Deep-Sea Hydrothermal Vent Communities Geol104/BioES154 Comparison with Other Deep-Sea Benthic Environments Most deep-sea environments are characterized by: �Low availability of food No light, no photosynthesis Falling remains of dead organisms, decaying organic matter �Low (0-2°C), relatively constant temperature �High pressure (400-500 times atmospheric) Geol 104/BioES 154 Summary of General Biological Characteristics of Deep-Sea Macrofauna � Reproduction and Development Late reproductive maturity Slow development � Physiology Low metabolic rate and activity level � Ecological Long lived species Slow colonization rates Low population densities, but high species diversity Geol 104/BioES 154 Hydrothermal Vents � Vents are associated with mid-ocean ridges, spreading centers. � Cold waters percolate into crust and are geothermally heated before being vented at very high temperatures. � Vent waters are not only hot, but low in oxygen and rich in metals and hydrogen sulfide. Geol 104/BioES 154 Hydrothermal Vent Communites � 25 years of exploration have revealed: A new phylum At least 20 new families Over 90 new genera Over 300 new species Over 250 new strains of free-living bacteria � Biomass Up to 30 kg/m2 1000 x greater than typical biomass observed on deep-sea floor Geol 104/BioES 154 Hydrothermal Vent Macrofauna: Worms Vestimentiferan worms (Riftia pachyptila ) Geol 104/BioES 154 Serpulid polychaete worms Hydrothermal Vent Macrofauna: Bivalves Giant clams (Calyptogena magnifica) Geol 104/BioES 154 Mussels (Bathymodiolus thermophilus) What supports this abundance of life around hydrothermal vents? What is the energy source for this ecosystem? Geol 104/BioES 154 Chemosynthesis �Basis of life around deep sea hydrothermal vents is chemosynthesis rather than photosynthesis. Chemical energy rather than solar energy supports the ecosystem. Bacteria rather than plants are the primary producers. �Aerobic chemoautolithotrophy CO2 + H2S + O2 + H2O CH2O] + H2SO4 Organisms must have adaptations to prevent sulfide from poisoning oxygen binding site. Geol 104/BioES 154 Vent Ecosystems Depend on 2 Types of Bacteria: Free-living bacteria Geol 104/BioES 154 Symbiotic bacteria Tube Worm: Riftia pachyptila � Unusual animal No mouth No anus No digestive tract Dependent upon bacteria living in its gut or “troposome” Gills extracts hydrogen sulfide, carbon dioxide & oxygen from seawater; blood delivers these to troposome In return, bacteria provide nourishment for Riftia Geol 104/BioES 154 Giant Clam: Calyptogena magnifica Symbiotic bacteria in gills. High hemoglobin content in blood. Clams on the half shell anyone? Geol 104/BioES 154 Hydrothermal Vent Macrofauna: Environmental Constraints on Life Cycles and Reproduction � Suitable vent environments for these organisms are rare. � Individual vents have short lifespans. � Volcanic eruptions and earthquakes pose further hazards. �These conditions favor rapid growth rates, continuous reproduction, and high fecundity. Geol 104/BioES 154