水稻多分蘖矮秆突变体htd1-2的遗传分析和基因定位

文章所采用的多分蘖矮秆突变体为htd1-2(high-tillering dwarf 1-2), 是野生型籼稻品种9311经350Gy的60Co- g射线辐射处理后产生的后代中选育出来的稳定多分蘖矮秆突变体。遗传分析表明, 突变体htd1-2多分蘖矮秆性状是由一对隐性核基因的突变造成的。文章利用简单重复序列(Simple sequence repeat, SSR)、酶切扩增多态性序列(Cleaved amplified polymorphic sequence, CAPS)和衍生型CAPS(derived CAPS, dCAPS)等分子标记的方法, 最终将多分蘖矮秆基因HIGH-TILLERING DWARF1-2(HTD1-2)定位在水稻第4号染色体116 kb的物理区间内。在该物理区间内有一个已经克隆的控制水稻分蘖的基因HIGH-TILLERING DWARF1(HTD1), 经过测序比对和dCAPS特异性分析, 认为HTD1就是HTD1-2基因。尽管突变体htd1与突变体htd1-2是等位基因的不同位点发生突变, 但是由于遗传背景的不同, 两者表型并不完全相同。此外, 通过去除分蘖芽的实验证明了突变体htd1-2的矮化部分是由于分蘖过多造成的。     

Artificial elevation of glutathione contents in salicylic acid‐deficient tobacco (Nicotiana tabacum cv. Xanthi NahG) reduces susceptibility to the powdery mildew pathogen Euoidium longipes

• The effects of elevated glutathione levels on defence responses to powdery mildew (Euoidium longipes) were investigated in a salicylic acid‐deficient tobacco (Nicotiana tabacum cv. Xanthi NahG) and wild‐type cv. Xanthi plants, where salicylic acid (SA) contents are normal.
• Aqueous solutions of reduced glutathione (GSH) and its synthetic precursor R‐2‐oxothiazolidine‐4‐carboxylic acid (OTC) were injected into leaves of tobacco plants 3 h before powdery mildew inoculation.
• SA‐deficient NahG tobacco was hyper‐susceptible to E. longipes, as judged by significantly more severe powdery mildew symptoms and enhanced pathogen accumulation. Strikingly, elevation of GSH levels in SA‐deficient NahG tobacco restored susceptibility to E. longipes to the extent seen in wild‐type plants (i.e. enhanced basal resistance). However, expression of the SA‐mediated pathogenesis‐related gene (NtPR‐1a) did not increase significantly in GSH or OTC‐pretreated and powdery mildew‐inoculated NahG tobacco, suggesting that the induction of this PR gene may not be directly involved in the defence responses induced by GSH.
• Our results demonstrate that artificial elevation of glutathione content can significantly reduce susceptibility to powdery mildew in SA‐deficient tobacco.

     

Salt hypersensitivity is associated with excessive xylem development in a thermospermine‐deficient mutant of Arabidopsis thaliana

In Arabidopsis, spermine is produced in most tissues and has been implicated in stress response, while its structural isomer thermospermine is only in xylem precursor cells. Studies on acaulis5 (acl5), a mutant defective in the biosynthesis of thermospermine, have revealed that thermospermine plays a repressive role in xylem development through enhancement of mRNA translation of the SAC51 family. In contrast, the pao5 mutant defective in the degradation of thermospermine has high levels of thermospermine and shows increased salt tolerance, suggesting a role of thermospermine in salt stress response. Here we compared acl5 with a mutant of spermine synthase, spms, in terms of abiotic stress tolerance and found that acl5 was much more sensitive to sodium than the wild‐type and spms. A double‐mutant of acl5 and sac51‐d, which suppresses the excessive xylem phenotype of acl5, recovered normal sensitivity, while a quadruple T‐DNA insertion mutant of the SAC51 family, which has an increased thermospermine level but shows excessive xylem development, showed increased salt sensitivity, unlike pao5. Together with the result that the salt tolerance of both wild‐type and acl5 seedlings was improved by long‐term treatment with thermospermine, we suggest a correlation of the salt tolerance with reduced xylem development rather than with the thermospermine level. We further found that the mutants containing high thermospermine levels showed increased tolerance to drought and heat stress, suggesting another role of thermospermine that may be common with that of spermine and secondary to that in restricting excess xylem development associated with salt hypersensitivity.     

Knockout of two BnaMAX1 homologs by CRISPR/Cas9‐targeted mutagenesis improves plant architecture and increases yield in rapeseed (Brassica napus L.)

Plant height and branch number are essential components of rapeseed plant architecture and are directly correlated with its yield. Presently, improvement of plant architecture is a major challenge in rapeseed breeding. In this study, we first verified that the two rapeseed BnaMAX1 genes had redundant functions resembling those of Arabidopsis MAX1, which regulates plant height and axillary bud outgrowth. Therefore, we designed two sgRNAs to edit these BnaMAX1 homologs using the CRISPR/Cas9 system. The T₀ plants were edited very efficiently (56.30%–67.38%) at the BnaMAX1 target sites resulting in homozygous, heterozygous, bi‐allelic and chimeric mutations. Transmission tests revealed that the mutations were passed on to the T₁ and T₂ progeny. We also obtained transgene‐free lines created by the CRISPR/Cas9 editing, and no mutations were detected in potential off‐target sites. Notably, simultaneous knockout of all four BnaMAX1 alleles resulted in semi‐dwarf and increased branching phenotypes with more siliques, contributing to increased yield per plant relative to wild type. Therefore, these semi‐dwarf and increased branching characteristics have the potential to help construct a rapeseed ideotype. Significantly, the editing resources obtained in our study provide desirable germplasm for further breeding of high yield in rapeseed.     

The gibberellin biosynthetic genes AtKAO1 and AtKAO2 have overlapping roles throughout Arabidopsis development

Ent‐kaurenoic acid oxidase (KAO), a class of cytochrome P450 monooxygenases of the subfamily CYP88A, catalyzes the conversion of ent‐kaurenoic acid (KA) to gibberellin (GA) GA₁₂, the precursor of all GAs, thereby playing an important role in determining GA concentration in plants. Past work has demonstrated the importance of KAO activity for growth in various plant species. In Arabidopsis, this enzyme is encoded by two genes designated KAO1 and KAO2. In this study, we used various approaches to determine the physiological roles of KAO1 and KAO2 throughout plant development. Analysis of gene expression pattern reveals that both genes are mainly expressed in germinating seeds and young developing organs, thus suggesting functional redundancy. Consistent with this, kao1 and kao2 single mutants are indistinguishable from wild‐type plants. By contrast, the kao1 kao2 double mutant exhibits typical non‐germinating GA‐dwarf phenotypes, similar to those observed in the severely GA‐deficient ga1‐3 mutant. Phenotypic characterization and quantitative analysis of endogenous GA contents of single and double kao mutants further confirm an overlapping role of KAO1 and KAO2 throughout Arabidopsis development.     

The dependence of leaf senescence on the balance between 1‐aminocyclopropane‐1‐carboxylate acid synthase 1 (ACS1)‐catalysed ACC generation and nitric oxide‐associated 1 (NOS1)‐dependent NO accumulation in Arabidopsis

• Ethylene and nitric oxide (NO) act as endogenous regulators during leaf senescence. Levels of ethylene or its precursor 1‐aminocyclopropane‐1‐carboxylate acid (ACC) depend on the activity of ACC synthases (ACS), and NO production is controlled by NO‐associated 1 (NOA1). However, the integration mechanisms of ACS and NOA1 activity still need to be explored during leaf senescence.
• Here, using experimental techniques, such as physiological and molecular detection, liquid chromatography‐tandem mass spectrometry and fluorescence measurement, we investigated the relevant mechanisms.
• Our observations showed that the loss‐of‐function acs1‐1 mutant ameliorated age‐ or dark‐induced leaf senescence syndrome, such as yellowing and loss of chlorophyll, that acs1‐1 reduced ACC accumulation mainly in mature leaves and that acs1‐1‐promoted NOA1 expression and NO accumulation mainly in juvenile leaves, when compared with the wild type (WT). But the leaf senescence promoted by the NO‐deficient noa1 mutant was not involved in ACS1 expression. There was a similar sharp reduction of ACS1 and NOA1 expression with the increase in WT leaf age, and this inflection point appeared in mature leaves and coincided with the onset of leaf senescence.
• These findings suggest that NOA1‐dependent NO accumulation blocked the ACS1‐induced onset of leaf senescence, and that ACS1 activity corresponds to the onset of leaf senescence in Arabidopsis.

     

Overexpression of AtPAD4 in transgenic Brachypodium distachyon enhances resistance to Puccinia brachypodii

• Brachypodium distachyon (L.) has recently emerged as a model for temperate grasses for investigating the molecular basis of plant–pathogen interactions. Phytoalexin deficient 4 (PAD4) plays a regulatory role in mediating expression of genes involved in plant defence.
• In this research, we generated transgenic B. distachyon plants constitutively overexpressing AtPAD4. Two transgenic B. distachyon lines were verified using PCR and GUS phenotype.
• Constitutive expression of AtPAD4 in B. distachyon enhanced resistance to Puccinia brachypodii. P. brachypodii generated less urediniospores on transgenic than on wild‐type plants. AtPAD4 overexpression enhanced salicylic acid (SA) levels in B. distachyon‐infected tissues. qRT‐PCR showed that expression of pathogenesis‐related 1 (PR1) and other defence‐related genes were up‐regulated in transformed B. distachyon following infection with P. brachypodii.
• Our results indicate that AtPAD4 overexpression in B. distachyon plants led to SA accumulation and induced PR gene expression that reduced the rate of colonisation by P. brachypodii.

     

Role of ethylene and related gene expression in the interaction between strawberry plants and the plant growth‐promoting bacterium Azospirillum brasilense

• Induced systemic resistance (ISR) is one of the indirect mechanisms of growth promotion exerted by plant growth‐promoting bacteria, and can be mediated by ethylene (ET). We assessed ET production and the expression of related genes in the Azospirillum–strawberry plant interaction.
• Ethylene production was evaluated by gas chromatography in plants inoculated or not with A. brasilense REC3. Also, plants were treated with AgNO₃, an inhibitor of ET biosynthesis; with 1‐aminocyclopropane‐1‐carboxylic acid (ACC), a precursor of ET biosynthesis; and with indole acetic acid (IAA). Plant dry biomass and the growth index were determined to assess the growth‐promoting effect of A. brasilense REC3 in strawberry plants. Quantitative real time PCR (qRT‐PCR) was performed to analyse relative expression of the genes Faetr1, Faers1 and Faein4, which encode ET receptors; Factr1 and Faein2, involved in the ET signalling pathway; Faacs1 encoding ACC synthase; Faaco1 encoding ACC oxidase; and Faaux1 and Faami1 for IAA synthesis enzymes.
• Results showed that ET acts as a rapid and transient signal in the first 12 h post‐treatment. A. brasilense REC3‐inoculated plants had a significantly higher growth index compared to control plants. Modulation of the genes Faetr1, Faers1, Faein4, Factr1, Faein2 and Faaco1 indicated activation of ET synthesis and signalling pathways. The up‐regulation of Faaux1 and Faami1 involved in IAA synthesis suggested that inoculation with A. brasilense REC3 induces production of this auxin, modulating ET signalling.
• Ethylene production and up‐regulation of genes associated with ET signalling in strawberry plants inoculated with A. brasilense REC3 support the priming activation characteristic of ISR. This type of resistance and the activation of systemic acquired resistance previously observed in this interaction indicate that both are present in strawberry plants, could act synergistically and increase protection against pathogens.

     

A substitution mutation in OsCCD7 cosegregates with dwarf and increased tillering phenotype in rice

Dwarf plant height and tillering ability are two of the most important agronomic traits that determine the plant architecture, and have profound influence on grain yield in rice. To understand the molecular mechanism controlling these two traits, an EMS-induced recessive dwarf and increased tillering1 (dit1) mutant was characterized. The mutant showed proportionate reduction in each internode as compared to wild type revealing that it belonged to the category of dn-type of dwarf mutants. Besides, exogenous application of GA3 and 24-epibrassinolide, did not have any effect on the phenotype of the mutant. The gene was mapped on the long arm of chromosome 4, identified through positional candidate approach and verified by cosegregation analysis. It was found to encode carotenoid cleavage dioxygenase7 (CCD7) and identified as an allele of htd1. The mutant carried substitution of two nucleotides CC to AA in the sixth exon of the gene that resulted in substitution of serine by a stop codon in the mutant, and thus formation of a truncated protein, unlike amino acid substitution event in htd1. The new allele will facilitate further functional characterization of this gene, which may lead to unfolding of newer signalling pathways involving plant development and architecture.     

Vertical inhibition of the MAPK pathway enhances therapeutic responses in NRAS‐mutant melanoma

The MEK inhibitor MEK162 is the first targeted therapy agent with clinical activity in patients whose melanomas harbor NRAS mutations; however, median PFS is 3.7 months, suggesting the rapid onset of resistance in the majority of patients. Here, we show that treatment of NRAS‐mutant melanoma cell lines with the MEK inhibitors AZD6244 or trametinib resulted in a rebound activation of phospho‐ERK (pERK). Functionally, the recovery of signaling was associated with the maintenance of cyclin‐D1 expression and therapeutic escape. The combination of a MEK inhibitor with an ERK inhibitor suppressed the recovery of cyclin‐D1 expression and was associated with a significant enhancement of apoptosis and the abrogation of clonal outgrowth. The MEK/ERK combination strategy induced greater levels of apoptosis compared with dual MEK/CDK4 or MEK/PI3K inhibition across a panel of cell lines. These data provide the rationale for further investigation of vertically co‐targeting the MAPK pathway as a potential treatment option for NRAS‐mutant melanoma patients.