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Phytoplankton

Phytoplankton. Announcements: Exam: next Wednesday Review Tuesday pm at Olin O4 (here?!). Concentrations same, volume different Same productivity ~~ same decomposition (O 2 demand). Little to no photosynthesis (why?) Not really strong stratification under ice (why?).

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Phytoplankton

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  1. Phytoplankton • Announcements: • Exam: next Wednesday • Review Tuesday pm at Olin O4 (here?!)

  2. Concentrations same, volume different Same productivity ~~ same decomposition (O2 demand) Little to no photosynthesis (why?) Not really strong stratification under ice (why?) Two nearby lakes are similar in area and productivity, but one experiences winterkills, and the other does not. Why?

  3. Lake Washington Deep basin that never went anoxic so little to know internal loading (P buried in sediments; how?) Forested and urban water (little non-point sources of P; why?) Low WRT (after sewage was diverted, P-laden water quickly washed out) Doesn’t work when… Hypolimnion goes anoxic, resulting in lots of internal loading of P (how does this work?) Non-point sources of P persist (like what?) Explain why Lake Washington's watershed, morphology and flushing rate influenced recovery from nutrient loading. WHY are these characteristics important? Under what conditions (lake characteristics) would simply reducing P-inputs not work? Why not?

  4. Organisms • Plankton: organisms that weakly swim or go where the water takes them • Phytoplankton • Periphyton: benthic algae • Epiphyton: algae growing on macrophytes

  5. Phytoplankton taxonomy • Was once based on morphology or pigments, now more molecular. See Graham and Wilcox 2000 Algae for more information. • Usually grouped in Divisions (VARIABLE!) • Also often grouped by • Size • Mobility (motility) • Flagella: movable filament that can be used to propel organism through the water • Gas vacuoles

  6. Phytoplankton groupings, con't • Origin: • Periphyton (benthic) • Tychoplankton (detach from benthos) • Meroplankton (part of life on sediments) • Euplankton/holoplankton (entire life in water column) • Potomoplankton (resuspended algae in lotic systems)

  7. Phytoplankton Taxonomy (Divisions) • Cyanophyta - cyanobacteria • Chlorophyta - green algae • Euglenophyta - single flagella • Bacillariophyta - diatoms • Chrysophyta - golden brown algae • Cryptophyta - flagellated • Pyrophyta - dinoflagellates

  8. Cyanobacteria ~1,350 species • Prokaryotes: lack plastids and distinct membrane bound nucleus • Photosynthesize functionally like plants • Chloroplasts of other algae and plants originated from cyanobacteria through endosymbiosis

  9. Often dominant, esp. eutrophic lakes Some species fix N (heterocysts) Large cyanobacteria often dominate due to disproportionate losses of other species Allelopathy (toxic or inhibitory effects on other species) Buoyant (gas vacuoles) Cyanobacteria, con't Anabaena 400x heterocysts

  10. Cyanobacteria, con't • Resting stages: • thick-walled resting cells (cysts) called akinetes (Anabaena & Aphanizomenon) • Vegetative resting stage (Mycrocystis) • linkage between benthos and pelagic

  11. Chlorophyta: Green algae ~2,400 species • Eukaryotes • Includes unicellular flagellated and nonflagellated cells, colonies and filaments and macroalgae (Chara) • Represent 40-60% species with high biomass contribution in eutrophic and hypereutrophic lakes • Often dominate benthic algae

  12. Chlamydomonas 400x Hydrodictyon 40x Spirogyra 200x Volvox Cladophora 40x Chlorophyta

  13. Scenedesmus 600x Chlorophyta Assorted desmids

  14. Euglena www.mib.uga.edu/.../mibo3000/ eukaryotic/01232001.html bio.rutgers.edu/euglena/ mainpage.htm Euglenophyta ~1,020 species • Small to medium sized flagellated species • Often abundant in well-mixed eutrophic ponds and littoral areas

  15. Bacillariophyta - diatoms ~5,000 species • Wide range in size: 2um - 2mm • Require silica (Si) to build frustules • abundant during mixing when Si abundant • when lake stratifies, diatoms sink to bottom & remove Si from epilimnion • Heavy & no flagella: sink after stratification & form resting stage on sediments: viable after 100's years • Two groups: • pennate: bilaterally symmetrical • centric: radially symmetrical

  16. www.mib.uga.edu/.../mibo3000/ eukaryotic/diatoms.jpg www.cnas.smsu.edu/labimages/ Biology/Bio122/week1.htm Diatoms

  17. Chrysophyta ~450 species • Small single-celled flagellates and flagellated colonies • Common in oligotrophic clear lakes and humic lakes • Often codominate with cryptophytes • Diatoms are often grouped under chrysophyta Synura, http://microbes.limnology.wisc.edu/outreach/majorgroups.php

  18. Cryptophyta ~100 species • Small or medium-sized flagellates • Common in oligotrophic lakes • Single-cell cryptophytes, chrysophytes, dinoflagellates main food of rotifers and crustacean zooplankton (next week!) • Mixotrophic (more than one more of nutrition): eat bacteria & smallest algae http://protist.i.hosei.ac.jp/taxonomy/Phytomastigophora/Cryptophyta/Cryptomonadaceae.html

  19. Ceratium www.cnas.smsu.edu/labimages/ Biology/Bio122/week1.htm Peridinium Pyrophyta - dinoflagellates ~ 220 species • Motile (flagellates) • Have resting cysts • Some do not have chlorophyll • Red tide in the ocean

  20. Sizeinfluences- growth rate- energy paths (consumption)- sinking time

  21. Size E Daphnia head (e - eye) (large zooplankton) • Picoplankton (0.2-2 m dia) • Nanoplankton (2-30 m dia) • Microplankton (30-200 m dia) • < 30 m = edible algae A bacterium C Scenedesmus (green) B Cryptomonas (Cryptomonad) D Keratella (small zooplankton)

  22. Influences of size • Pico- and nanoplankton: high rates of production • Large surface to volume ratio (exchange of nutrients) • Very slow sinking rates • Nanoplankton are tasty • Microplankton • Sink faster • Grow slower • Not tasty

  23. Extracellular release of organic compounds • Represent a significant loss of fixed C (<20%) • Multiple functions: • modify growth & behavior • e.g., fischerellin released by cyanobacteria; inhibits photosynthesis by algae • Release of metabolic intermediates of low molecular weight by diffusion (glycolic acid, organic acids, organic phosphates, peptides…) • Release of metabolic end products of high molecular weight more deliberate (?) (carbohydrates, peptides, volitile compounds, growth-promoting and growth-inhibiting compounds) • Bacteria rapidly utilize LMW compounds

  24. Photosynthesis • Photosynthesis= fixing carbon nCO2 + nH2O ------> (CH2O)n + nO2 (n=# molecules) • Change in population biomass = growth - consumption - sinking • Growth=photosynthesis

  25. Compensation point • Compensation point: photosynthesis = respiration • Maximize the amount of time spent above the compensation point (in the light)

  26. Ways to stay in light • Mixing • sink slow enough to stay in mixed epilimnion • Mobility • flagella • gas vacuoles • Change sinking rate • change shape or density

  27. modifications Muscilaginous cover around Staurastrum species (green) - reduce sinking (to a point) - reduce consumption (or digestion)

  28. Maximum photosynthesis Light Saturated (enzymatic rxns limited by temp) Photosynthesis rate (mg C) Light Limited (photo- chemical rxns) Photo- inhibited Available light Effects of light & temperature on photosynthesis

  29. Photosynthesis distribution=specific primary production * light climate * algae biomass Biomass Photosynthesis Mesotrophic epilimnion (well mixed) Eutrophic with surface bloom Oligotrophic with max. biomass at metalimnion Shallow transparent lakes with max. biomass on bottom Depth

  30. Depth distribution of photosynthesis Trophogenic zone ~ euphotic zone Note that phytoplankton on the surface of hypereutrophic lakes shade out the water column

  31. Horizontal distribution • Wind & currents surface algae Langmuir spirals deep algae Neg. buoyant algae Foam, buoyant algae

  32. Lake Mendota cyanobacteria blooms

  33. Horizontal distribution Proximity to littoral zone often results in less phytoplankton • Must compete for nutrients with periphytic algae and other microorganisms attached to macrophytes and sediments • Macrophytes are refuge for herbivorous zooplankton

  34. Factors influencing seasonal distribution Physical • Temperature • Light Limiting nutrients • silica • nitrogen • phosphorus Biological • competition • resources, sinking Biological • grazing • parasitism

  35. Seasonal distribution in a temperate, dimictic lake (green) (diatoms)

  36. 1. Light limited: small, often motile (but productive) 2. Light increasing,still ice cover, no mixing (dynoflagellates can swim up towards light)

  37. 3. Spring mixing: high nutrients, low grazing, increasing light, diatoms dominate

  38. 4. Initial stratification: diatoms settle & die, loss of Si to < 0.5 mg/L

  39. 5. Clearwater phase: high light availability, warm temperatures, but many herbivores and reduction of nutrients leads to population crashes

  40. 6. Mid-summer stratification: Cyanobacteria dominate (fix N, migrate between nutrient-rich lower depths & epilimnion)

  41. 7. Fall mixing: high nutrients, less light, diatoms dominate again with increases in Si 8. Late autumn decline

  42. The plankton

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