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1.
桑沟湾微微型浮游生物丰度和生物量分布的季节变化 总被引:1,自引:0,他引:1
于2013年4月、7月、10~月和2014年1月,分四个季节在桑沟湾利用流式细胞技术对桑沟湾微微型浮游生物丰度和生物量的时空分布特征进行了研究,并统计分析了其与环境因子之间的关系。结果表明,四个季节中桑沟湾聚球藻丰度和生物量分别为0.04×10~3~408.59×10~3个/mL、0.01~10~2.15 mg/m3,微微型真核浮游生物的丰度和生物量分别为0.21×10~3~99.64×10~3个/mL、0.31~149.46 mg/m3,异养细菌的丰度和生物量分别为3.34×10~5~50.16×10~5个/mL、6.68~10~0.32 mg/m3。四个季节中,夏季桑沟湾微微型浮游生物的丰度和生物量高于其他季节。异养细菌对微微型浮游生物总生物量的四季平均贡献为62.11%,高于自养微微型浮游生物;微微型真核浮游生物占自养微微型浮游生物总生物量比例最高,平均可达86.85%。统计分析显示温度、叶绿素a和营养盐浓度是影响桑沟湾微微型浮游生物丰度和生物量分布的主要因素。上述结果为桑沟湾生态环境的检测和评估提供了基础数据。 相似文献
2.
热带西太平洋Y3和M2海山微食物网主要类群生态分布与比较 总被引:2,自引:0,他引:2
2014年12月和2016年3月分别对热带西太平洋Y3海山(中层海山)和M2海山(浅海山)微食物网主要类群(包括聚球藻、原绿球藻、微微型真核浮游生物、异养细菌和浮游纤毛虫)丰度和生物量垂直分布进行了研究。结果表明,Y3和M2海山水文环境比较相似但略有区别,叶绿素最大值层(DCM)分别在75—100m和110m水层,微食物网各主要类群在垂直尺度上的分布与叶绿素a浓度紧密相关。其中浮游纤毛虫呈现"双峰型"模式,即丰度高值出现在表层和DCM层;原绿球藻和微微型真核浮游生物呈现"单峰型"模式,丰度高值出现在DCM层;聚球藻和异养细菌峰型相对不显著,DCM层以浅丰度较高,DCM层以深丰度明显降低。分析其原因,可能是受到温度、光照和营养盐的共同影响。Y3和M2海山微食物网结构的垂直变化不完全一致。其中,Y3海山30m以浅和150m以深异养细菌生物量占绝对优势,75—100m水层自养型生物(原绿球藻和微微型真核浮游生物)占绝对优势;M2海山75m以浅和200m以深异养细菌占绝对优势,110—150m自养型生物占绝对优势。M2海山自养型生物占优势的水层要明显深于Y3海山,可能与它们的海山类型和采样季节不同有关。 相似文献
3.
2009年冬、夏季南海北部超微型浮游生物的分布特征及其环境相关分析 总被引:2,自引:1,他引:1
2009年2月(冬季)和8月(夏季)在南海北部海域(nSCS)采用流式细胞术对聚球藻、原绿球藻、超微型光合真核生物3类超微型光合浮游生物和异养浮游细菌的丰度和碳生物量的时空分布特征进行了研究,并分析了其与环境因子之间的关系。结果表明,夏季聚球藻和原绿球藻的平均丰度高于冬季,超微型光合真核生物和异养浮游细菌的丰度反之,为冬季高于夏季。聚球藻、超微型光合真核生物和异养浮游细菌在富营养的近岸陆架海域丰度较高,而原绿球藻高丰度则出现在陆坡开阔海域。在垂直分布上,聚球藻主要分布在跃层以上,跃层以下丰度迅速降低;原绿球藻高丰度主要出现在真光层底部;超微型光合真核生物在水层中的高值同样出现在真光层底部,且与Pico级份叶绿素a浓度分布一致;异养浮游细菌在水体中的分布与聚球藻类似。这些分布格局的差异,取决于环境条件的变化和4类超微型浮游生物生态生理适应性的差异。在超微型光合浮游生物群落中,各类群碳生物量的贡献因季节和海域类型的不同而发生变化:聚球藻在夏季近岸陆架区占超微型光合浮游生物总碳生物量的41%,原绿球藻在陆坡开阔海成为主要贡献者(50%),超微型光合真核生物碳生物量以冬季为高(在近岸陆架区占比68%)。冬、夏季异养浮游细菌碳生物量均高于超微型光合浮游生物碳生物量。 相似文献
4.
获取并分析了2017年8月热带西太平洋M4海山水体中的超微型浮游生物样品,根据流式细胞术的散射光和荧光信号,检测到M4海山各水层中普遍存在四个超微型自养浮游生物类群(聚球藻、原绿球藻、微微型真核浮游生物、微型真核浮游生物)和两个超微型异养原核生物类群(低核酸含量和高核酸含量异养原核生物)。聚球藻丰度高值出现在100m以浅;原绿球藻和微微型真核浮游生物丰度高值区在深层叶绿素最大值附近(75—150m);微型真核浮游生物和异养原核生物分布范围较广,150m以浅丰度较高。异养原核生物的生物量(1.68—11.25μgC/L)高于自养浮游生物(0.05—6.02μgC/L)的生物量。在超微型自养浮游生物中,原绿球藻生物量在100—150m水层占优势(53.83%±6.32%),微型真核浮游生物的生物量在75m以浅(58.62%±8.53%)和200—300m水层占优势(46.18%±7.82%)。在异养原核生物中,高核酸含量异养原核生物的生物量所占百分比(61.05%±3.98%)高于低核酸含量异养原核生物(38.95%±3.98%),然而在海山附近DCM层低核酸含量异养原核生物比例最高可达58.64%。冗余分析表明,超微型浮游生物的丰度与温度呈正相关,与深度和营养盐呈负相关关系。在M4海山超微型自养浮游生物分布没有明显的"海山效应",但海山的存在会对异养原核生物两个类群生物量的比例产生影响。 相似文献
5.
6.
2006年6月12日至22日“东方红2号”考察船夏季航次期间,在长江口3个连续观测站位进行了水样采集,应用流式细胞仪分析了水样中的极微型浮游生物(Femtoplankton)和微微型浮游生物(Picoplankton)。结果显示,原绿球藻(Prochlorococcus)在所有样品中均未检测到;检测到的聚球藻(Synechococcus)和微微型真核浮游植物(Picoeukaryotes)平均丰度达数量级10^5~10^6个/L,异养细菌(Heterotrophic bacteria)和病毒(Viruses)平均丰度达数量级10^8~10^9个/L。在浑浊的长江口水域,极微型和微微型浮游生物的垂向分布特征不同,主要与各站位特有的水动力条件密切相关:浊度是调控微微型真核浮游植物、异养细菌和病毒周日变化的关键因子之一;微微型真核浮游植物成为微微型浮游植物中最重要的组成部分,与异养细菌具有显著的正相关关系。 相似文献
7.
夏季南黄海主要环境因子对微微型浮游生物分布影响 总被引:2,自引:1,他引:1
利用流式细胞技术, 获取南黄海夏季微微型浮游生物丰度数据, 分析了其组成和分布规律, 并探讨了主要的影响因子。2011年夏季, 聚球藻、微微型真核藻、异养细菌在整个调查海区的平均丰度分别在1×104、1×103、1×106 cells/mL数量级上。在全调查海区, 聚球藻和微微型真核藻受温度和光照的限制明显, 主要集中分布在温跃层及其以上水层;而营养盐的限制较小, 它们的影响只有在沿岸流影响明显的西部海区才能较为明显的体现出来。结果表明在该海域浓度较高的营养盐能够促进微微型浮游生物的生长, 但不是其限制因素;异养细菌受环境因子限制较小, 即使在深海也保持着较高的丰度。 相似文献
8.
南极考察航线跨越全球多个大洋,对认识超微型浮游生物在全球尺度分布及变化具有重要意义。依托中国第33次南极考察,利用流式细胞仪对航线海表水样中的超微型浮游生物进行了现场测定。结果表明,在热带与温带海域,超微型浮游生物量可占总叶绿素a浓度的60%以上,在南大洋则集中在15%~40%;原绿球藻主要分布在40°S以北海域,聚球藻主要分布在50°S以北海域,而超微型真核藻类和异养细菌则在沿线各海域均有明显分布。在纬向上,原绿球藻、聚球藻、超微型真核藻类和异养细菌的平均丰度分别为(5.50±9.09)×103 cells/mL、(13.56±20.33)×103 cells/mL、(3.87±3.08)×103 cells/mL和(6.39±4.78)×105 cells/mL;南大洋海域,超微型真核藻类和异养细菌的平均丰度分别为(3.31±1.46)×103 cells/mL和(4.68±4.39)×105 cells/mL,在少数站位检测到较低丰度的聚球藻,平均值... 相似文献
9.
养殖活动对超微型浮游生物分布影响的研究 总被引:2,自引:1,他引:1
利用流式细胞仪对河北省扇贝养殖区微微型浮游植物、异养细菌、浮游病毒4季的丰度分布特征进行了研究,分析了三者与环境因子的相关性,并与渤海、北黄海非养殖区的超微型浮游生物丰度的分布特征进行对比。结果显示:在养殖区海域,聚球藻丰度在9.00×102—7.07×105cell/m L之间,峰值出现在秋季,且与其他季节差异显著(P0.01)。微微型真核藻类丰度在5.80×102—3.23×105cell/m L之间,夏季赤潮暴发期间,丰度达到3.23×105cell/m L,显著高于其他季节(P0.01)。异养细菌丰度在3.10×105—3.79×106cell/m L之间,峰值出现在秋季,夏、秋季丰度显著高于春、冬季(P0.01)。浮游病毒丰度在2.50×105—2.17×106cell/m L之间,峰值出现在秋季,但无显著性季节差异(P0.05)。通过主成分分析发现,聚球藻、微微型真核藻类、异养细菌和浮游病毒的丰度在不同季节受到不同环境因子的影响。在春、冬季,温度是主要影响因素;而在夏、秋季,主要受到营养盐的影响。养殖区与非养殖区超微型浮游生物主成分4季均有显著差异,养殖区异养细菌4季均是超微型浮游生物的主成分,而非养殖区超微型浮游生物的主成分4季均是微微型浮游植物,结果表明养殖活动显著影响了养殖区超微型浮游生物的群落结构和功能。 相似文献
10.
为探究珠江口海域自养微微型浮游生物种群时空分布特征及其与环境之间的关系,于2013年5~11月,运用高液相色谱(HPLC)法和流式细胞术对珠江口海域表层水体中微微型浮游生物进行测定。流式细胞计数结果显示,珠江口海域自养微微型浮游生物由聚球藻(Synechococcus, Syn)和微微型真核生物(Picoeukaryotes,PEUK)组成。聚球藻始终占据总细胞丰度的主导地位。光合色素化学分类法(Chemotaxonomy,CHEMTAX)分析表明,自养微微型浮游生物群落结构具有明显的季节性变化,春季和夏季生物量以聚球藻为主,秋季生物量以青绿藻为主。CHEMTAX分析和流式细胞计数结果的相关性分析表明,在春季和夏季Syn细胞丰度与CHEMTAX生物量(即Syn贡献chla)之间呈现极显著正相关(P<0.01),PEUK细胞丰度与CHEMTAX生物量(即PEUK贡献chla)也存在显著正相关(P<0.05);然而,在秋季则无显著性相关关系(P>0.05)。冗余分析表明,温度和营养盐浓度是影响自养微微型浮游生物群落分布与组成的重要因素。另外,盐度、透明度、悬浮颗粒物对自养... 相似文献
11.
为全面了解黄海典型海区微微型浮游植物的季节变化特征,于2009年7月至2010年6月在北黄海獐子岛海域和2010年1~12月在南黄海胶州湾进行逐月调查采样,利用流式细胞仪检测了表层海水中微微型浮游植物(picophytoplankton)的丰度,包括聚球藻(Synechococcus,SYN)和微微型真核浮游植物(picoeukaryotes,PEUK),并分析了其与环境因子的关系。獐子岛海域和胶州湾SYN和PEUK全年广泛分布,獐子岛海域SYN丰度范围在0.05×103~120.00×103cells/mL之间,丰度在秋季最高;胶州湾SYN丰度范围在0.02×103~61.80×103cells/mL之间,丰度在夏季最高。獐子岛海域PEUK丰度范围在0.01×103~18.76×103cells/mL之间,丰度在秋季最高;胶州湾PEUK丰度范围在0.25×103~95.57×103 cells/mL之间,丰度在春季最高。獐子岛海域微微型浮游植物丰度组成以SYN为主;而胶州湾以PEUK为主。PEUK是两海区微微型浮游植物生物量的主要贡献者。相关性分析结果表明,温度是影响两海区SYN丰度季节变化的最主要因素;影响PEUK季节分布的因素不完全一致,獐子岛海域PEUK丰度主要受温度调控;胶州湾PEUK丰度主要受温度和营养盐浓度影响。与已有研究比较,这两个海区的微微型浮游植物生物量对浮游植物生物量的贡献明显高于其他温带沿岸海域,预示微微型浮游植物在獐子岛海域和胶州湾生态系统中的重要作用,值得进一步深入研究。 相似文献
12.
Community Structure and Dynamics of Phytoplankton in the Western Subarctic Pacific Ocean: A Synthesis 总被引:1,自引:1,他引:1
The phytoplankton community in the western subarctic Pacific (WSP) is composed mostly of pico- and nanophytoplankton. Chlorophyll
a (Chl a) in the <2 μm size fraction accounted for more than half of the total Chl a in all seasons, with higher contributions of up to 75% of the total Chl a in summer and fall. The exception is the western boundary along the Kamchatka Peninsula and Kuril Islands and the Oyashio
region where diatoms make up the majority of total Chl a during the spring bloom. Among the picophytoplankton, picoeukaryotes and Synechococcus are approximately equally abundant, but the former is more important in term of carbon biomass. Despite the lack of a clear
seasonal variation in Chl a concentration, primary productivity showed a large seasonal variation, and was lowest in winter and highest in spring. Seasonal
succession in the phytoplankton community is also evident with the abundance of diatoms peaking in May, followed by picoeukaryotes
and Synechococcus in summer. The growth of phytoplankton (especially >10 μm cell size) in the western subarctic Pacific is often limited by
iron bioavailability, and microzooplankton grazing keeps the standing stock of pico- and nano-phytoplankton low. Compared
to the other HNLC regions (the eastern equatorial Pacific, the Southern Ocean, and the eastern subarctic Pacific), iron limitation
in the Western Subarctic Gyre (WSG) may be less severe probably due to higher iron concentrations. The Oyashio region has
similar physical condition, macronutrient supply and phytoplankton species compositions to the WSG, but much higher phytoplankton
biomass and primary productivity. The difference between the Oyashio region and the WSG is also believed to be the results
of difference in iron bioavailability in both regions.
This revised version was published online in July 2006 with corrections to the Cover Date. 相似文献
13.
Role of environment and hydrography in determining the picoplankton community structure of Sagami Bay,Japan 总被引:1,自引:0,他引:1
Smita Mitbavkar Toshiro Saino Naho Horimoto Jota Kanda Takashi Ishimaru 《Journal of Oceanography》2009,65(2):195-208
Seasonal variations in the picoplankton community were investigated from June 2002 to March 2004 within the photic zone of
Sagami Bay, Japan. The study area was mostly dominated by coastal waters during the warm period (mixed layer water temperature
≥ 18°C). During the cold period (mixed layer water temperature ≤ 18°C), the water mass was characterized by low temperature
and high saline waters indicative of the North Pacific Subtropical Mode Water (NPSTMW). Occasionally, a third type of water
mass characterized by high temperature and low saline properties was observed, which could be evidence of the intrusion of
warm Kuroshio waters. Synechococcus was the dominant picophytoplankton (5−28 × 1011 cells m−2) followed by Prochlorococcus (1−5 × 1011 cells m−2) and picoeukaryotes during the warm period. Heterotrophic bacteria dominated the picoplankton community throughout the year,
especially in the warm period. During the Kuroshio Current advection, cyanobacterial abundance was high whereas that of picoeukaryotes
and heterotrophic bacteria was low. During the cold period, homogeneously distributed, lower picophytoplankton cell densities
were observed. The dominance of Synechococcus in the warm period reflects the importance of high temperature, low salinity and high Photosynthetically Active Radiation
(PAR) on its distribution. Cyanobacterial and heterotrophic bacterial abundance showed a positive correlation with temperature.
Prochlorococcus and picoeukaryotes showed a positive correlation with nutrients. Picoeukaryotes were the major contributors to the picophytoplankton
carbon biomass. The annual picophytoplankton contribution to the photosynthetic biomass was 32 ± 4%. These observations suggest
that the environmental conditions, combined with the seasonal variability in the source of the water mass, determines the
community structure of picoplankton, which contributes substantially to the phytoplankton biomass and can play a very important
role in the food web dynamics of Sagami Bay. 相似文献
14.
An-Yi Tsai Gwo-Ching Gong Robert W. Sanders Chien-Fu Chao Kuo-Ping Chiang 《Journal of Oceanography》2010,66(6):873-883
This two-year study investigates the possible factors that determine spatial and temporal dynamics of picoplankton (heterotrophic
bacteria, autotrophic picoplankton—Synechococcus spp., Prochlorococcus, and picoeukaryotes) and nanoflagellate abundance in the subtropical Ilan Bay, Taiwan, where the inner bay is affected by
freshwater run-off from the Lanyang River and the eastern outer bay by the Kuroshio Current. In the inner bay, there was more
rain and freshwater discharge in 2005 than in 2004 during the warm season (>24° C, June–September). The abundance of bacteria,
Synechococcus spp., Prochlorococcus, and picoeukaryotes and the percentage contributions of pigmented nanoflagellate (PNF %) were two- to eight-fold greater
during this period (July in 2005) than for other sampling periods. Relatively low abundance of heterotrophic nanoflagellates
(HNF) in the presence of abundant picoplankton prey suggests that top-down control determined HNF abundance in the Ilan Bay,
Taiwan. 相似文献
15.
Picoplankton community structure on the Atlantic Meridional Transect: a comparison between seasons 总被引:3,自引:0,他引:3
Mikhail V. Zubkov Michael A. Sleigh Peter H. Burkill Raymond J. G. Leakey 《Progress in Oceanography》2000,45(3-4)
Samples collected from 10 depths at 25 stations in September–October 1996 and 12 depths at 28 stations in April–May 1997 on an Atlantic Meridional Transect between the British Isles and the Falkland Islands were analysed by flow cytometry to determine the numbers and biomass of four categories of picoplankton: Prochlorococcus spp, Synechococcus spp, picoeukaryotic phytoplankton and heterotrophic bacteria. The composition of the picoplankton communities confirmed earlier findings (Zubkov, Sleigh, Tarran, Burkill & Leakey, 1998) about distinctive regions along the transect and indicated that the stations should be grouped into five provinces: northern temperate, northern Atlantic gyre, equatorial, southern Atlantic gyre and southern temperate, with an intrusion of upwelling water off the coast of Mauritania between the northern Atlantic gyre and equatorial waters. Prochlorococcus was the most numerous phototrophic organism in waters of both northern and southern gyres and in the equatorial region, at concentrations in excess of 0.1×106ml−1; it also dominated plant biomass in the gyres, but the biomass of the larger picoeukaryotic algae equalled that of Prochlorococcus in the equatorial region; higher standing stocks of both Prochlorococcus and picoeukaryotes were present in spring than in autumn in waters of both gyres. In temperate waters at both ends of the transect the numbers and biomass of picoeukaryotes and, more locally, of Synechococcus increased, and the Synechococcus, particularly, were more numerous in spring than in autumn. There was a pronounced southward shift of the main populations of both Synechococcus and Prochlorococcus in April–May in comparison to those of September–October, associated with seasonal changes in solar radiation, the abundance of Prochlorococcus dropping sharply near the 17°C contour, while Synechococcus was still present at temperatures below 10°C. Picoeukaryotes were more tolerant of low temperatures and lower light levels, often being more abundant in samples from greater depths, where they contributed to the deep chlorophyll maximum. Heterotrophic bacterial numbers and biomass tended to be highest in those samples where phototrophic biomass was greatest, with peaks in temperate and equatorial waters, which were shifted southwards in April–May compared with September–October. 相似文献
16.
Seasonal changes in nano/micro-zooplankton grazing on pico-, nano- and micro-size phytoplankton and heterotrophic nano-flagellates
(HNF) feeding on heterotrophic bacteria were quantified by the dilution technique in the surface layer off Cape Esan, southwestern
Hokkaido, Japan. Pico- and nano-size phytoplankton were major components throughout the year except in spring when a diatom
bloom was observed. Although there was little seasonal variation in bacteria and HNF biomass throughout the year, the micro-zooplankton
biomass varied appreciably with a peak in spring. Nano/micro-zooplankton grazing or feeding on pico-size chl-a and bacteria were well balanced throughout the year. However, nano-size and micro-size chl-a growth were much greater than grazing in summer. Nano/micro-zooplankton ingestion of phytoplankton was greater than their
ingestion of bacteria almost throughout the year, which suggests phytoplankton are more important as food sources of nano/micro-zooplankton
in microbial food webs off Cape Esan than bacteria off Cape Esan.
This revised version was published online in July 2006 with corrections to the Cover Date. 相似文献
17.
An-Yi Tsai Gwo-Ching Gong Robert W. Sanders Kuo-Ping Chiang Chien-Fu Chao 《Journal of Oceanography》2012,68(1):151-162
This study used the dilution method to examine growth and grazing rates of heterotrophic bacteria and an autotrophic picoplankton,
Synechococcus spp., from 1 to 11 July 2007 in the East China Sea. The main influence of oceanographic conditions in this aquatic system
was the introduction of fresh, high-nutrient water from Changjiang River and the extremely nutrient-poor, high-salinity waters
of Kuroshio Water. In these experiments, deviation from linearity in the relationship between dilution factor and net growth
rate was significant in a large number of cases. Growth rates for heterotrophic bacteria ranged from 0.024 to 0.24, and for
Synechococcus spp. from 0.03 to 0.21 h−1. Grazing rates ranged from 0.02 to 0.19 and 0.01 to 0.13 h−1, respectively. The spatial variations of Synechococcus spp. production to the primary production ratio (SP/PP) were low (<5%) in high Chl a environments and increased exponentially in low Chl a environments, indicating that Synechococcus spp. contributes to a large extent to the photosynthetic biomass in the open sea, especially in the more oligotrophic Kuroshio
Water. Furthermore, the results of our dilution experiments suggest that nanoflagellates largely depend on heterotrophic bacteria
as an important energy source. On average, heterotrophic bacteria contributes to 76 and 59% of carbon consumed by nanoflagellates
within the plume (salinity <31) and outside of it (salinity >31). 相似文献
18.
The concentration of nutrients was measured during the spring phytoplankton bloom in Funka Bay over a 5-year period (1988–92). During the winter mixing period, nutrient concentrations were similar in every year except in 1990 when a high concentration of silicate was observed. There was interannual variation in the onset of the bloom, presumably depending on the stability of the water column. The bloom developed in early March when the Oyashio water (OW), which has a lower density than the existing winter water, flowed into the bay and the pycnocline formed near the bottom of the euphotic zone. In this case, high chl a was found only in the euphotic zone and nutrient utilization was limited to this zone. In the year when the inflow of OW was not observed by April, the bloom took place at the end of March without strong stratification and high chl a was found in the whole water column, accompanied by a decrease in nutrients. Interannual differences were found not only at the beginning of the decrease, but also in the thickness of the layer which showed a decrease in nutrients. Primary production from the beginning to the end of the spring bloom was estimated from the nutrient budget before and after the spring bloom. The integrated production over the spring bloom period ranged from 25 to 73 g C m-2, which accounts for 19–56% of the annual production in this bay. We found that the timing of the bloom was strongly dependent on the inflow of OW, but the amount of production was not clearly related to this timing. 相似文献
19.
Koji Suzuki Akira KuwataNaoki Yoshie Akira Shibata Kyoko KawanobeHiroaki Saito 《Deep Sea Research Part I: Oceanographic Research Papers》2011,58(5):575-589
We characterized the community composition of phytoplankton in the western subarctic Pacific from the pre-bloom to the decline phase of the spring bloom with special reference to decreases in the silicic acid concentration in surface waters as an index for diatom bloom development. Furthermore, responses of heterotrophic bacteria and viruses to the spring bloom were also concomitantly investigated. Under pre-bloom conditions when nutrients were abundant but the surface mixed layer depth was relatively deep, chlorophyll (Chl) a concentrations were consistently low and green algae (chlorophytes and prasinophytes), cryptophytes, and diatoms were predominant in the phytoplankton assemblages as estimated by algal pigment signatures. Together with the shallowing of the mixed layer depth and the decrease in silicic acid concentration, diatoms bloomed remarkably in the Oyashio region, though the magnitude of the bloom in the Kuroshio-Oyashio transition (hereafter Transition) region was relatively small. A total of 77 diatom species were identified, with the bloom-forming diatoms mainly consisting of Thalassiosira, Chaetoceros, and Fragilariopsis species. It has become evident that the carotenoid fucoxanthin can serve as a strong indicator of the diatom carbon biomass during the spring diatom bloom. Differences in the species richness of diatoms among stations generally enabled us to separate the Oyashio bloom stations from the Transition and the Oyashio pre-bloom stations. Relatively high values of the Shannon-Wiener index for the diatom species were also maintained during the Oyashio bloom, indicating that a wide variety of species then shared dominance. In the decline phase of the Oyashio bloom when surface nutrient concentrations decreased, senescent diatom cells increased, as inferred from the levels of chlorophyllide a. Although the cell density of heterotrophic bacteria changed little with the development of the diatom bloom, viral abundance increased toward the end of the bloom, suggesting an increased likelihood of mortality among organisms including diatoms resulting from viral infection. This is the first report on the microbial trophodynamics, including viruses, during the spring diatom bloom in the western subarctic Pacific. 相似文献