Stable Plastid Transformation in Nicotiana benthamiana

Davarpanah, Seyed Javad; Jung, Seo Hee; Kim, Yaw Joo; Park, Youn‐Il; Min, Sung Ran; Liu, Jang Ryol; Jeong, Won Joong

doi:10.1007/s12374-009-9023-0

Cited by 33 publications

(19 citation statements)

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“…First, successful chloroplast transformation was reported in Chlamydomonas [12]. Then chloroplast transformation has been extended to an increasing number of dicotyledonous plants, including important plant bioreactor for pharmaceutical proteins: tobacco [7,[13][14][15]; the model plant species: Arabidopsis thaliana [16], petunia [17], and poplar tree [18]; species important in industrial economy: oilseed rape [19], Lesquerella fendleri [20], cotton [21], and sugar beet [22]; and edible crops: potato [23], tomato [24], carrot [25], soybean [26], lettuce [27,28], cauliflower [29], and cabbage [30]. Some preliminary studies have been made in chloroplast transformation of monocotyledonous species.…”

Section: Introductionmentioning

confidence: 99%

Stable chloroplast transformation of immature scutella and inflorescences in wheat (<italic>Triticum aestivum</italic> L.)

Cui¹,

Song²,

Tan³

et al. 2011

ABBS

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Chloroplast transformation in wheat was achieved by bombardment of scutella from immature embryos and immature inflorescences, respectively. A wheat chloroplast sitespecific expression vector, pBAGNRK, was constructed by placing an expression cassette containing neomycin phosphotransferase II (nptII) and green fluorescent protein (gfp) as selection and reporter genes, respectively, in the intergenic spacer between atpB and rbcL of wheat chloroplast genome. Integration of gfp gene in the plastome was identified by polymerase chain reaction (PCR) analysis and Southern blotting using gfp gene as a probe. Expression of GFP protein was examined by western blot. Three positive transformants were obtained and the Southern blot of partial fragment of atpB and rbcL (targeting site) probes verified that one of them was homoplasmic. Stable expression of GFP fluorescence was confirmed by confocal microscopy in the leaf tissues from T 1 progeny seedlings. PCR analysis of gfp gene also confirmed the inheritance of transgene in the T 1 progeny. These results strengthen the feasibility of wheat chloroplast transformation and also give a novel method for the introduction of important agronomic traits in wheat through chloroplast transformation.

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Section: Introductionmentioning

confidence: 99%

Stable chloroplast transformation of immature scutella and inflorescences in wheat (<italic>Triticum aestivum</italic> L.)

Cui¹,

Song²,

Tan³

et al. 2011

ABBS

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“…However, based on GFP protein accumulation in leaves, tubers and petals, it is clear that the relative performance of rrn and clpP regulatory sequences, and their potential applicability in plastid transformation approaches, vary with plastid types. In recent experiments in transplastomic N. benthamiana plants expressing the gfp gene under the control of the rrn promoter, decreasing transcript and protein expression levels were observed in leaves, petals and roots (Davarpanah et al 2009). The clpP 5 0 -UTR was previously used in combination with the rrn promoter to express the NPTII protein in tobacco leaves, but a mutant (chlorotic) phenotype was observed, even at low accumulation levels (Kuroda and Maliga 2002).…”

Section: Discussionmentioning

confidence: 96%

“…In contrast, no apparent reductions in transformation frequencies were observed in tobacco and tomato using homologous or homeologous N. tabacum and S. nigrum ptDNA sequences in transformation vectors (Kavanagh et al 1999;Horváth et al 2000;Nugent et al 2005;Nugent et al 2006), or in transformations of N. benthamiana plastids with tobacco-derived vectors (Davarpanah et al 2009), indicating that species-specific vectors are not always necessary. In the tobacco and tomato studies, it was demonstrated that integration of the cloned homeologous ptDNA sequences in the host plastome occurred by multiple recombination events in a similar region of the inverted repeats (IRs), that in comparison with ''Single Copy'' regions of the plastid genome, generally show a higher gene order conservation and a lower sequence divergence (Maier et al 1995).…”

Section: Discussionmentioning

confidence: 99%

“…The relative expression level of transgenes in tomato fruit chromoplasts, however, was higher with other proteins (Ruf et al 2001) and in any case sufficient to induce significant metabolic changes (Wurbs et al 2007;Apel and Bock 2009). Very low levels of mRNA and GFP protein were detected in roots of transplastomic Nicotiana benthamiana plants (less than 2% of that in the leaves), albeit expression levels up to 40-75% of those in leaf chloroplasts could be achieved in petal leucoplasts of the same plants or in chromoplasts of carrot taproots (Kumar et al 2004a;Davarpanah et al 2009). …”

Section: Introductionmentioning

confidence: 95%

“…A similar approach was adopted by Wurbs et al (2007), who used the atpI promoter containing both PEP and NEP signals, and the rps16 3 0 -UTR, to express carotenoidrelated genes in tomato fruits. Nevertheless, the short rrn promoter, containing only the sequences for PEP recognition, was successfully used to express transgenes in fruit chromoplasts of transplastomic tomato, and in petal leucoplasts and root amyloplasts of tobacco and Nicotiana benthamiana (Khan and Maliga 1999;Ruf et al 2001;Apel and Bock 2009;Davarpanah et al 2009).…”

Section: Introductionmentioning

confidence: 99%

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High efficiency plastid transformation in potato and regulation of transgene expression in leaves and tubers by alternative 5′ and 3′ regulatory sequences

Valkov¹,

Gargano

Manna³

et al. 2010

Transgenic Res

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Transformation of potato plastids is limited by low transformation frequencies and low transgene expression in tubers. In order to improve the transformation efficiency, we modified the regeneration procedure and prepared novel vectors containing potato flanking sequences for transgene integration by homologous recombination in the Large Single Copy region of the plastome. Vector delivery was performed by the biolistic approach. By using the improved regeneration procedure and the potato flanking sequences, we regenerated about one shoot every bombardment. This efficiency corresponds to 15-18-fold improvement compared to previous results with potato and is comparable to that usually achieved with tobacco. Further, we tested five promoters and terminators, and four 5 0 -UTRs, to increase the expression of the gfp transgene in tubers. In leaves, accumulation of GFP to about 4% of total soluble protein (TSP) was obtained with the strong promoter of the rrn operon, a synthetic rbcL-derived 5 0 -UTR and the bacterial rrnB terminator. GFP protein was detected in tubers of plants transformed with only four constructs out of eleven. Best results (up to approximately 0.02% TSP) were achieved with the rrn promoter and rbcL 5 0 -UTR construct, described above, and another containing the same terminator, but with the promoter and 5 0 -UTR from the plastid clpP gene. The results obtained suggest the potential use of clpP as source of novel regulatory sequences in constructs aiming to express transgenes in amyloplasts and other non-green plastids. Furthermore, they represent a significant advancement of the plastid transformation technology in potato, of relevance to its implementation in potato breeding and biotechnology.

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Transformation of the Plastid Genome in Tobacco: The Model System for Chloroplast Genome Engineering

Maliga

Tungsuchat-Huang

Lutz

2021

Methods in Molecular Biology

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Stable Plastid Transformation in Nicotiana benthamiana

Cited by 33 publications

References 18 publications

Stable chloroplast transformation of immature scutella and inflorescences in wheat (<italic>Triticum aestivum</italic> L.)

Stable chloroplast transformation of immature scutella and inflorescences in wheat (<italic>Triticum aestivum</italic> L.)

High efficiency plastid transformation in potato and regulation of transgene expression in leaves and tubers by alternative 5′ and 3′ regulatory sequences

Transformation of the Plastid Genome in Tobacco: The Model System for Chloroplast Genome Engineering

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Stable Plastid Transformation in Nicotiana benthamiana

Cited by 33 publications

References 18 publications

Stable chloroplast transformation of immature scutella and inflorescences in wheat (&lt;italic&gt;Triticum aestivum&lt;/italic&gt; L.)

Stable chloroplast transformation of immature scutella and inflorescences in wheat (&lt;italic&gt;Triticum aestivum&lt;/italic&gt; L.)

High efficiency plastid transformation in potato and regulation of transgene expression in leaves and tubers by alternative 5′ and 3′ regulatory sequences

Transformation of the Plastid Genome in Tobacco: The Model System for Chloroplast Genome Engineering

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Product

Resources

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Stable chloroplast transformation of immature scutella and inflorescences in wheat (<italic>Triticum aestivum</italic> L.)

Stable chloroplast transformation of immature scutella and inflorescences in wheat (<italic>Triticum aestivum</italic> L.)