ABSTRACT: It has been reported that a number of small coding genes (30–100 amino acids) tend to be lineage-specifically emerged in evolution but such de-novo genes tend to be missed in genomes. Plant mitochondrial genomes might be fostering sources of de-novo genes because of a high rearrangement rate. However, the functional role of de-novo genes derived from mitochondria is unclear. Here, in the best model species of plants (Arabidopsis thaliana), we showed that Arabidopsis-specifically emerged de-novo genes derived from mitochondrial genome contributed to phenotypic variation in a species. We previously identified 49 candidates of small coding genes inducing abnormal morphological changes on overexpression in the nuclear genome. Among them, we focused on a candidate (sORF2146) potentially encoding 66 amino acids in large-scale intergenic genomic transferring region from mitochondrial genome. Comparative genome analysis showed that sORF2146 had been appeared in Arabidopsis lineage. Mitochondrial sORF2146 is fixed among A. thaliana ecotypes but nucleus sORF2146 is not fixed in A. thaliana ecotypes. After showing evidence that nucleus sORF2146 was transcribed and translated as a coding gene, we performed transcriptome analysis in transgenic plant overexpressing sORF2146. Genes associated with flowering transition are highly regulated in the transgenic plant. We then examined phenotypic effects of overexpression and knockdown transgenic plant. Overexpression and knockdown transgenic plant induce late and early flowering, respectively. Taken together, we conclude that a nucleus de-novo gene derived from mitochondria contributes to the variation of floral timing in Arabidopsis population.