Close arrangement of CARK3 and PMEIL affects ABA-mediated pollen sterility in Arabidopsis thaliana.

Abscisic acid (ABA) signaling is a vital plant signaling pathway for plant responses to stress conditions. ABA treatment can alter global gene expression patterns and cause significant phenotypic changes. We investigated the responses to ABA treatment during flowering in Arabidopsis thaliana. Dipping the flowers of CARK3 T-DNA mutants in ABA solution, led to less reduction of pollen fertility than in the wild type plants (Col-0). We demonstrated that PMEIL, a gene located downstream of CARK3, directly affects pollen fertility. Due to the close arrangement of CARK3 and PMEIL, CARK3 expression represses transcription of PMEIL in an ABA-dependent manner through transcriptional interference. Our study uncovers a molecular mechanism underlying ABA-mediated pollen sterility and provides an example of how transcriptional interference caused by close arrangement of genes may mediate stress responses during plant reproduction.

Complete mitochondrial genomes of the Northern (Salvelinus malma) and Southern (Salvelinus curilus) Dolly Varden chars (Salmoniformes, Salmonidae).

The complete mitochondrial genomes were sequenced from the Northern and Southern Dolly Varden chars, Salvelinus malma and S. curilus. The genome sequences are 16,654 bp in size in both species, and the gene arrangement, composition, and size are very similar to the salmonid fish genomes published previously. The level of sequence divergence between S. malma and S. curilus inferred from the complete mitochondrial genomes is relatively low (1.88%) indicating recent divergence of the species and/or historical hybridization.

Complete mitochondrial genome of Empoasca vitis (Hemiptera: Cicadellidae).

The complete mitochondrial genome of Empoasca vitis was sequenced. The length of the mitogenome is 15,154 bp with 78.35% AT content (GenBank accession No. KJ815009). The genome encode 37 typical mitochondrial genes including 22 transfer RNA genes, 13 protein-coding genes, 2 ribosomal RNA genes and an A+T-rich region. The gene arrangement is similar to that of Drosophila yakuba, the presumed ancestral insect mitochondrial gene arrangement. Except for cox2 using GTG as start codon, other protein-coding genes (PCGs) share the start codons ATN. Usual termination codon TAA and incomplete stop codon T are using by 13 protein-coding genes. The A+T-rich region has a length of 977 bp with the AT content high to 88.95%.

Complete mitochondrial genome of the hydrothermal vent ghost shrimp Paraglypturus tonganus (Crustacea, Axiidea, Callianassidae).

Ghost shrimps are burrowing decapods that serve as bioturbators and habitat providers in seafloor environments. The hydrothermal vent ghost shrimp, Paraglypturus tonganus, was collected from a hydrothermal vent in the Tonga Arc. This species has a mitochondrial genome (mitogenome) of 15,924 bp in length with an AT content of 66.1%. The mitogenome was identical to the typical gene arrangement and transcriptional polarity of the infraorder Axiidea. Paraglypturus tonganus showed 65.3-70.1% nucleotide similarity with the known mitogenomes of other axiid shrimps. These results are useful for understanding the phylogenetic relationships among the members of Axiidea within the decapods.

The complete mitochondrial genome of Bos gaurus gon-shan (Bovidae; Bovinae).

In the present work we undertook the complete mitochondrial genome sequencing of a wild gon-shan chinese cattle Bos gaurus gon-shan. The total length of the mitogenome was 16,356 bp with the base composition of 33.4% for A, 27.2% for T, 26.0% for C, and 13.4% for G and an A-T (60.6%)-rich feature was detected. It harbored 13 protein-coding genes, two ribosomal RNA genes, 22 transfer RNA genes and one non-coding control region (D-loop region). The arrangement of all genes was identical to the typical mitochondrial genomes of cattle.

Complete mitochondrial genome of the hardnose shark Carcharhinus macloti (Carcharhiniformes: Carcharhinidae).

The complete mitochondrial genome of Carcharhinus macloti was determined in this study. It is 16,701 bp in length and contains 37 genes with the typical gene order and transcriptional orientation in vertebrates. A total of 29 bp overlaps and 29 bp short intergenic spaces located in 22 gene junctions. The overall base composition is 31.6% A, 26.2% C, 13.0% G and 29.2% T. Two start codons (ATG and GTG) and three stop codons (AGG, TAG and TAA/T) were found in 13 protein-coding genes. The length of 22 tRNA genes ranged from 66 bp (tRNA-Ser2) to 75 bp (tRNA-Leu1). The tRNA-Ser2 (GCU) lacks the dihydrouridine arm by a simple loop and can not be folded into the typical cloverleaf structure. The control region is 1066 bp in length with high A+T content (68.2%).

The complete mitochondrial genome of Phrynocephalus guinanensis (Reptilia, Squamata, Agamidae).

Recent phylogenetic researches discovered no reciprocal monophyly between morphological species of Phrynocephalus putjatia and P. guinanensis, P. guinanensis exhibits extensive sexual color dimorphism, whereas P. putjatia does not have. The complete mitochondrial genome of the putative taxa, Phrynocephalus guinanensis, was determined in order to compare the mitogenomes of both ecological forms. The mitogenome sequence was 16,279 bp in size. It consists of 13 protein-coding, 22 tRNA, 2 rRNA genes and 3 control region, and its gene order and gene content were identical with the mitogenome of P. putjatia.

Complete mitochondrial genome of the brown alga Sargassum fusiforme (Sargassaceae, Phaeophyceae): genome architecture and taxonomic consideration.

Sargassum fusiforme (Harvey) Setchell (=Hizikia fusiformis (Harvey) Okamura) is one of the most important economic seaweeds for mariculture in China. In this study, we present the complete mitochondrial genome of S. fusiforme. The genome is 34,696 bp in length with circular organization, encoding the standard set of three ribosomal RNA genes (rRNA), 25 transfer RNA genes (tRNA), 35 protein-coding genes, and two conserved open reading frames (ORFs). Its total AT content is 62.47%, lower than other brown algae except Pylaiella littoralis. The mitogenome carries 1571 bp of intergenic region constituting 4.53% of the genome, and 13 pairs of overlapping genes with the overlap size from 1 to 90 bp. The phylogenetic analyses based on 35 protein-coding genes reveal that S. fusiforme has a closer evolutionary relationship with Sargassum muticum than Sargassum horneri, indicating Hizikia are not distinct evolutionary entity and should be reduced to synonymy with Sargassum.

The low-prevalence Rh antigen STEM (RH49) is encoded by two different RHCE*ce818T alleles that are often in cis to RHD*DOL.

BACKGROUND: STEM (RH49) is a low-prevalence antigen in the Rh blood group system. A scarcity of anti-STEM has precluded extensive study of this antigen. We report that two alleles with a RHCE*ce818C>T change encode a partial e, and a hr(S) -, hr(B) +, STEM+ phenotype and that both alleles are frequently in cis to RHD*DOL1 or RHD*DOL2. STUDY DESIGN AND METHODS: Blood samples were from donors and patients in our collections. Hemagglutination, DNA, and RNA testing was performed by standard techniques. RESULTS: Fourteen STEM+ samples were heterozygous RHCE*ce818C/T: six had RHCE*ceBI and eight had a novel allele, RHCE*ceSM. Eleven were heterozygous for RHD*DOL1 or RHD*DOL2. Eleven samples, previously typed STEM-, had RHCE*ce818C/C (consensus nucleotide). RBCs from informative STEM+ samples were e+/- hr(S) - hr(B) +. One person who was heterozygous RHCE*ceBI and RHCE*cE had an anti-e-like antibody in her plasma, and one person, who was hemizygous for RHD*DOL2, had anti-D in her plasma. CONCLUSIONS: We show that two alleles with a RHCE*ce818C>T change (RHCE*ceBI and RHCE*ceSM) encode a hr(S) - hr(B) + STEM+ phenotype. In addition, both alleles are frequently in cis to RHD*DOL1 or RHD*DOL2 and RHCE*ceBI encodes a partial e antigen. In the small cohort of samples tested, RHD*DOL invariably traveled with RHCE*ce818T. Our study also confirmed the presumption that RHD*DOL2, like RHD*DOL1, encodes a partial D antigen and the low-prevalence antigen DAK.

First exon length controls active chromatin signatures and transcription.

Here, we explore the role of splicing in transcription, employing both genome-wide analysis of human ChIP-seq data and experimental manipulation of exon-intron organization in transgenic cell lines. We show that the activating histone modifications H3K4me3 and H3K9ac map specifically to first exon-intron boundaries. This is surprising, because these marks help recruit general transcription factors (GTFs) to promoters. In genes with long first exons, promoter-proximal levels of H3K4me3 and H3K9ac are greatly reduced; consequently, GTFs and RNA polymerase II are low at transcription start sites (TSSs) and exhibit a second, promoter-distal peak from which transcription also initiates. In contrast, short first exons lead to increased H3K4me3 and H3K9ac at promoters, higher expression levels, accuracy in TSS usage, and a lower frequency of antisense transcription. Therefore, first exon length is predictive for gene activity. Finally, splicing inhibition and intron deletion reduce H3K4me3 levels and transcriptional output. Thus, gene architecture and splicing determines transcription quantity and quality as well as chromatin signatures.

Gene positioning.

Eukaryotic gene expression is an intricate multistep process, regulated within the cell nucleus through the activation or repression of RNA synthesis, processing, cytoplasmic export, and translation into protein. The major regulators of gene expression are chromatin remodeling and transcription machineries that are locally recruited to genes. However, enzymatic activities that act on genes are not ubiquitously distributed throughout the nucleoplasm, but limited to specific and spatially defined foci that promote preferred higher-order chromatin arrangements. The positioning of genes within the nuclear landscape relative to specific functional landmarks plays an important role in gene regulation and disease.

Positioned and G/C-capped poly(dA:dT) tracts associate with the centers of nucleosome-free regions in yeast promoters.

Eukaryotic transcriptional regulation is mediated by the organization of nucleosomes in promoter regions. Most Saccharomyces cerevisiae promoters have a highly stereotyped chromatin organization, where nucleosome-free regions (NFR) are flanked by well-ordered nucleosomes. We have found that yeast promoters fall into two classes differing in NFR sharpness, and that this distinction follows a known transcriptional dichotomy in yeast genes. A class of yeast promoters having well-defined NFRs are characterized by positioned patterns of poly(dA:dT) tracts with several novel features. First, poly(dA:dT) tracts are localized in a strand-dependent manner, with poly(dA) tracts lying proximal to transcriptional start sites and poly(dT) tracts lying distal, and collectively define a symmetry axis that is coincident with NFR centers. Second, poly(dA:dT) tracts are preferentially "capped" by G:C residues on the terminus proximal to the symmetry axis. Both signature features co-vary with fine positional variations between NFRs, establishing a closely knit relationship between poly(dA:dT) tracts, their capping patterns, and the central coordinates of NFRs. We found that these features are unique to promoters with well-defined NFRs, and that these promoters display significant difference between in vitro and in vivo nucleosome occupancy patterns. These observations are consistent with a model in which localized and G:C-capped poly(dA:dT) tracts initiate or facilitate the formation of NFRs at their center, possibly with chromatin remodeling and transcriptional machines involved.

Nucleosomes are well positioned in exons and carry characteristic histone modifications.

The genomes of higher organisms are packaged in nucleosomes with functional histone modifications. Until now, genome-wide nucleosome and histone modification studies have focused on transcription start sites (TSSs) where nucleosomes in RNA polymerase II (RNAPII) occupied genes are well positioned and have histone modifications that are characteristic of expression status. Using public data, we here show that there is a higher nucleosome-positioning signal in internal human exons and that this positioning is independent of expression. We observed a similarly strong nucleosome-positioning signal in internal exons of Caenorhabditis elegans. Among the 38 histone modifications analyzed in man, H3K36me3, H3K79me1, H2BK5me1, H3K27me1, H3K27me2, and H3K27me3 had evidently higher signals in internal exons than in the following introns and were clearly related to exon expression. These observations are suggestive of roles in splicing. Thus, exons are not only characterized by their coding capacity, but also by their nucleosome organization, which seems evolutionarily conserved since it is present in both primates and nematodes.

Effect of location, organization, and repeat-copy number in satellite-DNA evolution.

Here, we analyze the evolutionary dynamics of a satellite-DNA family in an attempt to understand the effect of factors such as location, organization, and repeat-copy number in the molecular drive process leading to the concerted-evolution pattern found in this type of repetitive sequences. The presence of RAE180 satellite-DNA in the dioecious species of the plant genus Rumex is a noteworthy feature at this respect, as RAE180 satellite repeats have accumulated differentially, showing a distinct distribution pattern in different species. The evolution of dioecious Rumex gave rise to two phylogenetic clades: one clade composed of species with an ancestral XX/XY sex chromosome system and a second, derived clade of species with a multiple sex-chromosome system XX/XY(1)Y(2). While in the XX/XY dioecious species, the RAE180 satellite-DNA is located only in a small autosomal locus, the RAE180 repeats are present also in a small autosomal locus and additionally have been massively amplified in the Y chromosomes of XX/XY(1)Y(2) species. Here, we have found that the RAE180 repeats of the autosomal locus of XX/XY species are characterized by intra-specific sequence homogeneity and inter-specific divergence and that the comparison of individual nucleotide positions between related species shows a general pattern of concerted evolution. On the contrary, both in the autosomal and the Y-linked loci of XX/XY(1)Y(2) species, ancestral variability has remained with reduced rates of sequence homogenization and of evolution. Thus, this study demonstrates that molecular mechanisms of non-reciprocal exchange are key factors in the molecular drive process; the satellite DNAs in the non-recombining Y chromosomes show low rates of concerted evolution and intra-specific variability increase with no inter-specific divergence. By contrast, freely recombining loci undergo concerted evolution with genetic differentiation between species as occurred in the autosomal locus of XX/XY species. However, evolutionary periods of rapid sequence change might alternate with evolutionary periods of stasis with variability remaining by the reduced action of molecular mechanisms of non-reciprocal exchange as occurred in XX/XY(1)Y(2) species, which could depend on repeat-copy number and the processes involved in their amplification.

The complete mitochondrial genome of the subterranean crustacean Metacrangonyx longipes (Amphipoda): a unique gene order and extremely short control region.

Metazoan mitochondrial genomes usually consist of the same gene set, but some taxonomic groups show a considerable variety in gene order and nucleotide composition. The mitochondrial genomes of 37 crustaceans are currently known. Within the malacostracan superorder Peracarida, only three partial mitogenome sequences and the complete sequence of Ligia oceanica (Isopoda) are available. Frequent translocation events have changed the mitochondrial gene order in crustaceans, providing an opportunity to study the patterns and mechanisms of mitogenome rearrangement and to determine their impact on phylogenetic reconstructions. Here we report the first complete nucleotide sequence of an amphipod species, Metacrangonyx longipes, belonging to a phylogenetically enigmatic family occurring in continental subterranean waters. The genome has 14,113 bp and contains the usual 13 protein coding genes and two rRNA subunits, but only 21 out of the typical 22 tRNA genes of Metazoa. This is the shortest mitogenome described thus far for a crustacean and also one of the richest in AT (76.03%). The genome compactness results from a very small control region of 76 bp, the occurrence of frequent gene overlap, and the absence of large non-coding fragments. Six of the protein-coding genes have unusual start codons. Comparison of individual protein coding genes with the sequences known for other crustaceans suggests that nad2, nad6, nad4L and atp8 show the highest divergence rates. M. longipes shows a unique crustacean mitogenome gene order, differing even from the condition found in Parhyale hawaiiensis (Amphipoda), whose coding sequence has also been completed in the present study.

Silencing and nuclear repositioning of the lambda5 gene locus at the pre-B cell stage requires Aiolos and OBF-1.

The chromatin regulator Aiolos and the transcriptional coactivator OBF-1 have been implicated in regulating aspects of B cell maturation and activation. Mice lacking either of these factors have a largely normal early B cell development. However, when both factors are eliminated simultaneously a block is uncovered at the transition between pre-B and immature B cells, indicating that these proteins exert a critical function in developing B lymphocytes. In mice deficient for Aiolos and OBF-1, the numbers of immature B cells are reduced, small pre-BII cells are increased and a significant impairment in immunoglobulin light chain DNA rearrangement is observed. We identified genes whose expression is deregulated in the pre-B cell compartment of these mice. In particular, we found that components of the pre-BCR, such as the surrogate light chain genes lambda5 and VpreB, fail to be efficiently silenced in double-mutant mice. Strikingly, developmentally regulated nuclear repositioning of the lambda5 gene is impaired in pre-B cells lacking OBF-1 and Aiolos. These studies uncover a novel role for OBF-1 and Aiolos in controlling the transcription and nuclear organization of genes involved in pre-BCR function.

Chromatin structure and the regulation of gene expression: the lessons of PEV in Drosophila.

Position-effect variegation (PEV) was discovered in 1930 in a study of X-ray-induced chromosomal rearrangements. Rearrangements that place euchromatic genes adjacent to a region of centromeric heterochromatin give a variegated phenotype that results from the inactivation of genes by heterochromatin spreading from the breakpoint. PEV can also result from P element insertions that place euchromatic genes into heterochromatic regions and rearrangements that position euchromatic chromosomal regions into heterochromatic nuclear compartments. More than 75 years of studies of PEV have revealed that PEV is a complex phenomenon that results from fundamental differences in the structure and function of heterochromatin and euchromatin with respect to gene expression. Molecular analysis of PEV began with the discovery that PEV phenotypes are altered by suppressor and enhancer mutations of a large number of modifier genes whose products are structural components of heterochromatin, enzymes that modify heterochromatic proteins, or are nuclear structural components. Analysis of these gene products has led to our current understanding that formation of heterochromatin involves specific modifications of histones leading to the binding of particular sets of heterochromatic proteins, and that this process may be the mechanism for repressing gene expression in PEV. Other modifier genes produce products whose function is part of an active mechanism of generation of euchromatin that resists heterochromatization. Current studies of PEV are focusing on defining the complex patterns of modifier gene activity and the sequence of events that leads to the dynamic interplay between heterochromatin and euchromatin.

Polycomb group proteins and long-range gene regulation.

Genome regulation takes place at different hierarchically interconnected levels: the DNA sequence level, the chromatin level, and the three-dimensional (3D) organization of the nucleus. Polycomb group (PcG) proteins are silencers that regulate transcription at all these three levels. They are targeted to specific sequences in the genome, contributing to maintain cellular identity. Recent research reveals that PcG proteins may be important actors at the level of the nuclear 3D structure. Here, we discuss our current knowledge of how PcG proteins regulate transcription across the three mentioned levels, and in particular their possible role in regulation of remote genes. We suggest the possibility that PcG proteins establish 3D networks of chromatin contacts as a mechanism to orchestrate gene expression.

Beta-globin regulation and long-range interactions.

Transcriptional activation in higher eukaryotes frequently involves the long-range action of a number of regulatory DNA elements. One of the main questions in transcriptional regulation is how cis-regulatory elements communicate with the promoter of a gene over large distances. There has been a lively debate in recent years whether this communication takes place via a noncontact mechanism (linking, tracking) or via a contact mechanism (looping). The demonstration that the major regulatory element of the beta-globin locus, the locus control region (LCR), is in close proximity to the active beta-globin genes validates the contact model for long-range activation. Here, we will review the beta-globin locus as a model system to study long-range activation, briefly describe the different models for long-range activation, and summarize the recent findings that the LCR of the beta-globin locus is in close proximity to the active promoters. Although it is now firmly established that looping takes place within the beta-globin locus (and other loci), it is not clear how these long-range contacts are established and what the precise role is of the LCR. We will argue that the main action of the LCR takes place at the promoter and open reading frame of the gene itself and we will discuss key rate-limiting steps in transcriptional activation and the possible mechanisms by which they are influenced by the LCR.

Global control regions and regulatory landscapes in vertebrate development and evolution.

During the course of evolution, many genes that control the development of metazoan body plans were co-opted to exert novel functions, along with the emergence or modification of structures. Gene amplification and/or changes in the cis-regulatory modules responsible for the transcriptional activity of these genes have certainly contributed in a major way to evolution of gene functions. In some cases, these processes led to the formation of groups of adjacent genes that appear to be controlled by both global and shared mechanisms.