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Marine Biology Chapter 6 Marine Microbes • Microbes • Any living thing that is microscopic • Can be one of the following: » » » » » Viruses Prokaryotes (Bacteria) Unicellular Protists Unicellular Fungi Even very tiny animals Marine Viruses • Virology—the study of viruses – Viruses are diverse and are more abundant than any other organism in the sea – Have significance for marine food webs, population biology and diseases of marine organisms Viral Characteristics • Are they “alive”? Most say no • Remember you have to be made of at least one cell to be alive, viruses are not cells • Viruses consist of bits of DNA or RNA surrounded by protein • Have no metabolism, and rely entirely on host organism for energy, material and organelles to reproduce themselves – Viral replication must occur within a host cell • Viruses infect all groups of living organisms, but may be specialized • Infect specific species • Infect specific tissues of that species – Influenza infects respiratory cells – Hepatitis infects liver cells Viral Characteristics • Viral structure – virus particle is called a virion when outside the host cell – Can’t do anything until it enters into a host cell – virion composed of a nucleic acid core surrounded by a coat of protein called a capsid – may have a protective envelope, a membrane derived from the host’s nuclear or cell membrane Biodiversity and Distribution of Marine Viruses • 10 times more abundant than marine prokaryotes (bacteria) • may reach 1010 virons per liter of seawater, 1013 per kilogram of sediment • Bacteriophages – viruses that infect bacteria Ecology of Marine Viruses • Viruses kill host cells, and thus control populations of bacteria and other microbes in plankton communities in the marine environment • Viruses also responsible for chronic infection and mass mortality of populations of marine animals – Examples: – Problems with shrimp aquaculture – Papillomivirus and morbillivirus in marine mammal populations • Now we will talk about bacteria Marine Bacteria • General characteristics – simple, prokaryotic organization: no nuclei or membrane-bound organelles, few genes, nonliving cell wall – reproduce asexually by binary fission – many shapes and sizes • bacillus—rod shape • coccus—spherical shape • Marine bacteria play many different roles based on species • • • • • Some photosynthesize Some are important in the nitrogen cycle Some cause disease Some decompose Some have symbiotic relationships with other organisms Nutritional Types of bacteria • Cyanobacteria (blue-green bacteria) – photosynthetic bacteria which are found in environments high in dissolved oxygen, and produce free oxygen Photosynthesis • Cyanobacteria – may exist as single cells or form dense mats held together by mucilage • form associates called stromatolites—a coral-like mound of microbes that trap sediment and precipitate minerals in shallow tropical seas Nutritional Types of Bacteria • Heterotrophic bacteria – decomposers that obtain energy and materials from organic matter in their surroundings – return many chemicals to the marine environment through respiration and fermentation Nutritional Types (Heterotrophic Bacteria) • Heterotrophic bacteria – marine snow: large, cobweb-like drifting structures formed by mucus secreted by many kinds of plankton and bacteria, where particles may accumulate – Feces, dead material accumulate as marine snow – Drops through the water column feeding other species that are deeper Nitrogen Fixation and Nitrification • Nitrogen cycle – nitrogen fixation and nitrification • Why do we need nitrogen? • Nitrogen is needed to make DNA and amino acids to make proteins • There is lots of nitrogen gas in the atmosphere, but most species are not able to use it in that form • Therefore, there are some bacteria that can convert the atomospheric nitrogen into nitrogen they can use to make their DNA and proteins • That nitrogen then makes it’s way up the food chain • There are bacteria that during the decomposition process can convert the nitrogen back into nitrogen gas, therefore continuing the nitrogen cycle Symbiotic Bacteria • • • • Many bacteria have evolved symbiotic relationships with a variety of marine organisms Endosymbiotic theory – mitochondria, plastids & hydrogenosomes evolved as symbionts within other cells Chemosynthetic bacteria live within tube worms and clams Some deep-sea or nocturnal animals host helpful bioluminescent bacteria – photophores – embedded in the ink sacs of squid Archaea Bacteria • Archaeans are bacteria that include the “extremophile” bacteria • Example: Hyperthermophiles – organisms that can survive at temperatures exceeding 100o C, such as near deep-sea vents – Potential for biomedical and industrial application Nutritional Types of Bacteria • Chemosynthetic bacteria – Chemosynthesize instead of photosynthesize • Use sulfides and elemental sulfur, nitrites, hydrogen, and ferrous ion that are coming up from hydrothermal vents – chemosynthesis is less efficient than photosynthesis, so rates of cell growth and division are slower – found around hydrothermal vents and some shallower habitats where needed materials are available in abundance • Now we will talk about Eukaryotes Eukarya • Eukarya includes all organisms with eukaryotic cells • Examples: – plants – animals – fungi – algae – single-celled animal-like protozoa • For this chapter, we are only going to talk about Eukaryotes that are microscopic • Within Eukarya, we will now talk about the Fungi Fungi • General features of fungi – eukaryotes with cell walls of chitin – many are unicellular yeasts – filamentous fungi grow into long, multi-cellular filaments called hyphae that can branch to produce a tangled mass called a mycelium – heterotrohic decomposers that recycle organic material • can digest lignin (major component of wood) Fungi – Kingdom Fungi is divided into 4 phyla: • Chytridiomycota (motile cells) • Zygomycota (e.g. black bread mold) • Basidiomycota (club fungi, e.g. mushrooms) • Ascomycota (sac fungi) – in the sea, ascomycotes are the most diverse and abundant fungi Fungi • Ecology and physiology of marine fungi – can be either obligately marine, requiring ocean or brakish water or facultatively marine (primarily of terrestrial or fresh water origin) – salinity is toxic to fungi, so they must devote energy to removing sodium – most marine fungi live on wood from land – some live on grass in salt marshes – others live on algae, mangroves or sand – fungi decompose the chitinous remains of dead crustaceans in open sea plankton communities • Now we will talk about the protists • Here we will talk mainly about the unicellular protists » Unicellular algae – Phytoplankton » Unicellular heterotrophs - protozoans • Later, we will talk about multicellular protists » Algae - “seaweed” Diatoms • Extremely diverse and distinct members of marine phytoplankton • Diatom structure – frustule—a two-part, box-shaped organic cell wall impregnated with silica Diatoms • Diatomaceous sediments – frustules of dead diatoms sink and collect on the seafloor to form siliceous oozes – accumulations form sedimentary rock – these deposits, called diatomaceous earth, are mined for use as filtering material, a mild abrasive, and for soundproofing and insulation products – nutrient reserves, stored as lipids, accumulate in siliceous oozes accounting for most of the worlds petroleum reserves – Ancient diatoms sank to the bottom of the ocean, were covered by sediment before they decomposed, were subjected to pressure and heat and turned into petroleum Diatoms Coccolithophores • Photosynthetic organisms with 2 simple flagella both used for locomotion • Most are coccolithophores with a surface coating of disc-shaped scales (coliths) of calcium carbonate – remains form calcereous oozes Alveolates • Examples: – dinoflagellates – ciliates – apicomplexans (strictly parasitic) • Dinoflagellates – globular, unicellular (sometimes colonial) with 2 flagella – Most are planktonic, some are benthic and others parasitic, also can be bioluminescent – Bioluminescent Bay, Puerto Rico Dinoflagellates • Ecological roles of dinoflagellates – major component of phytoplankton – some are parasites of copepods (crustaceans) – zooxanthellae: species lacking flagella which are symbionts of jellyfish, corals and molluscs – photosynthetic zooxanthellae provide food for hosts – hosts provide carbon dioxide, other nutrients, and shelter – Harmful Algal Blooms (HABs) • occur when photosynthetic dinoflagellates undergo a population explosion • colors the water red, orange or brown • dinoflagellates that cause HABs produce toxins – paralytic shellfish poisoning (PSP) occurs in humans who consume shellfish contaminated with these toxins – toxins cannot be destroyed by cooking • oxygen content of the water may be reduced to deadly levels as bacteria decompose animals killed by dinoflagellate toxins Red Tides • Ciliates – protozoans that bear cilia for locomotion and for gathering food • membranelles—tufts or long rows of fused adjacent cilia • cytostome—an organelle serving as a permanent site for phagocytosis of food – planktonic and benthic – major links in marine food chains – form symbiotic and parasitic relationships Paramecium – a ciliate Choanoflagellates • Phylum of marine and freshwater flagellated cells that are more closely related to animals than any other group of one-celled microbes • Unicellular or colonial – colonies may be stalked or embedded in a gelatinous mass • Highly efficient consumers of bacteria • Ancestors to the animals? Choanoflagellate Sponge Amoeboid Protozoans • All have an organelle called a pseudopod—an extension of the cell surface that can change shape and is used for locomotion (benthic species) and food capture (benthic and pelagic) • Are hererotrophs consuming bacteria and other small organisms Amoeboid Protozoans • foraminiferans • radiolarians Amoeboid Protozoans • Foraminiferans (forams) – have branched pseudopods that form reticulopods (elaborate, net-like structures) used to: • snare prey • crawl (benthic) • reduce sinking rate (pelagic) – consume bacteria and diatoms – some harbor symbiotic green and red algae and zooxanthellae Amoeboid Protozoans • Radiolarians – named for long, needle-like pseudopods • pseudopods capture food and slow sinking – radiolarian oozes form from the internal siliceous skeleton of dead radiolarians – live in the photic zone and capture phyto- and zooplankton, sometimes copepods – larger radiolarians prey on copepods and other planktonic crustaceans • So far, we have talked about: – Viruses – Infect bacteria, protists, plants and animals in the marine environment – Domain Archaea – prokaryotes, extremophiles – Domain Bacteria – Cyanobacteria – photosynthetic bacteria – Heterotrophic bacteria – can be nitrogen fixers, can have symbiotic relationship with other organisms, can infect other organisms, can help with decay – Domain Eukarya – Fungi – Protists » Unicellular algae – diatoms, dinoflagellates, coccolithophores (Phytoplankton) » Protozoans – ciliates, choanoflagellates, amoeboids (foraminiferans, radiolarians)