Pogostemon cablin, an oil-producing plant, proceeded vegetative propagation due to limited natural pollination, leading to lower genetic variations. The presented study investigated the morphological diversity and productivity, specifically the ninth mutant vegetative (MV9) generation resulting from polyploid mutation induced by colchicine in the P. cablin var. Sidikalang. The study transpired between August 2022 and April 2023 at the Tissue Culture Laboratory, the Cikabayan Experimental Station, IPB University, Bogor, Indonesia. The experiment had a randomized complete block design (RCBD) arrangement with eight genotypes, including control as the single factor and three replications. Various characteristic measurements included essential oil yield growth and potential. The findings revealed that aneuploid mutants exhibited more leaves, primary, and secondary branches than the control plants and polyploid mutants (P < 0.05). Polyploid mutants (tetraploid and mixoploid) displayed longer and broader leaves, larger leaf surfaces, thicker leaves, and greater stem diameter (P < 0.05). Accumulation of leaves, primary, and secondary branches caused an increase in the patchouli plant’s fresh weight. Patchouli oil production per hectare indicated a correlation to leaf number (r = 0.48), primary branches (r = 0.41), secondary branches (r = 0.48), and essential oil yield (r = 0.87). The study also revealed the considerable genetic diversity among the patchouli mutants, paving the way to develop promising new plant lines, specifically to obtain superior patchouli with the highest biomass and oil.
aneuploidy, colchicine, growth and essential oil traits, patchouli, polyploidy
The patchouli (P. cablin) polyploid plants produced longer, broader, and larger leaves with bigger stem diameters. However, the aneuploid plants produced smaller but numerous leaves. Mutant lines emerged to have potential with higher biomass and patchouli oil.