A pair of partially overlapping Arabidopsis genes with antagonistic circadian expression

Diverse roles for a class II BPC gene in Camellia japonica through tissue-specific regulation of gene expression

Basic Pentacysteine (BPC) proteins are plant-specific transcription factors that bind to GAGA dinucleotide repeats in target gene promoters. Different classes of BPC proteins are able to form complexes and recruit chromatin-modifying proteins to regulate target gene expression. However, the mechanisms by which the relationships among BPC members regulate tissue-specific gene expression remain unclear. In this study, we investigated the tissue-specific functions and mechanisms of CjBPC5, a class II BPC gene from Camellia japonica. The ectopic overexpression of CjBPC5 induced pleiotropic morphological defects in the leaves and floral tissues. Global gene expression profiling and DNA binding-site analyses showed that CjBPC5 regulated tissue-specific expression of several downstream genes by binding to the GAGA-rich binding sites in their promoters. Furthermore, we identified DNA motifs in the BPC binding sites that were critical for regulating tissue-specific gene expression and various developmental processes via transcription factor binding. Chromatin immunoprecipitation (ChIP) assay demonstrated direct binding of CjBPC5 to the promoter regions of EARLY FLOWERING 3 (ELF3), BEL1-LIKE HOMEODOMAIN 6 (BLH6) and BRASSINOSTEROID-6-OXIDASE 2 (BR6OX2). In conclusion, our study suggests that CjBPC5 plays a critical role in plant development by interacting with specific transcription factors and regulating downstream genes in a tissue-specific manner.

PyMut: A Web Tool for Overlapping Gene Loss-of-Function Mutation Design

Loss-of-function study is an effective approach to research gene functions. However, currently most of such studies have ignored an important problem (in this paper, we call it "off-target" problem), that is, if the target gene is an overlapping gene (A gene whose expressible nucleotides overlaps with that of another one), loss-of-function mutation by deleting the complete open reading frame (ORF) may also cause the gene it overlaps lose function, resulting a phenotype which may be rather different from that of single gene deletion. Therefore, when doing such studies, the loss-of-function mutations should be carefully designed to guarantee only the function of the target gene will be abolished. In this paper, we present PyMut, an easy-to-use web tool for biologists to design such mutations. To the best of our knowledge, PyMut is the first tool that aims to solve the "off-target" problem regarding the overlapping genes. Our web server is freely available at http://www.bioinfo.tsinghua.edu.cn/∼liuke/PyMut/index.html.

Differential genomic arrangements in Caryophyllales through deep transcriptome sequencing of A. hypochondriacus

Genome duplication event in edible dicots under the orders Rosid and Asterid, common during the oligocene period, is missing for species under the order Caryophyllales. Despite this, grain amaranths not only survived this period but display many desirable traits missing in species under rosids and asterids. For example, grain amaranths display traits like C4 photosynthesis, high-lysine seeds, high-yield, drought resistance, tolerance to infection and resilience to stress. It is, therefore, of interest to look for minor genome rearrangements with potential functional implications that are unique to grain amaranths. Here, by deep sequencing and assembly of 16 transcriptomes (86.8 billion bases) we have interrogated differential genome rearrangement unique to Amaranthus hypochondriacus with potential links to these phenotypes. We have predicted 125,581 non-redundant transcripts including 44,529 protein coding transcripts identified based on homology to known proteins and 13,529 predicted as novel/amaranth specific coding transcripts. Of the protein coding de novo assembled transcripts, we have identified 1810 chimeric transcripts. More than 30% and 19% of the gene pairs within the chimeric transcripts are found within the same loci in the genomes of A. hypochondriacus and Beta vulgaris respectively and are considered real positives. Interestingly, one of the chimeric transcripts comprises two important genes, namely DHDPS1, a key enzyme implicated in the biosynthesis of lysine, and alpha-glucosidase, an enzyme involved in sucrose catabolism, in close proximity to each other separated by a distance of 612 bases in the genome of A. hypochondriacus in a convergent configuration. We have experimentally validated that transcripts of these two genes are also overlapping in the 3' UTR with their expression negatively correlated from bud to mature seed, suggesting a potential link between the high seed lysine trait and unique genome organization.

A Genome-wide Study of "Non-3UTR" Polyadenylation Sites in Arabidopsis thaliana

Alternative polyadenylation has been recognized as a key contributor of gene expression regulation by generating different transcript isoforms with altered 3′ ends. Although polyadenylation is well known for marking the end of a 3′ UTR, an increasing number of studies have reported previously less-addressed polyadenylation events located in other parts of genes in many eukaryotic organisms. These other locations include 5′ UTRs, introns and coding sequences (termed herein as non-3UTR), as well as antisense and intergenic polyadenlation. Focusing on the non-3UTR polyadenylation sites (n3PASs), we detected and characterized more than 11000 n3PAS clusters in the Arabidopsis genome using poly(A)-tag sequencing data (PAT-Seq). Further analyses suggested that the occurrence of these n3PASs were positively correlated with certain characteristics of their respective host genes, including the presence of spliced, diminutive or diverse beginning of 5′ UTRs, number of introns and whether introns have extreme lengths. The interaction of the host genes with surrounding genetic elements, like a convergently overlapped gene and associated transposable element, may contribute to the generation of a n3PAS as well. Collectively, these results provide a better understanding of n3PASs, and offer some new insights of the underlying mechanisms for non-3UTR polyadenylation and its regulation in plants.

Overlapping genes: a new strategy of thermophilic stress tolerance in prokaryotes

Overlapping genes (OGs) draw the focus of recent day's research. However, the significance of OGs in prokaryotic genomes remained unexplored. As an adaptation to high temperature, thermophiles were shown to eliminate their intergenic regions. Therefore, it could be possible that prokaryotes would increase their OG content to adapt to high temperature. To test this hypothesis, we carried out a comparative study on OG frequency of 256 prokaryotic genomes comprising both thermophiles and non-thermophiles. It was found that thermophiles exhibit higher frequency of overlapping genes than non-thermophiles. Moreover, overlap frequency was found to correlate with optimal growth temperature (OGT) in prokaryotes. Long overlap frequency was found to hold a positive correlation with OGT resulting in an abundance of long overlaps in thermophiles compared to non-thermophiles. On the other hand, short overlap (1-4 nucleotides) frequency (SOF) did not yield any direct correlation with OGT. However, the correlation of SOF with CAIavg (extent of variation of codon usage bias measured as the mean of codon adaptation index of all genes in a given genome) and IG% (proportion of intergenic regions) indicate that they might upregulate the aforementioned factors (CAIavg and IG%) which are already known to be vital forces for thermophilic adaptation. From these evidences, we propose that the OG content bears a strong link to thermophily. Long overlaps are important for their genome compaction and short overlaps are important to uphold high CAIavg. Our findings will surely help in better understanding of the significance of overlapping gene content in prokaryotic genomes.

Regulated DNA methylation and the circadian clock: implications in cancer

Since the cloning and discovery of DNA methyltransferases (DNMT), there has been a growing interest in DNA methylation, its role as an epigenetic modification, how it is established and removed, along with the implications in development and disease. In recent years, it has become evident that dynamic DNA methylation accompanies the circadian clock and is found at clock genes in Neurospora, mice and cancer cells. The relationship among the circadian clock, cancer and DNA methylation at clock genes suggests a correlative indication that improper DNA methylation may influence clock gene expression, contributing to the etiology of cancer. The molecular mechanism underlying DNA methylation at clock loci is best studied in the filamentous fungi, Neurospora crassa, and recent data indicate a mechanism analogous to the RNA-dependent DNA methylation (RdDM) or RNAi-mediated facultative heterochromatin. Although it is still unclear, DNA methylation at clock genes may function as a terminal modification that serves to prevent the regulated removal of histone modifications. In this capacity, aberrant DNA methylation may serve as a readout of misregulated clock genes and not as the causative agent. This review explores the implications of DNA methylation at clock loci and describes what is currently known regarding the molecular mechanism underlying DNA methylation at circadian clock genes.

Interplay between polymerase II- and polymerase III-assisted expression of overlapping genes

Up to 15% of the genes in different genomes overlap. This architecture, although beneficial for the genome size, represents an obstacle for simultaneous transcription of both genes. Here we analyze the interference between RNA-polymerase II (Pol II) and RNA-polymerase III (Pol III) when transcribing their target genes encoded on opposing strands within the same DNA fragment in Arabidopsis thaliana. The expression of a Pol II-dependent protein-coding gene negatively correlated with the transcription of a Pol III-dependent, tRNA-coding gene set. We suggest that the architecture of the overlapping genes introduces an additional layer of control of gene expression.