Basal Area, Soil, and Elevation Factors Affecting The Essential Oils Yield, Geranyl Acetate, and D-Limonene of Zanthoxylum acanthopodium
DOI:
https://doi.org/10.48048/tis.2024.8221Keywords:
Andaliman, Aromatic plant, Stem diameter, Nutrients, Altitude, Plsrglm, ClayAbstract
Andaliman (Z. acanthopodium) is an aromatic Non-Timber Forest Product (NTFP) plant species that contains essential oils (EOs), which have various benefits for cuisine, medicine, and cosmetics. This study is essential because it is not yet known what biotic factors (basal area) and abiotic factors (soil and elevation) influence the EOs yield, geranyl acetate, and D-limonene as skin anti-aging. This study investigated whether the basal area, soil, and elevation factors influence the EOs yield, geranyl acetate, and D-limonene content of Andaliman fruit. The biotic and abiotic factors were measured from 9 sample plots representing the Andaliman habitats in North Sumatra, Indonesia. A vegetation analysis was conducted to derive the Andaliman basal area of each sample plot. Soil samples were taken randomly in each plot and analyzed for their physicochemical (pH, C, SOM, N, CNR, P, K, Ca, Mg, CEC, BS, SA, DU, CL, WC, and BD) contents. Elevation gradients were measured on each plot. The EOs of Andaliman fruit include yield, geranyl acetate, and D-limonene as skin anti-aging. The data were analyzed using Partial Least Square Regression for Generalized Linear Models (PlsRglm) to determine which biotic and abiotic factors influenced the EOs yield, geranyl acetate, and D-limonene. This study confirmed that clay soil texture was the main factor influencing EOs of Andaliman fruit yield, geranyl acetate, and D-limonene. Apart from soil factors, basal area, and elevation factors were also essential to consider when cultivating Andaliman fruit as a source of skin anti-aging substances.
HIGHLIGHTS
- To the best of the authors’s knowledge, the first study in Indonesia 2024 that integrated biotic and abiotic factors affecting the essential oils (EOs) yield, geranyl acetate and D-limonene contents derived from of acanthopodium fruit as skin anti-aging substance.
- Using Partial Least Square Regression for Generalized Linear Models (PlsRglm) method for analyzing basal area, soil factors and elevation that influence the EOs of acanthopodium fruit.
- Of all the abiotic and biotic factors studied, Clay soil texture is the most critical factor that influences acanthopodium fruit EOs as skin anti-aging substances. Basal area and elevation are also essential factors in the cultivation of aromatic Andaliman plants.
GRAPHICAL ABSTRACT
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References
DI Junaedi and Y Nurlaeni. Ecology of Zanthoxylum acanthopodium: Spesific leaf area and habitat characteristics. Biodiversitas J. Biol. Divers. 2019; 20, 732-7.
TG Hartley. A revision of the Malesian species of Zanthoxylum (Rutaceae). J. Arnold Arboretum 1966; 47, 171-221.
E Kintamani, I Batubara, C Kusmana, T Tiryana, E Mirmanto and F Awaluddin. Potensi minyak atsiri daun Andaliman (Zanthoxylum acanthopodium) sebagai antiSARS-Cov-2 berdasarkan penambatan molekul (in Indonesian). Berita Biologi 2022; 21, 167-78.
Y Nurlaeni, J Iskandar and DI Junaedi. Ethnoecology of Zanthoxylum acanthopodium by local communities around Lake Toba, North Sumatra, Indonesia. Biodiversitas J. Biol. Divers. 2021; 22, 1806-18.
G Pasaribu, I Winarni, REP Gusti, R Maharani, A Fernandes, AH Harianja, GS Saragih, M Turjaman, AP Tampubolon, H Kuspradini, G Lukmandaru, GN Njurumana, A Sukito, A Aswandi and CR Kholibrina. Current challenges and prospocts of Indonesian non-timber forest products (NTFPs): A review. Forests 2021; 12, 1743.
M Turjaman and A Hidayat. Agarwood-planted tree inventory in Indonesia. In: Proceedings of the IOP Conference Series: Earth and Environmental Science, Prague, Czech Republic. 2017.
HH Rachmat, A Susilowati, D Elfiati, KS Hartini and WN Faradillah. Strong genetic differentiation of the endemic rosin producing tree Styrax sumatrana (Styracaceae) in North Sumatra, Indonesia. Biodiversitas J. Biol. Divers. 2017; 18, 1331-5.
S Darmokusumo, AA Nugroho, EU Botu, A Jehamat and M Benggu. Upaya memperluas kawasan ekonomis cendana di Nusa Tenggara Timur (in Indonesian). Berita Biol. 2001; 5, 509-14.
P Perhutani. 4.0+: Connecting through connectivity. Perum Perhutani, Jakarta, Indonesia, 2019.
CH Wijaya. Isolation and identification of trigeminally active compound of Andaliman (Zanthoxylum acanthopodium DC.). Hayati 2000; 7, 91-5.
CH Wijaya, FI Napitupulu, V Karnady and S Indariani. A review of the bioactivity and flavor properties of the exotic spice “Andaliman” (Zanthoxylum acanthopodium DC.). Food Rev. Int. 2019; 35, 1-19.
K Chen, L Xue, Q Li, Y Li, Y Mao, S Fan, L Zhang and L Zhao. Quantitative structure-pungency landscape of sanshool dietary components from Zanthoxylum species. Food Chem. 2021; 363, 130286.
J Luo, J Ke, X Hou, S Li, Q Luo, H Wu, G Shen and Z Zhang. Composition, structure and flavour mechanism of numbing substances in Chinese prickly ash in the genus Zanthoxylum: A review. Food Chem. 2022; 373, 131454.
S Deng, H Rong, H Tu, B Zheng, X Mu, L Zhu, X Zhou, W Peng, M Wu, E Zhang, X Li and H Shen. Molecular basis of neurophysiological and antioxidant roles of Szechuan pepper. Biomed. Pharmacother. 2019; 112, 108696.
MT Sibero, AP Siswanto, R Murwani, EH Frederick, AP Wijaya, E Syafitri, K Farabi, S Saito and Y Igarashi. Antibacterial, cytotoxicity and metabolite profiling of crude methanolic extract from Andaliman (Zanthoxylum acanthopodium) fruit. Biodiversitas J. Biol. Divers. 2020; 21, 4147-54.
P Patriani and NL Apsari. Improving the physical quality of beef meatballs using andaliman spice (Zanthoxylum acanthopodium DC) on shelflife. IOP Conf. Ser. Earth Environ. Sci. 2022; 977, 012134.
EC Purba, M Silalahi and Nisyawati. Gastronomic ethnobiology of “terites” - a traditional Batak Karo medicinal food: A ruminant’s stomach content as a human food resource. J. Ethnic Foods 2018; 5, 114-20.
Y Nurlaeni, DI Junaedi and J Iskandar. Botany, morphology, ecology, cultivation, traditional utilization and conservation of Andaliman (Zanthoxylum acanthopodium) in North Sumatra, Indonesia. Nusantara Biosci. 2024; 16, 68-80.
Q He, W Wang and L Zhu. Larvicidal activity of Zanthoxylum acanthopodium essential oil against the malaria mosquitoes, Anopheles anthropophagus and Anopheles sinensis. Malaria J. 2018; 17, 194.
FI Napitupulu, S Sulistiyani, E Prangdimurti and CH Wijaya. Inhibition of colon cancer cells via apoptosis pathway by ethanolic extract of Andaliman (Zanthoxylum acanthopodium DC.) fruits. Curr. Res. Nutr. Food Sci. 2022; 10, 1046-57.
QF Fan, L Zhou, PC Gongpan, CL Lu, H Chang and X Xiang. Bioactivity-guided high performance counter-current chromatography and following semi-preparative liquid chromatography method for rapid isolation of anti-inflammatory lignins from dai medicinal plant, Zanthoxylum acanthopodium var.timbor. Molecules 2023; 28, 2592.
CH Wijaya, IT Hadiprodjo and A Apriyantono. Identification of volatile compounds and key aroma compounds of Andaliman fruit (Zanthoxylum acanthopodium DC.). Food Sci. Biotechnol. 2002; 11, 680-3.
D Satria, J Silalahi, G Haro, S Ilyas and PAZ Hasibuan. Chemical analysis and cytotoxic activity of N-Hexane fraction of Zanthoxylum acanthopodium DC fruits. Rasayan J. Chem. 2019; 12, 803-8.
M Moektiwardoyo, M Muchtaridi and E Halimah. Chemical composition and locomotor activity of Andaliman fruits (Zanthoxylum acanthopodium DC.) essential oil on mice. Int. J. Pharm. Pharmaceut. Sci. 2014; 6, 547-50.
E Kintamani, I Batubara, C Kusmana, T Tiryana, E Mirmanto and SF Asoka. Essential oil compounds of Andaliman (Zanthoxylum acanthopodium DC.) fruit varieties and their utilization as skin anti-aging using molecular docking. Life 2023; 13, 754.
A Simorangkir. 2019, Analisis preferensi konsumen terhadap Andaliman (Zanthoxylum acanthopodium DC.) (Kasus: Konsumen pada beberapa pasar outlet Andaliman di Kota Medan) (in Indonesian). Undergraduate Paper. Universitas Sumatera Utara, Medan, Indonesia.
T Harsono, AS Kurniawan, H Prakasa, D Syahfitri, F Husna and E Prasetya. Analisis spasial geografi dan maximum entropy untuk menentukan zona konservasi in situ pada Andaliman (Zanthoxylum acanthopodium DC.) di Sumatera Utara (in Indonesian). In: Proceedings of the Seminar Nasional Perhimpunan Pemuliaan Indonesia (PERIPI) Komda Riau, Pekanbaru, Indonesia. 2016, p. 224-32.
C Suriani, E Prasetya, T Harsono and D Handayani. Habitat characteristics of Andaliman (Zanthoxylum acanthopodium DC.) in North Sumatra using a GIS (Geographical Information System) approach. J. Phys. Conf. Ser. 2019; 1317, 012097.
L Siahaan, I Hilwan and Y Setiawan. Spatial distribution of Andaliman potential habitat (Zanthoxylum acanthopodium DC.) in Samosir Island, North Sumatra. J. Nat. Resour. Environ. Manag. 2019; 9, 861-71.
BL Siregar. Budidaya tanaman Andaliman (Zanthoxylum acanthopodium DC.) di Desa Linggaraja II, Kabupaten Dairi (in Indonesian). Jurnal Methodagro 2022; 8, 126-36.
JJ Martinez, V Millien, I Simone and JW Priotto. Ecological preference between generalist and specialist rodents: Spatial and environmental correlates of phenotypic variation. Biol. J. Linnean Soc. 2014; 112, 180-203.
Y Nurlaeni and DI Junaedi. Studi ekologi habitat, teknik perbanyakan dan pengoleksian dalam rangka konservasi ex-situ Andaliman (Zanthoxylum acanthopodium DC.) (in Indonesian). Bioma 2018; 14, 79-88.
I Suwandhi, C Kusmana, A Suryani and T Tiryana. Rendemen dan komposisi minyak atsiri daun Kilemo (Litsea cubeba) dari gunung Papandayan, kaitannya dengan variasi tipe dan faktor-faktor habitat (in Indonesian). Jurnal Teknologi Industri Pertanian 2014; 24, 200-8.
N Phuyal, PK Jha, PP Raturi, S Gurung and S Rajbhandary. Essential oil composition of Zanthoxylum armatum leaves as a function of growing conditions. Int. J. Food Properties 2019; 22, 1873-85.
T Gschwantner, I Alberdi, A Balázs, S Bauwens, S Bender, D Borota, M Bosela, O Bouriaud, I Cañellas, J Donis, A Freudenschuß, JC Hervé , D Hladnik, J Jansons, L Kolozs, K T Korhonen, M Kucera, G Kulbokas, A Kuliešis, A Lanz, …, J Zell. Harmonisation of stem volume estimates in European national forest inventories. Ann. Forest Sci. 2019; 76, 24.
S Vospernik. Basal area increment models accounting for climate and mixture for Austrian tree species. Forest Ecol. Manag. 2021; 480, 118725.
M Wiesmeier, L Urbanski, E Hobley, B Lang, M von Lutzow, E Marin-Spiotta, B van Wesemael, E Rabot, M Ließ, NG Franco, U Wollschläger, HJ Vogel and IK Knabner. Soil organic carbon storage as a key function of soils-a review of drivers and indicators at various scales. Geoderma 2019; 333, 149-62.
A Chrysargyris, M Mikallou, S Petropoulos and N Tzortzakis. Profiling of essential oils components and polyphenols for their antioxidant activity of medical and aromatic plants grown in different environmental conditions. Agronomy 2020; 10, 727.
X Feng, W Zhang, W Wu, R Bai, S Kuang, B Shi and D Li. Chemical composition and diversity of the essential oils of Juniperus rigida along the elevations in Helan and Changbai Mountains and correlation with the soil characteristics. Ind. Crops Prod. 2021; 159, 113032.
S Sharma, K Arunachalam and P Phondani. Variation in yield and composition of Perilla frutescens essential oil across altitudinal gradients in the Indian himalayan region. Iranian J. Sci. Tech. Trans. A Sci. 2017; 43, 369-78.
A Chrysargyris, E Evangelides and N Tzortzakis. Seasonal variation of antioxidant capacity, phenols minerals and essential oil components of Sage, Spearmint and Sideritis plants grown at different altitudes. Agronomy 2021; 11, 1766.
Z Reaisi, M Yadegari and HA Shirmardia. Effects of phenological stage and elevation on phytochemical characteristics of essential oil of Teucrium polium L. and Teucrium orientale L. Int. J. Horticultural Sci. Tech. 2019; 6, 89-99.
A Stritih, P Bebi, C Rossi and AG Regamey. Addressing disturbance risk to mountain forest ecosystem services. J. Environ. Manag. 2021; 296, 113188.
S Klar and TJ Leeper. Identities and intersectionality: A case for purposive sampling in survey-experimental research. In: PJ Lavrakas, MW Traugott, C Kennedy, AL Holbrook, ED de Leeuw and BT West (Eds.). Experimental methods in survey research: Techniques that combine random sampling with random assignment. 1st ed. John Wiley & Sons, New Jersey, 2019, p. 419-33.
Rosmarlinasiah, DR Utami and AR Rahim. LEDA (Eucalyptus deglupta Blume) increment on various dimensions of growth. J. Adv. Zool. 2023; 44, 166.
Royal Botanic Garden Edinburgh. Guide to collecting herbarium specimens in the field. Royal Botanic Garden Edinburgh, Edinburgh, Scotland, 2017.
S Hauser, K Saito and M Pulleman. Soil sampling (disturbed and undisturbed), handling and storage for soil chemical, biological and physical properties, v1. Standard Operating Procedure 003. In: K Saito, JM Johnson, S Hauser, M Corbeels, M Devkota and M Casimero (Eds.). Guideline for measuring agronomic gain key performance indicators in on-farm trials, v. 1. excellence in agronomy for sustainable intensification and climate change adaptation initiative. CGIAR Center, Montpellier, France, 2023.
E Baidoo, JH Ephraim, G Darko and O Akoto. Potentiometric studies of the acid-base properties of tropical humic acids. Geoderma 2014; 217-218, 18-25.
Eviati and Sulaeman. Analisis kimia tanah, tanaman, air dan pupuk (in Indonesian). Balai Penelitian Tanah, Bogor, Indonesia, 2009.
Indriyanto. Ekologi hutan. Penerbit Bumi Aksara, Jakarta, Indonesia, 2006.
F Bertrand, M Maumy-Bertrand and N Meyer. PlsRglm: Regression PLS et medeles lineaires generalizes sous R. 42èmes Journées de Statistique, Marseille, France, 2010.
R Vera-Velez, SA Grover, BK Bischoff, CN Carlyle and EG Lamb. Wildlife-grazing impact on forage quality assessed with near-infrared spectroscopy and generalized partial least square regression. Rangeland Ecol. Manag. 2023; 87, 132-40.
plsRglm. Partial least squares regression for generalized linear models, Available at: https://www.google.com/url?sa=t&source=web&rct=j95,&opi=89978449&url=https://cran.r-project.org/package%3DplsRglm&ved=2ahUKEwjYrdTm4OOFAxWzT2wGHQgRCAgQFnoECBIQAQ&usg=AOvVaw2gteERHiqch_2cOZnryVNu, accessed April 2024.
AK Salam. Ilmu tanah. Global Madani Press, Bandar Lampung, Indonesia, 2020.
V Vaiciulyte, K Loziene, R Taraskevicius and R Butkiene. Variation of essential oil composition of Thymus pulegioides in relation to soil chemistry. Ind. Crops Prod. 2017; 95, 422-33.
R Verpoorte, R van der Heijden and J Memelink. Engineering the plant cell factory for secondary metabolite production. Transgenic Res. 2000; 9, 323-43.
A Kurniawan, W Rahayu and R Wahyuningrum. Perbandingan kadar eugenol minyak atsiri daun cengkeh (Syzygium aromaticum (L). Merr &Perry) yang tumbuh di dataran tinggi dan dataran rendah (in Indonesian). Pharmacy 2009; 06, 83-93.
R Sagar and JS Singh. Tree density, basal area and species diversity in a disturbed dry tropical forest of Northern India: Implications for conservation. Environ. Conservat. 2006; 33, 256-62.
JWF Slik, SI Aiba, FQ Brearley, CH Cannon, O Forshed, K Kitayama, H Nagamasu, R Nilus, J Payne, G Paoli, AD Poulsen, N Raes, D Sheil, K Sidiyasa, E Suzuki and JLCH van Valkenburg. Environmental correlates of tree biomass, basal area, wood specific gravity and stem density gradients in Borneo’s tropical forests. Global Ecol. Biogeogr. 2010; 19, 50-60.
EA Honda, NAL Pilon and G Durigan. The relationship between plant density and survival to water strees in seedlings of a legume tree. Acta Bot. Brasilica 2019; 33, 602-6.
KA Khalid. Influence of water stress on growth, essential oil and chemical composition of herbs (Ocimum sp.). Int. Agrophys. 2006; 20, 289-96.
M Kulak. Recurrent drought stress effects on essential oil profile of lamiaceae plants: An approach regarding stress memory. Ind. Crops Prod. 2020; 154, 112695.
RM Ubom, FO Ogbemudia and KO Benson. Soil-vegetation relationship in fresh water swamp forest. Sci. J. Biol. Sci. 2012; 1, 43-51.
CR Kholibrina and A Aswandi. The ethnobotany and ethnomedicine of Zanthoxylum acanthopodium in Lake Toba, North Sumatra, Indonesia. Jurnal Lahan Suboptimal 2021; 10, 78-90.
C Dordas. Foliar application of calcium and magnesium improves growth, yield, and essential oil yield of oregano (Origanum vulgare ssp.hirtum). Ind. Crops. Prod. 2009; 29, 599-608.
VLR Pullagurala, S Rawat, IO Adisa, JA Hernandez-Viezcas, JR Peralta-Videa and JL Gardea-Torresdey. Plant uptake and translocation of contaminants of emerging concern in soil. Sci. Total Environ. 2018; 636, 1585-96.
Y Li, J Ma, C Xiao and Y Li. Effects of climate factors and soil properties on soil nutrients and elemental stoichiometry across the Huang-Huai-Hai river basin, China. J. Soils Sediment. 2020; 20, 1970-82.
A Rawal, S Chakraborty, B Li, K Lewis, M Godoy, L Paulette and DC Weindorf. Determination of base saturation percentage in agricultural soils via pertable X-ray fluorescence spectrometer. Geoderma 2019; 338, 375-82.
A Yavari, V Nazeri, F Sefidkon and ME Hassani. Influence of some environmental factors on the essential oil variability of Thymus migricus. Nat. Prod. Comm. 2010; 5, 943-8.
J Torras, MD Grau, JF Lopez and FXC Heras. Analysis of essential oils from chemotypes of Thymus vulgaris in Catalonia. J. Sci. Food. Agr. 2007; 87, 2327-33.
AP Rueda, LC Martinez, GDS Rolim, RP Coelho, MH Santos, WDS Tavarez, JC Zanuncio and JE Serrão. Insecticidal and repellent activities of Cymbopogon citratus (Poaceae) essential oil and its terpeniods (citral and geranyl acetate) against Ulomoides dermestoides. Crop Protect. 2020; 137, 105299.
EE Aziz, MS Hussein, HE Wahba and AM Razin. Essential oil constituents of Dracocephalum moldavica L. grown under salt stress and different sources of soil amendment. Middle East J. Sci. Res. 2013; 16, 706-13.
MJ Goncalves, MT Cruz, AC Tavares, C Cavaleiro, MC Lopes, J Canhoto and L Salgueiro. Composition and biological activity of the essential oil from Thapsia minor, a new source of geranyl acetate. Ind. Crops Prod. 2012; 35, 166-71.
P Anandakumar, S Kamaraj and MK Vanitha. D-limonene: A multifunctional compound with potent therapeutic effects. J. Food Biochem. 2020; 45, e13566.
H Amiri, B Dousty and SR Hosseinzedeh. Water stress-induced changes of morphological, physiological and essential oil compounds in Thymus eriolaclyx from Iran. J. Essent. Oil Bearing Plants 2018; 21, 1210-23.
Y Yang, J Fang, Y Tang, C Ji, C Zheng and J He. Storage, patterns and control of soil organic in the Tibetan grasslands. Global Change Biol. 2008; 14, 1592-9.
K Khan and RK Verma. Essential oil bearing aromatic plants: Their potential for sequestering carbon in marginal soil of India. Soil Use Manag. 2020; 36, 565-70.
MF Cotrufo and JM Lavallee. Soil organic matter formation, persistence, and functioning: A synthesis of current understanding to inform its conservation and regeneration. Adv. Agron. 2022; 172, 1-66.
S Heidari, M Azizi, F Soltani and J Hadian. Foliar application of Ca (NO3)2 and KNO3 affects growth, essential oil content, and oil composition of Frech tarragon. Ind. Crops Prod. 2014; 62, 526-32.
AO Tursun. Impact of soil types on chemical composition of essential oil of purple basil. Saudi J. Biol. Sci. 2022; 29, 103314.
PR Chaudhari, DV Ahire, VD Ahire, M Chkravarty and S Maity. Soil bulk density as related to soil texture, organic matter content and available total nutrients of Coimbatore soil. Int. J. Sci. Res. Publ. 2013; 3, 1-7.
T HaiLong, G Wei, W JingYan, L XiaoMei, X Jing, Z LongDi and H YangXia. Effects of different N, P and K ratios on yield and quality of Zanthoxylum armatum. J. Northwest A F Univ. Nat. Sci. Ed. 2019; 47, 18-26.
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