Direct gene transfer to plants

Evidence for direct, gene-mediated stable genetic transformation of plant cells of Nicotiana tabacum is presented. A selectable hybrid gene comprising the protein coding region of the Tn5 aminoglycoside phosphotransferase type II gene under control of cauliflower mosaic virus gene VI expression signals was introduced into plant protoplasts as part of an Escherichia coli plasmid. The gene was stably integrated into plant genomic DNA and constitutively expressed in selected, drug resistant, protoplast-derived cell clones. The mode of integration of the foreign gene into the plant genome resembled that observed for DNA transfection of mammalian cells. Plants regenerated from transformed cell lines were phenotypically normal and fertile, and they maintained and expressed the foreign gene throughout the development of vegetative and generative organs. Microspores, grown in anther culture, developed into resistant and sensitive haploid plantlets. Genetic crossing analysis of one of the transformed plants revealed the presence of one dominant trait for kanamycin resistance segregating in a Mendelian fashion in the F₁ generation.     

Direct delivery of bacterial avirulence proteins into resistant Arabidopsis protoplasts leads to hypersensitive cell death

Many bacterial avirulence (Avr) proteins, including the Pseudomonas syringae proteins, AvrRpt2 and AvrB, appear to be recognized inside the host plant cell by resistance mechanisms mediated by the cognate resistance (R) genes. It is thought that Avr proteins are either delivered directly into the host cell via the bacterial type III secretion system (TTSS) or taken up by the plant cell following secretion into the apoplast through the TTSS. Recently, it was shown that the Xanthomonas campestris AvrBs2 protein can be delivered directly into the host plant cell by the TTSS. However, it is not known whether other type III effectors of phytopathogens behave similarly. Here, using a novel protein transfection method, we demonstrate that AvrRpt2 and AvrB must enter the plant cell to be recognized by R gene-mediated mechanisms. First, we established a hypersensitive cell death assay for protoplasts using the membrane-impermeable, nuclear-staining dye, YO-PRO-1, and transgenic Arabidopsis plants that carry an inducible avrRpt2 gene. Second, we transfected E. coli-produced AvrRpt2 or AvrB proteins into Arabidopsis protoplasts using a protein transfection kit based on the carrier peptide Pep-1, and demonstrated that hypersensitive cell death occurs in a gene-for-gene-specific manner. In contrast, these Avr proteins failed to elicit hypersensitive cell death when they were applied to protoplasts without the carrier peptide. We conclude that our preparations of E. coli-produced AvrRpt2 and AvrB are active, that AvrRpt2 and AvrB must be delivered into the plant cell to be recognized, and that a method based on a carrier peptide can be used to introduce proteins into plant cells.     

Simple and reliable system for transient gene expression for the characteristic signal sequences and the estimation of the localization of target protein in plant cell

The efficiency of transient gene expression in plants credibly demonstrated characteristics of gene functions in numerous studies. Two key strategies of transient expression became favorites among researchers: protoplast transfection and agroinfiltration. Each of them, alongside the advantages, has its own constraints. In this work, an easy, rapid, and reliable system for characterization of the signal sequences and determinations of target protein localization in a plant cell is proposed and tested. This system—called the AgI–PrI—implies production of protoplasts from plant tissues after agroinfiltration. Reliability of the proposed system for transient gene expression has been proved using characterized signal sequences in Nicotiana benthamiana cells. The corresponding protocol is less expensive and depends to a lesser degree on the professional skills in the area of protoplast isolation and transfection; furthermore, it may be applicable to other plant species with either available efficient methods of agroinfiltration and protoplast isolation or with the potential for one of the protocols to be supplemented. Thus, the AgI–PrI technique makes it possible to combine the advantages of two widely used methods for the transient gene expression in plants—agroinfiltration and protoplast isolation and transfection—and concurrently avoids their critical points.     

植物原生质体在分子细胞生物学研究中的应用

植物原生质体是去除了细胞壁的裸露细胞,其具有细胞全能性,现广泛应用于植物分子细胞生物学的研究中,可以大大缩减实验周期,并有助于得到体内实验的实时检测数据。该文除了介绍植物原生质体的提取和纯化方法外,还对国内外利用各种植物的原生质体进行细胞瞬时转化、亚细胞定位、细胞融合和大分子复合物相互作用等试验进行了总结和讨论。植物原生质体还可用于基因表达模式的实时检测,并作为生物反应器的受体细胞进行代谢物的体外生产。此外,还对当前该技术所面临的瓶颈进行了分析,为植物原生质体在分子细胞生物学领域的应用提供帮助,为技术的优化和推广提供参考。     

Linear forms of plasmid DNA are superior to supercoiled structures as active templates for gene expression in plant protoplasts

Introduction of the plasmids pUC8CaMVCAT and pNOSCAT into plant protoplasts is known to result in transient expression of the chloramphenicol acetyl transferase (CAT) gene. Also, transfection with the plasmid pDO432 results in transient appearance of the luciferase enzyme. In the present work we have used these systems to study the effect of DNA topology on the expression of the above recombinant genes. Linear forms of the above plasmids exhibited much higher activity in supporting gene expression than their corresponding super-coiled structures. CAT activity in protoplasts transfected with the linear forms of pUC8CaMVCAT and pNOSCAT was up to ten-fold higher than that observed in protoplasts transfected by the supercoiled template of these plasmids. This effect was observed in protoplasts derived from two different lines of Petunia hybrida and from a Nicotiana tabacum cell line. Transfection with the relaxed form of pUC8CaMVCAT resulted in very low expression of the CAT gene.Northern blot analysis revealed that the amount of poly(A)⁺ RNA extracted from protoplasts transformed with the linear forms of the DNA was about 10-fold higher than that found in protoplasts transformed with supercoiled DNA.Southern blot analysis revealed that about the same amounts of supercoiled and linear DNA molecules were present in nuclei of transfected protoplasts. No significant quantitative differences have been observed between the degradation rates of the various DNA templates used.     

Wheat dwarf virus vectors replicate and express foreign genes in cells of monocotyledonous plants.

Wheat dwarf virus (WDV) is a geminivirus that infects monocotyledonous plants. To exploit the potential of WDV as a replicative gene vector, we developed a transient replication and expression system based on the transfection of protoplasts derived from Triticum monococcum suspension culture cells. Cloned genomic copies of various WDV isolates as well as mutants constructed in vitro were introduced into the protoplasts and assayed for their ability to replicate. As a result, regions of the WDV genome necessary or dispensable for the viral DNA replication could be defined. In addition, the gene encoding the viral capsid protein was replaced by three different bacterial marker genes, neomycin phosphotransferase, chloramphenicol acetyltransferase, and beta-galactosidase. The beta-galactosidase gene doubled the size of the WDV genome. The replication of the recombinant WDV genomes and the expression of these genes were monitored in suspension culture cells of T. monococcum. The potential of replicative expression vectors based on the WDV genome is discussed.     

A transient expression system in soybean mesophyll protoplasts reveals the formation of cytoplasmic GmCRY1 photobody-like structures

Soybean(Glycine max(L.) Merr.), grown for its plant oils and proteins, is one of the most important crops throughout the world.Generating stable and heritable transgenic soybeans is relatively inefficient; therefore, there is an urgent need for a simple and high-efficient transient transformation method by which to enable the investigation of gene functions in soybeans, which will facilitate the elucidation and improvement of the molecular mechanisms regulating the associated agronomic traits. We established a system of transient expression in soybean mesophyll protoplasts and obtained a high level of protoplast transfection efficiency(up to 83.5%). The subcellular activity of the protoplasts was well preserved, as demonstrated by the dynamic formation of GmCRY nucleus photobodies(NPs) and/or cytoplasmic photobody-like structures(CPs) in response to blue light.In addition, we showed that GmCRY1b CPs colocalized with GmCOP1b, a co-ortholog of Arabidopsis thaliana CONSTITUTIVE PHOTOMORPHOGENIC 1(COP1), which provided new insight into the potential roles of GmCRY1s in the cytoplasm.     

Protoplast isolation and transient gene expression in the single-cell C4 species, Bienertia sinuspersici

Although transient gene expression using reporters such as green fluorescent protein is a versatile tool for examining gene functions and intracellular protein trafficking, the establishment of a highly efficient gene manipulation method remains a challenge in many plant species. A reliable transformation protocol has not yet been established for the three single-cell C₄ species, despite their potential of serving as model systems for their extraordinary C₄ photosynthetic metabolism. We report the first protocol optimized for isolating a large-scale and homogenous population of protoplasts from chlorenchyma cells of the single-cell C₄ species Bienertia sinuspersici. Cytochemical staining confirmed the preservation of the unusual subcellular compartmentation of organelles in chlorenchyma cells after cell wall digestion. Approximately 84% of isolated protoplasts expressed the reporter fluorescent protein following our optimized polyethylene glycol-mediated transfection procedures. Fluorescent fusion protein tagged with various intracellular sorting signals demonstrated potential use of the transient gene expression system in subcellular protein localization and organelle dynamics studies. Further applications of the current protoplast isolation and transfection techniques in understanding the novel single-cell C₄ photosynthetic mechanism are discussed.     

Secretory pathway research: the more experimental systems the better

Transient gene expression, in plant protoplasts or specific plant tissues, is a key technique in plant molecular cell biology, aimed at exploring gene products and their modifications to examine functional subdomains, their interactions with other biomolecules, and their subcellular localization. Here, we highlight some of the major advantages and potential pitfalls of the most commonly used transient gene expression models and illustrate how ectopic expression and the use of dominant mutants can provide insights into protein function.     

Heat-inducible expression of FLP gene in maize cells

The soybean heat-shock gene promoter ( Gmhsp 17.5-E ) has been used to direct expression of gusA and FLP genes in maize cells. At inducible temperatures, in transient expression assays, gusA gene expression controlled by the heat-shock promoter is about 10-fold higher than the expression directed by the CaMV 35S promoter. The Gmhsp 17.5-E promoter preserves its regulatory functions in heterologous maize cells after random integration into genomic DNA.
Heat-shock inducible expression of the FLP gene was investigated by co-transformation of the FLP expression vector (pHsFLP) and a recombination test vector (pUFNeo-FmG) into maize protoplasts. Co-transformed protoplasts were incubated at 42°C for 2 h. This treatment induced recombination of 20–25% of the available FRT sites in transient assays. As a result of heat-shock treatment of stably co-transformed maize cells, activation of gusA gene expression and an associated decrease or elimination of NPT-II activity in transgenic maize lines was observed. Molecular evidence was obtained of the expected DNA excision process catalyzed by the FLP protein in maize transgenic cells. Thus, the experiments presented in this paper indicate that the FLP protein can recognize and subsequently recombine the FRT target sites that had integrated into plant genomic DNA, and that regulated expression of the FLP gene is possible in maize cells using the soybean heat-shock promoter.     

Protoplasts in organelle research: Transfer and transformation of plastids

Protoplasts, because they lack the wall of a typical higher plant cell, offer unique opportunities for experimental manipulation of their organellar constituents. Here, we report on modification of the organellar content of Nicotiana tabacum protoplasts by microfusion-induced transfer of defined numbers of chloroplasts into albino recipient cells. A single chloroplast is found to be sufficient for establishing a new plastid population in the progeny of the recipient cell. The frequency of green or variegated regenerants is shown to be genotype dependent. It can be drastically increased by using selection pressure for the transferred organelle. We also report on transient expression of plastid specific reporter gene constructs in plastids after PEG-mediated direct gene transfer into Nicotiana plumbaginifolia protoplasts. The expression is shown to be localized in the plastids by determining gene expression in isolated chloroplasts under conditins which completely remove cytoplasmic enzyme activity derived from a nuclear reporter gene construct. These data demonstrate for the first time that functional DNA, introduced into the cytoplasm by direct gene transfer, enters the organellar compartment and is expressed.     

Influence of bacterial strain genotype on transient expression of plasmid DNA in plant protoplasts

It is demonstrated that transient expression of plasmid DNA in plant protoplasts can be strongly influenced by the bacterial strain used for plasmid propagation. Four different promoter constructs containing two light-responsive and two fungal elicitor-responsive parsley promoters translationally fused to the reporter gene, β-glucuronidase (GUS), were amplified in bacterial strains MC1061, DH5α or GM2163 and tested individually. Marked differences in basal expression levels and in fold inducibilities were observed upon transfection of parsley protoplasts. Low levels of basal expression and strong light or elicitor inducibilities were observed only with plasmid DNA derived from the methylation-deficient GM2163 strain. In vitro methylation of DNA prior to transformation also drastically increased basal expression levels. The results suggest that DNA methylation may be partly responsible for deregulating promoter activity in the transient expression system.