Spatial distribution pattern analysis of Dof1 transcription factor in different tissues of three <Emphasis Type="Italic">Eleusine coracana</Emphasis> genotypes differing in their grain colour,yield and photosynthetic efficiency

In the present study Dof1 gene of finger millet was cloned and sequenced. In silico analysis reveals 61% identity with the Sorghum bicolor and 57% identity with the Oryza sativa Dof1 sequence. A comparative analysis of gene sequences from different crops and three finger millet genotypes {Brown (PRM-1), Golden (PRM-701) and White (PRM-801)} differing in grain colour, yield and photosynthetic efficiency showed a high degree of sequence identity of Dof1 sequence gene ranging from 22 to 70% as evident from distance matrix of the built phylogenetic tree showing two major clusters. A total of five conserved motifs were observed in Dof1 sequences of different cereals. Motif 1 with multilevel consensus sequence CKNCRRYWTKGGAMRNVPVG contains zinc finger Dof domain. Motif 3 and motif 5 contains protein kinase phosphorylation site. Motif 2 contains Dof domain and zinc finger N-glycosylation site while motif 4 is involved in Zinc finger type profiling. Further, we studied the spatial distribution of Dof1 gene in three vegetative tissues (root, stem and flag leaf) as well as four stages of developing spikes (S1, S2, S3 and S4) of the three finger millet genotypes using qualitative and quantitative PCR based approaches. Physiological parameters (plant height, leaf area, chlorophyll content, SPAD value and photosynthetic efficiency) at the time of flowering was found to be highest in white (PRM-801) genotype followed by golden (PRM-701) and brown (PRM-1) genotype. Semi-quantitative RT-PCR and quantitative real-time PCR analysis revealed that the expression of Dof1 is highest in leaves and lowest in roots, which suggests its role in regulation of photosynthesis-related genes and carbon skeleton synthesis. Also at grain maturity stage, expression of Dof1 was higher in white (PRM-801) genotype followed by golden (PRM-701) and brown (PRM-1) genotype. The result is suggestive of Dof1 role in the accumulation of grain protein and yield attribute through regulation of key enzymes involved in source to sink relationship during grain filling stage.     

A Full-Length Dof1 Transcription Factor of Finger Millet and its Response to a Circadian Cycle

DOF1 (DNA binding with one finger) plays an important role in regulating C/N metabolism in cereals. In order to validate its role in the regulation of nitrogen use efficiency (NUE) and photosynthetic efficiency in finger millet, 5′–3′ RACE PCR was performed to obtain and characterize full-length Dof1 genes of high and low grain protein finger millet genotypes. The full-length DOF1 ORFs were both 1,284 nt long and were 98.8 % similar over 427 amino acids containing the characteristic Dof domain. Comparison of both the EcDof1 protein sequences with the Dof1 of other cereals revealed high sequence similarity to the Dof1 of rice. Southern hybridization carried out using the probe developed from the region encoding the highly variable C-terminal region of EcDof1 showed the presence of four copies of the DOF1 gene in finger millet, which might explain the high NUE and photosynthetic performance of finger millet. Since the genes involved in C/N metabolism are regulated diurnally and play crucial roles in determining grain protein content during grain filling, the diurnal expression of EcDOF1 was assessed in two finger millet genotypes (GE 3885 and GE 1437) with differing grain protein content (13.8 % and 6.15 % respectively). It was found that EcDOF1 exhibited diurnal regulation and peak differential pattern expression with early phasing in GE3885 and late phasing in GE1437. Differential expression of DOF1 might alter the regulation of genes involved in C/N metabolism affecting grain protein composition of finger millet genotypes.     

Dof基因家族调节植物生长发育功能的研究进展

Dof（DNA binding with one finger）蛋白是一类植物特异性转录因子,通常含有200～400个氨基酸和2个主要结构域。该家族成员的N 末端为高度保守的单锌指Dof结构域,具有与DNA和蛋白质相互作用的双重功能,其C末端的氨基酸序列则较为多变,是Dof蛋白重要的特异转录调控结构域。研究表明,Dof蛋白作为转录激活物或阻遏物参与了多方面的植物生长发育过程。随着基因组测序技术的发展,已有大量的Dof基因从植物基因组数据库中鉴定出来。该文对近年来国内外有关Dof基因家族的结构特点、全基因组鉴定、蛋白互作以及生物学功能等方面的研究进展进行综述,以期为Dof转录因子的深入研究提供参考。     

The promoter of the asi gene directs expression in the maternal tissues of the seed in transgenic barley

The bifunctional -amylase/subtilisin inhibitor (BASI) is an abundant protein in barley seeds, proposed to play multiple and apparently diverse roles in regulation of starch hydrolysis and in seed defence against pathogens. In the Triticeae, the protein has evolved the ability to specifically inhibit the main group of -amylases expressed during germination of barley and encoded by the amy1 gene family found only in the Triticeae. The expression of the asi gene that encodes BASI has been reported to be controlled by the hormones abscisic acid (ABA) and gibberellic acid (GA). Despite many studies at the gene and protein level, the function of this gene in the plant remains unclear. In this study, the 5-flanking region (1033 bp, 1033-asi promoter) and the 3-flanking region (655 bp) of the asi gene were isolated and characterised. The 1033-asi promoter sequence showed homology to a number of ciselements that play a role in ABA and GA regulated expression of other genes. With a green fluorescent protein gene (gfp) as reporter, the 1033-asi promoter was studied for spatial, temporal and hormonal control of gene expression. The 1033-asi promoter and its deletions direct transient gfp expression in the pericarp and at low levels in mature aleurone cells, and this expression is not regulated by ABA or GA. In transgenic barley plants, the 1033-asi promoter directed tissue-specific expression of the gfp gene in developing grain and germinating grain but not in roots or leaves. In developing grain, expression of gfp was observed specifically in the pericarp, the vascular tissue, the nucellar projection cells and the endosperm transfer cells and the hormones ABA or GA did not regulate this expression. In mature germinating grain gfp expression was observed in the embryo but not in aleurone or starchy endosperm. However, GA induced gfp expression in the aleurone of mature imbibed seeds from which the embryo had been removed. Expression in maternal rather than endosperm tissues of the grain suggests that earlier widespread assumptions that the protein is expressed largely in the endosperm may have been largely based on analysis of mixed grain tissues. This novel pattern of expression suggests that both activities of the protein may be primarily involved in seed defence in the peripheral tissues of the seed.     

Structural and expression analysis of prolamin genes in <Emphasis Type="Italic">Oryza sativa</Emphasis> L.

Rice is a staple crop with a small genome of 389 Mb. Rice grain is a source of carbohydrates and proteins and has a relatively low protein content compared to other legume seeds. Glutelin and prolamin are the major storage proteins in rice. Prolamins are characterized by high glutamine and proline content and are generally soluble only in strong alcohol solutions. In this study, we obtained a total of 51,383 expressed sequence tags (ESTs) from Ilpumbyeo (Oryza sativa L.), of which 33,201 and 18,182 clones were obtained from immature and germinating seeds, respectively. From the EST clones, 15,148 unigenes were identified, and 2,590 genes were expressed in both immature and germinating seeds. Gene expression profiling of rice prolamins indicated that prolamin gene expression increased 5 days after heading and reached maximal expression after 30 days, suggesting a high demand for prolamins during seed development and germination. Phylogenetic analysis grouped 33 prolamin genes based on the abundance of sulfur-containing amino acids methionine and cysteine according to the deduced amino acid sequences. Our results enhance the understanding of the regulation of seed maturation and germination, which can result in improved agricultural traits for the seed industry.     

Use of SSR,RAPD markers and protein profiles based analysis to differentiate <Emphasis Type="Italic">Eleusine coracana</Emphasis> genotypes differing in their protein content

Fifty-two genotypes of Eleusine coracana collected from Uttarakhand hills were subjected to simple sequence repeat (SSR), random amplified polymorphic DNA (RAPD)-PCR and protein profiling analysis to investigate the variation in protein content. The main objective of the present study was to detect variability among E. coracana and also assess the discriminating ability of these three molecular methods. A total of 21 RAPD and 24 SSR primers were assayed for their specificity in detecting genetic variability in E. coracana, of which 20 RAPD and 21 SSR primers were highly reproducible and were found suitable for use in PCR analysis. Assessing genetic diversity among E. coracana genotypes by RAPD-PCR using 20 polymorphic primers yielded 56 different RAPD markers which clustered the genotypes into different groups on the basis of protein content. Similarly, SSR-PCR with 21 polymorphic primers clustered the genotypes into different groups. On the other hand, biochemical typing of E. coracana using whole seed proteins generated profiles that showed no major difference indicating the technique to be not useful in typing genotypes of this crop. However, a few of the genotypes showed the presence of a unique band of 32 kDa that needs to be further investigated to understand the role of the protein from nutritional point of view, if any. In the present study, significant negative correlation (r = −0.69*) was found between the protein and calcium content of finger millet genotypes. Sodium Dodecyl Sulphate Polyacrylamide Gel Electrophoresis based seed storage proteins generated profiles showed no major differences in banding pattern among 52 finger millet genotypes while quantitative estimation of seed storage protein fractions using Lowry method revealed that glutelin was highest followed by prolamin, globulin and albumin.     

Genome-wide bioinformatics analysis of Dof transcription factor gene family of chickpea and its comparative phylogenetic assessment with Arabidopsis and rice

The genome mining of chickpea (Cicer arietinum L.) revealed a total of 37 putative Dof genes using NCBI BLAST search against the genome with a highly conserved Dof domain. The translated Dof proteins possessed 150–493 amino acid residues with molecular weight ranging from 16.9 to 54.4 kD and pI varied from 4.98 to 9.64 as revealed by ExPASy server ProtParam. The exon–intron organization showed predominance of intronless Dof genes in chickpea. The predicted Dof genes were distributed among the eight chromosomes with a maximum of 9 Dof genes present on chromosome 7 and a single Dof gene was found on chromosome 8.The predominance of segmental gene duplication as compared to tandem duplication was observed which might be the prime cause of Dof gene family expansion in chickpea. The cis-regulatory element analysis revealed the presence of light-responsive, hormone-responsive, endosperm-specific, meristem-specific and stress-responsive elements. Comprehensive phylogenetic analyses of Dof genes of chickpea with Arabidopsis, rice, soybean and pigeonpea revealed several orthologs and paralogs assisting in understanding the putative functions of CaDof genes. The functional divergence and site-specific selective pressures of chickpea Dof genes have been investigated. The bioinformatics-based genome-wide assessment of Dof gene family of chickpea attempted in the present study could be a significant step for deciphering novel Dof genes based on genome-wide expression profiling.     

Recombinant protein yield in rice seed is enhanced by specific suppression of endogenous seed proteins at the same deposit site

Human IL‐10 (hIL‐10) is a therapeutic treatment candidate for inflammatory allergy and autoimmune diseases. Rice seed‐produced IL‐10 can be effectively delivered directly to gut‐associated lymphoreticular tissue (GALT) via bio‐encapsulation. Previously, the codon‐optimized hIL‐10 gene was expressed in transgenic rice with the signal peptide and endoplasmic reticulum (ER) retention signal (KDEL) at its 5′ and 3′ ends, respectively, under the control of the endosperm‐specific glutelin GluB‐1 promoter. The resulting purified hIL‐10 was biologically active. In this study, the yield of hIL‐10 in transgenic rice seed was improved. This protein accumulated at the intended deposition sites, which had been made vacant through the selective reduction, via RNA interference, of the endogenous seed storage proteins prolamins or glutelins. Upon suppression of prolamins that were sequestered into ER‐derived protein bodies (PB‐I), hIL‐10 accumulation increased approximately 3‐fold as compared to rice seed with no such suppression and reached 219 μg/grain. In contrast, reducing the majority of the glutelins stored in protein‐storage vacuoles (PB‐II) did not significantly affect the accumulation of hIL‐10. Considering that hIL‐10 is synthesized in the ER lumen and subsequently buds off in ER‐derived granules called IL‐10 granules in a manner similar to PB‐Is, these results indicate that increases in the available deposition space for the desired recombinant proteins may be crucial for improvements in yield. Furthermore, efficient dimeric intermolecular formation of hIL‐10 by inhibiting interaction with Cys‐rich prolamins also contributed to the enhanced formation of IL‐10 bodies. Higher yield of hIL‐10 produced in rice seeds is expected to have broad application in the future.     

Dynamics of nutrient remobilisation from seed of wheat genotypes during imbibition,germination and early seedling growth

The changes in nutrient content of grain tissues and seedling parts of two wheat genotypes (Triticum aestivum L., Excalibur and Janz) with low or high seed Zn content were followed from imbibition to early seedling development (12 days). The grains were separated into seed coat, endosperm and embryo, while the seedlings were separated into roots and shoots. The dry weight of the seed coat did not change throughout the experimental period, whereas the endosperm weight declined rapidly from day 4 onward. The weight of embryo did not show any difference between and within cultivars. About a half of seed Zn was remobilised into shoot and roots during 12 days of growth, regardless of the initial seed Zn content in both genotypes. The seed coat contained 55–77% of the total seed nutrients in the two wheat genotypes, except in the case of S (around 40%). Manganese, Fe, Ca, K, and P were remobilised effectively from the seed coat as well as from the endosperm, while remobilisation of Zn and Cu was relatively less from the seed coat than from the endosperm. After 10 days of growth, all nutrients monitored were completely remobilised from the endosperm. Remobilised K was directed primarily into shoots; an increase in K content in shoots was relatively higher than the accumulation of dry matter, with a consequent increase in K concentration in shoot tissue. The remobilisation of some nutrients (eg. Fe, Ca and Zn) from various grain tissues during inbibition, germination and early growth is different from the remobilisation in more mature plants.