Cloning and characterization of two genes coding for the histone acetyltransferases,Elp3 and Mof,in brown planthopper (BPH), Nilaparvata lugens (Stål)

Histone acetylation is a vital mechanism for the post-translational modifications of chromatin components. Histone acetyltransferases (HATs) are critical elements that determine histone acetylation and regulate chromatin dynamics and gene expression. While histone acetyltransferases have been well studied in mammals and Drosophila melanogaster, information from agriculturally important insect pests is still limited. In our effort to understand the epigenetic mechanisms regulating development in the brown planthopper, Nilaparvata lugens (Stål) (Hemiptera: Geometroidea), a major rice pest in many parts of Asia, two full-length cDNA sequences encoding HAT members of the GNAT and MYST family, namely NlElp3 and NlMof, respectively, were isolated and structurally and phylogenetically characterized. The NlElp3 contains an open reading frame (ORF) of 1656 bp encoding a protein of 551 amino acids. The NlMof contains a 1353 bp ORF encoding a protein of 450 amino acids. Sequence analysis showed that NlElp3 contains GNAT-type HAT domain and Radical SAM domain, and NlMof contains chromodomain and MOZ-SAS acetyltransferase domain. Multiple sequence alignments showed that NlElp3 and NlMof have high amino acid sequence identity with other insect homologues. Expression analysis of the NlElp3 and NlMof revealed significant differences in mRNA expression levels among N. lugens developmental stages, suggesting that HAT activities of NlElp3 and NlMof may be controlled, at least in part, by their developmental regulation. Remarkably, the mRNA expression levels of NlElp3 and NlMof in female adults were significantly higher than that in male adults, supporting an important role for both genes in female reproductive function in N. lugens.     

The MYST histone acetyltransferases are essential for gametophyte development in Arabidopsis

Background  

Histone acetyltransferases (HATs) play critical roles in the regulation of chromatin structure and gene expression. Arabidopsis genome contains 12 HAT genes, but the biological functions of many of them are still unknown. In this work, we studied the evolutionary relationship and cellular functions of the two Arabidopsis HAT genes homologous to the MYST family members.     

The major volatile compound 2-phenylethanol from the biocontrol yeast,Pichia anomala,inhibits growth and expression of aflatoxin biosynthetic genes of Aspergillus flavus

Aspergillus flavus is a ubiquitous saprophyte that is able to produce the most potent natural carcinogenic compound known as aflatoxin B₁ (AFB₁). This toxin frequently contaminates crops including corn, cotton, peanuts, and tree nuts causing substantial economic loss worldwide. Consequently, more than 100 countries have strict regulations limiting AFB₁ in foodstuffs and feedstuffs. Plants and microbes are able to produce volatile compounds that act as a defense mechanism against other organisms. Pichia anomala strain WRL-076 is a biocontrol yeast currently being tested to reduce AF contamination of tree nuts in California. We used the SPME-GC/MS analysis and identified the major volatile compound produced by this strain to be 2-phenylethanol (2-PE). It inhibited spore germination and AF production of A. flavus. Inhibition of AF formation by 2-PE was correlated with significant down regulation of clustering AF biosynthesis genes as evidenced by several to greater than 10,000-fold decrease in gene expression. In a time-course analysis we found that 2-PE also altered the expression patterns of chromatin modifying genes, MYST1, MYST2, MYST3, gcn5, hdaA and rpdA. The biocontrol capacity of P. anomala can be attributed to the production of 2-PE, which affects spore germination, growth, toxin production, and gene expression in A. flavus.     

Comparative Genome-Wide Analysis and Expression Profiling of Histone Acetyltransferases and Histone Deacetylases Involved in the Response to Drought in Wheat

Histone acetyltransferases (HATs) and histone deacetylases (HDACs) contribute to plant growth, development, and stress responses. A number of HAT and HDAC genes have been identified in several plants. However, wheat HATs and HDACs have not been comprehensively characterized. In this study, 30 TaHAT genes and 53 TaHDAC genes were detected in the wheat genome. As described in other plants, TaHATs were classified into four subfamilies (i.e., GNAT, p300/CBP, MYST, and TAFII250) and TaHDACs were divided into three subfamilies (i.e., RPD3/HDA1, HD2, and SIR2). Phylogenetic and conserved domain analyses showed that TaHATs and TaHDACs are highly similar to those in Arabidopsis and rice; however, divergence and expansion from Arabidopsis and rice were also observed. We detected many stress-related cis-regulatory elements in the promoter regions of these genes (i.e., ABRE, STRE, MYB, etc.). Further, based on a comparative expression analyses of three varieties with different degrees of drought resistance under drought stress, we found that TaHAG2, TaHAG3, TaHAC2, TaHDA18, TaHDT1, and TaHDT2 are likely regulate drought stress in wheat.

     

Regulated expression of three alcohol dehydrogenase genes in barley aleurone layers

Three genes specify alcohol dehydrogenase (EC 1.1.1.1.; ADH) enzymes in barley (Hordeum vulgare L.) (Adh 1, Adh 2, and Adh 3). Their polypeptide products (ADH 1, ADH 2, ADH 3) dimerize to give a total of six ADH isozymes which can be resolved by native gel electrophoresis and stained for enzyme activity.

Under fully aerobic conditions, aleurone layers of cv Himalaya had a high titer of a single isozyme, the homodimer containing ADH 1 monomers. This isozyme was accumulated by the aleurone tissue during the later part of seed development, and survived seed drying and rehydration. The five other possible ADH isozymes were induced by O₂ deficit. The staining of these five isozymes on electrophoretic gels increased progressively in intensity as O₂ levels were reduced below 5%, and were most intense at 0% O₂.

In vivo³⁵S labeling and specific immunoprecipitation of ADH peptides, followed by isoelectric focusing of the ADH peptides in the presence of 8 molar urea (urea-IEF) demonstrated the following. (a) Aleurone layers incubated in air synthesized ADH 1 and a trace of ADH 2; immature layers from developing seeds behaved similarly. (b) At 5% O₂, synthesis of ADH 2 increased and ADH 3 appeared. (c) At 2% and 0% O₂, the synthesis of all three ADH peptides increased markedly.

Cell-free translation of RNA isolated from aleurone layers, followed by immunoprecipitation and urea-IEF of in vitro synthesized ADH peptides, showed that levels of mRNA for all three ADH peptides rose sharply during 1 day of O₂ deprivation. Northern hybridizations with a maize Adh 2 cDNA clone established that the clone hybridized with barley mRNA comparable in size to maize Adh 2 mRNA, and that the level of this barley mRNA increased 15- to 20-fold after 1 day at 5% or 2% O₂, and about 100-fold after 1 day at 0% O₂.

We conclude that in aleurone layers, expression of the three barley Adh genes is maximal in the absence of O₂, that regulation of mRNA level is likely to be a major controlling factor, and that whereas the ADH system of barley has strong similarities to that of maize, it also has some distinctive features.

     

Interactions between ethylene,abscisic acid and cytokinin during germination and seedling establishment in <Emphasis Type="Italic">Arabidopsis</Emphasis>

In order to investigate the interaction of the plant hormones ethylene, abscisic acid (ABA) and cytokinin in seed germination and early seedling development, we studied germination in ethylene-related mutants of Arabidopsis. Mutations in the genes etr1 and ein2, which reduce ethylene responses, showed increased dormancy and a delay in germination in comparison with wild type. Mutations in etr1, ein2 and ein6 also resulted in increased sensitivity to ABA with respect to inhibition of germination. Conversely, mutations in ctr1 and eto3, which lead to an increased ethylene response and overproduction of ethylene, respectively, decreased sensitivity to ABA during germination. Increased ABA sensitivity was also effected in wild type seeds by the presence during germination of AgNO₃, an inhibitor of ethylene action. The addition of the cytokinin N-6 benzyl adenine (BA) reversed the increased sensitivity of ethylene-resistant mutants to ABA. The action of cytokinin in reversing increased ABA sensitivity of ethylene-resistant mutants also suggests that at least part of the action of cytokinin in promoting germination is independent of its role in stimulating ethylene production. These observations further extend the evidence in support of interaction between ethylene, ABA and cytokinin signalling in controlling seed germination and early seedling development in Arabidopsis.     

Quantifying the sensitivity of barley seed germination to oxygen, abscisic acid, and gibberellin using a population-based threshold model

Barley (Hordeum vulgare L.) seeds (grains) exhibit dormancyat maturity that is largely due to the presence of the glumellae(hulls) that reduce the availability of oxygen (O₂) to the embryo.In addition, abscisic acid (ABA) and gibberellins (GAS) interactwith O₂ to regulate barley seed dormancy. A population-basedthreshold model was applied to quantify the sensitivities ofseeds and excised embryos to O₂, ABA, and GA, and to their interactiveeffects. The median O₂ requirement for germination of dormantintact barley seeds was 400-fold greater than for excised embryos,indicating that the tissues enclosing the embryo markedly limitO₂ penetration. However, embryo O₂ thresholds decreased by anotherorder of magnitude following after-ripening. Thus, increasesin both permeability of the hull to O₂ and embryo sensitivityto O₂ contribute to the improvement in germination capacityduring after-ripening. Both ABA and GA had relatively smalleffects on the sensitivity of germination to O₂, but ABA andGA thresholds varied over several orders of magnitude in responseto O₂ availability, with sensitivity to ABA increasing and sensitivityto GA decreasing with hypoxia. Simple additive models of O₂–ABAand O₂–GA interactions required consideration of theseO₂ effects on hormone sensitivity to account for actual germinationpatterns. These quantitative and interactive relationships amongO₂, ABA, and GA sensitivities provide insight into how dormancyand germination are regulated by a combination of physical (O₂diffusion through the hull) and physiological (ABA and GA sensitivities)factors. Key words: Abscisic acid, barley, germination, gibberellin, Hordeum vulgare L., model, oxygen, sensitivity Received 2 August 2007; Revised 14 November 2007 Accepted 19 November 2007     

Quantitative models characterizing seed germination responses to abscisic Acid and osmoticum

Mathematical models were developed to characterize the physiological bases of the responses of tomato (Lycopersicon esculentum Mill. cv T5) seed germination to water potential (ψ) and abscisic acid (ABA). Using probit analysis, three parameters were derived that can describe the germination time courses of a seed population at different ψ or ABA levels. For the response of seed germination to reduced ψ, these parameters are the mean base water potential (¯ψ_b, MPa), the standard deviation of the base water potential among seeds in the population (σ_ψb, MPa), and the “hydrotime constant” (θ_H, MPa·h). For the response to ABA, they are the log of the mean base ABA concentration ([unk]ABA_b, m), the standard deviation of the base ABA concentration among seeds in the population (σ_ABAb, log[m]), and the “ABA-time constant” (θ_ABA, log[m]·h). The values of ¯ψ_b and [unk]ABA_b provide quantitative estimates of the mean sensitivity of germination rate to ψ or ABA, whereas σ^ψ_b and σ_ABAb account for the variation in sensitivity among seeds in the population. The time constants, θ_H and θ_ABA, indicate the extent to which germination rate will be affected by a given change in ψ or ABA. Using only these parameters, germination time courses can be predicted with reasonable accuracy at any medium ψ according to the equation probit(g) = [ψ - (θ_H/t_g) - ¯ψ_b]/σ_ψb, or at any ABA concentration according to the equation probit(g) = [log[ABA] - (θ_ABA/t_g) - log[[unk]ABA_b]]/σ_ABAb, where t_g is the time to radicle emergence of percentage g, and ABA is the ABA concentration (m) in the incubation solution. In the presence of both ABA and reduced ψ, the same parameters can be used to predict seed germination time courses based upon strictly additive effects of ψ and ABA in delaying the time of radicle emergence. Further analysis indicates that ABA and ψ can act both independently and interactively to influence physiological processes preparatory for radicle growth, such as the accumulation of osmotic solutes in the embryo. The models provide quantitative values for the sensitivity of germination to ABA or ψ, allow evaluation of independent and interactive effects of the two factors, and have implications for understanding how ABA and ψ may regulate growth and development.     

Abscisic Acid localization and metabolism in barley aleurone layers

Aleurone layers of Hordeum vulgare, cv. `Himalaya' took up [¹⁴C]-abscisic acid (ABA) when incubated for various times. Radioactivity accumulated with time in a low speed, DNA-containing pellet accounting for 1.6 to 2.3% of the radioactivity recovered in subcellular fractions at 18 hours. Thin layer chromatography of ethanolic or methanolic extracts of the cytosol, which contained greater than 95% of the radioactivity taken up by layers, revealed that labeled ABA was metabolized to phaseic acid (PA) and 4′-dihydrophaseic acid (DPA) and three polar metabolites Mx₁, Mx₂, and Mx₃. ABA was not metabolized by endosperm, incubated under conditions used for layers, indicating that metabolism was tissue-specific. Layers metabolized [³H]DPA to Mx₁ and Mx₂. ABA, PA, and DPA-methyl ester and epi-DPA-methyl ester inhibited synthesis of α-amylase by layers incubated for either 37 or 48 hours. These layers converted the methyl DPA and epi-methyl-DPA esters to their respective acids. DPA did not inhibit Lactuca sativa germination or root and coleoptile elongation of germinating Hordeum vulgare seeds, or coleoptile elongation of germinating Zea mays seeds.