Cendana merupakan spesies asli Indonesia bagian timur, yang menjadi ras lahan di Gunung Sewu. Sembilan ras lahan di Gunung Sewu, seluruhnya tersusun atas tiga varian yang berbeda struktur dan warna bunganya (MK, merah kecil; MB, merah besar; dan KB, kuning besar). Penelitian ini bertujuan untuk menganalisis karakter pembungaan ketiga varian cendana di Gunung Sewu pada periode pembungaan tahun 2015; di tiga ras lahan yang mewakili tiap zona yaitu Nglanggeran (Zona Utara), Bleberan (Zona Tengah), dan Petir (Zona Selatan). Observasi meliputi fenologi, kemasakan organ reproduksi, display, dan struktur pembungaan. Struktur pembungaan dan longevity organ reproduksi berbeda antar varian. MB dan KB didominasi warna merah dan marun, perigonium lebih besar, organ reproduksi lebih panjang, posisi putik sejajar/lebih rendah dari benang sari, dan longevity lebih singkat. MK didominasi kuning hingga oranye, lebih kecil, posisi putik sejajar/lebih tinggi, dan longevity lebih lama. Display pembungaan berbeda antar ras lahan, namun tidak berbeda antar varian. Petir, dengan ukuran populasi terbesar, memproduksi paling banyak pohon berbunga dan total bunga untuk seluruh varian. Ras lahan dan varian berbunga dua kali setahun, namun dengan inisiasi dan durasi yang berbeda. KB berbunga lebih awal di seluruh ras lahan, sedangkan MB paling akhir. MK memiliki durasi pembungaan terpanjang. Perbedaan antar ras lahan lebih dipengaruhi oleh faktor lingkungan seperti ketinggian, jenis tanah, dan iklim. Ras lahan yang lebih rendah, kering, dan panas berbunga lebih awal dan singkat. Peningkatan temperatur dan turunnya status air tanah menyebabkan keguguran massal yang diikuti sequential replacement, mengakibatkan perubahan frekuensi pembungaan. Strategi konservasi cendana di Gunung Sewu perlu dirancang berbasis keragaman genetik, sinkroni pembungaan, dan kompatibilitas antar varian, dengan tetap mempertimbangkan keberagaman tempat tumbuhnya.

Kata kunci: cendana; Gunung Sewu; pembungaan; ras lahan; varian bunga

The Flowering Characters Variation Among Floral Variants and Landraces Along Geographical Gradients in Gunung Sewu

Abstract

Sandalwood was origin to the south-eastern islands of Indonesia, but is recently occured as new land-races in Gunung Sewu, Java island. All of land-races consisted of three floral variants (MK, refers to “merah kecil”; MB, “merah besar”; and KB, “kuning besar”, respectively). This research aimed to determine flowering of these variants among three of land-races which were representing geographical zone in Gunung Sewu: Nglanggeran, Blebera, and Petir. Observation on phenology, sexual organs maturity, floral structure, and display was conducted in 2015. Floral structures varied among variants. MB and KB dominated by red and maroon colors, possessed bigger perigonium, longer sexual organs but with shorter longevity, and similar/lower position of stylus to stamens. MK dominated by yellow to orange colors, smaller, similar/higher position of stylus, and longer longevity. Floral display varied among land-races but were similar among variants. Petir, with biggest population size, produced the most abundant flowers and flowering trees at all variants. Sandalwood flowered twice a year in all of land-races and variants, however, the onset and duration varied. KB flowered earliest while MB was the latest. MK possessed longest flowering period. Flowering varied among land-races due to the altitude, soils, and climatic differences. Lower altitude, drier, and warmer sites flowered earlier and shorter. Mass abortion and sequential replacement, resulting in the alteration on flowering frequency, occured due to the extreme temperature increment. Conservation strategy should be arranged based on genetic differentiation, flowering differences, and crossing abilities among variants. Differences of landscapes, which may contribute to the differences of environmental conditions and flowering processes, should also be considered.

Agullo JC, Perez-Banon C, Crespo MB, Juan A. 2015. Puzzling out the reproductive biology of the cat’s head rockrose (Helianthemum caput-felis, Cistaceae). Flora 217: 75-81.

Alizoti PG, Kilimis K, Gallios P. 2010. Temporal and spatial variation of flowering among Pinus nigra Arn. clones under changing climatic conditions. Forest Ecology and Management 259:786–797.

Angadi VG, Jain SH, Shankaranarayana KH. 2003. Genetic diversity between sandal populations of different provenances in India. Institute of Wood Science and Technology. Bangalore, India.

Anonim. 2015. Program rehabilitasi cendana di NTT telah gagal. Harian Kompas online. http://www.kompas.com. Diakses April 2015.

Arroyo MTK, Munoz MS, Henríquez C, Till-Bottraud I, Perez F. 2006. Erratic pollination, high selfing levels and their correlates and consequences in an altitudinally widespread above-tree-line species in the high Andes of Chile. Acta Oecologica 30: 248–257.

Barrett SCH, Baker AM, Jesson LK. 2006. Mating strategies in Monocotyledons. Monocots Newsletter II. Department of Botany, University of Toronto. Ontario, Canada.

Bottin L, Tassin J, Nasi R, Bouvet JM. 2007. Molecular, quantitative and abiotic variables for the delineation of evolutionary significant units: case of sandalwood (Santalum austrocaledonicum Vieillard) in New Caledonia. Conservation Genetics 8:99–109

Brand JE. 1994. Genotypic variation in Santalum album. Sandalwood Research Newsletter. II-1994.

Byrne M, MacDonald B, Broadhurst L, Brand J. 2003. Genetic differentiation in Western Australian sandalwood (Santalum spicatum) as revealed by nuclear RFLP. Theoritical and Applied Genetics 107:1208–1214

Collin CL, Shykoff JA. 2003. Outcrossing rates in the gynomonoecious-gynodioecious species Dianthus sylvestris (Caryophyllaceae). American Journal of Botany 90(4): 579–585.

da Silva JAT, Page T, Zhang X, Kher MM, Nataraj M, Soner D, Ma G. 2016. Sandalwood: basic biology, tissue culture, and genetic transformation. Planta 243: 847–887

Dalgleish HJ, Ott JP, Setshogo MP, Hartnett DC. 2012. Inter-specific variation in bud banks and flowering effort among semi-arid African savanna grasses. South African Journal of Botany 83: 127-133.

Dani KGS, Ravikumar P, Kumar RP, Kush A. 2011. Genetic variation within and among small isolated populations of Santalum album. Biologia Plantarum 55 (2): 323-326

Dinas Kehutanan DIY. 2015. Laporan inventory tegakan hutan di Kabupaten Gunungkidul. Bagian Perencanaan dan Pemetaan Hutan. KPHP Dinas Kehutanan Daerah Istimewa Yogyakarta.

Dreyer LL, Esler KJ, Zietsman J. 2006. Flowering phenology of South African Oxalis—possible indicator of climate change? South African Journal of Botany 72: 150 – 156.

Fernandez VA, Galetto L, Astegiano J. 2009. Infuence of flower functionality and pollination system on the pollen size-pistil length relationship. Organisms, Diversity, & Evolution 9 : 75–82.

Ghazoul J. 1997. Field studies of forest tree reproductive ecology. ASEAN-Canada Forest Tree Seed Center Project, Saraburi, Thailand.

Grab S, Craparo A. 2011. Advance of apple and pear full bloom dates in response to climate change in the south-western Cape, South Africa: 1973–2009. Agricultural & Forest Meteorology 151: 406–413.

Harbaugh DT, Baldwin BG. 2007. Phylogeny and biogeography of the Sandalwoods (Santalum, Santalaceae): repeated dispersals throughout the Pacific. American Journalof Botany 94(6): 1028–1040.

Haryono E, Suratman. 2010. Significant features of Gunung Sewu Karst as geopark site. Proceeding on 4th International UNESCO Conference on Geopark. April 12-15, 2010, Langkawi.

Haukka AK, Dreyer LL, Esler KJ. 2013. Effect of soil type and climatic conditions on the growth and flowering phenology of three Oxalis species in the Western Cape, South Africa. South African Journal of Botany 88: 152–163.

Herawan T, Na’iem M, Indrioko S, & Indrianto A. 2014. Somatic embryogenesis of Sandalwood (Santalum album L.). Indonesian Journal of Biotechnology 19(2):168-175.

Herlihy CR, Eckert CG. 2005. Evolution of self-fertilization at geographical range margins? A comparison of demographic, floral, and mating system variables in central vs. peripheral populations of Aquilegia canadensis (Ranunculaceae). American Journal of Botany 92(4): 744–751.

Indrioko S, Ratnaningrum YWN. 2016. Genetic differentiation, mating systems and crossability of three floral variants of sandalwood in Gunung Sewu Geopark. Prosiding 1st International Conference on Tropical Agriculture (ICTA) 2016. November 2016, Yogyakarta.

Indrioko S, Ratnaningrum YWN. 2015. Habitat loss caused clonality, genetic diversity reduction and reproductive failure in Santalum album (Santalaceae), an endangered endemic species of Indonesia. Hlm. 658-664. Procedia Environmental Sciences V.

IUCN. 2009. IUCN Red List Categories And Criteria: Version 3.1. International Union for Conservation of Nature and Natural Resources. Glad, Switzerland, and Cambridge. UK.

Jones CE, Little RJ. 1983. Handbook of experimental pollination biology. Van Nostrand Reinhold Co. Inc. New York.

Lesica P, Kittelson PM. 2010. Precipitation and temperature are associated with advanced flowering phenology in a semi-arid grassland. Journal of Arid Environments 74: 1013-1017.

Lhuillier E, Butaud JF, Bouvet JM. 2006. Extensive clonality and differentiation in the insular Pacific tree Santalum insulare: implications to its conservation. Annals of Botany 98: 1061-1072.

Owens JN, Sornsathapornkul P, Thangmitcharoen S. 2001. Studying flowering and seed ontogeny in tropical forest trees. ASEAN-Canada Forest Tree Seed Centre. Muak-lek, Saraburi 18180.

Park SH, Burchi G, Roh MS, Joung YH. 2014. Characterization of Kolkwitzia amabilis accessions based on flowering and molecular markers. Scientia Horticulturae 165: 190–195

Rao MN, Ganeshaiah KN, Shaanker RU. 2007. Assessing threats and mapping sandal resources to identify genetic ‘hot-spot’ for in-situ conservation in peninsular India. Conservation Genetics 8:925–935.

Ratnaningrum YWN, Indrioko S, Faridah E, Syahbudin A. 2016. Flowering and seed production of sandalwood (Santalum album Linn., Santalaceae) along environmental gradients in Gunung Sewu Geopark, Indonesia. Nusantara Bioscience 8(2): 180-191.

Ratnaningrum YWN, Indrioko S. 2016. Differences on floral structure of sandalwood along landscape gradients in Gunung Sewu and its consequences on pollination and reproductive outputs. Prosiding 1st International Conference on Tropical Agriculture (ICTA). November, 2016, Yogyakarta.

Ratnaningrum YWN, Indrioko S. 2015. Response of flowering and seed production of sandalwood (Santalum album Linn) to climate changes. Hlm. 665-675. Procedia Environmental Sciences V.

Ratnaningrum YWN, Indrioko S. 2014. Variation on genotypes and flowering characters affecting pollination mechanisms of sandalwood (Santalum album Linn., Santalaceae) planted on ex-situ gene conservation in Yogyakarta, Indonesia. Eurasian Journal of Forest Research 6: 167-179.

Ratnaningrum YWN, Prehaten D. 2005. Pollination mechanisms and breeding systems of Santalum album (Santalaceae), the endemic species of Eastern parts of Indonesia that became landrace of Gunungkidul, Central Java. Proceeding on The International Forestry Seminar. Faculty of Food and Agriculture. Universiti Putra Malaysia. March 7-9, 2005, Serawak, Malaysia.

Richardson AD, Keenan TF, Migliavacca M, Ryua Y, Sonnentaga O & Toomey M. 2013. Climate change, phenology, and phenological control of vegetation feedbacks to the climate system. Agricultural and Forest Meteorology 169: 156– 173.

Rughkla A, McComb JA, Jones MGK. 2006. Intra-and inter specific pollination of Santalum spicatum and S. album. Australian Journal of Botany 45(6): 1083-1095.

Simanjuntak T. 2002. Gunung Sewu in prehistoric times. Gadjah Mada University Press. Yogyakarta.

Sindhu-Veerendra HC, Anantha-Padmanabha HS. 1996. The breeding system in Sandal (Santalum album L.). Silvae Genetica 45(4): 188-190.

Suma TB, Balasundaran M. 2003. Isozyme variation in five provenances of Santalum album in India. Australian Journal of Botany 51(3): 243 – 249.

Tamla HT, Cornelius JP, Page T. 2012. Reproductive biology of three commercially valuable Santalum species: development of flowers and inflorescences, breeding systems, and interspecific crossability. Euphytica 184:323–333.

Tsaliki M, Diekmann M. 2011. Population size, pollination and reproductive success in two endangered Genista species. Flora 206: 246–250. Van-Breemen N, Buurman P. 2002. Soil formation. Kluwer Academic Publishers, Doordrecht.

Warburton CL, James EA, Fripp YJ, Trueman SJ, Wallace HM. 2000. Clonality and sexual reproductive failure in remnant populations of Santalum lanceolatum (Santalaceae). Biological Conservation. 96(1):45-54.

Weber A, Kolb A. 2013. Population size, pollination and phenotypic trait selection in Phyteuma spicatum. Acta Oecologica 47:46-51.

White TL, Adams WT, Neale DB. 2007. Forest genetics. CABI Publishing. CAB International. Wallingford, Oxfordshire, UK.

Wolf PG, Campbell DR, Waser NM, Sipes SD, Toler TR, Archibald JK. 2001. Tests of pre- and postpollination barriers to hybridization between sympatric species of Ipomopsis (Polemoniaceae). American Journal of Botany 88(2): 213–219.

Yang HW, Bain A, Garcia M, Chou LS, Kjellberg F. 2013. Evidence of genetic influence on the flowering pattern of Ficus microcarpa. Acta Oecologica 30: 1-7.