Site-specific excisional recombination strategies for elimination of undesirable transgenes from crop plants

A major limitation of crop biotechnology and breeding is the lack of efficient molecular technologies for precise engineering of target genomic loci. While transformation procedures have become routine for a growing number of plant species, the random introduction of complex transgenenic DNA into the plant genome by current methods generates unpredictable effects on both transgene and homologous native gene expression. The risk of transgene transfer into related plant species and consumers is another concern associated with the conventional transformation technologies. Various approaches to avoid or eliminate undesirable transgenes, most notably selectable marker genes used in plant transformation, have recently been developed. These approaches include cotransformation with two independent T-DNAs or plasmid DNAs followed by their subsequent segregation, transposon-mediated DNA elimination, and most recently, attempts to replace bacterial T-DNA borders and selectable marker genes with functional equivalents of plant origin. The use of site-specific recombination to remove undesired DNA from the plant genome and concomitantly, via excision-mediated DNA rearrangement, switch-activate by choice transgenes of agronomical, food or feed quality traits provides a versatile “transgene maintenance and control” strategy that can significantly contribute to the transfer of transgenic laboratory developments into farming practice. This review focuses on recent reports demonstrating the elimination of undesirable transgenes (essentially selectable marker and recombinase genes) from the plant genome and concomitant activation of a silent transgene (e.g., a reporter gene) mediated by different site-specific recombinases driven by constitutive or chemically, environmentally or developmentally regulated promoters. These reports indicate major progress in excision strategies which extends application of the technology from annual, sexually propagated plants towards perennial, woody and vegetatively propagated plants. Current trends and future prospects for optimization of excision-activation machinery and its practical implementation for the generation of transgenic plants and plant products free of undesired genes are discussed.     

Overexpression of HVA1 gene from barley generates tolerance to salinity and water stress in transgenic mulberry (Morus indica)

Late embryogenesis abundant (LEA) proteins are members of a large group of hydrophilic proteins found primarily in plants. The barley hva1 gene encodes a group 3 LEA protein and is induced by ABA and water deficit conditions. We report here the over expression of hva1 in mulberry under a constitutive promoter via Agrobacterium-mediated transformation. Molecular analysis of the transgenic plants revealed the stable integration and expression of the transgene in the transformants. Transgenic plants were subjected to simulated salinity and drought stress conditions to study the role of hva1 in conferring tolerance. The transgenic plants showed better cellular membrane stability (CMS), photosynthetic yield, less photo-oxidative damage and better water use efficiency as compared to the non-transgenic plants under both salinity and drought stress. Under salinity stress, transgenic plants show many fold increase in proline concentration than the non-transgenic plants and under water deficit conditions proline is accumulated only in the non-transgenic plants. Results also indicate that the production of HVA1 proteins helps in better performance of transgenic mulberry by protecting membrane stability of plasma membrane as well as chloroplastic membranes from injury under abiotic stress. Interestingly, it was observed that hva1 conferred different degrees of tolerance to the transgenic plants towards various stress conditions. Amongst the lines analysed for stress tolerance transgenic line ST8 was relatively more salt tolerant, ST30, ST31 more drought tolerant, and lines ST11 and ST6 responded well under both salinity and drought stress conditions as compared to the non-transgenic plants. Thus hva1 appears to confer a broad spectrum of tolerance under abiotic stress in mulberry.     

Forkhead-associated Domain-containing Protein Rv0019c and Polyketide-associated Protein PapA5, from Substrates of Serine/Threonine Protein Kinase PknB to Interacting Proteins of Mycobacterium tuberculosis

Mycobacterium tuberculosis profoundly exploits protein phosphorylation events carried out by serine/threonine protein kinases (STPKs) for its survival and pathogenicity. Forkhead-associated domains (FHA), the phosphorylation-responsive modules, have emerged as prominent players in STPK mediated signaling. In this study, we demonstrate the association of the previously uncharacterized FHA domain-containing protein Rv0019c with cognate STPK PknB. The consequent phosphorylation of Rv0019c is shown to be dependent on the conserved residues in the Rv0019c FHA domain and activation loop of PknB. Furthermore, by creating deletion mutants we identify Thr³⁶ as the primary phosphorylation site in Rv0019c. During purification of Rv0019c from Escherichia coli, the E. coli protein chloramphenicol acetyltransferase (CAT) specifically and reproducibly copurifies with Rv0019c in a FHA domain-dependent manner. On the basis of structural similarity of E. coli CAT with M. tuberculosis PapA5, a protein involved in phthiocerol dimycocerosate biosynthesis, PapA5 is identified as an interaction partner of Rv0019c. The interaction studies on PapA5, purified as an unphosphorylated protein from E. coli, with Rv0019c deletion mutants reveal that the residues N-terminal to the functional FHA domain of Rv0019c are critical for formation of the Rv0019c-PapA5 complex and thus constitute a previously unidentified phosphoindependent binding motif. Finally, PapA5 is shown to be phosphorylated on threonine residue(s) by PknB, whereas serine/threonine phosphatase Mstp completely reverses the phosphorylation. Thus, our data provides initial clues for a possible regulation of PapA5 and hence the phthiocerol dimycocerosate biosynthesis by PknB, either by direct phosphorylation of PapA5 or indirectly through Rv0019c.     

Eliminating expression of erucic acid-encoding loci allows the identification of “hidden” QTL contributing to oil quality fractions and oil content in <Emphasis Type="Italic">Brassica juncea</Emphasis> (Indian mustard)

Oil content and oil quality fractions (viz., oleic, linoleic and linolenic acid) are strongly influenced by the erucic acid pathway in oilseed Brassicas. Low levels of erucic acid in seed oil increases oleic acid content to nutritionally desirable levels, but also increases the linoleic and linolenic acid fractions and reduces oil content in Indian mustard (Brassica juncea). Analysis of phenotypic variability for oil quality fractions among a high-erucic Indian variety (Varuna), a low-erucic east-European variety (Heera) and a zero-erucic Indian variety (ZE-Varuna) developed by backcross breeding in this study indicated that lower levels of linoleic and linolenic acid in Varuna are due to substrate limitation caused by an active erucic acid pathway and not due to weaker alleles or enzyme limitation. To identify compensatory loci that could be used to increase oil content and maintain desirable levels of oil quality fractions under zero-erucic conditions, we performed Quantitative Trait Loci (QTL) mapping for the above traits on two independent F1 doubled haploid (F1DH) mapping populations developed from a cross between Varuna and Heera. One of the populations comprised plants segregating for erucic acid content (SE) and was used earlier for construction of a linkage map and QTL mapping of several yield-influencing traits in B. juncea. The second population consisted of zero-erucic acid individuals (ZE) for which, an Amplified Fragment Length Polymorphism (AFLP)-based framework linkage map was constructed in the present study. By QTL mapping for oil quality fractions and oil content in the ZE population, we detected novel loci contributing to the above traits. These loci did not co-localize with mapped locations of the fatty acid desaturase 2 (FAD2), fatty acid desaturase 3 (FAD3) or fatty acid elongase (FAE) genes unlike those of the SE population wherein major QTL were found to coincide with mapped locations of the FAE genes. Some of the new loci identified in the ZE population could be detected as ‘weak’ contributors (with LOD < 2.5) in the SE population in which their contribution to the traits was “masked” due to pleiotropic effects of erucic acid genes. The novel loci identified in this study could now be used to improve oil quality parameters and oil content in B. juncea under zero-erucic conditions.     

Heat-inducible Cre-<Emphasis Type="Italic">lox</Emphasis> system for marker excision in transgenic rice

The present study assessed the efficacy of a heat-inducible cre gene for conditional removal of the marker gene from a rice genome via Cre-lox recombination. A cre gene controlled by the soybean heat-shock promoter was introduced into the rice genome along with the recombination target (lox) construct. Cre-mediated recombination was expected to remove the marker gene and activate the promoter-less GUS gene. Six transgenic lines displayed well-regulated heat-inducible Cre activity in the callus. However, only one line that contained a single copy of the cre gene maintained this property in the regenerated plants and their progeny. Marker-free progeny were obtained from the plant that was heat-treated at the seedling stage, indicating the inheritance of the recombination ‘footprint’. The presence of the ‘footprint’ was verified by polymerase chain reaction and Southern analysis. Therefore, the cre gene controlled by the soybean heat-shock promoter is an effective tool for conditional removal of the marker gene in rice.     

The evidence for functional non-CpG methylation in mammalian cells

In mammalian genomes, the methylation of cytosine residues within CpG dinucleotides is crucial to normal development and cell differentiation. However, methylation of cytosines in the contexts of CpA, CpT, and CpC (non-CpG methylation) has been reported for decades, yet remains poorly understood. In recent years, whole genome bisulphite sequencing (WGBS) has confirmed significant levels of non-CpG methylation in specific tissues and cell types. Non-CpG methylation has several properties that distinguish it from CpG methylation. Here we review the literature describing non-CpG methylation in mammalian cells, describe the important characteristics that distinguish it from CpG methylation, and discuss its functional importance.     

Lymphocyte Activation Gene-3 (LAG-3) Negatively Regulates Environmentally-Induced Autoimmunity

Environmental factors including drugs, mineral oils and heavy metals such as lead, gold and mercury are triggers of autoimmune diseases in animal models or even in occupationally exposed humans. After exposure to subtoxic levels of mercury (Hg), genetically susceptible strains of mice develop an autoimmune disease characterized by the production of highly specific anti-nucleolar autoantibodies, hyperglobulinemia and nephritis. However, mice can be tolerized to the disease by a single low dose administration of Hg. Lymphocyte Activation Gene-3 (LAG-3) is a CD4-related, MHC-class II binding molecule expressed on activated T cells and NK cells which maintains lymphocyte homeostatic balance via various inhibitory mechanisms. In our model, administration of anti-LAG-3 monoclonal antibody broke tolerance to Hg resulting in autoantibody production and an increase in serum IgE level. In addition, LAG-3-deficient B6.SJL mice not only had increased susceptibility to Hg-induced autoimmunity but were also unresponsive to tolerance induction. Conversely, adoptive transfer of wild-type CD4⁺ T cells was able to partially rescue LAG-3-deficient mice from the autoimmune disease. Further, in LAG-3-deficient mice, mercury elicited higher amounts of IL-6, IL-4 and IFN-γ, cytokines known to play a critical role in mercury-induced autoimmunity. Therefore, we conclude that LAG-3 exerts an important regulatory effect on autoimmunity elicited by a common environmental pollutant.     

A protocol for in vitro mass propagation of asiatic hybrids of lily through liquid stationary culture

Summary A simple, rapid and cost-effective in vitro scheme has been proposed for mass propagating two cultivars of Asiatic lily hybrids. An average of seven bulblets was formed after 17 d when 1×1 cm² bulb scale segments (explants) were cultured on Murashige and Skoog (MS) medium with 3% sucrose and 0.5 μM α-naphthaleneacetic acid (NAA). On MS medium containing 0.5 μM NAA and 6 or 9% sucrose, depending on the cultivar, large numbers of bulblets of increased size (3.5–5.0 cm in circumference) were formed under a 16/8 h photoperiod. A continuous system of mass propagation of bulblets was achieved through in vitro scale formation (secondary explants) on MS medium supplemented with 23 μM kinetin and 0.5 μM NAA, as well as scale proliferation on MS basal liquid stationary medium. Upon transplantation all bulblets sprouted, of which 40% flowered in the first season. Under ideal conditions, ca. 9.68×10⁵ bulblets can be produced from a single scale segment in 1 yr by following the systematic propagation steps proposed here.     

A novel Phytochrome B allele in <Emphasis Type="Italic">Arabidopsis thaliana</Emphasis> exhibits partial mutant phenotype: a short deletion in N-terminal extension reduces Phytochrome B activity

During analysis of an Arabidopsis thaliana line possessing a Phytochrome A epiallele (phyA’), a partial Phytochrome B-deficient phenotype was observed, consisting of elongated hypocotyls in seedlings grown under constant white light or red light (660 nm). The observed hypocotyls were twice the length (8 mm) of wild-type (4 mm), but approximately half the length of a null phyB-9 mutant (14 mm). Several analyses were performed to characterize this apparent partial phyB mutant. Sequencing of the entire exonic region revealed three point mutations that altered codon usage, and one in-frame 12 base pair deletion. Each of the point mutations has been described in other lines that display wild-type phenotype, and therefore their effect is thought to be minimal, if any. The N-terminal deletion of amino acids 9 through 12 (GGGR) is a unique mutation found in this line. This deletion most likely contributes to the phyB mutant phenotype by lowering the binding affinity of the active form of Phytochrome B (Pfr) with Phytochrome Interacting Factor 3 (PIF3).