Evolution of Darwin’s Peloric Gloxinia (Sinningia speciosa) Is Caused by a Null Mutation in a Pleiotropic TCP Gene

Dong, Yang; Liu, Jing; Li, Pengwei; Li, Chaoqun; Lu, Tiancheng; Yang, Xinglun; Wang, Yin-Zheng

doi:10.1093/molbev/msy090

Cited by 20 publications

(33 citation statements)

References 57 publications

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“…As this mutation has probably occurred only once, all cultivated forms with actinomorphic flowers are likely descendants of Gloxinia “Fyfiana” (Citerne & Cronk, ; Dong et al, ). The identical mutation was confirmed in multiple cultivars by Dong et al () who identified a small deletion in the single CYCLOIDEA ‐like gene found in S. speciosa ( SsCYC ). The wild‐type allele of this and related genes are responsible for suppressing growth in the dorsal organs of wild zygomorphic flowers such as S. speciosa and Antirrhinum majus (snapdragon).…”

Section: Discussionsupporting

confidence: 90%

“…This particular cultivar occupies an important place in the history of S. speciosa , because most modern cultivars have inherited their distinctive flower shape from a single recessive mutation that was disseminated extensively during the early stages of domestication. As this mutation has probably occurred only once, all cultivated forms with actinomorphic flowers are likely descendants of Gloxinia “Fyfiana” (Citerne & Cronk, ; Dong et al, ). The identical mutation was confirmed in multiple cultivars by Dong et al () who identified a small deletion in the single CYCLOIDEA ‐like gene found in S. speciosa ( SsCYC ).…”

Section: Discussionmentioning

confidence: 99%

“…He associated seven domesticated cultivars with the wild forms “Avenida Niemeyer” and ‘São Conrado’, also collected along the coast in the city of Rio de Janeiro. Dong et al () however, obtained contrasting results. Their phylogenetic analysis was based on the SsCYC gene sequence and suggests that the actinomorphic allele, which is homozygous in most cultivated material, originated from the wild‐type “Cardoso Moreira”.…”

Section: Discussionmentioning

confidence: 99%

“…Their phylogenetic analysis was based on the SsCYC gene sequence and suggests that the actinomorphic allele, which is homozygous in most cultivated material, originated from the wild‐type “Cardoso Moreira”. The plant material used in the Dong et al () study traces to a population located 2–3 km from the town of the same name, located in the northern part of Rio de Janeiro state (more than 300 km distant from Rio de Janeiro city) ~50 km from the southern border of the state of Espírito Santo (Zaitlin, ). Both of our “Cardoso Moreira” samples (purple‐ and pink‐flowered forms) clustered together with "São Fidelis", an accession that was collected 30–40 km from the “Cardoso Moreira” population, validating its geographical origin.…”

Section: Discussionmentioning

confidence: 99%

“…These results are supported by our population structure analyses in conjunction with previous phenetic and phylogenetic analyses (Zaitlin, ) as well as by written records that disclose collection sites (Brackenridge, ; Hooker, ; Paxton, ). Second, the already narrow pool of alleles in cultivated material could have shrunken even further following the substantial selective sweep around the SsCYC gene (Dong et al, ) that has practically fixed the mutant actinomorphic allele in the modern cultivars.…”

Section: Discussionmentioning

confidence: 99%

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Extensive phenotypic diversity in the cultivated Florist’s Gloxinia, Sinningia speciosa (Lodd.) Hiern, is derived from the domestication of a single founder population

Hasing

Rinaldi

Manrique

et al. 2019

Plants People Planet

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Societal Impact Statement Domesticated plants are essential for agriculture and human societies. Hence, understanding the processes of domestication will be crucial as we strive for more efficient crops and improvements to plants that benefit humankind in other ways. Here, we study the ornamental plant Sinningia speciosa, and reveal that despite the incredible variety found in domesticated varieties (e.g., in flower colour and form), they are all derived from a single founder population near Rio de Janeiro, Brazil. Knowledge of the domestication of horticultural plants is scarce and given its small, low‐complexity genome, and ease of cultivation, we suggest that S. speciosa is a good model for studying genomic variation during domestication. Summary The process of domestication often involves a complex genetic structure with contributions from multiple founder populations, interspecific hybridization, chromosomal introgressions, and polyploidization events that occurred hundreds to thousands of years earlier. These complex origins complicate the systematic study of the sources of phenotypic variation. The Florist's Gloxinia, Sinningia speciosa (Lodd.) Hiern, was introduced into cultivation in England two hundred years ago from botanical expeditions that began in the 18th century. Since that time, amateur plant breeders and small horticultural companies have developed hundreds of cultivars with a wide range of flower colors and shapes. In our genetic study of S. speciosa, we examined an extensive diversity panel consisting of 115 individuals that included different species, wild representatives, and cultivated accessions. Our analysis revealed that all of the domesticated varieties are derived from a single founder population that originated in or near the city of Rio de Janeiro in Brazil. We did not detect any major hybridization or polyploidization events that could have contributed to the rapid increase in phenotypic diversity. Our findings, in conjunction with other features such as a small, low‐complexity genome, ease of cultivation, and rapid generation time, makes this species an attractive model for the study of genomic variation under domestication.

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Section: Discussionsupporting

confidence: 90%

Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

See 3 more Smart Citations

Extensive phenotypic diversity in the cultivated Florist’s Gloxinia, Sinningia speciosa (Lodd.) Hiern, is derived from the domestication of a single founder population

Hasing

Rinaldi

Manrique

et al. 2019

Plants People Planet

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Development of a petal protoplast transfection system for Sinningia speciosa

et al. 2022

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Premise Transient gene expression systems are powerful tools for studying gene interactions in plant species without available or stable genetic transformation protocols. We optimized a petal protoplast transformation protocol for Sinningia speciosa, a model plant, to study the development of floral symmetry. Methods and Results A high yield of petal protoplasts was obtained using a 6‐h enzyme digestion in a solution of 1.5% cellulase and 0.4% macerozyme. Modest transfection efficiency (average 41.4%) was achieved. The viability of the transfected protoplasts remained at more than 90%. A fusion of green fluorescent protein and CYCLOIDEA (SsCYC), the Teosinte branched 1/Cincinnata/Proliferating cell factor transcription factor responsible for floral symmetry, was subcellularly localized inside the nuclei of the protoplasts. Transiently overexpressing SsCYC indicates the success of this system, which resulted in the predicted increased (but nonsignificant) expression of its known target RADIALIS (SsRAD1), consistent with gene network expectations. Conclusions The transient transfection system presented herein can be effectively used to study gene‐regulatory interactions in Gesneriaceae species.

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Adaptation via pleiotropy and linkage: Association mapping reveals a complex genetic architecture within the sticklebackEdalocus

et al. 2020

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Genomic mapping of the loci associated with phenotypic evolution has revealed genomic "hotspots," or regions of the genome that control multiple phenotypic traits. This clustering of loci has important implications for the speed and maintenance of adaptation and could be due to pleiotropic effects of a single mutation or tight genetic linkage of multiple causative mutations affecting different traits. The threespine stickleback (Gasterosteus aculeatus) is a powerful model for the study of adaptive evolution because the marine ecotype has repeatedly adapted to freshwater environments across the northern hemisphere in the last 12,000 years. Freshwater ecotypes have repeatedly fixed a 16 kilobase haplotype on chromosome IV that contains Ectodysplasin (Eda), a gene known to affect multiple traits, including defensive armor plates, lateral line sensory hair cells, and schooling behavior. Many additional traits have previously been mapped to a larger region of chromosome IV that encompasses the Eda freshwater haplotype. To identify which of these traits specifically map to this adaptive haplotype, we made crosses of rare marine fish heterozygous for the freshwater haplotype in an otherwise marine genetic background. Further, we performed fine-scale association mapping in a fully interbreeding, polymorphic population of freshwater stickleback to disentangle the effects of pleiotropy and linkage on the phenotypes affected by this haplotype. Although we find evidence that linked mutations have small effects on a few phenotypes, a small 1.4-kb region within the first intron of Eda has large effects on three phenotypic traits: lateral plate count, and both the number and patterning of the posterior lateral line neuromasts. Thus, the Eda haplotype is a hotspot of adaptation in stickleback due to both a small, pleiotropic region affecting multiple traits as well as multiple linked mutations affecting additional traits.

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Evolution of Darwin’s Peloric Gloxinia (Sinningia speciosa) Is Caused by a Null Mutation in a Pleiotropic TCP Gene

Cited by 20 publications

References 57 publications

Extensive phenotypic diversity in the cultivated Florist’s Gloxinia, Sinningia speciosa (Lodd.) Hiern, is derived from the domestication of a single founder population

Extensive phenotypic diversity in the cultivated Florist’s Gloxinia, Sinningia speciosa (Lodd.) Hiern, is derived from the domestication of a single founder population

Development of a petal protoplast transfection system for Sinningia speciosa

Adaptation via pleiotropy and linkage: Association mapping reveals a complex genetic architecture within the sticklebackEdalocus

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