Genotype and phenotype variability of BC1F1 progenies from backcross of C3 and Koshihikari

Improvement of local rice variety could be conducted by crossing it with superior varieties. C3 is improved line of Acehnese rice ‘Cantik Manis’ by crossing it with the introduced Chinese rice variety Yin Zhan to make their progenies have shorter lifespan and good productivity. Although C3 line has been improved, this variety still has lifespan for about ± 135 days. Koshihikari is Japanese rice variety with its lifespan about 80-90 days. It is though that Koshihikari has various semidwarf gene such as sd-1 or other semidwarf genes. The strategy that can be used to decrease harvesting period of C3 is by crossing this variety with Koshihikari to insert semi-dwarf gene such as sd-1. The research was conducted to analyse the existing of sd-1 gen and phenotypic performance of their progenies specially in BC1F1. The seed of BC1F1 were found by crossing 2 prospective F1 plants (T8 and T10) with C3 parent. Molecular analysis showed that the whole progenies BC1F1-T8 inherit sd-1 gene (100%). Phenotypic observation showed the whole progenies had similar architecture as their parents with average heights at 45 DAP ranged from 74-91 cm, and number of tiller range from 3-9 tillers. Whereas in BC1F1-T10 progenies, there were 11 plant from 12 plants inherit sd-1 gene (91.7%). These progenies had average heights at 45 DAP ranged from 75-88 cm, and number of tiller range from 6-13 tillers.

Identifying mutations in sd1, Pi54 and Pi-ta, and positively selected genes of TN1, the first semidwarf rice in Green Revolution

Background: Taichung Native 1 (TN1) is the first semidwarf rice cultivar that initiated the Green Revolution. As TN1 is a direct descendant of the Dee-geo-woo-gen cultivar, the source of the sd1 semidwarf gene, the sd1 gene can be defined through TN1. Also, TN1 is susceptible to the blast disease and is described as being drought-tolerant. However, genes related to these characteristics of TN1 are unknown. Our aim was to identify and characterize TN1 genes related to these traits. Results: Aligning the sd1 of TN1 to Nipponbare sd1, we found a 382-bp deletion including a frameshift mutation. Sanger sequencing validated this deleted region in sd1, and we proposed a model of the sd1 gene that corrects errors in the literature. We also predicted the blast disease resistant (R) genes of TN1. Orthologues of the R genes in Tetep, a well-known resistant cultivar that is commonly used as a donor for breeding new blast resistant cultivars, were then sought in TN1, and if they were present, we looked for mutations. The absence of Pi54, a well-known R gene, in TN1 partially explains why TN1 is more susceptible to blast than Tetep. We also scanned the TN1 genome using the PosiGene software and identified 11 genes deemed to have undergone positive selection. Some of them are associated with drought-resistance and stress response. Conclusions: We have redefined the deletion of the sd1 gene in TN1, a direct descendant of the Dee-geo-woo-gen cultivar, and have corrected some literature errors. Moreover, we have identified blast resistant genes and positively selected genes, including genes that characterize TN1's blast susceptibility and abiotic stress response. These new findings increase the potential of using TN1 to breed new rice cultivars.

Semidwarf Gene d60 Affected by Ubiquitous Gamete Lethal Gene gal Produced Rare Double Dwarf with d30 via Recombination Breaking Repulsion-Phase Linkage on Rice Chromosome 2

The genotype of gal and d60 were investigated in 33 rice varieties chosen from representative semidwarf and dwarf rice varieties. These were crossed with three tester lines, the d60Gal line (genotype d60d60GalGal), the D60gal line (Koshihikari, D60D60galgal), and the D60Gal line (D60D60GalGal). Each F1 plant was measured for culm length, and seed fertility. As a result, all F1 lines with the d60Gal line showed tallness and partial sterility, reduced by 25% in average from those with the D60gal line (Koshihikari) and the D60Gal line. These data indicated that the genotype of the 33 varieties is D60D60galgal and that the d60 locus is not allelic to those of sd1, d1, d2, d6, d18k, d29, d30, d35, d49, d50, and qCL1 involved in the 33 varieties. In addition, the gal gene is not complementarily activated with the semidwarf and dwarf genes described above, other than d60. The Gal gene will be ubiquitously distributed in rice. It is emphasized that Gal is a rare and valuable mutant gene essential to the transmission of d60. The double dwarf genotype of homozygous d30d60 was rarely gained in the F3 of the d30 line × d60 line by breaking their repulsion d60-D30 linkage on chromosome 2.

Combining two semidwarfing genes d60 and sd1 for reduced height in ‘Minihikari’, a new rice germplasm in the ‘Koshihikari’ genetic background

SummaryDwarfing in rice has dramatically improved and stabilized rice yields worldwide, often controlled by a single dwarf gene, sd1. A novel semidwarf gene d60 complements the gametic lethal gene gal, such that the F1 between ‘Hokuriku 100’ (genotype d60d60GalGal, Gal: mutant non-lethal allele) and ‘Koshihikari’ (D60D60galgal, D60: tall allele) would show 25% sterility due to deterioration of gametes bearing both gal and d60. The F2 would segregate as one semidwarf (1 d60d60GalGal) : two tall and 25% sterile (2 D60d60Galgal) : six tall (2 D60d60GalGal : 1 D60D60GalGal : 2 D60D60Galgal : 1 D60D60galgal), skewed from a Mendelian segregation ratio of one semidwarf : three tall for a single recessive gene. To pyramid d60 and sd1, into the Japanese super-variety ‘Koshihikari’, the F1 (D60d60Galgal) of ‘Koshihikari’ × ‘Hokuriku 100’ was first backcrossed with ‘Koshihikari’, and the BCF1 segregated into a ratio of one tall and 25% sterile (D60d60Galgal) : two tall (1 D60D60Galgal : 1 D60D60galgal). Tall, 25% sterile BC1F1 plants (D60d60Galgal) were then selected for pollen sterility and backcrossed with ‘Koshihikari’ as the recurrent parent. It is unnecessary to grow out and select a semidwarf from the BCnF2 if a pollen parent with ∼70% pollen fertility is chosen from the BCnF1 to backcross with the recurrent parent. Semidwarfing genes d60 and sd1 were successfully pyramided into the ‘Koshihikari’ genome by crossing isogenic lines ‘Koshihikari d60’ and ‘Koshihikari sd1’, to produce ‘Minihikari’, a new parental source of both d60 and sd1. ‘Minihikari’ displayed super-short stature due to the combination of sd1 and d60, which are genetically and functionally independent.