Tianzhong Li

Null Mutation of the MdACS3 Gene, Coding for a Ripening-Specific 1-Aminocyclopropane-1-Carboxylate Synthase, Leads to Long Shelf Life in Apple Fruit

Expression of MdACS1, coding for 1-aminocyclopropane-1-carboxylate synthase (ACS), parallels the level of ethylene production in ripening apple (Malus domestica) fruit. Here we show that expression of another ripening-specific ACS gene (MdACS3) precedes the initiation of MdACS1 expression by approximately 3 weeks; MdACS3 expression then gradually decreases as MdACS1 expression increases. Because MdACS3 expression continues in ripening fruit treated with 1-methylcyclopropene, its transcription appears to be regulated by a negative feedback mechanism. Three genes in the MdACS3 family (a, b, and c) were isolated from a genomic library, but two of them (MdACS3b and MdACS3c) possess a 333-bp transposon-like insertion in their 5′ flanking region that may prevent transcription of these genes during ripening. A single nucleotide polymorphism in the coding region of MdACS3a results in an amino acid substitution (glycine-289 → valine) in the active site that inactivates the enzyme. Furthermore, another null allele of MdACS3a, Mdacs3a, showing no ability to be transcribed, was found by DNA sequencing. Apple cultivars homozygous or heterozygous for both null allelotypes showed no or very low expression of ripening-related genes and maintained fruit firmness. These results suggest that MdACS3a plays a crucial role in regulation of fruit ripening in apple, and is a possible determinant of ethylene production and shelf life in apple fruit.

A mobile signal transported over a long distance induces systemic transcriptional gene silencing in a grafted partner

Transcriptional gene silencing (TGS) can be induced by promoter-targeted small interfering RNA (siRNA). Long-distance transmission of TGS by viral infection in plants has been reported. However, systemic TGS has not been observed in the case of using an inverted repeat transgene as the silencing trigger. Here it is reported that a mobile signal, presumably the siRNA, produced from a hairpin structure transgene controlled by a companion cell-specific promoter can also induce transmissible TGS in both a modified agroinfiltration and a grafting system. Although the transmissible TGS occurred only in cells located in the vicinity of a leaf vein in the scion, very strong silencing was observed in the root system, especially the lateral roots, including the root apical meristem. The transmissible TGS was maintained through tissue culture and subsequently inherited by the progeny. The results suggest the potential application of mobile promoter-targeting siRNA in horticulture for improvement of plant cultivars by grafting.

Graft-Transmitted siRNA Signal from the Root Induces Visual Manifestation of Endogenous Post-Transcriptional Gene Silencing in the Scion

In plants, post-transcriptional gene silencing (PTGS) spreads systemically, being transmitted from the silenced stock to the scion expressing the corresponding transgene. It has been reported that a graft-transmitted siRNA signal can also induce PTGS of an endogenous gene, but this was done by top-grafting using silenced stock. In the present study involving grafting of Nicotiana benthamiana, we found that PTGS of an endogenous gene, glutamate-1-semialdehyde aminotransferase (GSA), which acts as a visible marker of RNAi via inhibition of chlorophyll synthesis, was manifested along the veins of newly developed leaves in the wild-type scion by the siRNA signal synthesized only in companion cells of the rootstock.

A novel gene, MdSSK1, as a component of the SCF complex rather than MdSBP1 can mediate the ubiquitination of S-RNase in apple

Summary The related components of the SCF complex in apple were cloned and it was proved that an SCF complex containing MdSSK1 rather than MdSBP1 can mediate the ubiquitination of S-RNase.

Apple 1-Aminocyclopropane-1-Carboxylic Acid Synthase Genes, MdACS1 and MdACS3a, are Expressed in Different Systems of Ethylene Biosynthesis

Abstract1-Aminocyclopropane-1-carboxylic acid synthase (ACS) is one of the key regulatory enzymes involved in the synthesis of ethylene. Climacteric fruit ripening is accompanied by increased ethylene production, in which ethylene biosynthesis is changed from system 1 to system 2. In apple, at least four members of the ACS gene family have been identified, two of which, MdACS1 and MdACS3a, have been studied extensively due to their specific expression in fruit tissue. However, the regulatory role of MdACS1 and MdACS3a in the ethylene biosynthesis system is unknown. Here we addressed this issue by investigating ACS expression in ripening apple fruits. Expression analysis in ‘Golden Delicious’ and ‘Red Fuji’ fruits, in combination with treatments of 1-MCP (1-methylcyclopropene, an ethylene inhibitor) and Ethephon (an ethylene releaser) has demonstrated that MdACS3a and MdACS1operate in system 1 and system 2 ethylene biosynthesis, respectively.

Isolation and characterisation of a nicotianamine synthase gene MxNas1 in Malus xiaojinensis.

Summary Iron (Fe) is one of the essential micronutrients required by all living organisms. In order to isolate genes involved in Fe-uptake, a subtracted cDNA library from roots of Malus xiaojinensis ‘Cheng et Jiang’ (Accession No. DGB0458 in the National Fruit Germplasm Repository) was constructed using suppression subtractive hybridisation (SSH). MxNas1, a gene that encodes a putative nicotianamine (NA) synthase, was cloned by differential screening of the subtracted library. By complementation, we demonstrated that MxNas1 was able to rescue the phenotype of an NA synthesis-defective tomato (Solanum lycopersicum) mutant ‘chloronerva’, suggesting it was a functional NA synthase. Transgenic tobacco (Nicotiana tabacum) plants that over-expressed MxNas1 were more tolerant to Fe-deficiency than wild-type tobacco plants. In contrast, when MxNas1 was introduced into plants in an anti-sense orientation, to reduce endogenous transcript levels of NA synthase genes, the resulting transgenic tobacco plants exhibited symptoms of Fe-deficiency earlier than control plants. Increased expression of MxNas1 in transgenic tobacco plants also resulted in increased concentrations of Fe, Mn, Cu, and Zn in the leaves.

Distribution of MdACS3 null alleles in apple (Malus × domestica Borkh.) and its relevance to the fruit ripening characters

Expression of MdACS3a, one of the ripening-related ACC synthase genes, plays a pivotal role in initiating the burst of ethylene production by MdACS1 in apple fruit. Although previous studies have demonstrated the presence of MdACS3a-null alleles through deficiency of transcription activity or loss of enzyme activity due to amino acid substitution, which may affect the storage properties of certain fruit cultivars, an overall picture of these null alleles in cultivars is still lacking. The present study investigated the distribution of null allelic genes in 103 cultivars and 172 breeding selections by using a simple sequence repeat (SSR) marker linked to them. The results indicated that both allelic genes were widely distributed throughout the examined cultivars and selections, some occurring as the null genotype, either homozygously or heterozygously, with each null allele. The implications of MdACS3a distribution results and the influence of its null allelotypes in fruit characters are discussed.

Long-distance transport of Gibberellic Acid Insensitive mRNA in Nicotiana benthamiana

BackgroundThe Gibberellic Acid (GA) signal is governed by the GAI (Gibberellic Acid Insensitive) repressor, which is characterized by a highly conserved N-terminal DELLA domain. Deletion of the DELLA domain results in constitutive suppression of GA signaling. As the GAI transcript is transportable in phloem elements, a Δ-DELLA GAI (gai) transgenic stock plant can reduce the stature of a scion through transport of gai mRNA from the stock. However, little is known about the characteristics of a scion on a gai stock.ResultsArabidopsis Δ-DELLA GAI (gai) was fused with a T7 epitope tag and expressed under the control of a companion cell-specific expression promoter, Commelina yellow mottle virus promoter (CoYMVp), to enhance transport in the phloem. The CoYMVp:Atgai-T7 (CgT) transgenic Nicotiana benthamiana exhibited a dwarf phenotype and lower sensitivity to GA enhancement of shoot stature. A wild-type (WT) scion on a CgT stock contained both Atgai-T7 mRNA and the translated product. Microarray analysis to clarify the effect of the CgT stock on the gene expression pattern in the scion clearly revealed that the WT scions on CgT stocks had fewer genes whose expression was altered in response to GA treatment. An apple rootstock variety, Malus prunifolia, integrating CoYMVp:Atgai moderately reduced the tree height of the apple cultivar scion.ConclusionsOur results demonstrate that Atgai mRNA can move from companion cells to sieve tubes and that the translated product remains at the sites to which it is transported, resulting in attenuation of GA responses by reducing the expression of many genes. The induction of semi-dwarfism in an apple cultivar on root stock harbouring Atgai suggests that long-distance transport of mRNA from grafts would be applicable to horticulture crops.

Md-miR156ab and Md-miR395 Target WRKY Transcription Factors to Influence Apple Resistance to Leaf Spot Disease

MicroRNAs (miRNAs) are key regulators of gene expression that post-transcriptionally regulate transcription factors involved in plant physiological activities. Little is known about the effects of miRNAs in disease resistance in apple (Malus×domestica). We globally profiled miRNAs in the apple cultivar Golden Delicious (GD) infected or not with the apple leaf spot fungus Alternaria alternaria f. sp. mali (ALT1), and identified 58 miRNAs that exhibited more than a 2-fold upregulation upon ALT1 infection. We identified a pair of miRNAs that target protein-coding genes involved in the defense response against fungal pathogens; Md-miR156ab targets a novel WRKY transcription factor, MdWRKYN1, which harbors a TIR and a WRKY domain. Md-miR395 targets another transcription factor, MdWRKY26, which contains two WRKY domains. Real-time PCR analysis showed that Md-miR156ab and Md-miR395 levels increased, while MdWRKYN1 and MdWRKY26 expression decreased in ALT1-inoculated GD leaves; furthermore, the overexpression of Md-miR156ab and Md-miR395 resulted in a significant reduction in MdWRKYN1 and MdWRKY26 expression. To investigate whether these miRNAs and their targets play a crucial role in plant defense, we overexpressed MdWRKYN1 or knocked down Md-miR156ab activity, which in both cases enhanced the disease resistance of the plants by upregulating the expression of the WRKY-regulated pathogenesis-related (PR) protein-encoding genes MdPR3-1, MdPR3-2, MdPR4, MdPR5, MdPR10-1, and MdPR10-2. In a similar analysis, we overexpressed MdWRKY26 or suppressed Md-miR395 activity, and found that many PR protein-encoding genes were also regulated by MdWRKY26. In GD, ALT-induced Md-miR156ab and Md-miR395 suppress MdWRKYN1 and MdWRKY26 expression, thereby decreasing the expression of some PR genes, and resulting in susceptibility to ALT1.

KNOTTED1 mRNA undergoes long-distance transport and interacts with movement protein binding protein 2C in pear (Pyrus betulaefolia)

KNOTTED1 (KN1)-like homologous box is a homeodomain transcription factor that is transported intercellularly through plasmodesmata and over long distances via phloem transport in plants. In this study, we investigated KN1 long-distance transport and its regulation by the viral movement protein binding protein of ‘Du Li’ (Pyrus betulaefolia, PbMPB2C) in two species of fruit trees, ‘Du Li’ (rootstock) and ‘Ya Li’ (P. bretschneideri, scion), using grafting experiments. The results showed that PbKN1 mRNA was present in the phloem in both transport directions across the graft junctions of tissue-cultured grafted plants and orchard saplings. To investigate the relationship between PbKN1 and PbMPB2C, we conducted interaction assays to demonstrate their physical interaction. An RNA–protein pull-down assay revealed that PbKN1 mRNA interacted with PbMPB2C protein in vitro but not with PbKN1 and that PbKN1 repressed the binding of PbMPB2C to PbKN1 mRNA. Additionally, using p35S:GFP-PbKN1 transgenic tobacco grafted with wild-type plants, we found that the movement of PbKN1 was increased by the silencing of NtMPB2C. Based on the above findings, we first demonstrate evidence of the bidirectional transport of PbKN1 mRNA and propose that PbMPB2C could act as a negative regulator of the phloem-mediated long-distance transport of PbKN1 mRNA.