Species composition and richness of viable seed bank after fire events in Mount Ciremai National Park and Kuningan Botanic Gardens, West Java, Indonesia

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INDRIANI EKASARI
RONGGO SADONO
DJOKO MARSONO
JOKO R. WITONO

Abstract

Abstract. Ekasari I, Sadono R, Marsono D, Witono JR. 2021. Species composition and richness of viable seed bank after fire events in Mount Ciremai National Park and Kuningan Botanic Gardens, West Java, Indonesia. Biodiversitas 22: 3437-3447. Forest fire is an environmental disaster that can decline ecosystem function and restoration efforts must be considered to restore forest ecosystems after fire events. Natural regeneration using existing soil seed banks is a promising approach in restoration due to its advantage in terms of minimizing cost. This study aimed to examine the species composition and richness of germinable seed banks in several post-fire sites in Mount Ciremai National Park (MNCP) and Kuningan Botanic Gardens (KGB), West Java, Indonesia. One hundred fifty-eight soil samples were collected from the study sites representing fire events (i.e., four post-fire sites and one non-fire site), and soil depths (i.e., upper, middle, and lower). The collection of soil samples and identification of seedlings emergence were conducted from September 2019 to February 2020. Data were analyzed using ANOVA and correspondence analysis using SPSS Version 22. In total, 4626 emergence seedlings were recorded, belonging to 158 species and 58 families in which 41 families in the upper soil layer, 35 families in the middle soil layer, and 33 families in the lower soil layer. The results showed that Poaceae, Asteraceae, and Euphorbiaceae as the most dominant families. The upper soil layer of post-fire site 2018 had the highest species richness (R=11.98), while the lower soil layer of post-fire site 2012 had the lowest species richness (R=2.64). Our findings suggest that when carrying out restoration activities in post-fire areas, it is preferable to use native species that do not compete with species persisted in soil seed banks.

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References
Akinyemi DS, Oseni SR, Oke SO. 2019. Effect of heat on soil seedbank of three contrasting physiognomies in Shasha forest reserve, Southwestern Nigeria. Acta Oecol 94(20): 22–30. doi: 10.1016/j.actao.2018.03.009.
Arizona, D. 2011. Etnobotany and potential useful plants in Mount Ciremai National Park, West Java. [Thesis]. Institut Pertanian Bogor, Bogor [Indonesian]
Benoit DL, Kenkel NC. Cavers PB. 1989. Factors influencing the precision of soil seed bank estimates. Can J Bot 67(10): 2833–2840. doi: 10.1139/b89-364.
Bogor Botanical Garden. 2016. Kebun Raya Kuningan. www.kebunrayadaerah.krbogor.lipi.go.id. [Indonesian]
BTNGC. 2010. Startegic plan for Mount Ciremai National Park for 2010-2014. Mount Ciremai National Park, Kuningan [Indonesian]
Chazdon RL. 2008. Beyond deforestation: Restoring forests and ecosystem services on degraded lands. Science 320(5882): 1458–1460. doi: 10.1126/science.1155365.
Chen W, Moriya K, Sakai T, Kayama L, Cao L. 2014. Post-fire forest regeneration under different restoration treatments in the Greater Hinggan Mountain area of China. Ecol Eng 70: 304–311. doi: 10.1016/j.ecoleng.2014.06.016.
Cubina A, Aide TM. 2010. The effect of distance from forest edge on seed rain and soil seed bank in a tropical pasture. Biotropica 33(2): 260–267.
Davari, N., Jouri, M. H. and Ariapour, A. 2011. Comparison of measurement indices of diversity, richness, dominance, and evenness in rangelands ecosystem. Case study: Jvaherdeh-Ramesar. J. of Range. Sci 2(1): 389–398.
Douh C, Dainov K, Joel J, Moutsambote J. 2018. Soil seed bank characteristics in two central African forest types and implications for forest restoration. J. For Sco 409: 766–776.
Dwipa I, Sumbari C, Anwar A. 2020. Plant soil seed bank analysis in wildfire former area of Mount Talang, West Sumatra, Indonesia. Biodiversitas 21(1): 155–160. doi: 10.13057/biodiv/d210120.
Ekasari I, Sadono R, Marsono D, Witono JR. 2020. Mapping Multi Stakeholder Roles on Fire Management in Conservation Areas of Kuningan Regency. J Manajemen Hutan Tropika 26(3): 254–267. doi: 10.7226/jtfm.26.3.254.
Forcella F, Webster T, Cardina J. 2003. Protocols for weed seed bank determination in agro-ecosystems. in Labrada, R. (ed.) Weed management for developing countries. Rome, Italy: FAO: 120.
Gunawan, H. 2015. Secondary succession on disturbed forest area ex illegal cultivation in Mount Ciremai National Park, West Java. National Seminar Proceeding Biodiversitas Indonesia: 1591–1599. doi: 10.13057/psnmbi/m010709. [Indonesian]
He M, Lv L, Li H, Meng W. 2016. Analysis on soil seed bank diversity characteristics and its relation with soil physical and chemical properties after substrate addition. PLoS ONE. 11(1): 1–16. doi: 10.1371/journal.pone.0147439.
Indriyanto. 2006. Forest ecology. Bumi Aksara, Jakarta. [Indonesian].
Krebs CJ. 2014. Ecological methodology. 3rd ed. New York: Addison-Wesley Educational Publishers, Inc,.
Kwiatkowska-Falinska A, Jankowska-Blaszczuk M, Jaroszewicz B. 2014. Post-fire changes of soil seed banks in the early succesional stage of Pine forest. Pol. J. Ecol 62: 455-466.
Lamb D, Erskine D. 2005. Restoration of Degraded Tropical Forest Landscapes. Science. 310(5754): 1628–1632.
Li, S. Liu, W. Lang, X. Huang, X. Su, J. 2021. Species richness, not abundance, drives ecosystem multifunctionality in a subtropical coniferous forest. J. Ecol Ind 120 (2021): 106911. doi: 10.1016/j.ecolind.2020.106911.
Liu Z, Ge X, Fu Z, Liu J. 2020. Alternanthera philoxeroides invasion affects the soil seed bank of reed community. J. Env Exp Bot 180 (August): 104196. doi: 10.1016/j.envexpbot.2020.104196.
Luo X, Cao M, Zhang M, Song X, Li J, Nakamura A, Kitching R. 2017. Plant diversity soil seed banks along elevational gradients in tropical, subtropical and subalpine forests in Yunnan Province, Southwest China. J. Plant Diversity 39(5): 273–286. doi: 10.1016/j.pld.2017.10.001.
Magurran A. 2004. Measuring biological diversity, measuring biological diversity. United Kingdom: Blackwell Publishing.
Marsono D, Husodo AH. 2017. Indipendent healthy based on ecology. Cakrawala Media, Yogyakarta. [Indonesian]
Marsono D. 1986. Teak forest understorey in KPH Kendal. Buletin Fakultas Kehutanan. III (2): 18–26. [Indonesian]
Mawazin M, Subiakto A. 2013. Species diversity and composition of logged over peat swamp forest in Riau. J. Indonesian Forest Rehabilitation 1(1): 59–73.
Muis N, Setyawati T, Tjitrosoedirdjo S, Ratnadewi Y. 2018. Estimating the abundance and composition of soil seed bank at Bekol in Baluran National Park, West Java. Jurnal Penelitian Kehutanan Wallacea 7(2): 131–140. [Indonesian]
Munthe AS, Purba E, Lahay RR. 2016. Germination seed response of Eleusine indica L. Gaertn to depth and buried time. Agroekoteknologi 4(4): 2367–2375. [Indonesian]
Nahdi MS, Darsikin D. 2015. Distribution and abundance of understory on Pinus merkusii, Acacia auriculiformis dan Eucalyptus alba shade in Gama Giri Mandiri Forest, Yogyakarta. Jurnal Natur Indonesia 16 (1): 33. doi: 10.31258/jnat.16.1.33-41. [Indonesian]
Numata I, Silva SS, Cochrane MA, D'Oliviera MV. 2017. Fire and edge effects in a fragmented tropical forest landscape in the southwestern Amazon. J. For Ecol &Manag 401: 135–146. doi: 10.1016/j.foreco.2017.07.010.
Odum E. 1996. Basics of ecology. 3rd Ed. Gadjah Mada University Press, Yogyakarta. [Indonesian]
Office of Communication and Informatics of Kuningan Regency. 2007. Kuningan Botanical Garden. www.kuningankab.go.id/sumber-daya-alam/kebun-raya-kuningan [Indonesian]
Poejirahajoe E, Marsono D, Wardhani FK. 2017. Usage of pricipal component analysis in the spatial distribution of mangrove vegetation in north coast Pemalang. Jurnal Ilmu Kehutanan 11(1): 29–42. [Indonesian]
Putri W, Qayim I, Qadir A. 2017. Soil seed bank of two karst ecosystems in Bogor, Indonesia: Similarity with the aboveground vegetation and its restoration potential. J Trop Life Sci 7(3): 224–236. doi: 10.11594/jtls.07.03.07.
Randriamalala JR, Herve D, Letourmy P, Carriere SM. 2015. Effects of slash-and-burn practices on soil seed banks in secondary forest successions in Madagascar. J. Agriculture, Ecosystems and Environment 199: 312–319. doi: 10.1016/j.agee.2014.09.010.
Ruwanza S, Gaertner M, Esler KJ, Richardson DM. 2013. The effectiveness of active and passive restoration on recovery of indigenous vegetation in riparian zones in the Western Cape, South Africa: A preliminary assessment. S Afr J Bot South African Association of Botanists 88: 132–141. doi: 10.1016/j.sajb.2013.06.022.
Sadili A, Kartawinata K. 2016. A study of the undergrowth vegetation of Sempu Island, East Java, Indonesia. Reinwardtia. 15(1): 1–9.
Santos DM, Santos JMFF, Silva KA, Araujo VK Araujo EL. 2016. Composition, species richness, and density of the germinable seed bank over 4 years in young and mature forests in Brazilian semiarid regions. J. Arid Env. 129: 93–101. doi: 10.1016/j.jaridenv.2016.02.012.
Setyawati T, Narulita S, Bahri H, Raharjo GT. 2015. A guide book to invasive plant species in Indonesia. Research, Developing and Innovation Agency. Ministry of Environment and Forestry Republic of Indonesia, Bogor. [Indonesian]
Shang Z, Yang Y, Wang Y, Shi J, Ding L. 2016. Soil seed bank and its relation with above-ground vegetation along the degraded gradients of alpine meadow. Ecol Eng. 90: 268–277. doi: 10.1016/j.ecoleng.2016.01.067.
Siahaan M, Purba E, Irmansyah T. 2014. Composition and weed seed bank density at variuos soil depth of crop planting area at Balai Benih Induk Tanjung Selamat. Agroekoteknologi 2(3): 1189–1195. [Indonesian]
Sileshi D, Abraha B. 2014. Assessment of Soil Seedbank Composition of Woody Species in Hgumbirda National Forest Priority Area, Northeastern Ethiopia. Momona Ethiopian Journal of Science 6(1): 25. doi: 10.4314/mejs.v6i1.102413.
Soegianto, A. 1994. Analysis method on ecology quantitative for community population. Usaha Nasional, Surabaya. [Indonesian]
Soerjani M, Kostermans AJGH, Tjirosoepomo G. 1987 Weeds of Rice In Indonesia. Balai Pustaka, Jakarta. [Indonesian]
Sulistyawati E, Fitriana S. 2017. Post fire succession in Tegal Panjang Grassland, Mount Papandayan, West Java, Indonesia. Biodiversitas. 18(3): 1226–1233. doi: 10.13057/biodiv/d180347.
Sutomo, S., Fardila, D. and Priyadi, A. 2015. Composition and diversity comparison of soil seed bank on post eruption and non eruption in Mount Merapi 2010. National Seminar Proceeding Biodiversitas Indonesia: 721–726. doi: 10.13057/psnmbi/m010406.
Tian X, Zhao F, Shu L, Wang M. 2013. Distribution characteristics and the influence factors of forest fires in China. For Ecol& Manag 310: 460–467. doi: 10.1016/j.foreco.2013.08.025.
Vosse S, Esler KJ, Richardson DM, Holmes PM. 2008. Can riparian seed banks initiate restoration after alien plant invasion? Evidence from the Western Cape, South Africa. S Afr J Bot 74(3): 432–444. doi: 10.1016/j.sajb.2008.01.170.
Zhang H, Chu LM. 2013. Changes in soil seed bank composition during early succession of rehabilitated quarries. Ecol Eng 55: 43–50. doi: 10.1016/j.ecoleng.2013.02.002.
Zida D, Sanou L, Diawara S, Savadogo P, Thiombiano A. 2020. Herbaceous seeds dominates the soil seed bank after long-term prescribed fire, grazing and selective tree cutting in savanna-woodlands of West Africa. Acta Oecol 108 (August): 103607. doi: 10.1016/j.actao.2020.103607.

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