cje ›› 2003, Vol. ›› Issue (4): 65-69.
Previous Articles Next Articles
WU Lisheng, WANG Guizhong, LI Shaojing
Received:
2002-01-30
Revised:
2002-05-09
Online:
2003-04-10
CLC Number:
WU Lisheng, WANG Guizhong, LI Shaojing. Advance in the diapause studies of marine planktonic copepoda[J]. cje, 2003, (4): 65-69.
Add to citation manager EndNote|Ris|BibTeX
[1] 王桂忠,李少菁,陈峰,等.1994.厦门港海区两种常见纺锤水蚤卵的生物学和季节演替[J].厦门大学学报(自然科学版),33(增刊):135~140. [2] 郑重.1993.节肢动物的滞育研究[C].见:郑重.郑重文集(续)[C].北京:海洋出版社,102~122. [3] 唐启升,苏纪兰,等.2000.中国海洋生态系统动力学研究Ⅰ.关键科学问题与研究发展战略[C],北京:科学出版社. [4] 韩希福,王荣.2001.桡足类的休眠与滞育[J].海洋科学,25(5):24~26. [5] Alldredge AL, Robison BH, Fleminger A. 1984. Direct sampling and in situ observation of a persistent copepod aggregation in the mesopelagic zone of the Santa Barbara Basin[J]. Mar. Biol.,80:75~81. [6] Ban S, Minoda T. 1992, Hatching of diapause eggs of Eurytemora affinis(Copepopda: Calanoida)collected from lake-bottom sediments[J]. Crustacea. Boilogy, 12: 51~56. [7] Blades-Eckelbarger PI, Marcus NH. 1992. The origin of cortical vesicles and their role in egg envelope formation in the "spiny" eggs of a Calanoid Copepod, Centropages velificatus[J]. Biol.Bull., 182:41~53 [8] Bruce CC, Jonathan G. 1981. Encystment discovered in a marine copepod[J]. Science, 212(17):342~344. [9] Butler EI, Corner EDS, Marshall SM. 1970. On the nutrition and metabolism of zooplankton, Ⅶ. Seasonal survey of nitrogen and phosphorus excretion by Calanus in the Clyde-sea[J]. J. Mar.Biol. Assoc. U. K., 50: 525~560. [10] Carlisle DB, Pitman WJ. 1961. Diapause, neurosecretion and bormones in Copepoda[J]. Nature, 190827~828. [11] Colebrook JM. 1985.Continuous plankton records:overwintering and annual fluctuations in the abundance of zooplankton[J].Mar. Biol., 84 :, 261~265. [12] Corner EDS, et al. 1974. On the nutrition and metabolism of zooplankton, Ⅸ. Studies relating to the nutrition of overwintering Calanus[J].J. Mar. Biol. Assoc. U. K.,54:319~331. [13] David WP, Edward J M. 2000. Factors influencing the induction of diapausing egg production in the Calanoid copepod Diaptomus leptopus[J]. Aquat. Ecol., 34(1): 9~17. [14] Grigg H, Bardwell SJ. 1982. Seasonal observations on moulting and maturation in stage V. Copepodites of Calanus finmarchincus from the Firth of Clyde[J].J. Mar. Biol. Assoc. U.K.,62:315~327. [15] Guisande C, Maneiro Ⅰ. Riveiro Ⅰ, 1999. Homeostasis in the essential amino acid composition of the marine copepod Euterpina acuti frons . Limnol . Oceanogr ., 44: 691~696. [16] Hairston JR, De NG, Stasio B. 1990. A field test for the cues of diapause in freshwater copeod[J]. Ecology, 71: 2218~2223. [17] Hairston Jr NG, De Stasio B. 1988. Rate of evolution slowed by a dormant propagule pool[J]. Nature, 336 : 239~242. [18] Hairston Jr, NG, Olds E J. 1984. The timing of copepod diapause as an evolutionarily stable strategy[J]. Amer. Natur., 123:733~751. [19] Hallberg E, Hirche HJ. 1980. Differentiation of mid-gut in adults and overwintering copepodids of Calanus finmarchicus(Gunnerus)and C. helgolandicus Claus[J].J. Exp. Mar. Biol.Ecol., 48 :, 283~295. [20] Ianora A, Santella L. 1991. Diapause embryos in the neusonic copepod Anomalocera patersoni[J]. Mar. Biol., 108:387~394. [21] Judith Williams-Howze, Dormancy in the free-living copepod orders Cyclopoida, Calanoida, and Harpacticoida, Oceanography and Marine Biology : An Annual Review[R],35:257~321. [22] Kasahara S, Uye S. 1979. Calanoid copepod eggs in sea-bottom muds V. seasonal changes in hatching of subitaneous and diapause eggs of Tortan us forci patus[J]. Mar Biol., 55 :63~68. [23] Marcus NH. 1979. On the population biology and nature of diapause of Labidocera aestiva(Copepoda.. Calanoida)[J]. Biol Bull, 157:297~305. [24] Marcus NH. 1980. Photoperiodic control of diapause in the marine calanoid copepod Labidocera asstiva[J] . Biol. Bull., 159:311~318. [25] Marcus NH. 1982. Photoperiodic and temperature regulation of diapause of Lab idocera aestiva,(Copepoda: Calanoida)[J]. Biol. Bull., 162:45~52. [26] Marcus NH. 1982. The reversibility of subitaneous and diapause egg production by individual females of Labidocera aestiva(Copepoda: Calanoida)[J]. Biol Bull., 162 :, 39~44. [27] Marcus NH. 1984. Recruitment of copepod nauplii into the panktion:importance of diapause eggs and benthic procesaes[J]. Mar Ecol. Progr. Ser.,15:47~54. [28] Marcus NH, 1984. Variation in the diapause response of Labidocera aestiv(Copepoda: Calanoida)from different latitudes and its importance in the evolutionary process[J]. Biol. Bull., 166:127~139. [29] Marcus NH. 1985. Population dynamics of marine copepods: the importance of genetic variation[J]. Bull. Mar. Sci., 37: 684~690. [30] Marcus NH. 1987.Differences in the duration of egg diapause of Labidocera aestiva(Copepoda: Calanoida)from t he Woods Hole,Massachusetts region[J]. Biol. Bull., 173:169~177. [31] Marcus NH. 1996. Ecological and evolutionary significance of resting eggs in marine copepods: past, present, and future studies[J]. Hydrobiologia, 320(1~3): 141-152. [32] Marcus NH, Boerf F. 1998. Minireview:the importance of benthic-pelagic coupling and the forgotten role of life cycles in coastal aquatic systems[J]. Limnol. Ocean., 43(5):763~768. [33] Marshall SM, Orr AP. 1958. On the biology of Calanus finmarchicus X. Seasonal changes in oxygen consumption[J]. J.Mar. Biol . Assoc . U. K.,37:459~472. [34] Naess T, Bergh O. 1994, Calanoid copepoda resting eggs can be surface-disinfected[J]. Aquac. Eng., 13:1~9. [35] Petersen G, Tande KS, Nilssen EM. 1995. Temporal and regional variation in the copepod community in the central Barents Sea during spring and early summer 1988 and 1989[J] .J. Plankton Res., 17(2):263~282. [36] Ranada MR. 1957. Observation on the resistance of Tigripus fulous(Fischer)to changes in temperature and salinity. J. Mar.Biol. Assoc. U. K.,36:115~119. [37] Romano G, Ianora A, Miralto A. 1996. Respiratory physiology in summer diapause embryos of the neustonic copepod Anomalocera patersoni[J]. Mar. Biol., 127(2): 229~234. [38] Romano G, lanora A, Miralto A. 1996. Respiratory metabolism during embryonic subitaneous and diapause development in Pontella mediterranea(Crustacea Copepoda)[J]. J. Compar.Physio. B-Biochem . Syst . Environ. Physiol., 166(3):157~163. [39] Sullivan BL, McManus LT. 1986. Factors controlling seasonal succession of the copepods Acartia hudsonica and A. tonsa in Narragansett Bay, Rhode Island: temperature and resting egg production. Mar. Ecol. Prog. Ser., 28:121~128. [40] Tande KS, Hopkins CE. 1981. Ecological investigations of the zooplankton community of Balsfjorden, northern Norway: the genital system in Calanus finmarchicus and the role of gonad development in overwintering strategy[J]. Mar. Biol., 63:159~164. [41] Tande KS. 1982. Ecological investigation on the zooplankton community of Balsfjorden, northern Norway:generation cycles, and variations in body weight and body content of carbon and nitrogen related to overwintering and reproduction in the copepod Calanus finmarchicus(Gunnerus)[J].J. Exp. Mar. Biol. Ecol.,62:129~142. [42] Uye S. 1980. Resting egg production as a life history strategy of marine planktonic copepods[J]. Bull. Mar. Sci, 37:440~449. [43] Uye S. 1985. Development of neretic copepods Acartia clausi and A. steuri Ⅰ . Some environmental factors affecting egg development and the nature of resting eggs[J]. Bull. Plankton Soc. Jpn.,27:1~9. [44] Watson NHF, Smallman B N1971., The physiology of diapause in Diacyclops navus Herrick(Crustacesa, Copepoda)[J]. Can.J. Zool., 49:1449~1454. [45] Williams-Howze J, Coull BC. 1992. Are temperature and pbotoperiod necessary cuses for encystment in the marine benthic harpacticoid copepod Heteropsyllus nunniCoull?[J]. Biol.Bull., 182:109~116. |
[1] | FU Furong, SUN Yang, ZHAO Lixia, LI Xiaojing, WENG Liping, LI Yongtao. Interaction effect and mechanism between microorganisms in earthworm intestine and pollutants in soil. [J]. Chinese Journal of Ecology, 2024, 43(4): 1170-1182. |
[2] | REN Yi, LIU Hongyan, WU Longhua, WANG Xulian, MEI Xue, JIAN Huailiang, ZHAO Luyue. The characteristics of fungal community in the rhizosphere soil of potato infected by late blight in an area with high geological background of heavy metals in Northwest Guizhou. [J]. Chinese Journal of Ecology, 2023, 42(9): 2148-2155. |
[3] | . Effects of Pb stress on physiology and biochemistry of three moss species in Northwest China. [J]. Chinese Journal of Ecology, 2023, 42(7): 1618-1626. |
[4] | TAO Changzhu, LI Linxin, ZHANG Ting, LI Nana, CAO Yue, HOU Xiaolong, WU Pengfei. Heavy metal accumulation capacity of Phragmites australis in wetland parks: A case study of Wulong River in Minjiang River basin. [J]. Chinese Journal of Ecology, 2023, 42(7): 1678-1686. |
[5] | CHANG Linxi, LIU Fengshuo, ZHAN Fangdong, LI Bo, CHEN Jianjun, ZU Yanqun, LI Yuan, HE Yongmei. Growth adaptability of 13 Rhododendron varieties in complex polluted cropland in a plateau lead-zinc mining area. [J]. Chinese Journal of Ecology, 2023, 42(6): 1449-1456. |
[6] | Nazupar SIDEKJAN, Mamattursun EZIZ, LI Xinguo, YANG Xiuyun. Potential ecological risks of heavy metals in soil along an urbanization gradient. [J]. Chinese Journal of Ecology, 2023, 42(5): 1107-1114. |
[7] | WU Yun-peng, ZENG Qing-jun, CHEN Ping-shan, OUYANG Xiao-fang, HU Ji-ye, FENG Chun-hua, SUN Jian. Effect and mechanism of Fe-based biochar combined with bioelectrochemical technology for in situ remediation of Pb-polycyclic aromatic hydrocarbons contaminated sediment. [J]. Chinese Journal of Ecology, 2023, 42(2): 504-512. |
[8] | DUAN Xiaoqing, ZHAO Guang, ZHANG Yangjian, MU Yu, YANG Wangxin, JIN Jie, HAN Xueqin, LIAO Chengfei. The responses of Moringa oleifera to combined Cd-Pb-Cu-Zn stresses and their enrichment characteristics in the dry-hot valley of Yunnan. [J]. Chinese Journal of Ecology, 2023, 42(12): 2817-2827. |
[9] | PENG Qingqing, ZHANG Yaoyi, ZHANG Huiling, PENG Yan, NI Xiangyin, WU Fuzhong. The resorption and accumulation of abiotic heavy metal elements in leaves from four types of forests in mid-subtropical China. [J]. Chinese Journal of Ecology, 2023, 42(12): 2828-2835. |
[10] | ZHANG Zixiang, MA Long, LIU Tingxi, SUN Guohua, LI Yao, BAO Yufeng. Assessment of the ecological risk of heavy metal pollution in groundwater of typical lead-zinc mine and influenced area in Inner Mongolia. [J]. Chinese Journal of Ecology, 2023, 42(12): 2853-2863. |
[11] | LI Jingming, TONG Menghan, GUO Shuhai, LI Fengmei. Research progress on bioremediation of polycyclic aromatic hydrocarbons and heavy metals co-contaminated soil. [J]. Chinese Journal of Ecology, 2023, 42(12): 2874-2884. |
[12] | ZHENG Meijie, ZHENG Dongmei, XIN Yuan, ZHANG Zhongsheng, WU Haitao. Effects of Spartina alterniflora invasion on the distribution pattern of metal elements in surface sediments of the Yellow River Delta wetlands. [J]. Chinese Journal of Ecology, 2023, 42(10): 2368-2375. |
[13] | ZHANG Qian, HAH Gui-lin. Soil geochemistry characteristics and ecological risks in critical zones of different lithologic backgrounds. [J]. Chinese Journal of Ecology, 2023, 42(1): 115-122. |
[14] | WANG Guang-hao, KONG Xing-jie, SUN Cai-li, WU Pan. Effects of land use conversion around a lead-zinc slag heap on soil extracellular enzyme activities. [J]. Chinese Journal of Ecology, 2022, 41(6): 1166-1172. |
[15] | JIANG Yu, GUO Qing-jun, DENG Yi-nan. Research progress in the distribution of heavy metals in sediments and soils in the Yangtze River Basin. [J]. Chinese Journal of Ecology, 2022, 41(4): 804-812. |
Viewed | ||||||
Full text |
|
|||||
Abstract |
|
|||||