Variation in rates of early development in Haliotis asinina generate competent larvae of different ages
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- 作者:Daniel J Jackson (1) (2)
Sandie M Degnan (1)
Bernard M Degnan (1) - 关键词:Developmental variation ; Developmental timing ; Invertebrate ; Competence ; Heterochrony ; Metamorphosis ; Dispersal ; Plankton ; Larva
- 刊名:Frontiers in Zoology
- 出版年:2012
- 出版时间:December 2012
- 年:2012
- 卷:9
- 期:1
- 全文大小:358KB
- 参考文献:1. Chan YF, Marks ME, Jones FC, Villarreal G, Shapiro MD, Brady SD, Southwick AM, Absher DM, Grimwood J, Schmutz J, Myers RM, Petrov D, Jonsson B, Schluter D, Bell MA, Kingsley DM: Adaptive Evolution of Pelvic Reduction in Sticklebacks by Recurrent Deletion of a Pitx1 Enhancer. / Science 2010, 327:302鈥?05. CrossRef
2. Wasik BR, Rose DJ, Moczek A: Beetle horns are regulated by the Hox gene, Sex combs reduced, in a species- and sex-specific manner. / Evol Dev 2010, 12:353鈥?62. CrossRef
3. Werner T, Koshikawa S, Williams TM, Carroll SBC: Generation of a novel wing colour pattern by the Wingless morphogen. / Nature 2010, 464:1143鈥?148. CrossRef
4. Jackson DJ, Ellemor N, Degnan BM: Correlating gene expression with larval competence, and the effect of age and parentage on metamorphosis in the tropical abalone Haliotis asinina. / Mar Biol 2005, 147:681鈥?97. CrossRef
5. Strathmann R: The spread of sibling larvae of sedentary marine invertebrates. / Am Nat 1974, 108:29鈥?4. CrossRef
6. Thorson G: Reproductive and larval ecology of marine bottom invertebrates. / Biol Rev 1950, 25:1鈥?5. CrossRef
7. Christiansen F, Fenchel T: Evolution of marine invertebrate reproductive patterns. / Theor Popul Biol 1979, 16:267鈥?82. CrossRef
8. Nielsen C: Origin and evolution of animal life cycles. / Biol Rev 1998, 73:125鈥?55. CrossRef
9. Vance R: On reproductive strategies in marine benthic invertebrates. / Am Nat 1973, 107:339鈥?52. CrossRef
10. Strathmann R: The evolution and loss of feeding larval stages of marine invertebrates. / Evol 1978, 32:894鈥?06. CrossRef
11. Marshall DJ, Keough MJ: Variable effects of larval size on post-metamorphic performance in the field. / Mar Ecol Prog Ser 2004, 279:73鈥?0. CrossRef
12. Kirkendale LA, Meyer CP: Phylogeography of the Patelloida profunda group (Gastropoda: Lottidae): diversification in a dispersal-driven marine system. / Mol Ecol 2004, 13:2749鈥?762. CrossRef
13. Marshall DJ, Bolton TF, Keough MJ: Offspring size affects the post-metamorphic performance of a colonial marine invertebrate. / Ecol 2003, 84:3131鈥?137. CrossRef
14. Hilbish TJ, Winn EP, Rawson PD: Genetic variation and covariation during larval and juvenile growth in Mercenaria mercenaria. / Mar Biol 1993, 115:97鈥?04. CrossRef
15. Jarrett JN, Pechenik JA: Temporal variation in cyprid quality and juvenile growth capacity for an intertidal barnacle. / Ecol 1997, 78:1262鈥?265. CrossRef
16. Hilbish TJ, Sasada K, Eyster LS, Pechenik JA: Relationship between rates of swimming and growth in veliger larvae: genetic variance and covariance. / J Exp Mar Biol Ecol 1999, 239:183鈥?93. CrossRef
17. Krug PJ, Zimmer RK: Developmental Dimorphism: Consequences for Larval Behavior and Dispersal Potential in a Marine Gastropod. / Biol Bull 2004, 207:233鈥?46. CrossRef
18. Kelly DW, MacIsaac HJ, Heath DD: Vicariance and dispersal effects on phylogeographic structure and speciation in a widespread estuarine invertebrate. / Evol 2006, 60:257鈥?67.
19. Palumbi SR: Marine speciation on a small planet. / Trend Ecol Evol 1992, 7:114鈥?18. CrossRef
20. Avila C: Competence and metamorphosis in the long-term planktotrophic larvae of the nudibranch mollusc Hermissenda crassicornis (Eschscholtz, 1831). / J Exp Mar Biol Ecol 1998, 231:81鈥?17. CrossRef
21. Davis M: Short-term competence in larvae of queen conch Strombus gigas: shifts in behavior, morphology and metamorphic response. / Mar Ecol Prog Ser 1994, 104:101鈥?08. CrossRef
22. Pechenik JA, Gee CC: Onset of Metamorphic Competence in Larvae of the Gastropod Crepidula Fornicata (L.), Judged by a Natural and an Artificial Cue. / J Exp Mar Biol Ecol 1993, 167:59鈥?2. CrossRef
23. Degnan SM, Degnan BM: The initiation of metamorphosis as an ancient polyphenic trait and its role in metazoan life-cycle evolution. / Philos Trans R Soc Lond B 2010, 365:641鈥?51. CrossRef
24. Hadfield MG, Carpizo-Ituarte EJ, Carmen K, Nedved BT: Metamorphic Competence, a Major Adaptive Convergence in Marine Invertebrate Larvae. / Am Zool 2001, 41:1123鈥?131. CrossRef
25. Jackson DJ, Leys SP, Hinman VF, Woods R, Lavin MF, Degnan BM: Ecological regulation of development: induction of marine invertebrate metamorphosis. / Int J Dev Biol 2002, 46:679鈥?86.
26. Bakker K: Selection for rate of growth and its influence on competitive ability of larvae of Drosophila melanogaster. / Neth J Zool 1969, 19:541鈥?69. CrossRef
27. Chippendale AK, Alipaz JA, Chen H-W, Rose MR: Experimental evolution of accelerated development in Drosophila. 1. Developmental speed and larval survival. / Evol 1997, 51:1536鈥?551. CrossRef
28. da Cruz IBM, Cruz do Nascimento J, da Cruz IBM, Monjelo LA, de Oliveira AK: Genetic components affecting embryonic developmental time of Drosophila melanogaster. / Gen Mol Biol 2002, 25:157鈥?60. CrossRef
29. Marien D: Selection for developmental rate of Drosophila melanogaster. / Genetics 1958, 38:996鈥?003.
30. Sang JH, Clayton GA: Selection for larval development time in Drosophila. / J Hered 1957, 48:265鈥?70.
31. Mensch J, Lavagnino N, Carreira VP, Massaldi A, Hasson E, Fanara JJ: Identifying candidate genes affecting developmental time in Drosophila melanogaster: pervasive pleiotropy and gene-by-environment interaction. / BMC Dev Biol 2008, 8:78. CrossRef
32. Hadfield MG: Settlement requirements of molluscan larvae: new data on chemical and genetic roles. / Aquaculture 1984, 39:283鈥?98. CrossRef
33. Lucchetta EM, Lee JH, Fu LA, Patel NH, Ismagilov RF: Dynamics of Drosophila embryonic patterning network perturbed in space and time using microfluidics. / Nature 2005, 434:1134鈥?138. CrossRef
34. Hoegh-Guldberg O, Pearse JS: Temperature, food availability, and the development of marine invertebrate larvae. / Am Zool 1995, 35:415鈥?25.
35. Stanwell-Smith D, Peck LS: Temperature and embryonic development in relation to spawning and field occurrence of larvae of three Antarctic echinoderms. / Biol Bull 1998, 194:44鈥?2. CrossRef
36. Schirone RC, Gross L: Effect of temperature on early embryological development of the zebra fish, Brachydanio rerio. / J Exp Zool 1968, 169:43鈥?2. CrossRef
37. Jackson DJ, W枚rheide G, Degnan BM: Dynamic expression of ancient and novel molluscan shell genes during ecological transitions. / BMC Evol Biol 2007, 7:160. CrossRef
38. Kniprath E: Ontogeny of the molluscan shell field: a review. / Zool Script 1981, 10:61鈥?9. CrossRef
39. Williams EA, Degnan BMD, Gunter H, Jackson DJJ, Woodcroft BJ, Degnan SM: Widespread transcriptional changes pre-empt the critical pelagic-benthic transition in the vetigastropod Haliotis asinina. / Mol Ecol 2009, 18:1006鈥?025. CrossRef
40. Tills O, Rundle SD, Salinger M, Haun T, Pfenninger M, Spicer JI: A genetic basis for intraspecific differences in developmental timing? Evo . / Dev 2011, 13:542鈥?48.
41. Lucas T, Macbeth M, Degnan SM, Knibb W, Degnan BM: Heritability estimates for growth in the tropical abalone Haliotis asinina using microsatellites to assign parentage. / Aquaculture 2006, 259:146鈥?52. CrossRef
42. Trapido-Rosenthal HG, Morse DE: Availability of chemosensory receptors is down regulated by habituation of larvae to a morphogenetic signal. / Proc Natl Acad Sci USA 1986, 83:7658鈥?662. CrossRef
43. Roberts RD, Lapworth C: Effect of delayed metamorphosis on larval competence, and post-larval survival and growth, in the abalone Haliotis iris Gmelin. / J Exp Mar Biol Ecol 2001, 258:1鈥?3. CrossRef
44. Hubbard EJA: Larval growth and the induction of metamorphosis of a tropical sponge-eating nudibranch. / J Moll Stud 1988, 54:259鈥?69. CrossRef
45. Maldonado M, Young CM: Effects of the duration of larval life on postlarval stages of the demosponge Sigmadocia caerulea. / J Exp Mar Biol Ecol 1999, 232:9鈥?1. CrossRef
46. Gaines S, Roughgarden J: Larval settlement rate: a leading determinant of structure in an ecological community of the marine intertidal zone. / Proc Natl Acad Sci USA 1985, 82:3707. CrossRef
47. Hadfield MG, Strathmann MF: Variability, flexibility and plasticity in life histories of marine invertebrates. / Oceanol Acta 1996, 19:323鈥?34.
48. Todd CD, Lambert WJ, Thorpe JP: The genetic structure of intertidal populations of two species of nudibranch molluscs with planktotrophic and pelagic lecithotrophic larval stages: are pelagic larvae "for" dispersal? / J Exp Mar Biol Ecol 1998, 228:1鈥?8. CrossRef
49. Johannesson K: The paradox of Rockall: why is a brooding gastropod (Littorina saxatilis) more widespread than one having a planktonic larval dispersal stage (L. littorea)? / Mar Biol 1988, 99:507鈥?13. CrossRef
50. Minchinton T, Scheibling R: The influence of larval supply and settlement on the population structure of barnacles. / Ecol 1991, 72:1867鈥?879. CrossRef
51. Davis A: Effects of variation in initial settlement on distribution and abundance of Podoclavella moluccensis Sluiter. / J Exp Mar Biol Ecol 1988, 117:157鈥?67. CrossRef
52. Connell JH: The consequences of variation in initial settlement vs. post-settlement mortality in rocky intertidal communities. / J Exp Mar Biol Ecol 1985, 93:11鈥?5. CrossRef
53. White C, Selkoe KA, Watson J, Siegel DA, Zacherl DC, Toonen RJ: Ocean currents help explain population genetic structure. / Proc R Soc B: Biol Sci 2010, 277:1685鈥?694. CrossRef
54. Marshall DJ, Morgan SG: Ecological and evolutionary consequences of linked life-history stages in the sea. / Curr Biol 2011, 21:R718-R725. CrossRef
55. Marshall DJ, Styan CA, Keough MJ: Sperm environment affects offspring quality in broadcast spawning marine invertebrates. / Ecol Lett 2002, 5:173鈥?76. CrossRef
56. Counihan RT, McNamara DC, Souter DC, Jebreen EJ, Preston NP, Johnson CR, Degnan BM: Pattern, synchrony and predictability of spawning of the tropical abalone Haliotis asinina from Heron Reef, Australia. / Mar Ecol Prog Ser 2001, 213:193鈥?02. CrossRef
57. Jackson DJ, McDougall C, Green KM, Simpson F, W枚rheide G, Degnan BM: A rapidly evolving secretome builds and patterns a sea shell. / BMC Biol 2006, 4:40. CrossRef
58. Macnification [http://www.macnification.com/] - 作者单位:Daniel J Jackson (1) (2)
Sandie M Degnan (1)
Bernard M Degnan (1)
1. School of Biological Sciences, University of Queensland, St. Lucia, 4072, Queensland, Australia
2. Courant Research Centre Geobiology, Georg-August University of G枚ttingen, Goldschmidtstr.3, 37077, G枚ttingen, Germany
文摘
Introduction Inter-specific comparisons of metazoan developmental mechanisms have provided a wealth of data concerning the evolution of body form and the generation of morphological novelty. Conversely, studies of intra-specific variation in developmental programs are far fewer. Variation in the rate of development may be an advantage to the many marine invertebrates that posses a biphasic life cycle, where fitness commonly requires the recruitment of planktonically dispersing larvae to patchily distributed benthic environments. Results We have characterised differences in the rate of development between individuals originating from a synchronised fertilisation event in the tropical abalone Haliotis asinina, a broadcast spawning lecithotrophic vetigastropod. We observed significant differences in the time taken to complete early developmental events (time taken to complete third cleavage and to hatch from the vitelline envelope), mid-larval events (variation in larval shell development) and late larval events (the acquisition of competence to respond to a metamorphosis inducing cue). We also provide estimates of the variation in maternally provided energy reserves that suggest maternal provisioning is unlikely to explain the majority of the variation in developmental rate we report here. Conclusions Significant differences in the rates of development exist both within and between cohorts of synchronously fertilised H. asinina gametes. These differences can be detected shortly after fertilisation and generate larvae of increasingly divergent development states. We discuss the significance of our results within an ecological context, the adaptive significance of mechanisms that might maintain this variation, and potential sources of this variation.