生态环境学报
生態環境學報
생태배경학보
ECOLOGY AND ENVIRONMENT
2014年
12期
1964-1971
,共8页
郑金秀%池仕运%李聃%汪红军%胡菊香
鄭金秀%池仕運%李聃%汪紅軍%鬍菊香
정금수%지사운%리담%왕홍군%호국향
轮虫%种群结构%富营养化%浅水湖泊
輪蟲%種群結構%富營養化%淺水湖泊
륜충%충군결구%부영양화%천수호박
rotifers%community structure%eutrophication%shallow lakes
石臼湖和固城湖是长江中下游两个浅水湖泊,富营养化问题日益突出。为探索湖泊富营养化对轮虫的影响,于2012年平水期和枯水期对这两个湖泊轮虫种群结构进行了调查,并检测水体理化因子,分析轮虫分布与水环境因子及水体富营养状况的关系。水质检测结果显示,平水期石臼湖除个别点水体综合营养状态指数(TLI)>50为轻度富营养状态外,大多数站点TLI<50,为中营养状态;枯水期两个湖泊TLI>50,处于轻度-中度富营养化状态。水生生物调查检出轮虫35种,其中石臼湖33种,固城湖27种,平水期种类多于枯水期。出现的轮虫以臂尾轮虫(Brachionus)和异尾轮虫(Trichocerca)居多,优势种主要有螺形龟甲轮虫(Keratella cochlearis)、广生多肢轮虫(Polyarthra vulgaris)、疣毛轮虫(Trichocerca sp.)、沟痕泡轮虫(Pompholyx sulcata)、异尾轮虫属和臂尾轮虫属等。轮虫平均密度3023.19 ind·L-1,平均生物量745.72μg·L-1。现存量季节变动明显,大部分站点平水期大于枯水期。轮虫多样性指数也是平水期大于枯水期,石臼湖轮虫多样性大于固城湖。水体综合营养状态指数(TLI)与轮虫种类数和多样性成显著负相关,随着富营养化加剧,轮虫种类减少,多样性降低。典范对应分析(Canonical Correspondence Analysis,CCA)表明,影响轮虫种群分布的主要环境因子为NH4+-N、TN、TP和CODMn。按轮虫丰度分布与水环境因子的关系排序,2次调查的24个站点可大致分成3个组。轮虫种群结构受水体富营养状态影响,每组站点的代表性种类对水体营养状态有较好的指示作用。组1的代表性种类为曲腿龟甲轮虫,指示营养级别O-β;组2代表性种类萼花臂尾轮虫,指示的营养级别为β-α;组3以O营养级种类为主。
石臼湖和固城湖是長江中下遊兩箇淺水湖泊,富營養化問題日益突齣。為探索湖泊富營養化對輪蟲的影響,于2012年平水期和枯水期對這兩箇湖泊輪蟲種群結構進行瞭調查,併檢測水體理化因子,分析輪蟲分佈與水環境因子及水體富營養狀況的關繫。水質檢測結果顯示,平水期石臼湖除箇彆點水體綜閤營養狀態指數(TLI)>50為輕度富營養狀態外,大多數站點TLI<50,為中營養狀態;枯水期兩箇湖泊TLI>50,處于輕度-中度富營養化狀態。水生生物調查檢齣輪蟲35種,其中石臼湖33種,固城湖27種,平水期種類多于枯水期。齣現的輪蟲以臂尾輪蟲(Brachionus)和異尾輪蟲(Trichocerca)居多,優勢種主要有螺形龜甲輪蟲(Keratella cochlearis)、廣生多肢輪蟲(Polyarthra vulgaris)、疣毛輪蟲(Trichocerca sp.)、溝痕泡輪蟲(Pompholyx sulcata)、異尾輪蟲屬和臂尾輪蟲屬等。輪蟲平均密度3023.19 ind·L-1,平均生物量745.72μg·L-1。現存量季節變動明顯,大部分站點平水期大于枯水期。輪蟲多樣性指數也是平水期大于枯水期,石臼湖輪蟲多樣性大于固城湖。水體綜閤營養狀態指數(TLI)與輪蟲種類數和多樣性成顯著負相關,隨著富營養化加劇,輪蟲種類減少,多樣性降低。典範對應分析(Canonical Correspondence Analysis,CCA)錶明,影響輪蟲種群分佈的主要環境因子為NH4+-N、TN、TP和CODMn。按輪蟲豐度分佈與水環境因子的關繫排序,2次調查的24箇站點可大緻分成3箇組。輪蟲種群結構受水體富營養狀態影響,每組站點的代錶性種類對水體營養狀態有較好的指示作用。組1的代錶性種類為麯腿龜甲輪蟲,指示營養級彆O-β;組2代錶性種類萼花臂尾輪蟲,指示的營養級彆為β-α;組3以O營養級種類為主。
석구호화고성호시장강중하유량개천수호박,부영양화문제일익돌출。위탐색호박부영양화대륜충적영향,우2012년평수기화고수기대저량개호박륜충충군결구진행료조사,병검측수체이화인자,분석륜충분포여수배경인자급수체부영양상황적관계。수질검측결과현시,평수기석구호제개별점수체종합영양상태지수(TLI)>50위경도부영양상태외,대다수참점TLI<50,위중영양상태;고수기량개호박TLI>50,처우경도-중도부영양화상태。수생생물조사검출륜충35충,기중석구호33충,고성호27충,평수기충류다우고수기。출현적륜충이비미륜충(Brachionus)화이미륜충(Trichocerca)거다,우세충주요유라형구갑륜충(Keratella cochlearis)、엄생다지륜충(Polyarthra vulgaris)、우모륜충(Trichocerca sp.)、구흔포륜충(Pompholyx sulcata)、이미륜충속화비미륜충속등。륜충평균밀도3023.19 ind·L-1,평균생물량745.72μg·L-1。현존량계절변동명현,대부분참점평수기대우고수기。륜충다양성지수야시평수기대우고수기,석구호륜충다양성대우고성호。수체종합영양상태지수(TLI)여륜충충류수화다양성성현저부상관,수착부영양화가극,륜충충류감소,다양성강저。전범대응분석(Canonical Correspondence Analysis,CCA)표명,영향륜충충군분포적주요배경인자위NH4+-N、TN、TP화CODMn。안륜충봉도분포여수배경인자적관계배서,2차조사적24개참점가대치분성3개조。륜충충군결구수수체부영양상태영향,매조참점적대표성충류대수체영양상태유교호적지시작용。조1적대표성충류위곡퇴구갑륜충,지시영양급별O-β;조2대표성충류악화비미륜충,지시적영양급별위β-α;조3이O영양급충류위주。
Shijiu Lake and Gucheng Lake are two shallow lakes in the middle and downstream areas of the Yangtze River. The lake eutrophication in the lakes has attracted wide attention. To explore the influence of eutrophication on rotifers, an investigation on rotifer community structure were carried out in normal season and dry season in 2012. At the same time water quality parameters were tested to study the relationship between the rotifers distribution and water quality including the eutrophication status. The results showed that almost of sites in Shijiu Lake were mesotrophic (Trophic Level Index, TLI<50) except that few sites in mesotrophication (TLI>50). However in dry season, both lakes were mesotrophic (TLI>50). The investigation of aquatic organism showed that 35 species of rotifers were detected in total. There were 33 species in Shijiu lake and 27 species in Gucheng lake. the species were more in normal season. The frequency of Brachionus and Trichocerca was the highest. The dominant species were Keratella cochlearis, Polyarthra vulgaris, Trichocerca sp, Pompholyx sulcata, Trichocerca sp and Brachionus sp. The average density of the rotifers was 3023.19 ind·L-1 and the average biomass was 745.72 μg·L-1. The seasonal changes were obvious in the standing crop. The standing crop in the normal season was higher than in the dry season in almost of the sites. Rotifers diversity index was higher in Shijiu lake. TLI was significantly negatively related to the rotifers species number and diversity. With the increasing of nutrient loading, rotifer species and diversity decreased. Further, Canonical Correspondence Analysis(CCA) showed that the main water qualtiy factors affecting the rotifer species distribution were NH4+-N, TN,TP and CODMn. According to the sort of the relationships between the rotifer abundance and the water environment factors, 24 sites can be roughly divided into three groups. The results showed that Rotifer community structure was affected by eutrophication, and the representative species in each group had a good indication on the trophic status. The representative species in Group 1 wasKeratella valga, indicating the trophic level of oligosaprobic-β mesosaprobic; the representative species of Group 2 wasBrachionus calyciflorus, indicating the nutrition level ofβ-α mesosaprobic; the representative species of Group 3 complicated, mainly as the indicators for oligosaprobic.