Host genetic architecture and the landscape of microbiome composition: humans weigh in

Comparative analyses of the control of mammalian microbiomes by host genetic architecture reveal striking conserved features that have implications for the evolution of host–microbiome interactions.See related Research article: http://www.genomebiology.com/2015/16/1/191     

Interactome analysis brings splicing into focus

The spliceosome is a huge molecular machine that assembles dynamically onto its pre-mRNA substrates. A new study based on interactome analysis provides clues about how splicing-regulatory proteins modulate assembly of the spliceosome to either activate or repress splicing.Please see related Research article: http://www.genomebiology.com/2015/16/1/119/abstract     

SNES makes sense? Single-cell exome sequencing evolves

Technologies for single-cell sequencing are improving steadily. A recent study describes a new method for interrogating all coding sequences of the human genome at single-cell resolution.See related research by Leung et al., http://genomebiology.com/2015/16/1/55     

Birds do it,bees do it,worms and ciliates do it too: DNA methylation from unexpected corners of the tree of life

Studies describing intricate patterns of DNA methylation in nematode and ciliate are controversial due to the uncertainty of genomic evolutionary conservation of DNA methylation enzymes.See related research articles http://genomebiology.com/2012/13/10/R99 and http://genomebiology.com/2012/13/10/R100     

Identification of evolutionarily meaningful information within the mammalian RNA editing landscape

A large comparative genomic sequence study has determined the extent of conservation between RNA editing sites within the mammalian evolutionary tree.See related research by Pinto et al., http://genomebiology.com/2014/15/1/R5     

Of RNA-binding proteins and their targets: interaction determines expression

Combining the prediction of interactions between mRNAs and RNA-binding proteins with experimental expression profiles uncovers novel regulatory paradigms concerning proliferation and differentiation processes.See related research, http://genomebiology.com/2014/15/1/R13     

Bringing non-human primate research into the post-genomic era: how monkeys are teaching us about elite controllers of HIV/AIDS

Whole-genome sequencing of Mauritian cynomolgus macaques reveals novel candidate loci for controlling simian immunodeficiency virus replication.See related Research, http://genomebiology.com/2014/15/11/478     

Timber! Felling the loblolly pine genome

Conventional short read sequences derived from haploid DNA were extended into long super-reads enabling assembly of the massive 22 Gbp loblolly pine, Pinus taeda, genome.See related research http://genomebiology.com/2014/15/3/R59     

Insecticide resistance comes of age

A new study integrates biochemistry, genetics and structural biology to reveal the mechanism of metabolic resistance in a vector mosquito in unprecedented detail.See related research http://genomebiology.com/2014/15/2/R27     

The complex binding of PRDM9

A recent study investigates the in vitro DNA binding behavior of PRDM9, a zinc finger protein involved in the localization of recombination hotspots in mammals.Please see related research article: http://genomebiology.com/2013/14/4/R35     

Rising from the crypt: decreasing DNA methylation during differentiation of the small intestine

The differentiation of intestinal stem cells involves few DNA methylation changes, assayed by bisulfite sequencing, in contrast to other adult somatic stem cell hierarchies.Please see related Research article: http://genomebiology.com/2013/14/5/R50     

Binding the boundaries of chromatin domains

A new study proposes an integrated framework to improve our understanding of the multiple functions of insulator elements, and their architectural role in the genome.See related research; http://genomebiology.com/2014/15/6/R82     

Finding smORFs: getting closer

Millions of small open reading frames exist in eukaryotes. We do not know how many, or which are translated, but bioinformatics is getting us closer to the answer.See related Research article: http://www.genomebiology.com/2015/16/1/179DNA sequences encoding small open reading frames (smORFs) of fewer than 100 amino acids (aa) exist in each eukaryotic genome in numbers several orders of magnitude higher than the corresponding annotated protein-coding genes (Fig. 1). Due to difficulties with bioinformatic detection and experimental analysis, along with their sheer numbers, smORFs have been ignored for a long time by mainstream genomics. Thanks to recent advances in bioinformatic and experimental techniques, however, smORFs are receiving increasing attention. Extensive use of RNA-Seq has shown that thousands of smORFs are transcribed, in many cases, in putative noncoding RNAs, and high-throughput experimental techniques have detected translation of a few hundred of these. However, the possibility remains that many more smORFs are functional, but yet uncharacterized. Bioinformatic methods followed by targeted experimental verification are needed to improve the identification of putative functional smORFs. A new paper in Genome Biology [1] provides a significant step towards such a solution.Open in a separate windowFig. 1The number of small open reading frames (smORFs) in eukaryotic genomes (shown in log scale) greatly exceeds that of annotated protein-coding genes, and reaches 265,000 in yeast [4], 556,000 in the fruit fly Drosophila [2], and 40,700,000 in mouse [3]. Note that the current number of corroborated functional smORFs is but a small fraction of these (see text and [1] for details). The number of annotated protein-coding genes was obtained from the Saccharomyces Genome Database (yeast; http://www.yeastgenome.org/), FlyBase (fruit fly; http://flybase.org/), and Ensembl (mouse; http://www.ensembl.org/index.html) (accessed 12 August 2015)     

Smaug destroys a huge treasure

Smaug, a protein repressing translation and inducing mRNA decay, directly controls an unexpectedly large number of maternal mRNAs driving early Drosophila development.See related research, http://genomebiology.com/2014/15/1/R4Regulation of translation and mRNA stability is a key aspect of early metazoan development. One of the best studied factors involved in these processes is the Drosophila protein Smaug. In this issue of Genome Biology, Chen et al. [1] report that a large number of maternal mRNAs in the fly embryo are probably regulated directly by Smaug.     

An enigmatic satellite

McLaughlin and Chadwick describe an X-linked tandem repeat that is transcribed, conserved and defies X inactivation. Is it selfish, functional or just an oddity?See research article: http://genomebiology.com/2011/12/4/R37