1. The Not-So-Secret Sex Lives of Scleractinian Corals

2. Asexual Reproduction Modes of asexual reproduction Sexual Reproduction sexuality broadcast spawning versus brooding reproductive effort and fecundity timing and synchrony gamete buoyancy and dispersal during spawning fertilization & early development planula dispersal and settlement Asexual Reproduction Modes of asexual reproduction Sexual Reproduction sexuality broadcast spawning versus brooding reproductive effort and fecundity timing and synchrony gamete buoyancy and dispersal during spawning fertilization & early development planula dispersal and settlement

3. Asexual Reproduction colony growth versus formation of new colonies

4. Types of Polyp Budding Intratentacular (fission) Intratentacular (fission) Extratentacular (budding)

5. Fission Polyp within calyx

6. Budding Polyp within calyx

7. Modes of Asexual Reproduction accidental fragmentation nonaccidental fragmentation partial colony mortality asexual planulae polyp bail-out accidental fragmentation nonaccidental fragmentation partial colony mortality asexual planulae polyp bail-out

8. Accidental Fragmentation Wave Damage

9. Accidental Fragmentation Turtle Damage of Porites compressa in Kane‘ohe Bay

10. Nonaccidental Fragmentation Radial Division in Cycloseris fragilis

11. Nonaccidental Fragmentation Transverse Division in Fungia scutaria anthocaulus anthocyathus

12. Nonaccidental Fragmentation Transverse Division in Fungia scutaria stalk regenerates new disk

13. Partial Colony Mortality Porites compressa with live branch ends, but dead towards the bases

14. Partial Colony Mortality Parricidal Budding in Fungia scutaria The Phoenix Effect Parricidal Budding in Fungia scutaria The Phoenix Effect

15. Anthocaulus-like Stalk Grown from a Septal Fragment in Fungia scutaria

16. Tissue Regeneration in Fungia scutaria Before Regeneration After Regeneration

17. Partial Colony Mortality The Phoenix Effect in Porites compressa The Phoenix Effect in Porites compressa Cut surface of a broken finger showing living tissue beneath the surface of the skeleton Normal colony next to a colony exposed to freshwater P. Jokiel

18. Asexual Planula D. Gulkol

19. Polyp Bail-Out D. Gulko

20. zygote Sexual Reproduction planula larvae egg sperm

21. Sexual Reproduction Hermaphroditic vs gonochoric Broadcast spawning vs brooding

22. Acropora sp., a hermaphoditic coral Fungia scutaria, a gonochoric coral eggs sperm packet egg cloud Hermaphroditism both sexes in the same individuals Gonochorism sexes are separate Hermaphroditism versus Gonochorism

23. Location of Gonads in Coral Polyps Ovaries Testes eggs nucleus sperm tails sperm tails sperm heads sperm heads

24. Types of Hermaphroditism Simultaneous Hermaphrodites male and female gametes mature at the same time in the same individual or colony Sequential Hermaphrodites one sex appears first followed by the other sex at a later time

25. Adaptive Considerations Gonochorism and sequential hermaphroditism ensures outcrossing and maintains genetic diversity in the population. Simultaneous hermaphroditism may result in inbreeding and a higher frequency of genetic disorders being manifested. However, “selfing” may be advantageous when the probability of finding an individual of the opposite sex to mate with is low. Most studies suggest that their are barriers to self-fertilization in corals.

26. Hermaphroditic Corals in Hawai‘i Acropora cytheria Montipora capitata Montipora flabellata Montipora patula Leptastrea purpurea Cyphastrea ocellina Acropora cytheria Montipora capitata Montipora flabellata Montipora patula Leptastrea purpurea Cyphastrea ocellina

27. Gonochoric Corals in Hawai‘i Pocillopora meandrina Pocillopora eydouxi Porites compressa Porites lobata Tubastrea coccinea Pocillopora meandrina Pocillopora eydouxi Porites compressa Porites lobata Tubastrea coccinea Pavona duerdeni Pavona varians Cycloseris vaughani Fungia scutaria Pocillopora damicornis Pavona duerdeni Pavona varians Cycloseris vaughani Fungia scutaria Pocillopora damicornis

28. Brooding Versus Broadcast Spawning Brooding eggs develop to planula stage in gastrovascular cavity of parent polyp Broadcast Spawning eggs and sperm are shed into the water column where fertilization and development occurs Brooding eggs develop to planula stage in gastrovascular cavity of parent polyp Broadcast Spawning eggs and sperm are shed into the water column where fertilization and development occurs broadcast spawner Pocillopora damicornis, a brooder planula in polyp released gametes D. Gulko

29. Adaptive Considerations Brooding typically produces planula with the immediate capability to settle out after planulation occurs. Broadcasting requires developing embryos and planula to spend substantial time in the plankton before settlement can occur.

30. Adaptive Considerations Brooding requires a substantial reproductive cost on the parent in order to successfully rear on planula. Broadcast spawning imposes a lower per-egg reproductive cost.

31. Adaptive Considerations Brooded planula have a relatively higher probability of settlement and recruitment success. While many gametes are wasted during broadcast spawning, the shear numbers of gametes released ensures that a few eggs will be fertilized, develop to planulae, and settle out as corals.

32. Brooding Corals in Hawai‘i Cyphastrea ocellina Pocillopora damicornis Tubastrea coccinea Cyphastrea ocellina Pocillopora damicornis Tubastrea coccinea

33. Broadcast Spawning Corals in Hawai‘i Acropora cytheria Montipora capitata Montipora flabellata Montipora patula Pavona duerdeni Pavona varians Leptatrea pupurea Acropora cytheria Montipora capitata Montipora flabellata Montipora patula Pavona duerdeni Pavona varians Leptatrea pupurea Cycloseris vaughani Fungia scutaria Pocillopora edouxi Pocillopora meandrina Porites compressa Porites lobata Cycloseris vaughani Fungia scutaria Pocillopora edouxi Pocillopora meandrina Porites compressa Porites lobata

34. Reproductive Effort and Fecundity Reproductive Effort the energy invested into reproduction Fecundity the number of eggs a female produces

35. Reproductive Effort and Fecundity Adaptive Considerations many small eggs versus few large eggs brooding versus broadcast spawning number of eggs per polyp number of eggs per colony spatial variation across a colony number of spawning events per year size/age at first reproduction reproductive senescence spatial variation across a population

36. Environmental Stresses Yielding Lower Fecundity in Corals turbidity & sedimentation high temperature low salinity aerial exposure at low tide low irradiance lack of uv light mechanical damage intraspecific competition oil & fuel oil pollution eutrophication

37. Zooxanthellae Incorporation into Eggs Direct Transmission Montipora capitata Direct Transmission Montipora capitata Indirect Transmission Fungia scutaria Indirect Transmission Fungia scutaria

38. Timing and Synchrony Monthly periodicity in planula release (planulation) by Pocillorpora damicornis. P. Jokiel

39. Reproductive Cycles Observed Seasonal (annual) Lunar (monthly) Day/Night Seasonal (annual) Lunar (monthly) Day/Night

40. Advantages to Synchronized Spawning maximizes chance of encounter between sperm & egg maximizes outcrossing in self-fertile hermaphrodites minimizes predation by swamping predators maximizes successful recruitment within natal reef maximizes dispersal beyond natal reef

41. Proximate Factors Synchronizing Spawning in Corals Possible Seasonal Cycles Involved –seasonal temperature changes –seasonal changes in day length –seasonal changes in irradiance –seasonal changes in wind & current patterns –seasonal changes rainfall & runoff –latitudinal differences opposite hemispheres higher latitudes tend to exhibit shorter breeding season

42. Winter solstice Dec. 22 Sun vertical at 23.5 o S Winter solstice Dec. 22 Sun vertical at 23.5 o S Autumnal equinox Sep. 23 Sun vertical at equator Summer solstice June 21 Sun vertical at 23.5 o N Vernal equinox March 21 Sun vertical at equator Northern Hemisphere Names

43. Earth further from sun Earth closer to sun

44. Isotherms Lines of equal temperature 60 o 30 o 0o0o 60 o tropic temperate polar

45. Sea Surface Temperature

46. Surface temperature

47. Wind-driven surface currents

48. Proximate Factors Synchronizing Spawning in Corals Possible Lunar Cycles Involved –Lunar light intensities related to lunar phases –May also be correlated spring-neap tide cycles

50. 1.Gravitational pull of the moon and sun 2.Centripetal force of the rotating Earth Tides are generated by:

51. the gravitational pull of the moon and sun - moon has 2x greater gravitational pull than the sun - sun is 10 million x more massive than the moon and is 390 times farther away

52. Centripetal force

53. CENTRIPETAL GRAVITATIONAL FORCE GRAVITATIONAL & CENTRIPETAL

54. Diurnal Tide: 24 hr 50 min cycle Semi Diurnal Tide: 12 hr 25 min cycle Mixed Tide: 12 hr 25 min cycle Tidal Cycles

55. High water: a water level maximum ("high tide") Low water: a water level minimum ("low tide") Tidal range: the difference between high and low tide Description of tides Intertidal zone High tide Low tide

56. The monthly tidal cycle (29½ days) About every 7 days, Earth alternates between: –Spring tide Alignment of Earth-Moon-Sun system Lunar and solar bulges constructively interfere Large tidal range –Neap tide Earth-Moon-Sun system at right angles (quadrature) Lunar and solar bulges destructively interfere Small tidal range About every 7 days, Earth alternates between: –Spring tide Alignment of Earth-Moon-Sun system Lunar and solar bulges constructively interfere Large tidal range –Neap tide Earth-Moon-Sun system at right angles (quadrature) Lunar and solar bulges destructively interfere Small tidal range

57. Earth-Moon-Sun positions and the monthly tidal cycle Spring Tide Highest high tide and lowest low tide Neap Tide Moderate tidal range

60. Tidal Patterns Semidiurnal tides- two high and two low per day; Cape Cod, MA (high latitudes) Diurnal tides- one high and one low per day; Mobile, AL (low latitudes) Mixed pattern tides- Two high and two low tides per day BUT with successive high tide levels that are VERY DIFFERENT from each other; Hawaii (mid latitudes) Type of tide depends on: Position on the globe Water depth Contour- shape of ocean basins

63. Corals exposed to air at extreme low tide

64. Proximate Factors Synchronizing Spawning in Corals Possible Daily Cycles Involved –Daily light-dark cycles probably important in final synchronization & release –Daily tidal cycle may also play a role

65. Proximate Factors Synchronizing Spawning in Corals Other Factors Involved –Water motion or lack of it –Chemical cues

66. Reproductive Synchrony in Some Hawaiian Corals Montipora capitata hermaphroditic broadcaster, 8-10 pm, 1-4 nights following the new moon, June-August Fungia scutaria gonochoric broadcaster, 5-7 pm, 1-4 nights following the full moon, June-September Porites compressa gonochoric broadcaster, 11pm-1am 1-4 nights following the full moon, June-August Pocillopora damicornis gonochoric brooder, lunar periodicity in planulation throughout the year Montipora capitata hermaphroditic broadcaster, 8-10 pm, 1-4 nights following the new moon, June-August Fungia scutaria gonochoric broadcaster, 5-7 pm, 1-4 nights following the full moon, June-September Porites compressa gonochoric broadcaster, 11pm-1am 1-4 nights following the full moon, June-August Pocillopora damicornis gonochoric brooder, lunar periodicity in planulation throughout the year

67. Differences in the Timing of Planulation by Pocillopora damicornis Y-type B-type P. Jokiel

68. Multiple Species Mass Spawning Events Great Barrier Reef, Australia Western Australia OkinawaGuam Gulf of Mexico Great Barrier Reef, Australia Western Australia OkinawaGuam Gulf of Mexico

69. Advantages and Disadvantages of Multispecies Mass Spawning Advantage – Swamp potential egg predators Disadvantage –Production of infertile hybrids resulting from interspecies fertilizations –Single catastrophic event can wipe of one year’s entire reproductive effort –Massive amounts of organic matter from spawn slick may result in reef kill Advantage – Swamp potential egg predators Disadvantage –Production of infertile hybrids resulting from interspecies fertilizations –Single catastrophic event can wipe of one year’s entire reproductive effort –Massive amounts of organic matter from spawn slick may result in reef kill

70. Egg Buoyancy During Spawning egg cloud from spawning coral Acropora sp. spawning positively buoyant eggs Fungia scutararia spawning negatively buoyant eggs

71. Egg-Sperm Bundle Break Up by Montipora capitata

72. Fungia scutaria Egg

73. Fungia scutaria Cleavage - Two Cells

74. Fungia scutaria Cleavage - Four Cells

75. Fungia scutaria Early Blastula

76. Fungia scutaria Planula Stages Before Zooxanthellae Infection After Zooxanthellae Infection zooxanthellae epidermis cilia

77. Mouth of Fungia Planula epidermis mouth zooxanthellae cilia

78. Fungia scutaria Settled Polyp mouth developing mesentery developing mesentery

79. Planula Dispersal and Settlement

80. Possible Planula Food Sources Zooxanthellae in planulae may produce food via photosynthesis. Planulae may feed upon plankton while in the water column. Planulae may survive on stored food reserves without feeding.

81. Life Cycle of Fungia scutaria

82. How did corals arrive in Hawaii? ?

83. Coral Dispersal by Rafting on Floating Objects P. Jokiel

84. Western Pacific “Cradle of Diversity” Guam American Samoa Johnston Island Midway Island Hawaiian Islands Palmyra