Bleomycin resistance: a new dominant selectable marker for plant cell transformation

Expression of a Tardigrade Dsup Gene Enhances Genome Protection in Plants

DNA damage is one of the most impactful events in living organisms, leading to DNA sequence changes (mutation) and disruption of biological processes. A study has identified a protein called Damage Suppressor Protein (Dsup) in the tardigrade Ramazzotius varieornatus that has shown to reduce the effects of radiation damage in human cell cultures (Hashimoto in Nature Communications 7:12808, 2016). We have generated tobacco plants that express the codon-optimized tardigrade Dsup gene and examined their responses when treated with mutagenic chemicals, ultraviolet (UV) and ionizing radiations. Our studies showed that compared to the control plants, the Dsup-expressing plants grew better in the medium containing mutagenic ethylmethane sulfonate (EMS). RT-qPCR detected distinct expression patterns of endogenous genes involved in DNA damage response and repair in the Dsup plants in response to EMS, bleomycin, UV-C and X-ray radiations. Comet assays revealed that the nuclei from the Dsup plants appeared more protected from UV and X-ray damages than the control plants. Overall, our studies demonstrated that Dsup gene expression enhanced tolerance of plants to genomutagenic stress. We suggest the feasibility of exploring genetic resources from extremotolerant species such as tardigrades to impart plants with tolerance to stressful environments for future climate changes and human space endeavors.

Investigating the plant and air-quality performances of an internal green wall system under hydroponic conditions

Internal green wall systems can be combined with building structures to bring positive impacts on people's quality of life in interior spaces. However, obtaining green wall systems to optimize the performances of these living walls still needs research works. This study was conducted to investigate the plant, and air-quality performance resulted from combining ornamental plants and growing media types in an internal green wall system. The growing media types (mixed based on volume percentage) included cocopeat, perlite, cocopeat + perlite (1v:1v) and cocopeat + perlite + vermicompost (1v:1v:1v). The ornamental species included Peperomia magnoliiaefolia, Kalanchoe blossfeldiana, Aptenia cordifolia, and Carpobrotus edulis. There were significant differences among the plant species and the growing media types for improvement of the plant growth and morphophysiological factors. Organic-rich growing media of vermicompost along with perlite and cocopeat, combined with Aptenia cordifolia as the species can be used to create a horticulturally sustainable internal green wall, and also improve the health index in the building interior environments.

Plant genetic transformation efficiency of selected Malaysian rice based on selectable marker gene (hptII)

Rice is one of the most important cereal crops with great potential for biotechnology progress. In transformation method, antibiotic resistance genes are routinely used as powerful markers for selecting transformed cells from surrounding non-transformed cells. In this study, the toxicity level of hygromycin was optimized for two selected mutant rice lines, MR219 line 4 and line 9. The mature embryos were isolated and cultured on an MS medium with different hygromycin concentrations (0, 20, 40, 60, 80 and 100 mg L(-1)). Evidently, above 60 mg L(-1) was effective for callus formation and observed completely dead. Further there were tested for specific concentration (0-60). Although, 21.28% calli survived on the medium containing 45 mg L(-1) hygromycin, it seemed suitable for the identification of putative transformants. These findings indicated that a system for rice transformation in a relatively high frequency and the transgenes are stably expressed in the transgenic plants. Green shoots were regenerated from the explant under hygromycin stress. RT-PCR using hptII and gus sequence specific primer and Southern blot analysis were used to confirm the presence of the transgene and to determine the transformation efficiency for their stable integration in regenerated plants. This study demonstrated that the hygromycin resistance can be used as an effective marker for rice transformation.

Transgenic plants: performance, release and containment

This review focuses on transgenic plants, from the initial stages of the genetic modification process in the laboratory to their release stage in the field and indicates possible areas of concern and strategies for dealing with them. The classes of marker genes and issues about their safety, the gene flow and strategies that are used to isolate transgenic plants genetically are specifically examined. In addition, an assessment is provided of the phenomena which affect the performance of transgenic plants, such as gene disruption, the pleiotropic effect on plant phenotype and genetic variation. Finally, strategies are suggested for preventing unexpected consequences of transgenic plant production.

Transgenic plants as tools to study the molecular organization of plant genes

Transgenic plants are generated in nature by Agrobacterium tumefaciens, a pathogen that produces disease through the transfer of some of its own DNA into susceptible plants. The genes are carried on a plasmid. Much has been learned about how the plasmid is transferred, how the plasmid-borne genes are organized, regulated, and expressed, and how the bacteria's pathogenic effects are produced. The A. tumefaciens plasmid has been manipulated for use as a general vector for the transfer of specific segments of foreign DNA of interest (from plants and other sources) into plants; the activities of various genes and their regulation by enhancer and silencer sequences have been assessed. Future uses of the vector (or others like it that have different host ranges) by the agriculture industry are expected to aid in moving into vulnerable plants specific genes that will protect them from such killers as nonselective herbicides, insects, and viruses.

Advances in selectable marker genes for plant transformation

Plant transformation systems for creating transgenics require separate process for introducing cloned DNA into living plant cells. Identification or selection of those cells that have integrated DNA into appropriate plant genome is a vital step to regenerate fully developed plants from the transformed cells. Selectable marker genes are pivotal for the development of plant transformation technologies because marker genes allow researchers to identify or isolate the cells that are expressing the cloned DNA, to monitor and select the transformed progeny. As only a very small portion of cells are transformed in most experiments, the chances of recovering transgenic lines without selection are usually low. Since the selectable marker gene is expected to function in a range of cell types it is usually constructed as a chimeric gene using regulatory sequences that ensure constitutive expression throughout the plant. Advent of recombinant DNA technology and progress in plant molecular biology had led to a desire to introduce several genes into single transgenic plant line, necessitating the development of various types of selectable markers. This review article describes the developments made in the recent past on plant transformation systems using different selection methods adding a note on their importance as marker genes in transgenic crop plants.

Improved protocols for functional analysis in the pathogenic fungus Aspergillus flavus

Background

An available whole genome sequence for Aspergillus flavus provides the opportunity to characterize factors involved in pathogenicity and to elucidate the regulatory networks involved in aflatoxin biosynthesis. Functional analysis of genes within the genome is greatly facilitated by the ability to disrupt or mis-express target genes and then evaluate their result on the phenotype of the fungus. Large-scale functional analysis requires an efficient genetic transformation system and the ability to readily select transformants with altered expression, and usually requires generation of double (or multi) gene deletion strains or the use of prototrophic strains. However, dominant selectable markers, an efficient transformation system and an efficient screening system for transformants in A. flavus are absent.

Results

The efficiency of the genetic transformation system for A. flavus based on uracil auxotrophy was improved. In addition, A. flavus was shown to be sensitive to the antibiotic, phleomycin. Transformation of A. flavus with the ble gene for resistance to phleomycin resulted in stable transformants when selected on 100 μg/ml phleomycin. We also compared the phleomycin system with one based on complementation for uracil auxotrophy which was confirmed by uracil and 5-fluoroorotic acid selection and via transformation with the pyr4 gene from Neurospora crassa and pyrG gene from A. nidulans in A. flavus NRRL 3357. A transformation protocol using pyr4 as a selectable marker resulted in site specific disruption of a target gene. A rapid and convenient colony PCR method for screening genetically altered transformants was also developed in this study.

Conclusion

We employed phleomycin resistance as a new positive selectable marker for genetic transformation of A. flavus. The experiments outlined herein constitute the first report of the use of the antibiotic phleomycin for transformation of A. flavus. Further, we demonstrated that this transformation protocol could be used for directed gene disruption in A. flavus. The significance of this is twofold. First, it allows strains to be transformed without having to generate an auxotrophic mutation, which is time consuming and may result in undesirable mutations. Second, this protocol allows for double gene knockouts when used in conjunction with existing strains with auxotrophic mutations.

To further facilitate functional analysis in this strain we developed a colony PCR-based method that is a rapid and convenient method for screening genetically altered transformants. This work will be of interest to those working on molecular biology of aflatoxin metabolism in A. flavus, especially for functional analysis using gene deletion and gene expression.

Selectable marker genes in transgenic plants: applications, alternatives and biosafety

Approximately fifty marker genes used for transgenic and transplastomic plant research or crop development have been assessed for efficiency, biosafety, scientific applications and commercialization. Selectable marker genes can be divided into several categories depending on whether they confer positive or negative selection and whether selection is conditional or non-conditional on the presence of external substrates. Positive selectable marker genes are defined as those that promote the growth of transformed tissue whereas negative selectable marker genes result in the death of the transformed tissue. The positive selectable marker genes that are conditional on the use of toxic agents, such as antibiotics, herbicides or drugs were the first to be developed and exploited. More recent developments include positive selectable marker genes that are conditional on non-toxic agents that may be substrates for growth or that induce growth and differentiation of the transformed tissues. Newer strategies include positive selectable marker genes which are not conditional on external substrates but which alter the physiological processes that govern plant development. A valuable companion to the selectable marker genes are the reporter genes, which do not provide a cell with a selective advantage, but which can be used to monitor transgenic events and manually separate transgenic material from non-transformed material. They fall into two categories depending on whether they are conditional or non-conditional on the presence of external substrates. Some reporter genes can be adapted to function as selectable marker genes through the development of novel substrates. Despite the large number of marker genes that exist for plants, only a few marker genes are used for most plant research and crop development. As the production of transgenic plants is labor intensive, expensive and difficult for most species, practical issues govern the choice of selectable marker genes that are used. Many of the genes have specific limitations or have not been sufficiently tested to merit their widespread use. For research, a variety of selection systems are essential as no single selectable marker gene was found to be sufficient for all circumstances. Although, no adverse biosafety effects have been reported for the marker genes that have been adopted for widespread use, biosafety concerns should help direct which markers will be chosen for future crop development. Common sense dictates that marker genes conferring resistance to significant therapeutic antibiotics should not be used. An area of research that is growing rapidly but is still in its infancy is the development of strategies for eliminating selectable marker genes to generate marker-free plants. Among the several technologies described, two have emerged with significant potential. The simplest is the co-transformation of genes of interest with selectable marker genes followed by the segregation of the separate genes through conventional genetics. The more complicated strategy is the use of site-specific recombinases, under the control of inducible promoters, to excise the marker genes and excision machinery from the transgenic plant after selection has been achieved. In this review each of the genes and processes will be examined to assess the alternatives that exist for producing transgenic plants.

Forest tree biotechnology

The forest products industry has traditionally viewed trees as merely a raw, and more or less immutable, natural resource. However, unlike such inanimate resources as metallic ores, trees have the potential to be modified genetically, essentially transmuting lead into gold. Increasingly, modern alchemists are applying the tools of biotechnology in efforts to reduce the biological constraints on forest productivity. Several new methodologies being used to address problems in forest biology are described with respect to their potential impact on forest tree improvement. In addition to addressing problems inherent to the current use of trees for production of pulp and paper or solid wood products, genetic manipulation of trees brings with it the potential to create new industries based on the novel characteristics of transgenic trees, e.g. trees containing transgenes to detoxify specific pollutants could be used in the remediation of sites contaminated with hazardous wastes. Efforts to modify trees through biotechnology are in their infancy, and this review seeks to outline the underpinnings of what will undoubtedly be an area of increased emphasis in the next millennium.

A novel principle for selection of transgenic plant cells: positive selection

A novel principle for selection of transgenic plant cells is presented. In contrast to traditional selection where the transgenic cells acquire the ability to survive on selective media while the non-transgenic cells are killed (negative selection), this selection method actively favours regeneration and growth of the transgenic cells while the non-transgenic cells are starved but not killed. Therefore, this selection strategy is termed 'positive selection'. TheE. coli β-glucuronidase gene was used as selectable (as well as screenable) gene and a glucuronide derivative of the cytokinin benzyladenine as selective agent which is inactive as cytokinin but, upon hydrolysis by GUS, active cytokinin is released stimulating the transformed cells to regenerate. Selection ofAgrobacterium tumefaciens inoculated of tobacco leaf discs on benzyladenine N-3-glucuronide (7.5-15 mg/l) resulted in 1.7-2.9 fold higher transformation frequencies compared to kanamycin selection. A significant advantage of this selection procedure is the elimination of the need for herbicide and antibiotic resistance genes.

New plant binary vectors with selectable markers located proximal to the left T-DNA border

Five new binary vectors have been constructed which have the following features: (1) different plant selectable markers including neomycin phosphotransferase (nptII), hygromycin phosphotransferase (hpt), dihydrofolate reductase (dhfr), phosphinothricin acetyl transferase (bar), and bleomycin resistance (ble); (2) selectable markers are located near the T-DNA left border and; (3) selectable marker and beta-glucuronidase (uidA) reporter genes are divergently organized for efficient expression, and can easily be removed or replaced as needed.

Bleomycin resistance as a selectable marker for transformation of the eukaryote, Dictyostelium discoideum

An expression cassette was constructed, which has the bacterial bleomycin (Bm) resistance-encoding gene (ble) fused to the Dictyostelium discoideum actin-6 promoter, with a segment of 3'-flanking DNA from the actin-8-encoding gene placed downstream from the ble gene to serve as a transcription terminator. Plasmid pMUW161, which contains this cassette and the D. discoideum plasmid Ddp2 origin of DNA replication, transformed D. discoideum with high efficiency under Bm selection. Hence, this construct is useful as a dominant selectable marker for D. discoideum.

Techniques in plant molecular biology--progress and problems

Progress in plant molecular biology has been dependent on efficient methods of introducing foreign DNA into plant cells. Gene transfer into plant cells can be achieved by either direct uptake of DNA or the natural process of gene transfer carried out by the soil bacterium Agrobacterium. Versatile gene-transfer vectors have been developed for use with Agrobacterium and more recently vectors based on the genomes of plant viruses have become available. Using this technology the expression of foreign DNA, the functional analysis of plant DNA sequences, the investigation of the mechanism of viral DNA replication and cell to cell spread, as well as the study of transposition, can be carried out. In addition, the versatility of the gene-transfer vectors is such that they may be used to isolate genes not amenable to isolation using conventional protocols. This review concentrates on these aspects of plant molecular biology and discusses the limitations of the experimental systems that are currently available.

Optimized vectors and selection for transformation of Neurospora crassa and Aspergillus nidulans to bleomycin and phleomycin resistance

To provide a dominant selectable marker for transformation of Neurospora crassa strains lacking specific auxotrophic mutations, we have engineered the bleomycin (Bm) resistance-encoding gene (ble) from the bacterial transposon Tn5 for expression in N. crassa. The coding region of the ble gene was fused to the promoter and terminator regions of the N. crassa am gene. In some vectors, multiple cloning sites were placed flanking the ble gene to provide a versatile ble cassette. When introduced into N. crassa, the hybrid ble gene conferred resistance to greater than 15 micrograms Bm/ml. Under optimal conditions, the levels of Bm required (2.5 micrograms/ml) make even large-scale transformation experiments very economical. Aspergillus nidulans could also be efficiently transformed to Bm resistance using the N. crassa ble gene fusion. Since the ble gene functions in both N. crassa and A. nidulans, the gene should be useful as a transformation marker for the many other filamentous fungi which are sensitive to Bm.

Agrobacterium-mediated plant transformation by novel mini-T vectors in conjunction with a high-copy vir region helper plasmid

A new binary vector system for Agrobacterium-mediated plant transformation was developed. A set of four mini-T vectors comprised of T-DNA border sequences from nopaline-type Ti-plasmid pTiC58 flanking a chimaeric hygromycin-resistance gene for selection of transformants and up to eight unique restriction sites for cloning foreign DNA was constructed on a broad-host replicon containing the oriV of plasmid pSa. In two of the constructs these multiple cloning sites are flanked by a strong promoter to activate transcription of inserted DNA in planta. High-efficiency transformation was prompted by a high-copy, stable virulence helper plasmid pUCD2614, which contains a cloned virulence region of pTiC58 and tandem copies of the par locus of plasmid pTAR. Southern blot hybridization and genetic analyses of the progeny of transformed plants showed that the hygromycin resistance gene was stably inherited.

Cloning of Saccharomyces cerevisiae promoters using a probe vector based on phleomycin resistance

Vectors that confer high levels of phleomycin (Ph) resistance to Saccharomyces cerevisiae have been constructed with the TEF1 and ENO1 promoters, the Tn5 ble gene and the CYC1 terminator. They are able to transform yeast cells grown on rich glucose medium containing a moderate level of Ph (10 micrograms/ml, corresponding to 100-fold the minimal inhibitory concentration). Frequencies of transformation are identical to those obtained with the URA3 marker on a defined medium. A promoter probe vector, based on the same ble marker, enabled us to isolate sequences from chromosomal yeast DNA that had promoter activities. These DNA fragments have been sequenced and those which promote the highest levels of Ph resistance have been found to be either A + T-rich or have a potentially new and more efficient translation start site.

Sulfonamide resistance gene for plant transformation

The sulfonamide resistance gene from plasmid R46 encodes for a mutated dihydropteroate synthase insensitive to inhibition by sulfonamides. Its coding sequence was fused to the pea ribulose bisphosphate carboxylase/oxygenase transit peptide sequence. Incubation of isolated chloroplasts with the fusion protein synthesised in vitro, showed that the bacterial enzyme was transported to the chloroplast stroma and processed into a mature form. Expression of the gene fusion in transgenic plants resulted in a high level of resistance to sulfonamides. Direct selection of transformed shoots on leaf explants was efficient using sulfonamides as sole selective agents. Transformed shoots rooted normally on sulfonamides at concentrations toxic for untransformed ones. Sulfonamide resistance was transmitted to the progeny of transformed plants as a single Mendelian dominant character. These results demonstrate that this chimeric gene can be used as an efficient and versatile selectable marker for plant transformation.

Aminoglycoside-3''-adenyltransferase confers resistance to spectinomycin and streptomycin in Nicotiana tabacum

The bacterial gene aadA encodes the enzyme aminoglycoside-3"-adenyltransferase that confers resistance to spectinomycin and streptomycin in Escherichia coli. Chimeric genes have been constructed for expression in plants, and were introduced into Nicotiana tabacum by Agrobacterium binary transformation vectors. Spectinomycin or streptomycin in selective concentrations prevent greening of N. tabacum calli. Transgenic clones, however, formed green calli on selective media containing spectinomycin, streptomycin, or both drugs. Resistance was inherited as a dominant Mendelian trait in the seed progeny. Resistance conferred by the chimeric aadA gene can be used as a color marker similar to the resistance conferred by the streptomycin phosphotransferase gene to streptomycin.

Phleomycin resistance as a dominant selectable marker for plant cell transformation

Tobacco cells are sensitive to bleomycin and phleomycin. The Tn5 and the Streptoalloteichus hindustanus (Sh) bleomycin resistance ('Ble') genes conferring resistance to these antibiotics have each been inserted into two plant expression vectors. They are flanked by the nopaline synthase (nos) or the cauliflower mosaic virus (CaMV) 35S promoters on one side, and by the nos polyadenylation signal on the other. These four chimaeric genes were introduced into the binary transformation vector pGA 492, which were thereafter mobilized into Agrobacterium tumefaciens strain LBA 4404. The resulting strains were used to transform Nicotiana tabacum cv. Xanthi nc using the leaf disc transformation procedure. In all cases, phleomycin- and bleomycin-resistant tobacco plants were regenerated from transformed cells under selective conditions; however, the highest frequency of rooted plants was obtained when transformation was carried out with the 'Sh Ble' gene under the control of the 35S promoter. Phleomycin resistance was stably transmitted to sexual offspring as a dominant nuclear trait as confirmed by Southern blotting.

Repair of bleomycin-induced DNA double-strand breaks in Vicia faba

As detected by neutral DNA elution, bleomycin induced at the concentrations tested (5, 10 and 50 micrograms/ml) DNA double-strand breaks (dsbs) in in vitro cultured embryos of V. faba. Most of these breaks were repaired during a 4-h incubation period after treatment. Dsbs also occurred after treatment with 2.5 and 5 mM of N-methyl-N-nitrosourea (MNU) but in contrast to those induced by bleomycin, these dsbs remained unrepaired during the 4-h incubation period following the treatment.

Phleomycin resistance as a dominant selectable marker in CHO cells

The Tn5 and the Streptoalloteichus hindustanus (Sh) ble genes conferring resistance to bleomycin-phleomycin antibiotics have been cloned into a mammalian vector under the RSV-LTR promoter. The resulting plasmids, pUT506 and pUT507 respectively, were used to transfect CHO cells by either the calcium phosphate or the recently described polybrene-DMSO method. Phleomycin- or bleomycin-resistant clones arose with a higher frequency after transfection with pUT507, and pUT507 transfectants were more resistant to both antibiotics than pUT506 transfectants. Phleomycin resistance in pUT507 transfectants was stable and associated with integration of plasmid sequences in genomic DNA. The Sh ble gene, which confers a dominant phleomycin-resistance phenotype, should provide a useful transferable selectable marker in CHO cells as well as in other animal cell lines.

Bleomycin resistance conferred by a drug-binding protein

The protein coded by a bleomycin-resistance gene (ble) cloned from producing actinomycetes was purified from a culture of a recombinant E. coli strain and its action on bleomycin was determined by in vitro assays. The protein binds reversibly in a one to one ratio to bleomycin which can no longer cleave DNA. The bleomycin resistance of cells harboring a ble gene could be accounted for by a sequestering effect of the bleomycin-binding protein.

The effect of cefotaxime on the growth and regeneration of callus from four varieties of barley (Hordeum vulgare L.)

Recently it has been reported that the cephalosporin antibiotic cefotaxime increases growth, regeneration and embryogenesis in wheat calli. We investigated the effect of cefotaxime on callus initiated from immature embryos of four barley (Hordeum vulgare L.) varieties. In calli cultured in the presence of antibiotic callus growth was up to 45% greater than in controls and the frequency of regenerating calli was increased by up to 80%. There was an apparent interaction of the antibiotic with genotype and the 2,4-D in the medium.