Sequence and expression analysis of the thioredoxin protein gene family in rice

Thioredoxin (Trx) proteins play important biological functions in cells by changing redox via thioldisulfied exchange. This system is especially widespread in plants. Through database search, we identified 30 potential Trx protein-encoding genes (OsTrx) in rice (Oryza sativa L.). An analysis of the complete set of OsTrx proteins is presented here, including chromosomal location, conserved motifs, domain duplication, and phylogenetic relationships. Our findings suggest that the expansion of the Trx gene family in rice, in large part, occurred due to gene duplication. A comprehensive expression profile of Trx genes family was investigated by analyzing the signal data of this family extracted from the whole genome microarray analysis of Minghui 63 and Zhenshan 97, two indica parents, and their hybrid Shanyou 63, using 27 different tissues representing the entire life cycle of rice. Results revealed specific expression of some members at germination transition as well as the 3-leaf stage during the vegetative growth phase of rice. OsTrx genes were also found to be differentially up- or down-regulated in rice seedlings subjected to treatments of phytohormones and light/dark conditions. The expression levels of the OsTrx genes in the different tissues and under different treatments were also checked by RT-PCR analysis. The identification of OsTrx genes showing differential expression in specific tissues among different genotypes or in response to different environmental cues could provide a new avenue for functional analyses in rice.     

The phytocyanin gene family in rice (Oryza sativa L.): genome-wide identification, classification and transcriptional analysis

Background

Phytocyanins (PCs) are plant-specific blue copper proteins involved in electron transport, and a large number of known PCs are considered to be chimeric arabinogalactan proteins (AGPs). To date there has not been a genome-wide overview of the OsPC gene family. Therefore, as the first step and a useful strategy to elucidate the functions of OsPCs, there is an urgent need for a thorough genome-wide analysis of this gene family.

Methodology/Principal Findings

In this study, a total of 62 OsPC genes were identified through a comprehensive bioinformatics analysis of the rice (Oryza sativa L.) genome. Based on phylogeny and motif constitution, the family of OsPCs was classified into three subclasses: uclacyanin-like proteins (OsUCLs), stellacyanin-like proteins (OsSCLs) and early nodulin-like proteins (OsENODLs). Structure and glycosylation prediction indicated that 46 OsPCs were glycosylphosphatigylinositol-anchored proteins and 38 OsPCs were chimeric AGPs. Gene duplication analysis revealed that chromosomal segment and tandem duplications contributed almost equally to the expansion of this gene family, and duplication events were mostly happened in the OsUCL subfamily. The expression profiles of OsPC genes were analyzed at different stages of vegetative and reproductive development and under abiotic stresses. It revealed that a large number of OsPC genes were abundantly expressed in the various stages of development. Moreover, 17 genes were regulated under the treatments of abiotic stresses.

Conclusions/Significance

The genome-wide identification and expression analysis of OsPC genes should facilitate research in this gene family and give new insights toward elucidating their functions in higher plants.     

Sequencing, mutational analysis, and transcriptional regulation of the Escherichia coli htrB gene

The Escherichia coli htrB gene was originally discovered because its insertional inactivation led to an exquisitely temperature-sensitive phenotype in rich media, i.e. the ability to form colonies at temperatures below 32 degrees C, but not above 33 degrees C. The htrB gene has been sequenced. It can potentially code for two proteins, with Mr values of 35,407 Da and 8669 Da, that are encoded by overlapping, divergent open reading frames. Our data are consistent with the 35,407 Da protein being HtrB. Northern blot analysis clearly shows that the monocistronic htrB message is not under heat-shock regulation. We have also sequenced the flanking DNA and have discovered a new gene, designated orf39.9, located immediately adjacent to htrB, but divergently transcribed.     

Sequence and expression analysis of the Arabidopsis IQM family

Four major families have been found so far to possess the calmodulin binding IQ motif/s in plants: the IQD, the myosin, the CAMTA and the CNGC family. We have systematically identified and characterized a novel IQ motif-containing protein family, IQM, in Arabidopsis (Arabidopsis thaliana) using bioinformatics methods. IQM family contains six-member proteins (IQM1-6) which share sequence homology with a pea heavy metal-induced protein 6 and a ribosome-inactivating protein, trichosanthin, as well as IQ motif. IQM family can be divided into two groups, IQM3 and the other member proteins, based on sequence similarity and phylogenetic analysis of sequences. Though almost constitutive expression patterns were found in various plant organs of 6-week-old plants for IQM1 and 2, the other genes exhibited distinct organ-specific expression patterns. Light irradiation and treatment with heavy metals such as CdCl₂ or Pb(NO₃)₂ and high concentrations of mannitol or NaCl also changed expression of each IQM gene in a distinct manner in 7-day-old seedlings. However, treatment with various hormones, such as auxin, abscisic acid, gibberellin, methyl jasmonate and ethylene precursor, did not affect gene expression significantly. These results suggest that each IQM family gene plays a different role in plant development and responses to environmental cues.     

Species-specific posttranscriptional regulation of interferon synthesis

Human fibroblast and Syrian hamster embryo cells were induced to synthesize interferon (IF) with rIn . rCn and rIn . rCn + DEAE-dextran, respectively. Following induction, these cells synthesized IF for only a short time before entering into a repressed state and shutting off the synthesis of IF. Homologous and heterologous whole cell translational systems were developed to investigate the molecular basis for the shut-off of IF synthesis. These systems allowedd for the introduction of exogenous hamster and human IF-mRNAs into intact normal and repressed hamster and human cells via an improved CaCl2 precipitation technique. Human IF-mRNA was translated in normal human and hamster cells and in repressed hamster cells but not in repressed human cells. In contrast, the hamster IF-mRNA was translated in normal human, normal hamster, and repressed human cells but not in repressed hamster cells. These results indicate that a species-specific mechanism inhibiting translation of IF-mRNA is directly responsible for the shut-off of IF synthesis in human fibroblasts and Syrian hamster embryo cells.     

Sequence analysis of the AAA protein family.

The AAA protein family, a recently recognized group of Walker-type ATPases, has been subjected to an extensive sequence analysis. Multiple sequence alignments revealed the existence of a region of sequence similarity, the so-called AAA cassette. The borders of this cassette were localized and within it, three boxes of a high degree of conservation were identified. Two of these boxes could be assigned to substantial parts of the ATP binding site (namely, to Walker motifs A and B); the third may be a portion of the catalytic center. Phylogenetic trees were calculated to obtain insights into the evolutionary history of the family. Subfamilies with varying degrees of intra-relatedness could be discriminated; these relationships are also supported by analysis of sequences outside the canonical AAA boxes: within the cassette are regions that are strongly conserved within each subfamily, whereas little or even no similarity between different subfamilies can be observed. These regions are well suited to define fingerprints for subfamilies. A secondary structure prediction utilizing all available sequence information was performed and the result was fitted to the general 3D structure of a Walker A/GTPase. The agreement was unexpectedly high and strongly supports the conclusion that the AAA family belongs to the Walker superfamily of A/GTPases.