A loss-of-function allele of a TAC1-like gene (SlTAC1) located on tomato chromosome 10 is a candidate for the Erectoid leaf (Erl) mutation

The genetic basis of an erectoid leaf phenotype was investigated in distinct tomato breeding populations, including one derived from Solanum lycopersicum ‘LT05’ (with the erectoid leaf phenotype and uniform ripening, genotype uu ) ×  S. pimpinellifollium ‘TO-937’ (with the wild-type leaf phenotype a...

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Bibliographic Details
Published in:Euphytica 2019-05, Vol.215 (5), p.1-16, Article 95
Main Authors: González-Arcos, Matías, de Noronha Fonseca, Maria Esther, Zandonadi, Daniel Basílio, Peres, Lázaro E. P., Arruabarrena, Ana, Ferreira, Demetryus S., Kevei, Zoltan, Mohareb, Fady, Thompson, Andrew J., Boiteux, Leonardo S.
Format: Article
Language:English
Subjects:
Alleles
Amino acids
Biomedical and Life Sciences
Biotechnology
Breeding
Chromosome 10
Construction
Gene polymorphism
Gene sequencing
Genomes
Genomic analysis
Genotype & phenotype
Glutamine
Leaves
Life Sciences
Mutation
Phenotypes
Plant Genetics and Genomics
Plant Pathology
Plant Physiology
Plant Sciences
Polymorphism
Proteins
Recombinants
Ripening
Single-nucleotide polymorphism
Solanum lycopersicum
Tomatoes
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Summary:The genetic basis of an erectoid leaf phenotype was investigated in distinct tomato breeding populations, including one derived from Solanum lycopersicum ‘LT05’ (with the erectoid leaf phenotype and uniform ripening, genotype uu ) ×  S. pimpinellifollium ‘TO-937’ (with the wild-type leaf phenotype and green fruit shoulder, genotype UU ). The erectoid leaf phenotype was inherited as a semi-dominant trait and it co-segregated with the u allele of gene SlGLK2 ( Solyc10g008160 ). This genomic location coincides with a previously described semi-dominant mutation named as Erectoid leaf ( Erl ). The genomes of ‘LT05’, ‘TO-937’, and three other unrelated accessions (with the wild-type Erl + allele) were resequenced with the aim of identifying candidate genes. Comparative genomic analyses, including the reference genome ‘Heinz 1706’ ( Erl + allele), identified an Erectoid leaf -specific single nucleotide polymorphism (SNP) in the gene Solyc10g009320 . This SNP caused a change of a glutamine codon (present in all the wild-type genomes) to a TAA (= ochre stop-codon) in the Erl allele, resulting in a smaller version of the predicted mutant protein (221 vs. 279 amino acids). Solyc10g009320 , previously annotated as an ‘unknown protein’, was identified as a TILLER ANGLE CONTROL1 -like gene. Linkage between the Erl and Solyc10g009320 was confirmed via Sanger sequencing of the PCR amplicons of the two variant alleles. No recombinants were detected in 265 F 2 individuals. Contrasting S 7 near-isogenic lines were also homozygous for each of the alternate alleles, reinforcing Solyc10g009320 as a strong Erl candidate gene and opening the possibility for fine-tuning manipulation of tomato architecture in breeding programs.
ISSN:0014-2336
1573-5060
DOI:10.1007/s10681-019-2418-1