Hibridação somática entre Citrus sinensis e C. grandis. / Somatic hybridization of Citrus sinensis and C. grandis.

Calixto, Marcia Cristina

12 June 2003

A hibridação somática de citros tem sido extensivamente aplicada, favorecendo o desenvolvimento de híbridos somáticos em programas de melhoramento genético, como fonte de germoplasma ou como variedades copa e porta-enxerto. Neste contexto, este trabalho foi desenvolvido com o objetivo de selecionar plantas de toranja (Citrus grandis L. Osbeck) tolerantes à Phytophthora sp. e utilizá-las como parentais no processo de hibridação somática com outras espécies do gênero Citrus, a fim de produzir híbridos somáticos para o melhoramento de porta-enxertos. Plantas de 20 variedades de toranja tolerantes à Phytophthora spp. foram selecionadas, após serem cultivadas em solo infestado. Experimentos de fusão de protoplastos foram realizados envolvendo laranjas doces, tangerinas e o tangor ‘Murcote’, como parentais embriogênicos, e variedades de toranja selecionadas e plantas enxertadas de 12 variedades de toranja, como parentais não-embriogênicos, utilizando-se a técnica de fusão química, via polietilenoglicol (PEG). Microcolônias foram transferidas para meio de cultura MT semi-sólido, suplementado com 500 mg.l -1 de extrato de malte para indução da embriogênese somática. A confirmação da hibridação somática das plantas regeneradas e aclimatizadas foi realizada por meio de análises de morfologia foliar, de citologia, pela contagem do número de cromossomos, e moleculares, por marcadores do tipo RAPD. As metodologias utilizadas para seleção de plantas matrizes, fusão de protoplastos, regeneração de plantas e confirmação da hibridação somática foram adequadas, e permitiram a obtenção de híbridos somáticos de laranja ‘Hamlin’ com toranja enxertada ‘Indian Red’ e com ‘seedling’ selecionado de toranja ‘Singapura’, que apresentam potencial para serem incorporados em programas de melhoramento de porta-enxertos. / Citrus somatic hybridization has been extensively applied assisting the development of the somatic hybrids which can be used in improvement programs, indirectly as germoplasm source or directly as scion and rootstock varieties. In this context, this research was developed with the objective of selecting plants of pummelo (C. grandis L. Osb) tolerant to Phytophthora sp. and use these plants as parents in the somatic hybridization process with other species of Citrus. Plants of 20 pummelo varieties, tolerant to Phytophthora sp., were selected after being grown in infested soil. Protoplast fusion experiments were induced by chemical method, with polyethylene glicol (PEG), involving sweet oranges, mandarins and Murcott tangor, as embryogenic parents, selected pummelo varieties and grafted plants of 12 pummelo varieties, as non-embryogenic parents. Microcolonies were transferred to EME semi-solid MT containing 500 mg.l -1 of malt extract for somatic embryogenesis. Somatic hybridization was confirmed by analysis of leaf morphology, citology by chromosome counting and molecular analysis by RAPD markers. The protocols used to select plants to be used as protoplast source, protoplast fusion, plant regeneration and somatic hybridization confirmation were adequate, allowing to produce somatic hybrids of Hamlin sweet orange with Indian Red grafted pummelo and Singapura pummelo selected seedling, which may be used as rootstocks and incorporated in rootstocks improvement programs.

citricultura

citriculture

fusão de protoplasto

genética vegetal

hibridação vegetal

laranja

melhoramento genético vegetal

orange

plant genetic

plant genetic improvement

plant hybridization

porta-enxertos.

protoplast fusion

rootstocks.

Hibridação somática entre Citrus sinensis e C. grandis. / Somatic hybridization of Citrus sinensis and C. grandis.

Marcia Cristina Calixto

12 June 2003

A hibridação somática de citros tem sido extensivamente aplicada, favorecendo o desenvolvimento de híbridos somáticos em programas de melhoramento genético, como fonte de germoplasma ou como variedades copa e porta-enxerto. Neste contexto, este trabalho foi desenvolvido com o objetivo de selecionar plantas de toranja (Citrus grandis L. Osbeck) tolerantes à Phytophthora sp. e utilizá-las como parentais no processo de hibridação somática com outras espécies do gênero Citrus, a fim de produzir híbridos somáticos para o melhoramento de porta-enxertos. Plantas de 20 variedades de toranja tolerantes à Phytophthora spp. foram selecionadas, após serem cultivadas em solo infestado. Experimentos de fusão de protoplastos foram realizados envolvendo laranjas doces, tangerinas e o tangor ‘Murcote’, como parentais embriogênicos, e variedades de toranja selecionadas e plantas enxertadas de 12 variedades de toranja, como parentais não-embriogênicos, utilizando-se a técnica de fusão química, via polietilenoglicol (PEG). Microcolônias foram transferidas para meio de cultura MT semi-sólido, suplementado com 500 mg.l -1 de extrato de malte para indução da embriogênese somática. A confirmação da hibridação somática das plantas regeneradas e aclimatizadas foi realizada por meio de análises de morfologia foliar, de citologia, pela contagem do número de cromossomos, e moleculares, por marcadores do tipo RAPD. As metodologias utilizadas para seleção de plantas matrizes, fusão de protoplastos, regeneração de plantas e confirmação da hibridação somática foram adequadas, e permitiram a obtenção de híbridos somáticos de laranja ‘Hamlin’ com toranja enxertada ‘Indian Red’ e com ‘seedling’ selecionado de toranja ‘Singapura’, que apresentam potencial para serem incorporados em programas de melhoramento de porta-enxertos. / Citrus somatic hybridization has been extensively applied assisting the development of the somatic hybrids which can be used in improvement programs, indirectly as germoplasm source or directly as scion and rootstock varieties. In this context, this research was developed with the objective of selecting plants of pummelo (C. grandis L. Osb) tolerant to Phytophthora sp. and use these plants as parents in the somatic hybridization process with other species of Citrus. Plants of 20 pummelo varieties, tolerant to Phytophthora sp., were selected after being grown in infested soil. Protoplast fusion experiments were induced by chemical method, with polyethylene glicol (PEG), involving sweet oranges, mandarins and Murcott tangor, as embryogenic parents, selected pummelo varieties and grafted plants of 12 pummelo varieties, as non-embryogenic parents. Microcolonies were transferred to EME semi-solid MT containing 500 mg.l -1 of malt extract for somatic embryogenesis. Somatic hybridization was confirmed by analysis of leaf morphology, citology by chromosome counting and molecular analysis by RAPD markers. The protocols used to select plants to be used as protoplast source, protoplast fusion, plant regeneration and somatic hybridization confirmation were adequate, allowing to produce somatic hybrids of Hamlin sweet orange with Indian Red grafted pummelo and Singapura pummelo selected seedling, which may be used as rootstocks and incorporated in rootstocks improvement programs.

citricultura

fusão de protoplasto

genética vegetal

hibridação vegetal

laranja

melhoramento genético vegetal

porta-enxertos.

citriculture

orange

plant genetic

plant genetic improvement

plant hybridization

protoplast fusion

rootstocks.

Molecular analysis of genetic diversity in dometicated pigeonpea (Cajanus cajan (L.) Millsp.) and wild relatives / Molecular analysis of genetic diversity in domesticated pidgeonpea (Cajanus cajan Milsp.) and wild relatives : insights into the domestication of pidgeonpea

Kassa, Mulualem Tamiru

January 2011

Cajanus cajan (L.) Millsp. (Pigeonpea) belongs to the Leguminosae genus Cajanus which is composed of 34 species. Pigeonpea is the only cultivated member of the genus, while the remaining species are wild relatives belonging mainly to the secondary gene pool. DNA sequence data from the nuclear ITS region and the chloroplast trnL-F spacer were utilized to investigate the phylogenetic relationships between Cajanus and five other allied genera in the subtribe Cajaninae. This study revealed the non-monophyly of Cajanus and Rhynchosia and supported the monophyly of Eriosema and Flemingia, but more sampling ,especially from the large genera of Rhynchosia and Eriosema, is recommend to adequately test the hypothesis of generic monophyly. The phylogenetic relationships within the genus Cajanus resolved Cajanus scarabaeoides (L.) Thouars as the most basal species in the Cajanus clade. The study also utilized Single Nucleotide Polymorphism (SNP) markers derived from low copy orthologous genes and genotyped using the high throughput SNP-OPA Illumina golden gate assay. The aim was to understand phylogenetic and domestication history, genetic structure, patterns of genetic diversity, gene flow and historical hybridization between Cajanus cajan (pigeonpea) and wild relatives. The neighbor-joining tree resolved well-supported clusters, which reflect the distinctiveness of species and congruence with their geographical origin. It supported the ITS based phylogeny and resolved C. scarabaeoides as basal to the Cajanus clade. The phylogenetic signal and genetic signatures revealed insights into the domestication history of pigeonpea. Our results supported Cajanus cajanifolius as the presumed progenitor of pigeonpea and we speculate that for pigeonpea there was a single major domestication event in India. Genetic admixture and historical hybridization were evident between pigeonpea and wild relatives. Abundant allelic variation and genetic diversity was found in the wild relatives, with the exception of wild species from Australia, as compared to the domesticated pigeonpea. There was a reduction of about 75% in genetic polymorphism in domesticated pigeonpea as compared to the wild relatives, indicating a severe “domestication bottleneck” during pigeonpea domestication. We discovered SNP markers associated with disease resistance (NBS-LRR) loci. The SNPs were mined in a comparison of BAC-end sequences (BES) of C. cajan and amplicons of the wild species, C. scarabaeoides. A total of ~3000 SNPs were identified from 304 BES. These SNPs could potentially be used in constructing a genetic map and for marker assisted breeding.

Pigeon pea -- Variation

Cajanus -- Variation

Pigeon pea -- Genetics

Cajanus -- Genetics

Biodiversity

Pigeon pea -- Phylogeny

Cajanus -- Phylogeny

Plant hybridization

Plant diversity

Transgenic plants