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Chloroplast Biotechnology in Higher Plants: Expressing Antimicrobial Genes in the Plastid GenomeRuhlman, Tracey 10 August 2005 (has links)
While genetic improvement of susceptible crop species may enhance resistance to microbial pathogens and facilitate reduced pesticide load, the possibility for transmission of novel genes to wild relatives has hampered acceptance of GM crops in some markets. Chloroplast transformation presents an attractive alternative to nuclear transformation and offers the potential to ameliorate these environmental concerns. Most agronomically important species exhibit maternal inheritance of organellar genomes which eliminates the threat of transgene escape through pollen. Gene silencing is absent due to site directed, single copy insertion by homologous recombination. Foreign proteins can accumulate to high levels (up to 50% of total soluble protein) and are retained within the chloroplast envelope protecting them from degradation by host cytoplasmic proteases. A bacterial chloroperoxidase gene (cpo-p) was transformed into the tobacco chloroplast genome to test its efficacy against plant pathogens and the mycotoxin producing saprophyte Aspergillus flavus.
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Evaluation Of Immunogenicity Of Transgenic Chloroplast Derived ProtectKoya, Vijay 01 January 2004 (has links)
Anthrax, a fatal bacterial infection is caused by Bacillus anthracis, a gram-positive, spore forming, capsulated, rod shaped organism. Centers for Disease Control (CDC) lists anthrax as Category A biological agent due to its severity of impact on human health, high mortality rate, acuteness of the disease and potential for delivery as a biological weapon. The currently available human vaccine in the United States (AVA anthrax vaccine adsorbed) is prepared from Alum adsorbed formalin treated supernatant culture of toxigenic, non-encapsulated strain of Bacillus anthracis with the principle component being protective antigen (PA83). Evaluation of anthrax vaccine given to nearly 400,000 US military personnel by Vaccine Adverse Event Reporting System (VAERS) showed adverse effects such as flu-like symptoms, local pain, large degree of inflammation, edema, malaise, rash, arthralgia, and headache following vaccination. All the adverse reactions are attributed to the composition of vaccine components. These vaccine preparations contain trace contaminants of lethal and edema factors that contribute to the adverse side effects. Also, the current method of vaccine manufacture has limited production capacity.The production of PA83, in plants through chloroplast genetic engineering might eliminate the concerns of adverse side effects and the levels of expression would ensure the availability of vaccine for the human population in an environmentally friendly approach. The primary concern is whether the PA83 purified from transgenic chloroplasts is as immunogenic as the PA83 in the AVA. For this, PA83 has been expressed in transgenic chloroplasts of Nicotiana tabacum var. petit Havana, by inserting the pag (2205 bp) with the N-terminal 6X histidine tag, into the chloroplast genome by homologous recombination. Chloroplast integration of the pag was confirmed by PCR and Southern analysis. The PA83 protein was detected in transgenic chloroplasts by immunoblot analysis using anti-PA83 antibodies. Maximum expression levels of PA83 (14.17% TSP) were observed in mature leaves upon continuous illumination, due to the presence psbA 5'UTR, a light and developmentally regulated translation enhancer sequence. The PA83 has been purified by affinity chromatography using Ni resin columns. Chloroplast derived PA83 was functional in vitro and was able to lyse the mouse macrophages when combined with the lethal factor. The in vitro assays showed that the crude extracts contained up to 20ug/ml of functional PA83.The immunization studies of PA83 on Balb/c mice, revealed highly immunogenic IgG titers. Subcutaneous immunization with purified chloroplast derived PA83 with adjuvant yielded IgG titers up to 1:320,000, similar to that of the group immunized with PA83 derived from Bacillus anthracis. Immunization of groups with PA83 combined with alhydrogel adjuvant showed four - eight times higher immune response than the groups without adjuvant. The higher expression levels of PA83 in transgenic chloroplasts might ensure the availability of anthrax vaccine to the general public and the high immune response observed in the mouse model would enable the replacement of the current AVA with a cleaner and safer vaccine.
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Genetic engineering tools for transforming the nucleus and chloroplast of microalgaeHerrera Rodriguez, Leopoldo January 2017 (has links)
Biotechnology of microalgae is a fast-growing field and several species have become targets for transgenic manipulation. Microalgae provide low-cost and scalable production platforms for manufacturing recombinant proteins and other high value products. However, the exploitation of microalgae as expression systems is restricted by the low yield of recombinant proteins and the limited availability of tools for the genetic manipulation of commercially important species. This thesis explores transgene instability and gene autoregulation as causes for low recombinant protein accumulation in the chloroplast of Chlamydomonas reinhardtii and describes the isolation of a mutant phytoene desaturase (PDS) gene which confers resistance to the herbicide norflurazon for future use as a selection marker for the marine microalga Dunaliella tertiolecta. Recombination between short dispersed DNA repeats (SDR) found in the chloroplast genome of C. reinhardtii was identified as a cause of transgene instability. The genes coding for β-glucuronidase (GUS) and peridinin-chlorophyll binding protein (PCP) were inserted in the chloroplast genome next to the atpB 3' UTR by homologous recombination. Recombination of a 30bp SDR located within the 3' UTR of atpB was identified as the cause of transgene excision in the transplastomic lines. Such transgene instability was tackled by replacing the 3' UTR of atpB with the rbcL 3' UTR from D. tertiolecta. Using this 3'UTR sequence from a different species produced a photosynthetic strain and prevented excision of the transgene by SDR recombination in all transfomants. Very low levels of recombinant GUS and PCP accumulated in chloroplast transformants when using the psbD 5' regulatory region to drive their expression. To address low levels of accumulation caused by regulatory pathways that inhibit transgene expression, I have engineered the chloroplast genome of a non-photosynthetic atpB mutant of C. reinhardtii by replacing the endogenous psbD promoter and 5'UTR with the promoter and 5'UTR of psbA. The engineered strain was subsequently transformed with the wildtype atpB and two different reporter genes driven by the psbD regulatory regions: gusA and kat, which code for GUS and the fluorescent protein Katushka respectively. Analysis of the transformants showed that accumulation of recombinant proteins in our engineered strain was 10 to 20 fold higher than in the nonengineered cells. Most of the selectable markers used in plants and algae are inefficient in Dunaliella, which is naturally resistant to many of the antibiotics used for the selection of transformants. Norflurazon inhibits PDS, an essential enzyme for carotenoid biosynthesis. Using forward genetics I have isolated, sequenced and characterised mutant PDS alleles conferring norflurazon resistance in D. tertiolecta. Independent mutations in pds, leading to substitutions R265C, S472L, S472F and L502F, all result in high resistance to norflurazon but differ in sensitivity to other bleaching herbicides. By mapping the four amino acid substitutions on 3D models of D. tertiolecta PDS I determined that R265C, S472L, S472F and L502F, cluster together in proximity to a Rossman-like domain and to aminoacids F128 and V469, previously reported to confer norflurazon resistance. This suggests that the mode of action of norflurazon is by competition with flavin adenine dinucleotide (FAD) for its binding site. A unique aspect of the R265C substitution is its negative cross-resistance to diflufenican and beflutamid which could be advantageous for its use as a positive/negative selection marker for transformation.
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Chloroplasts as bioreactors : high-yield production of active bacteriolytic protein antibioticsOey, Melanie January 2008 (has links)
Plants, more precisely their chloroplasts with their bacterial-like expression machinery inherited from their cyanobacterial ancestors, can potentially offer a cheap expression system for proteinaceous pharmaceuticals. This system would be easily scalable and provides appropriate safety due to chloroplasts maternal inheritance. In this work, it was shown that three phage lytic enzymes (Pal, Cpl-1 and PlyGBS) could be successfully expressed at very high levels and with high stability in tobacco chloroplasts. PlyGBS expression reached an amount of foreign protein accumulation (> 70% TSP) that has never been obtained before. Although the high expression levels of PlyGBS caused a pale green phenotype with retarded growth, presumably due to exhaustion of plastid protein synthesis capacity, development and seed production were not impaired under greenhouse conditions.
Since Pal and Cpl-1 showed toxic effects when expressed in E. coli, a special plastid transformation vector (pTox) was constructed to allow DNA amplification in bacteria. The construction of the pTox transformation vector allowing a recombinase-mediated deletion of an E. coli transcription block in the chloroplast, leading to an increase of foreign protein accumulation to up to 40% of TSP for Pal and 20% of TSP for Cpl-1. High dose-dependent bactericidal efficiency was shown for all three plant-derived lytic enzymes using their pathogenic target bacteria S. pyogenes and S. pneumoniae. Confirmation of specificity was obtained for the endotoxic proteins Pal and Cpl-1 by application to E. coli cultures. These results establish tobacco chloroplasts as a new cost-efficient and convenient production platform for phage lytic enzymes and address the greatest obstacle for clinical application. The present study is the first report of lysin production in a non-bacterial system. The properties of chloroplast-produced lysins described in this work, their stability, high accumulation rate and biological activity make them highly attractive candidates for future antibiotics. / Lytische Enzyme aus Bakteriophagen bieten Eigenschaften, die sie zu vielversprechenden Medikamenten im Einsatz gegen bakterielle Krankheiten machen. Obwohl sie speziell beim Einsatz gegen bakterielle Infektionen, welche durch Antibiotika resistente Erreger hervorgerufen werden, eine maßgebende Rolle spielen könnten, waren bisher die hohen Produktionskosten ein Hindernis für die medizinische Anwendung. Ein kostengünstiges und einfach zu handhabendes System, wie beispielsweise Chloroplasten in Pflanzen, würde diese lytischen Enzyme zu einer effizienten Alternative zu herkömmlichen Antibiotika machen.
In dieser Arbeit wird erstmals die erfolgreiche Produktion von lytischen Enzymen in Tabak-Chloroplasten vorgestellt, welche mit einem Fremdproteingehalt von mehr als 70% des gesamtlöslichen Proteins der Pflanze eine Menge beschreibt, die bisher mit diesem Verfahren noch nicht erreicht wurde.
Alle in Chloroplasten hergestellten lytischen Enzyme zeigten hohe spezifische bakteriolytische Aktivität gegen die gewählten Humanpathogene und waren innerhalb von Minuten in der Lage diese Bakterien abzutöten.
Zur Herstellung von zwei lytischen Enzymen wurde in dieser Arbeit ein spezieller Shuttle-Vektor entworfen, der die Expression von toxischen Genen innerhalb von E. coli Zellen im Zuge der DNA Replikation vermeidet, jedoch die Herstellung einer ungehinderten Expression der toxischen Gene in den Chloroplasten nach Beseitigung des Selektionsmarkers erlaubte.
Ein Vergleich zwischen einem herkömmlich verwendeten Transformationsvektor und dem Shuttle-Vektor mittels eines Reportergens zeigte, dass das neu entwickelte System bis zu 4 mal mehr Protein produzierte.
Diese Ergebnisse zeigen das Potential von Chloroplasten als kostengünstige und leicht zu handhabende Produktionsplattform für lytische Enzyme, welche als neue Generation von Antibiotika attraktive Alternativen zu herkömmlichen Therapien bieten.
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Expression Of Cholera Toxin B Subunit-rotavirus Nsp4 Enterotoxin Fusion Protein In Transgenic ChloroplastsKalluri, Anila 01 January 2005 (has links)
Rotavirus, the major cause of life-threatening infantile gastroenteritis, is a member of the Reoviridae family and is considered to be the single most important cause of virus-based severe diarrheal illness in infants and young children particularly 6 months to 2 years of age in industrialized and developing countries. Infection in infants and young children is often accompanied by severe life threatening diarrhea, most commonly following primary infection. Diarrhea is the major cause of death among children around the world. Responsible for 4 to 6 million deaths per year according to the World Health Organization (WHO), diarrhea is especially dangerous for infants and young children. Globally, it is estimated that 1.4 billion episodes of diarrhea occur in children less than five years of age annually. In the United States alone, rotavirus causes more than 3 million cases of childhood diarrhea each year, leading to an estimated 55,000 to 100,000 hospitalizations and 20 to 100 deaths. And is a major cause of mortality for children in developing countries with approximately one million deaths annually. Rotaviruses belong to the family Reoviridae and are spherical 70-nm particles. The virus genome contains 11 segments of double-stranded RNA, each encoding a viral capsid or nonstructural protein. The identification of a rotavirus nonstructural protein gene (NSP4) encoding a peptide, which functions both as a viral enterotoxin and as a factor involved in the acquisition of host cell membrane during virus budding from cells, provides a new approach for mucosal immunization. Protein expression through chloroplast transformation system offers a number of advantages like high level of transgene expression, transgene containment via maternal inheritance, lack of gene silencing and position effect due to site specific gene integration and also the possibility of multi gene engineering in single transformation event. It is also an environmentally friendly approach due to effective gene containment and lack of transgene expression in pollen. To achieve an enhanced immune response to rotavirus infection, a fusion gene encoding the cholera toxin B subunit linked to rotavirus enterotoxin 90 aa protein (CTB-NSP490) was introduced into transgenic chloroplast and was transformed into chloroplast genome of Nicotiana tabacum by homologous recombination. The chloroplast integration of CTB-NSP4(90) fusion gene was confirmed in transgenic tobacco plants by PCR analysis. Southern blot analysis further confirmed site specific gene integration and homoplasmy. Immunoblot analysis of transformed chloroplast confirmed the expression of CTBNSP490 fusion protein both in monomeric and pentameric forms that retained the binding affinity to the enterocytes GM1 ganglioside receptor. Expression levels of CTB-NSP4 protein was quantified by GM1 ganglioside binding ELISA assay; mature leaves expressed CTB-NSP4 fusion protein to upto 2.45 % in total soluble protein, 100-400 fold higher than nuclear expression which was only 0.006%-0.026%. Antibody titration and virus challenge experiments will be performed in mice at Loma Linda University to evaluate the antigenic and protective properties of the chloroplast derived CTB-NSP4 fusion protein.
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Determinants Of Chloroplast Gene Expression And Applications Of Chloroplast Transformation In Lactuca Sativa And Nicotiana TabacumRuhlman, Tracey 01 January 2009 (has links)
Genetic modification of plastids in the model plant tobacco (Nicotiana tabacum) has demonstrated that numerous foreign gene products can accumulate to high levels in this setting. Plastid biotechnology is maturing to encompass the improvement of food and feed species and the production of biopharmaceutical proteins for oral delivery necessitating development of stable transplastomic edible plants. In the interest of establishing an edible platform we have investigated the use of native and foreign regulatory elements in relation to foreign gene expression in plastids. Multiple sequence alignments of intergenic regions for 20 species of angiosperm showed that despite 95% identity in the coding region, identity in the psbA upstream region is 59% across all taxa examined, other gene coding regions displayed sequence identity of 80-97%, whereas the non-coding regions were 45-79% suggesting that our physical data can be extrapolated beyond the model presented. We found that by exchanging psbA untranslated regions (UTRs) between N. tabacum and lettuce (Lactuca sativa), the expression of the CTB-proinsulin (CTB-Pins) monocistronic transcript declined by 84% and foreign protein accumulation was reduced by as much as 97% in mature leaves. Polyribosome association assays suggest that ribosome-free transgenic transcripts are stabilized where the native UTR is employed. RNA EMSA revealed that binding proteins interacted with psbA 5' UTRs in a species specific manner and the half life of the L. sativa 5'UTR-CTB-Pins mRNA was reduced by 3.7 fold in N. tabacum stromal extracts. Our data indicate that the use of species-specific regulatory elements could lead to establishment of reproducible plastid transformation in desirable target species such as L. sativa. Using transplastomic L. sativa for oral delivery of bioencapsulated CTB-Pins we delayed the onset of diabetes in NOD mice when retinyl acetate supplement was provided compared to untouched mice. In this 30 week study we monitored blood glucose levels and evaluated the in vitro suppressive capacity of regulatory T cells isolated from diabetic mice. Whether delay or prevention was achieved appeared to be a function of antigen dose as high dose resulted in a nine week delay of onset while low dose reduced the incidence of diabetes by 36%. In addition we have evaluated metabolic engineering in the N. tabacum model where we generated cis-genic lines expressing nucleus-encoded methionine pathway enzymes in plastids. Transplastomic expression of Cystathionine gamma-Synthase led to a three-fold increase in enzyme activity and a doubling of methionine content in leaves without a deleterious phenotype. In exploring molecular mechanisms supporting gene expression in plastids and applying transplastomic technology to real human problems this work seeks address the potential of plastid biotechnology for improvement of commodity crops and production of biopharmaceuticals.
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Análise de homoplasmia de plantas transplastômicas de fumo via PCR em tempo real / Homoplasmy analysis of tobacco transplastomic plants via real-time PCRTanaka, Simone Missae 10 January 2012 (has links)
A transformação plastidial oferece uma série de vantagens em relação à transformação nuclear, como: altos níveis de expressão de proteínas, capacidade de expressar múltiplos transgenes em operons e contenção gênica pela ausência de transmissão pelo pólen. Devido ao alto número de cópias do genoma plastidial por cloroplasto e ao alto número de cloroplastos por células vegetais, são necessários ciclos de regeneração sob condições seletivas para obter transformantes homoplásmicos. A análise de homoplasmia é realizada pela metodologia de Southern blot ou pelo teste de herança do transgene pela germinação de sementes em meio seletivo. O Southern blot é trabalhoso, demorado e para maior sensibilidade envolve o uso de radioisótopos, enquanto o teste de germinação é realizado somente após a produção de sementes necessitando de um ciclo de reprodução da planta. Assim, o objetivo deste trabalho foi desenvolver um método rápido, sensível e eficaz para determinar o grau de homoplasmia de plantas transplastômicas, baseado na técnica de PCR em tempo real. Folhas de fumo foram transformadas com vetores compostos pelos genes 9 dessaturase (pMR1), 15 dessaturase (pMR3), -3 elongase (pMR5) e 12/3 dessaturase (pMR10), todos contendo o gene de seleção aadA. No total, 44 plantas foram obtidas, sendo 21 plantas positivas para a inserção do transgene. O grau de homoplasmia foi determinado pela proporção entre o número de cópias do transgene e o número de cópias do gene endógeno. Inicialmente, misturas de DNA de plantas transplastômicas homoplásmicas (pMR1 e pMR3) com DNA de planta tipo selvagem foram preparadas para simular diferentes graus de homoplasmia. DNA da planta transplastômica ou do plasmídeo foi diluído em série para construção das curvaspadrão, com a quantidade dos genes sendo estimada por meio da plotagem nessas curvas. Os índices de homoplasmia detectados na PCR em tempo real foram compatíveis com os resultados do teste de germinação com valores abaixo de 1 para plantas heteroplásmicas, 1 para a planta homoplásmica e 0 para as plantas sem a inserção do transgene. Os resultados das análises de amostras coletadas após o primeiro ciclo de regeneração mostraram que 13 das 21 plantas já se apresentavam em estado homoplásmico não sendo necessários mais ciclos de regeneração. A PCR em tempo real mostrou ser um método eficiente para análise do grau de homoplasmia de plantas transplastômicas. / Plastid transformation offers several advantages in relation to nuclear transformation, such as high-level of protein expression, the feasibility of expressing multiple transgenes in operons and gene containment through the lack of pollen transmission. Due to the high copy number of plastidial genome in chloroplasts and the high number of chloroplasts per plant cells, regeneration cycles under selective conditions are necessary to obtain homoplasmic transformants. Homoplasmy analysis is performed by Southern blot methodology or transgene inheritance test through seed germination in selective medium. Southern blot is laborious, time consuming and for more sensitivity it would require the use of radioisotopes, while germination test can be performed only after seed production which require a plant reproduction cycle. The objective of this study was to develop a fast, sensitive and effective method to determine the homoplasmy degree of transplastomic plants, based on real-time PCR. Tobacco leaves were transformed with vectors containing the 9 desaturase (pMR1), 15 desaturase (pMR3), -3 elongase (pMR5) and 12/3 desaturase (pMR10) each one with the aadA selection gene. In total, 44 plants were obtained, of which 21 were positive for the insertion of the transgene. The homoplasmy degree was determined by the proportion between the number of transgene copies and the number of endogenous gene copies. Initially, mixtures of homoplastomic plants DNA (pMR1 and pMR3) with wild-type plant DNA were prepared to simulate different degrees of homoplasmy. Transplastomic plant DNA or plasmid DNA was diluted to construct the standard curves and the gene amount was detected by plotting in this curves. The homoplasmy rate detected in real-time PCR were consistent with the results of germination test with values below 1 for heteroplasmic plants, 1 for homoplasmic plants and 0 for plants without the transgene insertion. The results obtained from the samples collected after the first regeneration cycle showed that 13 of the 21 plants were already in a homoplasmic state and did not require more cycles of regeneration. The real-time PCR proved to be an effective method for analyzing the homoplasmy degree of transplastomic plants.
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Análise de homoplasmia de plantas transplastômicas de fumo via PCR em tempo real / Homoplasmy analysis of tobacco transplastomic plants via real-time PCRSimone Missae Tanaka 10 January 2012 (has links)
A transformação plastidial oferece uma série de vantagens em relação à transformação nuclear, como: altos níveis de expressão de proteínas, capacidade de expressar múltiplos transgenes em operons e contenção gênica pela ausência de transmissão pelo pólen. Devido ao alto número de cópias do genoma plastidial por cloroplasto e ao alto número de cloroplastos por células vegetais, são necessários ciclos de regeneração sob condições seletivas para obter transformantes homoplásmicos. A análise de homoplasmia é realizada pela metodologia de Southern blot ou pelo teste de herança do transgene pela germinação de sementes em meio seletivo. O Southern blot é trabalhoso, demorado e para maior sensibilidade envolve o uso de radioisótopos, enquanto o teste de germinação é realizado somente após a produção de sementes necessitando de um ciclo de reprodução da planta. Assim, o objetivo deste trabalho foi desenvolver um método rápido, sensível e eficaz para determinar o grau de homoplasmia de plantas transplastômicas, baseado na técnica de PCR em tempo real. Folhas de fumo foram transformadas com vetores compostos pelos genes 9 dessaturase (pMR1), 15 dessaturase (pMR3), -3 elongase (pMR5) e 12/3 dessaturase (pMR10), todos contendo o gene de seleção aadA. No total, 44 plantas foram obtidas, sendo 21 plantas positivas para a inserção do transgene. O grau de homoplasmia foi determinado pela proporção entre o número de cópias do transgene e o número de cópias do gene endógeno. Inicialmente, misturas de DNA de plantas transplastômicas homoplásmicas (pMR1 e pMR3) com DNA de planta tipo selvagem foram preparadas para simular diferentes graus de homoplasmia. DNA da planta transplastômica ou do plasmídeo foi diluído em série para construção das curvaspadrão, com a quantidade dos genes sendo estimada por meio da plotagem nessas curvas. Os índices de homoplasmia detectados na PCR em tempo real foram compatíveis com os resultados do teste de germinação com valores abaixo de 1 para plantas heteroplásmicas, 1 para a planta homoplásmica e 0 para as plantas sem a inserção do transgene. Os resultados das análises de amostras coletadas após o primeiro ciclo de regeneração mostraram que 13 das 21 plantas já se apresentavam em estado homoplásmico não sendo necessários mais ciclos de regeneração. A PCR em tempo real mostrou ser um método eficiente para análise do grau de homoplasmia de plantas transplastômicas. / Plastid transformation offers several advantages in relation to nuclear transformation, such as high-level of protein expression, the feasibility of expressing multiple transgenes in operons and gene containment through the lack of pollen transmission. Due to the high copy number of plastidial genome in chloroplasts and the high number of chloroplasts per plant cells, regeneration cycles under selective conditions are necessary to obtain homoplasmic transformants. Homoplasmy analysis is performed by Southern blot methodology or transgene inheritance test through seed germination in selective medium. Southern blot is laborious, time consuming and for more sensitivity it would require the use of radioisotopes, while germination test can be performed only after seed production which require a plant reproduction cycle. The objective of this study was to develop a fast, sensitive and effective method to determine the homoplasmy degree of transplastomic plants, based on real-time PCR. Tobacco leaves were transformed with vectors containing the 9 desaturase (pMR1), 15 desaturase (pMR3), -3 elongase (pMR5) and 12/3 desaturase (pMR10) each one with the aadA selection gene. In total, 44 plants were obtained, of which 21 were positive for the insertion of the transgene. The homoplasmy degree was determined by the proportion between the number of transgene copies and the number of endogenous gene copies. Initially, mixtures of homoplastomic plants DNA (pMR1 and pMR3) with wild-type plant DNA were prepared to simulate different degrees of homoplasmy. Transplastomic plant DNA or plasmid DNA was diluted to construct the standard curves and the gene amount was detected by plotting in this curves. The homoplasmy rate detected in real-time PCR were consistent with the results of germination test with values below 1 for heteroplasmic plants, 1 for homoplasmic plants and 0 for plants without the transgene insertion. The results obtained from the samples collected after the first regeneration cycle showed that 13 of the 21 plants were already in a homoplasmic state and did not require more cycles of regeneration. The real-time PCR proved to be an effective method for analyzing the homoplasmy degree of transplastomic plants.
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