Tuber as one of the vegetative organs of plants, can be utilized as a complementary food or a substitute for rice. Tuber productivity depends on the amount and rate of assimilation, so growth regulators are needed that can increase the productivity of tuberous plants, such as paclobutrazol. Paclobutrazol is a growth regulator that has a major role in inhibiting the vegetative phase of plants. Paclobutrazol will inhibit the rate of gibberellin biosynthesis thus inhibiting plant height growth. Paclobutrazol, containing triazoles, boosts cytokinin biosynthesis, supporting chloroplast separation and chlorophyll biosynthesis whereas anticipating debasement. This comes about in delayed photosynthetic action, expanding acclimatize aggregation for tuber arrangement. At ideal measurements, paclobutrazol keeps up shoot biomass, chlorophyll substance, morphogenesis, photosynthetic capacity, and phytohormone adjust, driving to physiological and morphological changes in plants.

accumulation, biosynthesis, photosynthesis, retardants

Acquaah, G. (2002). Plant Physiology Second Edition. Pearson Education Inc, New Jersey.

Anjum, S.A., Wang, L.C., Farooq, M., Hussain, M., Xue, L.L., & Zou, C.M. (2011). Brassinolide application improves the drought tolerance in maize through modulation of enzymatic antioxidants and leaf gas exchange. J Agron Crop Sci, 197. 177–185.

Ardian, Aritonang, P., & Setiawan, K. (2019). Effect of application of several concentrations of paclobutrazol and koh on growth and production of cassava (Manihot esculenta Crantz). Jurnal Penelitian Pertanian Terapan, 19 (3): 199-207.

Arianti, Y.S., & Harinta, Y.W. (2021). Sweet potatoes: Development and potential as alternative food ingredients in Karanganyar Regency, Indonesia. E3S Web of Conferences ICoN BRAT, 1-6.

Asra, R., Samarlina, R.A., & Silalahi, M. Hormon Tumbuhan. UKI Press, Jakarta.

Assuero, S.G., Lorenzo, M., Ramirez, N.M.P, Velazquez, L.M., & Tognetti J. A. (2012). Tillering promotion by paklobutrazol in wheat and its relationship with plant carbohydrate status. New Zeal J Agric Res, 55(4):347–358.

Bandumula, N. (2014). Rice production in Asia: Key to global food security. Proceedings of the National Academy of Sciences, India Section B. ICAR-Indian Institute of Rice Research, Hyderabad 500030, India. 1-6.

Cokrowati, N., & Diniarti, N. (2019). Components of Sargassum aquifolium as growth-inducing hormones for Eucheuma cottonii. Jurnal Biologi Tropis, 19(2):316-321.

Davis, T., & Curry, E. (1991). Chemical regulation of vegetative growth. Critical Review in Plant Science, 10:204–16.

Desta, B., & Amare, G. (2021). Paclobutrazol as a plant growth regulator. Chem Biol Technol Agric, 8(1):1–15.

Dewi, K. D. (2018). Effect of paclobutrazol and cytokinin on growth and source-sink relationship during grain filling of black rice (Oryza sativa L. “Cempo Ireng”). Indian J Plant Physiol, 23(3):507–515.

Elizani, P., & Sulistyaningsih, E. (2019). The correlation and regression analysis of the growth and physiological parameters: how paklobutrazol increases bulb yield on three cultivars of true shallot seed. J Sustain Agric, 34(2):128-139.

Estiasih, T., Putri, W.D.R., & Waziiroh, E. (2017). Tubers and their processing. Brawijaya University Press, Indonesia.

Ewing, E.E., & Struik, P.C. (2010). Tuber formation in potato: Induction, initiation and growth, horticultural Reviews. Horticultural Reviews, 14(3):89-198.

Falcon, M.R., Bou, J., & Prat, S. (2006). Seasonal control of tuberization in potato: Conserved elements with the flowering response. Annu Rev Plant Biol, 57:151– 180.

Firdaus, L.N., Sri, W., & Yusnida B. (2006). Plant Physiology. University Education Development Centre, Pekan Baru Riau.

Hamdani, J.S., Sumadi, Suriadinata, Y.R., & Martins, L. (2016). Effects of shading and plant growth regulator on growth and yield of potato atlantik cultivar planted in medium altitude. J Agron Indones, 44(1):33-39.

Hidayah, S.N., Hidayat, R., & Triani, N. (2022). Study of paclobutrazol dosage and seed size on growth and yield of porang (Amorphophallus onchophyllus P.). JTEP-L, 11(4):574-588.

Husen, S., Purnomo, A.E., Wedyan, M.A., Susilowati, E., & Nurfitriani, R. 92024). Optimization of Potato Cuttings of Granola Kembang Cultivars with the Application of Auxin and Paclobutrazol for Tuber Production. BIO Web of Conferences 104, 00045 3rd ICoN-BEAT 2022 and 4th ICoN-BEAT, 1-8.

Karmelia, N., & Sunaryo, W.T. (2018). Application of paclobutrazol to growth and yield of three potato varieties (Solanum tuberosum L.) in medium altitude. Jurnal Produksi Tanaman, 6(9):2257–2263.

Kegley, S.E., Hill, B.R., Orme, S., & Choi, A.H. (2010). PAN pesticide database. Pesticide Action Network, North America, SanFrancisco.

Kishore, K., Singh, H.S., & Kurian, R.M. (2015). Paclobutrazol use in perennial fruit crops and its residual effects: A review. Indian J Agric Sci, 85(7):863–872.

Kishorekumar, A., Jaleel, C.A., Manivannan, P., Sankar, B., Sridharan, R., Somasundaram, R., & Panneerselvam, R. (2006). Differential effects of hexaconazole and paclobutrazol on the foliage characteristics of Chinese potato (Solenostemon rotundifolius Poir., J.K. Morton). Acta Biologica Szegediensis,50(3-4):127-129.

Lende, M., Theresia, L.B., Maria, T.D., & Siprianus, R.T. (2020). Inventory of tubers and their utilization as substitutes for staple food in Waimangura Village, West Wewewa Sub-district, Southwest Sumba Regency. Jurnal Biotropikal Sains, 17(1):103–117.

Lestari, E.G. (2011). The role of growth regulators and plant propagation through tissue culture. Jurnal AgroBiogen, 7(1):63-68.

Lolaei, A., Mobasheri, S., Bemana, R., & Teymori, N. (2013). Role of paklobutrazol on vegetative and sexual growth of plants. J Agric, 5(9):958-961.

Neela, S., & Fanta, S.W. (2019). Review on nutritional composition of orange-fleshed sweet potato and its role in management of vitamin A deficiency. Food Sci Nutr, 7(6):1920–45.

Neviani, P., Santhanam, R., Trotta, R., Notari, M., Blaser, B.W., & Liu, S. (2005). The tumor suppressor PP2A is functionally inactivated in blast crisis CML through the inhibitory activity of the BCR/ABL regulated SET protein. Cancer Cell, 8:355-68.

Ni’mah, F., Ratnasari, E., & Budi, P.L.

(2014). Effect of various combinations of sucrose and kinetin concentrations on the induction of micro tuber of potato (Solanum tuberosum L.) cultivar granola kembang in vitro. Jurnal Lentera Bio, 1(1):41-48.

Novi, Rizki. (2017). Induction of flower expansion (anthesis) of white jasmine (Jasmine sambac L. W. Ait) plants with paclobutraol at several concentrations. Jurnal Pelangi, 7(1):120-125.

Nurmala, T., Ruminta, & Wahyudin, A. (2017). Growth and yield of jobs tears (Coix lacryma-jobi l.) ‘batu’ due to application of liquid silica fertilizer and paclobutrazo. Jurnal Kultivasi, 16(3): 474-481.

Parra, A.L., Yhebra, R.S., Sardinas, I.G., & Buela, L.I. (2001). Comparative study of the assay of Artemia salina L. and the estimate of the medium lethal dose (LD50 value) in mice, to determine oral acute toxicity of plant extracts. Phytomedicine, 8(5):395-400.

Ribeiro, N.P., Fernandes, A.M., da Silvia, R.M., Pelvine, R.A., & Assunção N,A. (2021). Growth and yield of sweet potato in response to the application of nitrogen rates and paclobutrazol. Soil and Plant Nutrition, 80(e3821):1-13.

Rice, R.P., Rice, L.W., & Tindall, H.D. (1990). Fruit and vegetable production in 129 warm climates. MacMillan Educational Crop, Hong Kong.

Runtunuwu, S.D., Sumampouw, D.M.F., Tumewu, P., Mamarimbing, R., & Rengkung, R.M.N. (2016). Respons of paclobutrazol on growth and yield of wesel local rice. Eugenia, 22(3):115–123.

Salisbury, F.B., & Ross, C.W. (1959). Plant Physiology Volume 3. ITB Press, Bandung.

Sambeka, F., Runtunuwu, S.D., & Rogi, J.E.X. (2012). Effectiveness of time application and concentration of paclobutrazol on growth and yield potato (Solanum tuberosum L.) varieties supejohn. Eugenia, 18(2):126-134.

Saputra, I., Nurbaiti, & Tabrani, G. (2017). The study of paclobutrazol and its application on different time to tomato (Lycopersicum esculentum Mill.). JOM Faperta UR, 4(1):1-14.

Sasvita, W., Hanum, C., & Purba, E. (2013). Growth and yield of three sweet potato clones at different plant spacings. Jurnal Online Agroekoteknologi, 2(1):462-473.

Singha, K., Choudhary, R., & Vishnu, K. (2014). Growth and diversification of horticulture crops in Karnataka: An inter-district analysis. SAGE Open, 1-12.

Soumya, P.R., Kumar, P., & Pal, M. (2017). Paclobutrazol: A novel plant growth regulator and multi-stress ameliorant. Indian J Plant Physiol, 22(3):267–278.

Suharjo, U.K.J., Hasanudin, H., Pamekas, T., Pujiwati, H., & Vanturini, A. (2019). Promoting tuber formation in vitro with benzyl amino purine and paclobutrazol at different concentrations. Akta Agrosia, 22(1):29–35.

Tjitrosoepomo, G. (2020). Plant Morphology. Gadjah Mada University Press, Yogyakarta.

Wang, W., Su, X., Tian, Z., Liu, Y., Zhou, Y., & He, M. (2018). Transcriptome profiling provides insights into dormancy release during cold storage of Lilium pumilum. BMC Genomics, 19:1–17.

Wattimena, G.W. (2006). The effect of paclobutrazol treatment on starch content, mycorrhiza colonization, and fine root density of white oaks (Quercus alba L.). Arboric, 32(3):114-117.

Wieland, C.L., & Wampe. (1988). Control of vegetative growth of stone fruits with paclobutrazol. HortScience, 23(3):467-470.

Zhang, D.Q., Mu, T.H., & Sun, H.N. (2016). Domestic and abroad research progress of potato tuber-specific storage protein patatin. Sci Agric Sin, 49:1746–1756.

Zheng, R., Wu, Y., & Xia, Y. (2012). Chlorocholine chloride and paclobutrazol treatments promote carbohydrate accumulation in bulbs of Lilium Oriental hybrids ‘Sorbonne’. Journal Zhejiang Univ-Sci B (Biomed Biotechnol), 13(2):136–144.