1. LIFE IN THE DEEP: THE OCEAN DEPTHS (the mesopelagic, bathypelagic and abyssopelagic zones)

2. Alvin © Rod Catanach/MCT/Landov

3. Living Conditions on the Deep-Sea Floor –Most of the seafloor is covered with thick accumulations of fine sediment particles: –mineralized skeletal remains of planktonic organisms, known as oozes, that sink to the deep sea and accumulate very slowly (about 1 cm every 1000 years).

4. Living Conditions on the Deep-Sea Floor Two types of seafloor samplers: (a) bottom dredge, which skims the surface of the sediment, and (b) grab sampler, which removes a quantitative “bite” of sediment and its inhabitants.

5. Living Conditions on the Deep-Sea Floor Fine-grained bottom sediments off the Oregon coast disturbed by the impact of a current-direction indicator.

6. Living Conditions on the Deep-Sea Floor Manganese nodules scattered on the surface of the seafloor in the Pacific Ocean. © Woods Hole Oceanographic Institution

7. Part 1 “reminder:” WHERE ARE WE? (1)Mesopelagic (2)Bathypelagic (3)Abyssopelagic

8. Marine zones

9. MESOPELAGIC: 1. Below the epipelagic zone 2. No primary photosynthesis, but there is still productivity (i.e. still in the photic zone but it is disphotic) 3. 200-1000 m depth BATHYPELAGIC, ABYSSOPELAGIC 1. The “deep sea,” aphotic, twilight zone 2. After 1000 m in depth (to ocean floor)

11. Part 2 “reminder:” WHAT IS THE “WATER CHEMISTRY” IN THIS LAYER?

12. Living Conditions on the Deep-Sea Floor

13. Deep water originates near the surface

14. Deep water oxygen is circulated and replenished w/ open ocean circulation from the surface

15. Where does the oxygen come from?

16. Transfer of Oxygen and Energy to the Deep Sea –The diffusion and sinking of cold, dense water masses are the chief mechanisms of O 2 transport into the deep sea. –Dissolved O 2 is slowly diminished by animals and bacteria, leaving an O 2 minimum zone at intermediate depths. –Below this zone, dissolved O 2 gradually increases to just above the sea bottom.

17. Part 3 (new) (a) WHO LIVES THERE? (b) WHAT SPECIAL ADAPTATIONS DO THEY HAVE (and why)?

18. Living Conditions on the Deep-Sea Floor

19. Life on Abyssal Plains Comparison of deep-sea species diversity (for polychaete annelids and bivalve mollusks) with three other marine environments. Adapted from Sanders, H. L., Am Nat. 102 (1968): 243-282.

20. Living Conditions on the Deep-Sea Floor Gigantism is surprisingly common in the deep sea. The Greenland shark, Somniosus, a dogfish that occurs down to at least 1200 meters, can exceed 6 meters in length unlike its diminutive relatives. © WaterFrame/Alamy Images

21. Mesopelagic (lantern vs. dragonfish)

22. Mesopelagic fish

23. Mesopelagic, Bathypelagic and Abyssopelagic zone species have many unique characteristics to adapt to their “extreme environment.” (1) Fish start to show different characteristics… (a) Based on light availability: --higher eyes; 2 fields of vision --photophores; bioluminescence, countershading (b) “other” adaptations: -- musculature changes -- jaw adaptations

24. Where are we? Light????

25. (mesopelagic) Bristlemouth w/ tubular eyes

28. w/o photophores

32. …DEEP SEA FISH… Everything has a BIG MOUTH Everything is LONG and “SKINNY” Everything is BIGGER

33. viperfish

34. Rattrap fish

37. Swallower eel

38. Stomias deep-sea bioluminescent fish. Credit: © HBOI/Visuals Unlimited

39. Angler Fish (Melanocetus johnsonii) uses lights to attract prey, an example of bioluminescence. Credit: © HBOI/Visuals Unlimited

40. The Fangtooth (Anoplogaster cornuta) is a bioluminescent fish found in the deep sea. Credit: © HBOI/Visuals Unlimited

41. Some still live on the bottom…

42. A bait can quickly attracts mobile scavenging fishes © Scripps Institution of Oceanography Archives, UCSD

44. Not everything is a “fish,” but adaptations are still very similar!

45. Deep Sea Amphipod (1’!)

46. Mesopelagic shrimp

48. Mesopelagic squid

49. Vampyroteuthis infernalis

51. BENTHOS TOO: Fine-grained bottom sediments disturbed by a current direction indicator

52. Life on Abyssal Plains A shift in dominant taxonomic groups occurs in deeper water –echinoderms, polychaete worms, pycnogonids, and isopod and amphipod crustaceans become abundant –mollusks and sea stars decline in number

53. Life on Abyssal Plains –Most benthic animals in the deep sea are infaunal deposit feeders, extracting nourishment from the sediment in much the same manner as earthworms. –Croppers have merged the roles of predator and deposit feeder by preying heavily on populations of smaller deposit feeders and bacteria.

54. Sea-floor images showing the deposition of phytodetritus (marine snow)

55. Deep-sea cucumber © David Wrobel/Visuals Unlimited

56. Slower invertebrates at the bait can © Scripps Institution of Oceanography Archives, UCSD

58. The “Deep” even contains an entirely new (and very different) Marine Community – Hydrothermal vents!

59. An artist's rendition of the research submersible Alvin exploring the deep- sea floor © Phototake, Inc./Alamy Images

60. Vent and Seep Communities –Deep-sea hot springs, recently discovered along the axes of ridge and rise systems, support unique communities of deep-sea animals and bacteria. –Seep communities are more dispersed in areas where hydrocarbons, particularly methane or other natural gases, are percolating up through deep-sea sediments.

61. Vent and Seep Communities Hydrothermal Vent Communities –Dissolved H 2 S emerging from seafloor cracks is used as an energy source by chemosynthetic bacteria –These bacteria become the source of nutrition for dense populations of the unique animals clustered around these springs.

63. Importance of Vent Ecosystem Discovery 1.Life in extreme environments 2.Life independent of sun

64. Chemosynthesis = a type of primary production Photosynthesis  uses sunlight + carbon dioxide  coverts to food Chemosynthesis  uses sulfur + carbon dioxide  converts to food Photosynthesis reaction: CO 2 + H 2 O + sunlight  CH 2 O + O 2 Chemosynthesis reaction: O 2 + CO 2 + H 2 O + H 2 S  CH 2 O + H 2 SO 4 where H 2 S is hydrogen sulfide, H 2 SO 4 is sulfuric acid, and CH 2 O is “food” or organic material

65. PHOTOSYNTHESIS + CO 2 + H 2 O O 2 + [CH 2 O] CHEMOSYNTHESIS CO 2 + H 2 O + H 2 S + O 2 [CH 2 O] + H 2 SO 4

66. Importance of Vent Bacteria Base of vent ecosystem -- chemosynthesis Possible origin of life on Earth Illustrate link between biology and habitat

67. Vent and Seep Communities Diversity of Vent Inhabitants –Just as the geology of hydrothermal vents is dissimilar in the eastern Pacific versus the North Atlantic, so too is the assortment of organisms living around the vents in each ocean –To date, six major seafloor provinces have been defined

68. Approximate locations of confirmed hydrothermal vents and cold seeps

69. Cross-section of a ridge axis and the plumbing connected to a vent chimney

70. Sidescan sonar image overlaid onto multibeam bathymetry

71. A black smoker on the Galápagos Rift Zone. Courtesy of UCSB, University S. Carolina, WHOI/NOAA

72. “Black Smoker” Hydro- thermal Vent (at a Mid Ocean Ridge)

73. Red-plumed tube worms Courtesy of Monika Bright, University of Vienna, hydrothermalvent.com

75. External appearance of Riftia © Dr. Ken MacDonlad/SPL/Photo Researchers, Inc.

76. Internal anatomy of Riftia

77. Aggregations of large vent crabs Courtesy of Dr. Ana I. Dittel, University of Delaware

78. Aggregations of large vent clams Courtesy of Dr. Ana I. Dittel, University of Delaware

79. Hydrothermal Vent Crab: Galtheid Crab (“Pinchbug”)

80. Vent and Seep Communities Diversity of Vent Inhabitants Eyeless vent shrimp, Rimicaris, dominate deep hydrothermal vents in the North Atlantic Ocean. © Tim Shank, Woods Hole Oceanographic Institution

81. Final Thought: ??? Connection to our “earliest life forms?”

82. Paleodictyon (500 million yr. old fossil)

83. Paleodictyon, 1976

84. For more information on Paleodictyon, hydrothermal vent communities and deep sea research try the following web page link: http://www.naturalhistorymag.com/0904/0904_feature.html Covering: Dr. Peter Rona (Rutgers) and his Alvin research team Film: “Volcanoes of the Deep” (IMAX)