The Agrobacterium rhizogenes oncogenes rolB and ORF13 increase formation of generative shoots and induce dwarfism in Arabidopsis thaliana (L.) Heynh

•Expression of rolB increases flowering in A. thaliana.•Expression of ORF13 causes dwarfism in A. thaliana.•ORF13 may be essential for the characteristic phenotype induced by A. rhizogenes. Plant transformation with the wild type Ri plasmid T-DNA of Agrobacterium rhizogenes is a promising method for...

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Published inPlant science (Limerick) Vol. 252; pp. 22 - 29
Main Authors Kodahl, Nete, Müller, Renate, Lütken, Henrik
Format Journal Article
LanguageEnglish
Published Ireland Elsevier B.V 01.11.2016
Subjects
Agrobacterium - genetics
Agrobacterium rhizogenes oncogenes
Arabidopsis - genetics
Arabidopsis - physiology
Arabidopsis - virology
Arabidopsis thaliana
Bacterial Proteins - genetics
Bacterial Proteins - physiology
beta-Glucosidase - genetics
beta-Glucosidase - physiology
breeding methods
Dwarfed phenotype
dwarfing
flowers
Flowers - genetics
Flowers - physiology
Flowers - virology
Genome, Plant
leaves
necrosis
oncogenes
open reading frames
Open Reading Frames - genetics
phenotype
plant breeding
Plant Breeding - methods
plant growth
Plant Shoots - genetics
Plant Shoots - physiology
Plant Shoots - virology
plasmids
Reduced flower size
Rhizobium rhizogenes
Ri plasmid
shoots
transfer DNA
Transformation, Genetic
Arabidopsis thaliana
Agrobacterium rhizogenes oncogenes
Reduced flower size
Dwarfed phenotype
Ri plasmid
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Abstract •Expression of rolB increases flowering in A. thaliana.•Expression of ORF13 causes dwarfism in A. thaliana.•ORF13 may be essential for the characteristic phenotype induced by A. rhizogenes. Plant transformation with the wild type Ri plasmid T-DNA of Agrobacterium rhizogenes is a promising method for breeding of compact plants and has been the subject of numerous studies. However, knowledge concerning the isolated functions of single genes and ORFs from the plasmid is limited. The rolB and ORF13 oncogenes of A. rhizogenes show considerable promise in plant breeding, but have not been comprehensively studied. Detailed information regarding the morphological impact of specific genes of the Ri plasmid will allow for optimized targeted breeding of plants transformed with the wild type Ri plasmid T-DNA. rolB and ORF13 were recombined into the genome of Arabidopsis thaliana using Gateway® cloning and the effect on plant growth was assessed biometrically throughout the plants’ life cycle. rolB-lines exhibited dwarfing, early necrosis of rosette leaves, altered leaf and flower morphology, and developed an increased number of inflorescences per rosette area compared to the wild type. ORF13-lines were extremely dwarfed, attaining only ca. 1% of the rosette area of the wild type, leaf and flower size was reduced, and the shape modified. The study documents that the traits inferred by the rolB oncogene yield plants with increased formation of generative shoots, but also result in some degree of premature senescence of vegetative organs. The extreme dwarfism seen in ORF13-lines indicate that this oncogene may be more important in the dwarfing response of plants transformed with the wild type Ri plasmid T-DNA than previously assumed and that transformation with this oncogene induces a very compact phenotype.
AbstractList Plant transformation with the wild type Ri plasmid T-DNA of Agrobacterium rhizogenes is a promising method for breeding of compact plants and has been the subject of numerous studies. However, knowledge concerning the isolated functions of single genes and ORFs from the plasmid is limited. The rolB and ORF13 oncogenes of A. rhizogenes show considerable promise in plant breeding, but have not been comprehensively studied. Detailed information regarding the morphological impact of specific genes of the Ri plasmid will allow for optimized targeted breeding of plants transformed with the wild type Ri plasmid T-DNA. rolB and ORF13 were recombined into the genome of Arabidopsis thaliana using Gateway® cloning and the effect on plant growth was assessed biometrically throughout the plants’ life cycle. rolB-lines exhibited dwarfing, early necrosis of rosette leaves, altered leaf and flower morphology, and developed an increased number of inflorescences per rosette area compared to the wild type. ORF13-lines were extremely dwarfed, attaining only ca. 1% of the rosette area of the wild type, leaf and flower size was reduced, and the shape modified. The study documents that the traits inferred by the rolB oncogene yield plants with increased formation of generative shoots, but also result in some degree of premature senescence of vegetative organs. The extreme dwarfism seen in ORF13-lines indicate that this oncogene may be more important in the dwarfing response of plants transformed with the wild type Ri plasmid T-DNA than previously assumed and that transformation with this oncogene induces a very compact phenotype.
Plant transformation with the wild type Ri plasmid T-DNA of Agrobacterium rhizogenes is a promising method for breeding of compact plants and has been the subject of numerous studies. However, knowledge concerning the isolated functions of single genes and ORFs from the plasmid is limited. The rolB and ORF13 oncogenes of A. rhizogenes show considerable promise in plant breeding, but have not been comprehensively studied. Detailed information regarding the morphological impact of specific genes of the Ri plasmid will allow for optimized targeted breeding of plants transformed with the wild type Ri plasmid T-DNA. rolB and ORF13 were recombined into the genome of Arabidopsis thaliana using Gateway® cloning and the effect on plant growth was assessed biometrically throughout the plants' life cycle. rolB-lines exhibited dwarfing, early necrosis of rosette leaves, altered leaf and flower morphology, and developed an increased number of inflorescences per rosette area compared to the wild type. ORF13-lines were extremely dwarfed, attaining only ca. 1% of the rosette area of the wild type, leaf and flower size was reduced, and the shape modified. The study documents that the traits inferred by the rolB oncogene yield plants with increased formation of generative shoots, but also result in some degree of premature senescence of vegetative organs. The extreme dwarfism seen in ORF13-lines indicate that this oncogene may be more important in the dwarfing response of plants transformed with the wild type Ri plasmid T-DNA than previously assumed and that transformation with this oncogene induces a very compact phenotype.Plant transformation with the wild type Ri plasmid T-DNA of Agrobacterium rhizogenes is a promising method for breeding of compact plants and has been the subject of numerous studies. However, knowledge concerning the isolated functions of single genes and ORFs from the plasmid is limited. The rolB and ORF13 oncogenes of A. rhizogenes show considerable promise in plant breeding, but have not been comprehensively studied. Detailed information regarding the morphological impact of specific genes of the Ri plasmid will allow for optimized targeted breeding of plants transformed with the wild type Ri plasmid T-DNA. rolB and ORF13 were recombined into the genome of Arabidopsis thaliana using Gateway® cloning and the effect on plant growth was assessed biometrically throughout the plants' life cycle. rolB-lines exhibited dwarfing, early necrosis of rosette leaves, altered leaf and flower morphology, and developed an increased number of inflorescences per rosette area compared to the wild type. ORF13-lines were extremely dwarfed, attaining only ca. 1% of the rosette area of the wild type, leaf and flower size was reduced, and the shape modified. The study documents that the traits inferred by the rolB oncogene yield plants with increased formation of generative shoots, but also result in some degree of premature senescence of vegetative organs. The extreme dwarfism seen in ORF13-lines indicate that this oncogene may be more important in the dwarfing response of plants transformed with the wild type Ri plasmid T-DNA than previously assumed and that transformation with this oncogene induces a very compact phenotype.
Plant transformation with the wild type Ri plasmid T-DNA of Agrobacterium rhizogenes is a promising method for breeding of compact plants and has been the subject of numerous studies. However, knowledge concerning the isolated functions of single genes and ORFs from the plasmid is limited. The rolB and ORF13 oncogenes of A. rhizogenes show considerable promise in plant breeding, but have not been comprehensively studied. Detailed information regarding the morphological impact of specific genes of the Ri plasmid will allow for optimized targeted breeding of plants transformed with the wild type Ri plasmid T-DNA. rolB and ORF13 were recombined into the genome of Arabidopsis thaliana using Gateway cloning and the effect on plant growth was assessed biometrically throughout the plants' life cycle. rolB-lines exhibited dwarfing, early necrosis of rosette leaves, altered leaf and flower morphology, and developed an increased number of inflorescences per rosette area compared to the wild type. ORF13-lines were extremely dwarfed, attaining only ca. 1% of the rosette area of the wild type, leaf and flower size was reduced, and the shape modified. The study documents that the traits inferred by the rolB oncogene yield plants with increased formation of generative shoots, but also result in some degree of premature senescence of vegetative organs. The extreme dwarfism seen in ORF13-lines indicate that this oncogene may be more important in the dwarfing response of plants transformed with the wild type Ri plasmid T-DNA than previously assumed and that transformation with this oncogene induces a very compact phenotype.
•Expression of rolB increases flowering in A. thaliana.•Expression of ORF13 causes dwarfism in A. thaliana.•ORF13 may be essential for the characteristic phenotype induced by A. rhizogenes. Plant transformation with the wild type Ri plasmid T-DNA of Agrobacterium rhizogenes is a promising method for breeding of compact plants and has been the subject of numerous studies. However, knowledge concerning the isolated functions of single genes and ORFs from the plasmid is limited. The rolB and ORF13 oncogenes of A. rhizogenes show considerable promise in plant breeding, but have not been comprehensively studied. Detailed information regarding the morphological impact of specific genes of the Ri plasmid will allow for optimized targeted breeding of plants transformed with the wild type Ri plasmid T-DNA. rolB and ORF13 were recombined into the genome of Arabidopsis thaliana using Gateway® cloning and the effect on plant growth was assessed biometrically throughout the plants’ life cycle. rolB-lines exhibited dwarfing, early necrosis of rosette leaves, altered leaf and flower morphology, and developed an increased number of inflorescences per rosette area compared to the wild type. ORF13-lines were extremely dwarfed, attaining only ca. 1% of the rosette area of the wild type, leaf and flower size was reduced, and the shape modified. The study documents that the traits inferred by the rolB oncogene yield plants with increased formation of generative shoots, but also result in some degree of premature senescence of vegetative organs. The extreme dwarfism seen in ORF13-lines indicate that this oncogene may be more important in the dwarfing response of plants transformed with the wild type Ri plasmid T-DNA than previously assumed and that transformation with this oncogene induces a very compact phenotype.
Author Müller, Renate
Kodahl, Nete
Lütken, Henrik
Author_xml – sequence: 1
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  givenname: Renate
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  email: ren@plen.ku.dk
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  givenname: Henrik
  surname: Lütken
  fullname: Lütken, Henrik
  email: hlm@plen.ku.dk
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Keywords Arabidopsis thaliana
Agrobacterium rhizogenes oncogenes
Reduced flower size
Dwarfed phenotype
Ri plasmid
Language English
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Snippet •Expression of rolB increases flowering in A. thaliana.•Expression of ORF13 causes dwarfism in A. thaliana.•ORF13 may be essential for the characteristic...
Plant transformation with the wild type Ri plasmid T-DNA of Agrobacterium rhizogenes is a promising method for breeding of compact plants and has been the...
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SubjectTerms Agrobacterium - genetics
Agrobacterium rhizogenes oncogenes
Arabidopsis - genetics
Arabidopsis - physiology
Arabidopsis - virology
Arabidopsis thaliana
Bacterial Proteins - genetics
Bacterial Proteins - physiology
beta-Glucosidase - genetics
beta-Glucosidase - physiology
breeding methods
Dwarfed phenotype
dwarfing
flowers
Flowers - genetics
Flowers - physiology
Flowers - virology
Genome, Plant
leaves
necrosis
oncogenes
open reading frames
Open Reading Frames - genetics
phenotype
plant breeding
Plant Breeding - methods
plant growth
Plant Shoots - genetics
Plant Shoots - physiology
Plant Shoots - virology
plasmids
Reduced flower size
Rhizobium rhizogenes
Ri plasmid
shoots
transfer DNA
Transformation, Genetic
Title The Agrobacterium rhizogenes oncogenes rolB and ORF13 increase formation of generative shoots and induce dwarfism in Arabidopsis thaliana (L.) Heynh
URI https://dx.doi.org/10.1016/j.plantsci.2016.06.020
https://www.ncbi.nlm.nih.gov/pubmed/27717457
https://www.proquest.com/docview/1835395590
https://www.proquest.com/docview/1836660969
Volume 252
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