Understanding hormonal and temporal factors associated with tomato (Solanum lycopersicum L. cv. Micro-Tom) acquisition of competence: key concepts for in vitro shoot regeneration / Compreensão dos fatores hormonais e temporais associados à aquisição de competência em tomateiro (Solanum lycopersicum L. cv. Micro-Tom): conceitos-chave para a regeneração in vitro de gemas caulinares

Notini, Marcela Morato

25 August 2017

Plant regeneration through de novo organogenesis is a critical step in most of the plant micropropagation and genetic transformation procedures. In the last years, significant progress has been made in the understanding of the mechanisms underlying de novo organogenesis in the worldwide crop tomato (Solanum lycopersicum). However, the hormonal and molecular factors involving the acquisition of competence for tomato shoot formation, an essential step for the regeneration process, are still not known. The failure in acquire competence can be the reason for the widely described absence of shoot regeneration from tomato root explants. In the first chapter, we conducted a temporal and hormonal characterization of the tomato acquisition of competence and the shoot induction phases using the model system cv. Micro-Tom. Regeneration was improved by pre-incubation on root-inducing medium (RIM) during the early two days in culture, a period corresponding to acquisition of competence step in cotyledon explants. Conversely, the pre-incubation on another auxin-rich condition, the callus-inducing medium (CIM), under the same period, abolished the regeneration achievement. The 2d RIM pre-treatment induced an extensive and intense endogenous auxin response in the explant, probably improving the cells competence to produce shoots under further cytokinin induction on shoot-inducing medium (SIM). This knowledge was applied to improve the Agrobacterium-mediated tomato genetic transformation procedure, leading to an efficient, simple, inexpensive and genotype-independent protocol. In the second chapter, we developed an unprecedented method for tomato shoot regeneration from root explants. The shoot organogenesis was obtained by adjusting the CIM pre-treatment to the acquisition of competence period, corresponding to the initial four days in culture for root explants. The number and quality of shoots formed were also augmented by the optimization of explants properties, medium components, and culture conditions. Taken the two chapters together, the knowledge obtained about organogenic competence advanced and created new regeneration and genetic transformation systems, which are very useful tools for biotechnology and functional studies of specific genes in tomato. / A regeneração de plantas através da organogênese de novo é uma fase crítica para a maioria dos procedimentos de micropropagação e transformação genética. Recentemente, progressos significativos tem sido alcançados no entendimento dos mecanismos fundamentais à organogênese de novo de tomateiro (Solanum lycopersicum). Entretanto, fatores hormonais e moleculares envolvidos na aquisição de competência para formação de gemas caulinares na espécie, etapa essencial ao processo de regeneração, permancece desconhecido. O fracasso em adquirir competência pode ser associado a amplamente descrita incapacidade de tomateiro em regenerar brotos caulinares a partir de raízes. No primeiro capítulo, realizou-se uma caracterização temporal e hormonal das fases de aquisição de competência e indução de gemas caulinares usando a cultivar modelo Micro-Tom. A eficiência de regeneração foi melhorada através de pré-incubação em meio indutor de raízes (RIM) durante os dois primeiros dias de cultivo, período correspondente à fase de aquisição de competência em explantes cotiledonares. Diferentemente, a pré-incubação em outro meio rico em auxina, o meio indutor de calo (CIM), sob mesmo intervalo, aboliu completamente a regeneração. A pré-incubação de dois dias em RIM induziu uma intensa e extensa resposta a auxina endógena no explante, o que provavelmente aumentou a competência das células a induzir brotos caulinares em resposta a citocinina presente no meio indutor de gemas caulinares (SIM). A aplicação desse conhecimento na melhoria do procedimento de transformação genética via Agrobacteria levou a um eficiente, simples, barato e genótipo-independente protocolo. No segundo capítulo, nós desenvolvemos um método inédito de regeneração de tomateiro via explante radicular. A formação de brotos caulinares foi obtida por ajuste do pré-tratamento em CIM ao período de aquisição de competência, correspondente a quatro dias de cultivo em explantes radiculares. O número e qualidade dos brotos também foram elevados pela otimização do explante, composição do meio de cultivo, e condições de cultivo. Somando-se os dois capítulos, o conhecimento obtido a cerca da competência organogênica resultou em novos sistemas de regeneração e transformação genética, ferramentas importantes para processos biotecnológicos e estudos funcionais de genes específicos em tomateiro.

In vitro regeneration

Solanum lycopersicum

Solanum lycopersicum

Auxin

Auxina

Competência organogênica

Organogenic competence

Regeneração in vitro

Genetic manipulation of Grain storage protein digestibility in sorghum.

Phuong Mai Hoang

Unknown Date

Abstract Sorghum (Sorghum bicolor L. Moench) is the world’s fifth most common cereal crop and provides an important source of staple food in the semi-arid tropics and feed in many other countries. The plant has the ability to grow and yield in hot and dry climates. However, sorghum grain is less digestible than the other major staple crops such as rice, wheat and maize. Therefore, the aim of this project is to improve the nutritional quality of sorghum grain by applying cutting-edge biotechnologies which involve the use of tissue culture and genetic transformation. Recently, Agrobacterium has been used by many researchers to introduce foreign genes into the sorghum genome. This method has some advantages compared to particle bombardment, however, one limitation is the regeneration of transgenic tissues. In this study successfully transformed sorghum using Agrobacterium and regenerated transgenic plants via an organogenic tissue culture system is reported. The results of transformation efficiency were achieved with co-cultivation after 48 hours. Regeneration of the sorghum transgenic plants was improved by using organogenic tissues. The GUS reporter gene and the Hpt and bar selectable markers were used. Southern blots and PCR were used to confirm transgene presence in the T0 and T1 generations. In this study, stable transgenic sorghum plants have been produced. The factors found to most influence Agrobacterium transformation were the type of organogenic tissue from different genotypes. The genotypes and the period of co-cultivation, as well as the selectable marker gene and selection strategy used. However, the transformation efficiency from this method was low (1.12%) compared with the previous efficiencies published for Agrobacterium-mediated sorghum transformation. Therefore, to improve the transformation efficiency for this method further work may need to be done. Thioredoxin genes were transformed into the sorghum genotype 296B by particle bombardment. In the first experiment no transgenics over-expressing trx and ntr were confirmed by Southern blot. In subsequent experiments, a limited number of transgenics of the T1 generation were confirmed and used for further analysis. A transgenic line with both trx & ntr was created by crossing a trx line and a ntr line. The 2 genes in this line were confirmed and showed different levels of expression by Real Time PCR. Also, the level of expression in the T2 hybrid plants was higher compared to the T1 parents. The grains from the transgenic lines were different in gelatinization, viscosity, pasting properties and in-vitro digestibility. The ntr line was confirmed to be more digestible than the other transgenic lines and a non-transgenic line. There was a significant increase of 11% (P=0.02) in digestibility of the sorghum ntr line over the non-transgenic. However, the transgenic sorghum seeds did not germinate after storage for more than 6 months. Differences in the morphology of the starch granules and protein matrix of the transgenic lines when compared to non-transgenic were observed with Scanning Electron microscopy. The difference was observed from the transition to the central zone. Pores appeared in the starch granules of the sorghum transgenic lines, but not in the non-transgenic. This may be directly related to the changes in gelatinization, viscosity, pasting and digestibility. To find regulatory sequences which can direct expression of transgenes in developing endosperm, the β-kafirin promoter was identified and cloned. Two constructs of varying length were made to test tissue specificity of the promoter, by replacing the Ubi promoter of the pUBIGUS vector. The GUS gene was used as the marker gene under the control of the amplified β-kafirin promoter. The result was determined on different explants of sorghum by transient expression via particle bombardment. The result shows the successful identification of the β-kafirin promoter region and its effect on transient expression levels. Agrobacterium transformation of sorghum organogenic tissue was developed. The digestibility of grain sorghum was improved by over-expressing the thioredoxin genes. In conclusion, the sorghum grain digestibility can be improved by transforming sorghum with thioredoxin genes, via Agrobacterium-mediated transformation. Further experimentation is required to identify regulatory sequences to optimise transgene expression in sorghum endosperm. In order to determine the reason behind the difficulties of seed germination, larger numbers of independent transgenic lines need to be generated and tested to determine whether over-expression of trx & ntr always has detrimental effects on seed longevity and germination.

Genetic manipulation of Grain storage protein digestibility in sorghum.

Phuong Mai Hoang

Unknown Date

Abstract Sorghum (Sorghum bicolor L. Moench) is the world’s fifth most common cereal crop and provides an important source of staple food in the semi-arid tropics and feed in many other countries. The plant has the ability to grow and yield in hot and dry climates. However, sorghum grain is less digestible than the other major staple crops such as rice, wheat and maize. Therefore, the aim of this project is to improve the nutritional quality of sorghum grain by applying cutting-edge biotechnologies which involve the use of tissue culture and genetic transformation. Recently, Agrobacterium has been used by many researchers to introduce foreign genes into the sorghum genome. This method has some advantages compared to particle bombardment, however, one limitation is the regeneration of transgenic tissues. In this study successfully transformed sorghum using Agrobacterium and regenerated transgenic plants via an organogenic tissue culture system is reported. The results of transformation efficiency were achieved with co-cultivation after 48 hours. Regeneration of the sorghum transgenic plants was improved by using organogenic tissues. The GUS reporter gene and the Hpt and bar selectable markers were used. Southern blots and PCR were used to confirm transgene presence in the T0 and T1 generations. In this study, stable transgenic sorghum plants have been produced. The factors found to most influence Agrobacterium transformation were the type of organogenic tissue from different genotypes. The genotypes and the period of co-cultivation, as well as the selectable marker gene and selection strategy used. However, the transformation efficiency from this method was low (1.12%) compared with the previous efficiencies published for Agrobacterium-mediated sorghum transformation. Therefore, to improve the transformation efficiency for this method further work may need to be done. Thioredoxin genes were transformed into the sorghum genotype 296B by particle bombardment. In the first experiment no transgenics over-expressing trx and ntr were confirmed by Southern blot. In subsequent experiments, a limited number of transgenics of the T1 generation were confirmed and used for further analysis. A transgenic line with both trx & ntr was created by crossing a trx line and a ntr line. The 2 genes in this line were confirmed and showed different levels of expression by Real Time PCR. Also, the level of expression in the T2 hybrid plants was higher compared to the T1 parents. The grains from the transgenic lines were different in gelatinization, viscosity, pasting properties and in-vitro digestibility. The ntr line was confirmed to be more digestible than the other transgenic lines and a non-transgenic line. There was a significant increase of 11% (P=0.02) in digestibility of the sorghum ntr line over the non-transgenic. However, the transgenic sorghum seeds did not germinate after storage for more than 6 months. Differences in the morphology of the starch granules and protein matrix of the transgenic lines when compared to non-transgenic were observed with Scanning Electron microscopy. The difference was observed from the transition to the central zone. Pores appeared in the starch granules of the sorghum transgenic lines, but not in the non-transgenic. This may be directly related to the changes in gelatinization, viscosity, pasting and digestibility. To find regulatory sequences which can direct expression of transgenes in developing endosperm, the β-kafirin promoter was identified and cloned. Two constructs of varying length were made to test tissue specificity of the promoter, by replacing the Ubi promoter of the pUBIGUS vector. The GUS gene was used as the marker gene under the control of the amplified β-kafirin promoter. The result was determined on different explants of sorghum by transient expression via particle bombardment. The result shows the successful identification of the β-kafirin promoter region and its effect on transient expression levels. Agrobacterium transformation of sorghum organogenic tissue was developed. The digestibility of grain sorghum was improved by over-expressing the thioredoxin genes. In conclusion, the sorghum grain digestibility can be improved by transforming sorghum with thioredoxin genes, via Agrobacterium-mediated transformation. Further experimentation is required to identify regulatory sequences to optimise transgene expression in sorghum endosperm. In order to determine the reason behind the difficulties of seed germination, larger numbers of independent transgenic lines need to be generated and tested to determine whether over-expression of trx & ntr always has detrimental effects on seed longevity and germination.

Genetic manipulation of Grain storage protein digestibility in sorghum.

Phuong Mai Hoang

Unknown Date

Abstract Sorghum (Sorghum bicolor L. Moench) is the world’s fifth most common cereal crop and provides an important source of staple food in the semi-arid tropics and feed in many other countries. The plant has the ability to grow and yield in hot and dry climates. However, sorghum grain is less digestible than the other major staple crops such as rice, wheat and maize. Therefore, the aim of this project is to improve the nutritional quality of sorghum grain by applying cutting-edge biotechnologies which involve the use of tissue culture and genetic transformation. Recently, Agrobacterium has been used by many researchers to introduce foreign genes into the sorghum genome. This method has some advantages compared to particle bombardment, however, one limitation is the regeneration of transgenic tissues. In this study successfully transformed sorghum using Agrobacterium and regenerated transgenic plants via an organogenic tissue culture system is reported. The results of transformation efficiency were achieved with co-cultivation after 48 hours. Regeneration of the sorghum transgenic plants was improved by using organogenic tissues. The GUS reporter gene and the Hpt and bar selectable markers were used. Southern blots and PCR were used to confirm transgene presence in the T0 and T1 generations. In this study, stable transgenic sorghum plants have been produced. The factors found to most influence Agrobacterium transformation were the type of organogenic tissue from different genotypes. The genotypes and the period of co-cultivation, as well as the selectable marker gene and selection strategy used. However, the transformation efficiency from this method was low (1.12%) compared with the previous efficiencies published for Agrobacterium-mediated sorghum transformation. Therefore, to improve the transformation efficiency for this method further work may need to be done. Thioredoxin genes were transformed into the sorghum genotype 296B by particle bombardment. In the first experiment no transgenics over-expressing trx and ntr were confirmed by Southern blot. In subsequent experiments, a limited number of transgenics of the T1 generation were confirmed and used for further analysis. A transgenic line with both trx & ntr was created by crossing a trx line and a ntr line. The 2 genes in this line were confirmed and showed different levels of expression by Real Time PCR. Also, the level of expression in the T2 hybrid plants was higher compared to the T1 parents. The grains from the transgenic lines were different in gelatinization, viscosity, pasting properties and in-vitro digestibility. The ntr line was confirmed to be more digestible than the other transgenic lines and a non-transgenic line. There was a significant increase of 11% (P=0.02) in digestibility of the sorghum ntr line over the non-transgenic. However, the transgenic sorghum seeds did not germinate after storage for more than 6 months. Differences in the morphology of the starch granules and protein matrix of the transgenic lines when compared to non-transgenic were observed with Scanning Electron microscopy. The difference was observed from the transition to the central zone. Pores appeared in the starch granules of the sorghum transgenic lines, but not in the non-transgenic. This may be directly related to the changes in gelatinization, viscosity, pasting and digestibility. To find regulatory sequences which can direct expression of transgenes in developing endosperm, the β-kafirin promoter was identified and cloned. Two constructs of varying length were made to test tissue specificity of the promoter, by replacing the Ubi promoter of the pUBIGUS vector. The GUS gene was used as the marker gene under the control of the amplified β-kafirin promoter. The result was determined on different explants of sorghum by transient expression via particle bombardment. The result shows the successful identification of the β-kafirin promoter region and its effect on transient expression levels. Agrobacterium transformation of sorghum organogenic tissue was developed. The digestibility of grain sorghum was improved by over-expressing the thioredoxin genes. In conclusion, the sorghum grain digestibility can be improved by transforming sorghum with thioredoxin genes, via Agrobacterium-mediated transformation. Further experimentation is required to identify regulatory sequences to optimise transgene expression in sorghum endosperm. In order to determine the reason behind the difficulties of seed germination, larger numbers of independent transgenic lines need to be generated and tested to determine whether over-expression of trx & ntr always has detrimental effects on seed longevity and germination.

Genetic manipulation of Grain storage protein digestibility in sorghum.

Phuong Mai Hoang

Unknown Date

Abstract Sorghum (Sorghum bicolor L. Moench) is the world’s fifth most common cereal crop and provides an important source of staple food in the semi-arid tropics and feed in many other countries. The plant has the ability to grow and yield in hot and dry climates. However, sorghum grain is less digestible than the other major staple crops such as rice, wheat and maize. Therefore, the aim of this project is to improve the nutritional quality of sorghum grain by applying cutting-edge biotechnologies which involve the use of tissue culture and genetic transformation. Recently, Agrobacterium has been used by many researchers to introduce foreign genes into the sorghum genome. This method has some advantages compared to particle bombardment, however, one limitation is the regeneration of transgenic tissues. In this study successfully transformed sorghum using Agrobacterium and regenerated transgenic plants via an organogenic tissue culture system is reported. The results of transformation efficiency were achieved with co-cultivation after 48 hours. Regeneration of the sorghum transgenic plants was improved by using organogenic tissues. The GUS reporter gene and the Hpt and bar selectable markers were used. Southern blots and PCR were used to confirm transgene presence in the T0 and T1 generations. In this study, stable transgenic sorghum plants have been produced. The factors found to most influence Agrobacterium transformation were the type of organogenic tissue from different genotypes. The genotypes and the period of co-cultivation, as well as the selectable marker gene and selection strategy used. However, the transformation efficiency from this method was low (1.12%) compared with the previous efficiencies published for Agrobacterium-mediated sorghum transformation. Therefore, to improve the transformation efficiency for this method further work may need to be done. Thioredoxin genes were transformed into the sorghum genotype 296B by particle bombardment. In the first experiment no transgenics over-expressing trx and ntr were confirmed by Southern blot. In subsequent experiments, a limited number of transgenics of the T1 generation were confirmed and used for further analysis. A transgenic line with both trx & ntr was created by crossing a trx line and a ntr line. The 2 genes in this line were confirmed and showed different levels of expression by Real Time PCR. Also, the level of expression in the T2 hybrid plants was higher compared to the T1 parents. The grains from the transgenic lines were different in gelatinization, viscosity, pasting properties and in-vitro digestibility. The ntr line was confirmed to be more digestible than the other transgenic lines and a non-transgenic line. There was a significant increase of 11% (P=0.02) in digestibility of the sorghum ntr line over the non-transgenic. However, the transgenic sorghum seeds did not germinate after storage for more than 6 months. Differences in the morphology of the starch granules and protein matrix of the transgenic lines when compared to non-transgenic were observed with Scanning Electron microscopy. The difference was observed from the transition to the central zone. Pores appeared in the starch granules of the sorghum transgenic lines, but not in the non-transgenic. This may be directly related to the changes in gelatinization, viscosity, pasting and digestibility. To find regulatory sequences which can direct expression of transgenes in developing endosperm, the β-kafirin promoter was identified and cloned. Two constructs of varying length were made to test tissue specificity of the promoter, by replacing the Ubi promoter of the pUBIGUS vector. The GUS gene was used as the marker gene under the control of the amplified β-kafirin promoter. The result was determined on different explants of sorghum by transient expression via particle bombardment. The result shows the successful identification of the β-kafirin promoter region and its effect on transient expression levels. Agrobacterium transformation of sorghum organogenic tissue was developed. The digestibility of grain sorghum was improved by over-expressing the thioredoxin genes. In conclusion, the sorghum grain digestibility can be improved by transforming sorghum with thioredoxin genes, via Agrobacterium-mediated transformation. Further experimentation is required to identify regulatory sequences to optimise transgene expression in sorghum endosperm. In order to determine the reason behind the difficulties of seed germination, larger numbers of independent transgenic lines need to be generated and tested to determine whether over-expression of trx & ntr always has detrimental effects on seed longevity and germination.

Genetic manipulation of Grain storage protein digestibility in sorghum.

Phuong Mai Hoang

Unknown Date

Abstract Sorghum (Sorghum bicolor L. Moench) is the world’s fifth most common cereal crop and provides an important source of staple food in the semi-arid tropics and feed in many other countries. The plant has the ability to grow and yield in hot and dry climates. However, sorghum grain is less digestible than the other major staple crops such as rice, wheat and maize. Therefore, the aim of this project is to improve the nutritional quality of sorghum grain by applying cutting-edge biotechnologies which involve the use of tissue culture and genetic transformation. Recently, Agrobacterium has been used by many researchers to introduce foreign genes into the sorghum genome. This method has some advantages compared to particle bombardment, however, one limitation is the regeneration of transgenic tissues. In this study successfully transformed sorghum using Agrobacterium and regenerated transgenic plants via an organogenic tissue culture system is reported. The results of transformation efficiency were achieved with co-cultivation after 48 hours. Regeneration of the sorghum transgenic plants was improved by using organogenic tissues. The GUS reporter gene and the Hpt and bar selectable markers were used. Southern blots and PCR were used to confirm transgene presence in the T0 and T1 generations. In this study, stable transgenic sorghum plants have been produced. The factors found to most influence Agrobacterium transformation were the type of organogenic tissue from different genotypes. The genotypes and the period of co-cultivation, as well as the selectable marker gene and selection strategy used. However, the transformation efficiency from this method was low (1.12%) compared with the previous efficiencies published for Agrobacterium-mediated sorghum transformation. Therefore, to improve the transformation efficiency for this method further work may need to be done. Thioredoxin genes were transformed into the sorghum genotype 296B by particle bombardment. In the first experiment no transgenics over-expressing trx and ntr were confirmed by Southern blot. In subsequent experiments, a limited number of transgenics of the T1 generation were confirmed and used for further analysis. A transgenic line with both trx & ntr was created by crossing a trx line and a ntr line. The 2 genes in this line were confirmed and showed different levels of expression by Real Time PCR. Also, the level of expression in the T2 hybrid plants was higher compared to the T1 parents. The grains from the transgenic lines were different in gelatinization, viscosity, pasting properties and in-vitro digestibility. The ntr line was confirmed to be more digestible than the other transgenic lines and a non-transgenic line. There was a significant increase of 11% (P=0.02) in digestibility of the sorghum ntr line over the non-transgenic. However, the transgenic sorghum seeds did not germinate after storage for more than 6 months. Differences in the morphology of the starch granules and protein matrix of the transgenic lines when compared to non-transgenic were observed with Scanning Electron microscopy. The difference was observed from the transition to the central zone. Pores appeared in the starch granules of the sorghum transgenic lines, but not in the non-transgenic. This may be directly related to the changes in gelatinization, viscosity, pasting and digestibility. To find regulatory sequences which can direct expression of transgenes in developing endosperm, the β-kafirin promoter was identified and cloned. Two constructs of varying length were made to test tissue specificity of the promoter, by replacing the Ubi promoter of the pUBIGUS vector. The GUS gene was used as the marker gene under the control of the amplified β-kafirin promoter. The result was determined on different explants of sorghum by transient expression via particle bombardment. The result shows the successful identification of the β-kafirin promoter region and its effect on transient expression levels. Agrobacterium transformation of sorghum organogenic tissue was developed. The digestibility of grain sorghum was improved by over-expressing the thioredoxin genes. In conclusion, the sorghum grain digestibility can be improved by transforming sorghum with thioredoxin genes, via Agrobacterium-mediated transformation. Further experimentation is required to identify regulatory sequences to optimise transgene expression in sorghum endosperm. In order to determine the reason behind the difficulties of seed germination, larger numbers of independent transgenic lines need to be generated and tested to determine whether over-expression of trx & ntr always has detrimental effects on seed longevity and germination.

Understanding hormonal and temporal factors associated with tomato (Solanum lycopersicum L. cv. Micro-Tom) acquisition of competence: key concepts for in vitro shoot regeneration / Compreensão dos fatores hormonais e temporais associados à aquisição de competência em tomateiro (Solanum lycopersicum L. cv. Micro-Tom): conceitos-chave para a regeneração in vitro de gemas caulinares

Marcela Morato Notini

25 August 2017

Plant regeneration through de novo organogenesis is a critical step in most of the plant micropropagation and genetic transformation procedures. In the last years, significant progress has been made in the understanding of the mechanisms underlying de novo organogenesis in the worldwide crop tomato (Solanum lycopersicum). However, the hormonal and molecular factors involving the acquisition of competence for tomato shoot formation, an essential step for the regeneration process, are still not known. The failure in acquire competence can be the reason for the widely described absence of shoot regeneration from tomato root explants. In the first chapter, we conducted a temporal and hormonal characterization of the tomato acquisition of competence and the shoot induction phases using the model system cv. Micro-Tom. Regeneration was improved by pre-incubation on root-inducing medium (RIM) during the early two days in culture, a period corresponding to acquisition of competence step in cotyledon explants. Conversely, the pre-incubation on another auxin-rich condition, the callus-inducing medium (CIM), under the same period, abolished the regeneration achievement. The 2d RIM pre-treatment induced an extensive and intense endogenous auxin response in the explant, probably improving the cells competence to produce shoots under further cytokinin induction on shoot-inducing medium (SIM). This knowledge was applied to improve the Agrobacterium-mediated tomato genetic transformation procedure, leading to an efficient, simple, inexpensive and genotype-independent protocol. In the second chapter, we developed an unprecedented method for tomato shoot regeneration from root explants. The shoot organogenesis was obtained by adjusting the CIM pre-treatment to the acquisition of competence period, corresponding to the initial four days in culture for root explants. The number and quality of shoots formed were also augmented by the optimization of explants properties, medium components, and culture conditions. Taken the two chapters together, the knowledge obtained about organogenic competence advanced and created new regeneration and genetic transformation systems, which are very useful tools for biotechnology and functional studies of specific genes in tomato. / A regeneração de plantas através da organogênese de novo é uma fase crítica para a maioria dos procedimentos de micropropagação e transformação genética. Recentemente, progressos significativos tem sido alcançados no entendimento dos mecanismos fundamentais à organogênese de novo de tomateiro (Solanum lycopersicum). Entretanto, fatores hormonais e moleculares envolvidos na aquisição de competência para formação de gemas caulinares na espécie, etapa essencial ao processo de regeneração, permancece desconhecido. O fracasso em adquirir competência pode ser associado a amplamente descrita incapacidade de tomateiro em regenerar brotos caulinares a partir de raízes. No primeiro capítulo, realizou-se uma caracterização temporal e hormonal das fases de aquisição de competência e indução de gemas caulinares usando a cultivar modelo Micro-Tom. A eficiência de regeneração foi melhorada através de pré-incubação em meio indutor de raízes (RIM) durante os dois primeiros dias de cultivo, período correspondente à fase de aquisição de competência em explantes cotiledonares. Diferentemente, a pré-incubação em outro meio rico em auxina, o meio indutor de calo (CIM), sob mesmo intervalo, aboliu completamente a regeneração. A pré-incubação de dois dias em RIM induziu uma intensa e extensa resposta a auxina endógena no explante, o que provavelmente aumentou a competência das células a induzir brotos caulinares em resposta a citocinina presente no meio indutor de gemas caulinares (SIM). A aplicação desse conhecimento na melhoria do procedimento de transformação genética via Agrobacteria levou a um eficiente, simples, barato e genótipo-independente protocolo. No segundo capítulo, nós desenvolvemos um método inédito de regeneração de tomateiro via explante radicular. A formação de brotos caulinares foi obtida por ajuste do pré-tratamento em CIM ao período de aquisição de competência, correspondente a quatro dias de cultivo em explantes radiculares. O número e qualidade dos brotos também foram elevados pela otimização do explante, composição do meio de cultivo, e condições de cultivo. Somando-se os dois capítulos, o conhecimento obtido a cerca da competência organogênica resultou em novos sistemas de regeneração e transformação genética, ferramentas importantes para processos biotecnológicos e estudos funcionais de genes específicos em tomateiro.

Solanum lycopersicum

Auxina

Competência organogênica

Regeneração in vitro

In vitro regeneration

Solanum lycopersicum

Auxin

Organogenic competence