundamental pattern occur, and I shall mention some of these below. However, I think that they are adaptations to survival in changing environments, particularly where parasitism is involved. In particular, I propose to consider the structure and functions of the surface or epicuticle of the cortical zone, for it is here that reactions similar to those occurring at cell surfaces and in cell membranes are thought to occur in a wide range of "helminth" organisms. At the moment, particularly for the Nematoda, these ideas require more experimental evidence to establish them as facts. However, the use of sensitive techniques currently employed by membrane physicists and chemists to isolate, label, analyze, measure, and observe interactions taking place in cell membranes have in many instances yet to be used on the nematode cuticle. There is no doubt that the free-living bacterial-feeding nematodes such as those belonging to the genus Caenorhabditis, and in particular C. elegans, are the experimental models of choice for this purpose.
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[
Methods Cell Biol,
1995]
The clone-based physical map of the 100-Mb Caenorhabditis elegans genome has evolved over a number of years. Although the detection of clone overlaps and construction of the map have of necessity been carried out centrally, it has been essentially a community project. Without the provision of cloned markers and relevant map information by the C. elegans community as a whole, the map would lack the genetic anchor points and coherent structure that make it a viable entity. Currently, the map consists of 13 mapped contigs totaling in excess of 95 Mb and 2 significant unmapped contigs totaling 1.3 Mb. Telomeric clones are not yet in place. The map carries 600 physically mapped loci, of which 262 have genetic map data. With one exception, the physical extents of the remaining gaps are not known. The exception is the remaining gap on linkage group (LG) II. This has been shown to be bridged by a 225-kb Sse83871 fragment. Because the clones constituting the map are a central resource, there is essentially no necessity for individuals to construct cosmid and yeast artificial chromosome (YAC) libraries. Consequently, such protocols are not included here. Similarly, protocols for clone fingerprinting, which forms the basis of the determination of cosmid overlaps and the mapping of clones received from outside sources and has to be a centralized operation, and YAC linkage are not give here. What follows is essentially a "user's guide" to the physical map. Details of map construction are given where required for interpretation of the map as distributed. The physical mapping has been a collaboration between the MRC Laboratory of Molecular Biology, Cambridge, United Kingdom (now at The Sanger Centre, Cambridge, UK) and Washington University School of Medicine, St. Louis, Missouri. Inquiries regarding map interpretation, information, and materials should be addressed to alan@sanger.ac.uk or rw@nematode.wustl.edu.
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Crit Rev Biochem Mol Biol,
2012]
The CCAAT box promoter element and NF-Y, the transcription factor (TF) that binds to it, were among the first cis-elements and trans-acting factors identified; their interplay is required for transcriptional activation of a sizeable number of eukaryotic genes. NF-Y consists of three evolutionarily conserved subunits: a dimer of NF-YB and NF-YC which closely resembles a histone, and the "innovative" NF-YA. In this review, we will provide an update on the functional and biological features that make NF-Y a fundamental link between chromatin and transcription. The last 25 years have witnessed a spectacular increase in our knowledge of how genes are regulated: from the identification of cis-acting sequences in promoters and enhancers, and the biochemical characterization of the corresponding TFs, to the merging of chromatin studies with the investigation of enzymatic machines that regulate epigenetic states. Originally identified and studied in yeast and mammals, NF-Y - also termed CBF and CP1 - is composed of three subunits, NF-YA, NF-YB and NF-YC. The complex recognizes the CCAAT pentanucleotide and specific flanking nucleotides with high specificity (Dorn et al., 1997; Hatamochi et al., 1988; Hooft van Huijsduijnen et al, 1987; Kim & Sheffery, 1990). A compelling set of bioinformatics studies clarified that the NF-Y preferred binding site is one of the most frequent promoter elements (Suzuki et al., 2001, 2004; Elkon et al., 2003; Marino-Ramirez et al., 2004; FitzGerald et al., 2004; Linhart et al., 2005; Zhu et al., 2005; Lee et al., 2007; Abnizova et al., 2007; Grskovic et al., 2007; Halperin et al., 2009; Hakkinen et al., 2011). The same consensus, as determined by mutagenesis and SELEX studies (Bi et al., 1997), was also retrieved in ChIP-on-chip analysis (Testa et al., 2005; Ceribelli et al., 2006; Ceribelli et al., 2008; Reed et al., 2008). Additional structural features of the CCAAT box - position, orientation, presence of multiple Transcriptional Start Sites - were previously reviewed (Dolfini et al., 2009) and will not be considered in detail here.