후박나무 10개 천연집단의 엽형질 변이

The Leaf Morphological Variation of Ten Regions of Natural Populations of Machilus thunbergii in Korea

  • 양병훈 (산림청 산림환경보호과) ;
  • 송정호 (국립산림과학원 산림유전자원과) ;
  • 이재천 (국립산림과학원 산림유전자원과) ;
  • 박용구 (경북대학교 임학과)
  • Yang, Byeong-Hoon (Forest Environment Conservation Division, Korea Forest Service) ;
  • Song, Jeong-Ho (Division of Forest Genetic Resources, Korea Forest Research Institute) ;
  • Lee, Jae-Cheon (Division of Forest Genetic Resources, Korea Forest Research Institute) ;
  • Park, Young-Goo (Department of Forestry, Kyungpook National University)
  • 투고 : 2011.03.21
  • 심사 : 2011.06.23
  • 발행 : 2011.06.30

초록

후박나무의 유전자원보존을 위하여 10개 천연집단을 대상으로 9가지 엽의 형태적 특성에 대한 집단간 및 집단내 개체간 변이를 조사하고 다변량분석을 실시하였다. 엽의 평균 생장은 엽신장 9.8cm, 최대엽폭 4.0cm, 엽병길이 1.8cm, 엽맥수 8.4개, 엽저각 $67.9^{\circ}$, 엽두각 $78.0^{\circ}$로 나타났다. 각 형질특성에 대한 변이계수 값은 대체적으로 20% 내외의 비교적 유사한 특성을 나타냈다. Nested 분산분석 결과 모든 특성에서 집단간 및 개체간에 고도의 유의적인 차이가 인정되었으며, 전체 분산 가운데 집단간보다 집단내 개체간 차지하는 비율이 모든 특성들에서 높게 나타났다. 집단간 유연관계는 Euclidean distance 1.2 수준에서 크게 4개의 그룹으로 나뉘었으나 지리적 분포에 따른 특별한 경향은 나타나지 않았다. 유집군의 유형에 대한 주성분분석 결과 제3주성분까지가 누적변이 값이 92.8%로 나타났다. 제1주성분의 기여율은 40.3%로 대체적으로 최대엽폭, 제2주성분의 기여율은 28.7%로 엽신장, 제3주성분의 기여율은 23.8%로 엽병길이 특성의 기여도가 높게 나타나 후박나무 집단간 유연관계에 중요한 정보를 주는 요인으로 나타났다.

This study was conducted to examine genetic variation on leaf characteristics of Machilus thunbergii populations. Ten populations were subjected to multivariate analysis for 9 characteristics of leaf morphology. Average length of leaf blade, leaf width, petiole length, vein number were 9.8cm, 4.0cm, 1.8cm, 8.4 respectively, while angle of leaf base and leaf apex were $67.9^{\circ}$ and $78^{\circ}$ respectively. The coefficient of variation (C.V.) on leaf characteristics was 20% which indicate similar features among the populations. Nested analysis showed statistically signigicant differences among populations as well as among individuals within populations. Genetic relationship between populations using complete linkage method showed four groups to Euclidean distance 1.2 and did not show a tendency to cluster into the same group. There were three principal components that had a meaningful eigenvalue over 1.0 among the 9 components. The explanatory power of the top three main components on the total variation was 92.8%. The first principal component (PC) was explained about 40.3% which is mainly correlated with maximum leaf width and the second PC was explained about 28.7% which is correlated with leaf blade length. The third PC was explained about 23.8% which is correlated with petiole length ($X_3$). These characters were important factors for analysis of the relationship among natural populations of M. thunbergii.

키워드

참고문헌

  1. Ahn, Y. S., S. H. Kim, H. K. Jung, Y. S. Jang, Y. C. Choi, and K. I. Oh. 2002. The variation of leaf characters among natural populations of Kalopanax septemlobus Koidz.. Jour. Korean For. Soc. 91: 755-764.
  2. Crawford, D. J. 1990. Plant Molecular Systematics. Macromolecular Approaches. John Wiley & Sons. New York. pp. 388.
  3. Kim, C. S., Y. J. Kang, J. G. Koh, and L. M. Cho. 1994. Variation of leaf and seed characteristics in selected population of Machillus thunbergii. Res. Res. For. Gen. Res. Inst. Korea 30: 85-92.
  4. Kim, I. S., H. Y. Kwon, K. O. Ryu, and H. S. Choi. 2010. Variation of leaf morphology among 18 populations of Zelkova serrata Mak.. Korean J. Breed. Sci. 42: 40-49.
  5. Kim, Y. J., K. C. Kim, B. S. Lee, G. Y. Lee, K. J. Cho, J. T. Kang, and T. D. Kim. 2005. The variation of leaf characteristics in 6 natural populations of Stewartia koreana Nakai.. Jour. Korean For. Soc. 94: 446-452.
  6. Kim, Y. S. 1985. The variation in Foliar characteristics of natural population of Camellia japonica L. Jour. Korean For. Soc. 69: 69-76.
  7. Lance, G. N. and W. T. Williams. 1967. "Mixed-data classificatory programs", comput. J., 9: 373-380. https://doi.org/10.1093/comjnl/9.4.373
  8. Lee, S. W., S. C. Kim, W. W. Kim, S. D. Han, and K. B. Yim. 1997. Characteristics of leaf morphology, vegetation and genetic variation in the endemic populations of a rare tree species, Koelreuteria paniculata Laxm. Jour. Korean For Soc. 86: 167-176.
  9. Lee, C. H., C. H. Shin, and K. S. Kim. 2007. Geographic variation in needle characteristics of Pinus densiflora in Korea. Korean J. Plant Res. 20: 336-341.
  10. Lee, K. Y. and H. K. Kim. 1982. The variation in needle characteristics of natural population of Abies koreana Wilson. Jour. Korean For. Soc. 57: 39-44.
  11. Park, Y. G. 1994. Strategy for bio-diversity and genetic conservation of forest resource in Korea. Jour. Korean For. Soc. 83: 191-204.
  12. SAS Institute Inc. 1996. SAS/STAT User's Guide, Version 6.12 SAS Institute, USA.
  13. Song, J. H., M. H. Park, H. K. Moon, S. U. Han, and J. S. Yi. 2000. The variation of leaf form of natural populations of Quercus variabilis in Korea. Jour. Korean For. Soc. 89: 666-676.
  14. Shin, H. C., N. C. Park, H. K. Song, Y. G. Jeong, J. H. Choi, Y. H Kwon, K. S. Lee, and Y. K. Kim. 2002. Analysis of vegetation structure and vegetation-environment relationship in the Machilus thunbergii stands, Korea. Jour. Korean For. Soc. 91: 765-774.
  15. Yakovlev, I. A. 1997. A study of common oak's (Quercus robur L.) population structure at the north-eastern limit of its distribution in Russia using leaf morphological traits. pp.37-45. Proc. of 2nd Meeting of IUFRO Working Party 2.08.05, Genetics of Quercus. Oct. 12-17. 1997. Pen. Sta. Uni., Pennsylvania, USA.
  16. 김찬수, 김태수, 강영제, 김원우, 서재덕, 심상영. 1989. 한반도 남부지방에 생육하는 후박나무의 분포 및 특성. 임목육종연구노트 35: 6-11.
  17. 현정오. 1984. 강원도내 거제수나무 천연집단의 엽형질 변이. 서울대 농학연구 9: 21-25.