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Dynamics of Zooplankton Community in Maryland Coastal Bays and Their Driving Mechanisms CREST Teacher Development Workshop July 17 , 2012 Paulinus Chigbu , Ph.D. University of Maryland Eastern Shore . Goal 1: Study, understand, model & predict the impacts of land use & climate variability .
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Dynamics of Zooplankton Community in Maryland Coastal Bays and Their Driving MechanismsCREST Teacher Development WorkshopJuly 17, 2012PaulinusChigbu, Ph.D. University of Maryland Eastern Shore
Goal 1: Study, understand, model & predict the impacts of land use & climate variability • Subproject 1: Water quality dynamics in relation to land use and climate variability (Project Leaders: Eric May & Ali Ishaque) • Subproject 2: Understand the dynamics of phytoplankton and macroalgae species including HABs in MCBs (Project Leaders: MadhumiMitra & Chunlei Fan) • Subproject 3: Dynamics of zooplankton community structure and the driving mechanisms (Project Leaders: PaulinusChigbu & Kam Tang) • Subproject 4: Physiological effects of hypoxia and environmental contaminants on Atlantic croaker (Project Leader: Andrea Johnson) • Subproject 5: Effects of environmental factors on blue crab and its relation to infection by Hematodinium sp. (Project Leaders: Joseph Pitula & Sook Chung)
Theme 1 Land Use Zooplankton Community Structure & Dynamics Theme 3 HABs Occurrence & Dynamics Theme 2 Dynamics Water Effects of water quality on Hamatodinium- Blue crab relationships Theme 5 Distributional & Physiological Effects of water quality on Fish Theme 4 Quality Climate Variability Weather Interrelationships Among the Subprojects
Plankton • Aquatic organisms that have limited powers of locomotion & therefore can not swim independent of water movement • Two sub-divisions of plankton: • Phytoplankton: Free-floating organisms capable of photosynthesis • Zooplankton: Free-floating animals & animal-like protists • Bacterioplankton (bacteria)
Animal Phyla & Animal-like Protists • Protozoan Groups • Sponges: Phylum Porifera • Radiate Animals: Phylum Cnidaria & Phylum Ctenophora • Acoelomate Bilateral Animals: e.g. Flatworms (Phylum Platyhelminthes) • Pseudocoelomate Animals (e.g. Phylum Rotifera) • Molluscs (Phylum Mollusca) • Segmented Worms (Phylum Annelida) • Arthropods (Phylum Arthropoda) • Echinoderms (Phylum Echinodermata) • Chordates (Phylum Chordata)
Classification of Plankton by Size • Net Plankton: • Megaplankton (> 20 cm) • Macroplankton (2 – 20 cm) • Mesoplankton (0.2 – 20 mm) • Microplankton (20 – 200 micron) • Nanoplankton: (2 – 20 micron) • Picoplankton: (0.2 – 2 micron)-> bacteria & cyanobacteria • Femtoplankton: (0.02 – 0.2 micron)
Classification of Zooplankton based on Life History Characteristics • Holoplankton: Spend their entire lives in the water column as plankton • Meroplankton: Spend part of their lives in the water column
http://www.bluecrab.info/lifecycle.html Planktonic as a larva (live in the water column) Planktonic as a larva (live in the water column) Benthic as adult (live on the bottom) Benthic as adult (live on the bottom)
Diversity of Zooplankton • Zooplankton consist of a host of larval & adult forms that represent most of the animal & many of the protistan phyla. • In the marine environment, the dominant net zooplankton are the copepods (subclass: Copepoda; subphylum: Crustacea; Phylum: Arthropoda)
Copepods • May be free-living, planktonic, benthic or parasitic • Free-living planktonic forms swim weakly, using their jointed thoracic limbs & have a characteristic jerky movement • Use their large antennae to slow their rate of sinking
Reproduction in Copepods • Sexes are separate • Sperm packaged in spermatophores is transferred to the female • Eggs are fertilized & enclosed in a sac attached to the female’s body • Eggs hatch into nauplius larvae which pass through many naupliar stages, copepodid stages and finally adult stage
Cladocerans, Ostracods, Mysids, Amphipods, Euphausids *Most are small filter feeders straining algae out of water *Some (e.g.) mysids are also active predators
Other Zooplankton Kingdom: Protista Phylum: Sarcomastigophora Order: Foraminiferida (forams) Order: Radiolaria *Important grazers in the marine environments *Net plankton, Holoplankton *Radiolarians & foraminiferans are single-celled organisms that produce skeletons of CaCO3and SiO2 (glass), respectively *Thick layers of their skeletal remains occur on the ocean floor as foraminiferan and radiolarian ooze
Other Zooplankton contd. • Other important grazers include: ciliates (Phylum Ciliophora) and small flagellates (Phylum Sarcomastigophora) • Are nanoplankton • Are major grazers of the nanophytoplankton
Examples of some plankton members of the Kingdom Protista (a) Foraminiferan (b) Radiolarian (c) Ciliate (d) Flagellate (e) Flagellate
Holoplanktonic Members of the Phylum: Cnidaria • Includes: • Jellyfishes of the classes Hydrozoa and Scyphozoa and • Complex hydrozoan colonies known as siphonophores *Scyphozoan jellyfishes are among the largest planktonic organisms and may occasionally be found in large numbers
The large Scyphozoan Jellyfish (Pelagiacolorata) with juvenile cancer crabs
Jellyfish (scyphozoan) & Siphonophore (Colonial hydrozoan; Physalia)
Benthos bottom dwellers • Epifauna • Infauna • Nektobenthos
Meroplankton • Larvae of meroplankton are derieved from virtually all animal phyla and from all different marine habitats • Larvae of Decapod crustaceans, Bryozoa, Phoronida, Echinodermata, Porifera, Nemertea, Mollusca and Annelida
Role of Zooplankton in Aquatic Ecosystems and Significance to Humans • Role in food webs • Role in disease transmission • Transmission of guinea worm in the tropics • Transmission of pathogenic bacteria • Importance in aquaculture
Microbial Loop & Relationship to the “Classical” Plankton Food Web
Guinea Worm (Dracunculusmedinensis) Transmission in the Tropics http://upload.wikimedia.org/wikipedia/commons/2/27/Drac_life_cycle.gif
Transmission of Pathogenic Bacteria • Harbor various types of pathogenic bacteria • Vibrio species • Vibrio cholerae • Vibrio vulnificus • Vibrio parahaemolyticus • Vibrio alginolyticus
Main Species of Rotifer Used for Rearing Larval Fish • Brachionus plicatilis (Marine) • B. rotundiformis (Marine) • B. calyciflorus (freshwater)
Rotifers • Commonly used species: Brachionus plicatilis (~239 mm) and B. rotundiformis (~160 mm) • Used in the rearing of over 100 spp. of fish and crustaceans • Fast growing and relatively easy to culture • Still, too big for some marine fish larvae Pictures: vivo.library.cornell.edu/ servlet/entity?home=...
Problem in the Use of B. plicatilis to Rear Larval Fish • Are too Big to be Consumed by Larvae of Some Marine Fish (e.g. Red Snapper). • Large Strain (L) = 200 - 360 micron • Small Strain (S) = 150 - 220 micron • Super Small Strain (SS) = 94 - 163 micron
Isolation and Culture of a Small Marine Rotifer, Colurelladicentra (Chigbu & Suchar 2006)
Copepods • Common in marine environments • Principal diet of many marine fish larvae in nature • High content in nutrients • Size: 0.5 – 50 mm • Difficult to mass culture (unpredictable yields) • Only few sp. (Tigriopus japonicus) successfully mass cultured Pictures: www.woodbridge.tased.edu.au/ mdc/Species%20Reg... Harpacticoid Cyclopoid Calanoid
Zooplankton of the MCBs • MCBs serve as nurseries for larvae and juveniles of many economically and ecologically important fish species • Zooplankton are important components of the aquatic food webs • Dynamics of zooplankton community in coastal aquatic ecosystems depend on many factors including climate variability, water quality & biotic interactions
Theme 1 Land Use Mesozooplankton Community Structure & Dynamics Phytoplankton including HABs Occurrence & Dynamics Dynamics Water Quality Climate Variability Weather Some environmental factors that regulate the abundance of zooplankton Planktivorous fish, Mysids & Ctenophores Microzooplankton Community Structure & Dynamics
Examples of Negative Effects of HABs (A. anophagefferens) on zooplankton • Negative effect on growth of hard clam larvae (Padilla et al. 2006) • Inhibit growth of some ciliates, e.g. Strombidium sp. (Caron et al. 2004, Lonsdale et al. 1996) • Delay in copepod nauplii development; deterrence to grazing by copepod nauplii (Smith et al. 2008) • Poor survival of copepodites of Acartiahudsonica and nauplii of Coullana canadensis fed unialgal diet (Lonsdale et al. 1996). • Toxicity to copepod nauplii (Buskey & Hyatt 1995, Buskey et al. 2003) --- Aureoumbra lagunensis. • Decrease in copepod egg viability (Felipe et al. 2006) ---- Karlodinium sp.
Need for Zooplankton Studies in MCBs • As changes occur in the trophic state of the Coastal Bays, it is important to study and understand the impacts of such changes on zooplankton community. • Information on the dynamics of zooplankton in the MCBs is very limited • Monitoring of the mesozooplankton community
Objectives • Determine the assemblage/community structure of micro- and mesozooplankton in relation to water quality • Examine mesozooplankton mortality in situ, using a novel staining technique (Elliott & Tang 2009), under HAB and non-HAB conditions • Examine mesozooplankton feeding, growth rates and reproduction under HAB and non-HAB conditions
Objectives contd. • Quantify the size distribution, density and biomass of ctenophores Mnemiopsis leidyi relative to environmental factors • Examine using field studies and laboratory experiments whether ctenophores are having any significant effects on zooplankton community structure.