[1] |
Travis J. Princeton Guide to Ecology. Princeton, NJ, USA: Princeton University Press, 2009: 65-71
|
[2] |
Starck JM. Structural flexibility of the gastro-intestinal tract of vertebrates: Implications for evolutionary morphology. Zoologischer Anzeiger, 1999, 238: 87-102
|
[3] |
Olsson J, Quevedo M, Colson C, et al. Gut length plasticity in perch: Into the bowels of resource polymorphisms. Biological Journal of the Linnean Society, 2007, 90: 517-523
|
[4] |
Zandonà E, Auer SK, Kilham SS, et al. Contrasting population and diet influences on gut length of an omnivorous tropical fish, the trinidadian guppy (Poecilia reticulata). PLoS One, 2015, 10(9): e0136079
|
[5] |
Sibly RM. Physiological Ecology: An Evolutionary Approach to Resource Use. Oxford, UK: Blackwell Publishing, 1981: 109-139
|
[6] |
Post DM. Using stable isotopes to estimate trophic position: Models, methods, and assumptions. Ecology, 2002, 83: 703-718
|
[7] |
Jackson AL, Inger R, Parnell AC, et al. Comparing isotopic niche widths among and within communities: SIBER-stable isotope bayesian ellipses in R. Journal of Animal Ecology, 2011, 80: 595-602
|
[8] |
谭支良. 动物胃肠道微生态理论与实践. 应用生态学报, 2003, 14(1): 148-150 [Tan Z-L. Micro-ecology in animal stomach and digestive tracts-theory and practice. Chinese Journal of Applied Ecology, 2003, 14(1): 148-150]
|
[9] |
Gómez GD, Balcázar JL. A review on the interactions between gut microbiota and innate immunity of fish. FEMS Immunology and Medical Microbiology, 2008, 52: 145-154
|
[10] |
Greene LK, Williams C, Junge RE, et al. A role for gut microbiota in host niche differentiation. The ISME Journal, 2020, 14: 1675-1687
|
[11] |
Miyake S, Ngugi DK, Stingl U, et al. Diet strongly influences the gut microbiota of surgeonfishes. Molecular Ecology, 2015, 24: 656-672
|
[12] |
Amato KR. Co-evolution in context: The importance of studying gut microbiomes in wild animals. Microbiome Science and Medicine, 2013, 1: 10-29
|
[13] |
Ley RE, Hamady M, Lozupone CA, et al. Evolution of mammals and their gut microbes. Science, 2008, 320: 1647-1651
|
[14] |
Woodhams DC, Bletz MC, Becker CG, et al. Host-associated microbiomes are predicted by immune system complexity and climate. Genome Biology, 2020, 21: 23
|
[15] |
Field JC, Elliger C, Baltz K, et al. Foraging ecology and movement patterns of jumbo squid (Dosidicus gigas) in the California Current System. Deep Sea Researc Part Ⅱ: Topical Studies in Oceanography, 2013, 95: 37-51
|
[16] |
Hanlon R, Vecchione M, Allcock L. Octopus, Squid, and Cuttlefish: A Visual, Scientific Guide to the Oceans’ Most Advanced Invertebrates. Chicago, IL, USA: University of Chicago Press, 2018: 34-36
|
[17] |
Waluda CM, Yamashiro C, Rodhouse PG, et al. Influence of the ENSO cycle on the light-fishery for Dosidicus gigas in the Peru Current: An analysis of remotely sensed data. Fisheries Research, 2006, 79: 56-63
|
[18] |
Gilly WF, Markaida U. Perspectives on Dosidicus gigas in a changing world. Globec Reports, 2006, 24: 81-90
|
[19] |
Hoving HT, Gilly WF, Markaida U, et al. Extreme plasticity in life-history strategy allows a migratory pre-dator (jumbo squid) to cope with a changing climate. Global Change Biology, 2013, 19: 2089-2103
|
[20] |
Li YK, Gong Y, Zhang YY, et al. Inter-annual variabi-lity in trophic patterns of jumbo squid (Dosidicus gigas) off the exclusive economic zone of Peru, implications from stable isotope values in gladius. Fisheries Research, 2017, 187: 22-30
|
[21] |
Portner E, Markaida U, Robinson CJ, et al. Trophic ecology of Humboldt squid, Dosidicus gigas, in conjunction with body size and climatic variability in the Gulf of California, Mexico. Limnology and Oceanography, 2020, 65: 732-748
|
[22] |
Roper CFE, Boss KJ. The giant squid. Scientific American, 1982, 246: 96-105
|
[23] |
Keyl F, Argüelles J, Mariátegui L, et al. A hypothesis on range expansion and spatio-temporal shifts in size at maturity of jumbo squid (Dosidicus gigas) in the Eas-tern Pacific Ocean. California Cooperative Oceanic Fishe-ries Investigations Report, 2014, 49: 119-128
|
[24] |
Chavez FP, Messie M, Pennington JT, et al. Marine Primary Production in Relation to Climate Variability and Change. Annual Review of Marine Science, 2011, 3: 227-260
|
[25] |
Watanabe H, Kawaguchi K. Decadal change in the diets of the surface migratory myctophid fish Myctophum niditulum in the Kuroshio region of the western North Pacific: Predation on sardine larvae by myctophyds Fish. Fisheries Science, 2003, 69: 716-721
|
[26] |
Robinson CJ, Gutierrez JG, Markaida U, et al. Prolonged decline of jumbo squid (Dosidicus gigas) landings in the Gulf of California is associated with chronically low wind stress and decreased chlorophyll a after El Niño 2009-2010. Fisheries Research, 2016, 173: 128-138
|
[27] |
Karachle PK, Stergiou KI. Gut length for several marine fish: Relationships with body length and trophic implications. Marine Biodiversity Records, 2010, 3: e106
|
[28] |
Richardson TJ, Potts WM, Santos CV, et al. Ontogenetic dietary shift and morphological correlates for Diplodus capensis (Teleostei: Sparidae) in Southern Angola. African Zoology, 2011, 46: 280-287
|
[29] |
Egerton S, Culloty SC, Whooley J, et al. The gut microbiota of marine fish. Frontiers in Microbiology, 2018, 9: 873
|
[30] |
Sullam KE, Essinger S, Lozupone CA, et al. Environmental and ecological factors that shape the gut bacterial communities of fish: A meta-analysis. Molecular Ecology, 2012, 21: 3363-3378
|
[31] |
Roura Á, Doyle SR, Nande M, et al. You are what you eat: A genomic analysis of the gut microbiome of captive and wild Octopus vulgaris Paralarvae and their zooplankton prey. Frontiers in Physiology, 2017, 8: 362, doi: 10.3389/fphys.2017.00362
|
[32] |
Liu H, Guo X, Gooneratne R, et al. The gut microbiome and degradation enzyme activity of wild freshwater fishes influenced by their trophic levels. Scientific Reports, 2016, 6: 24340
|
[33] |
Stolze Y, Bremges A, Maus I, et al. Targeted in situ metatranscriptomics for selected taxa from mesophilic and thermophilic biogas plants. Microbial Biotechnology, 2018, 11: 667-679
|
[34] |
Claesson MJ, Cusack S, Osullivan O, et al. Composition, variability, and temporal stability of the intestinal microbiota of the elderly. Proceedings of the National Academy of Sciences of the United States of America, 2011, 108: 4586-4591
|
[35] |
Ji M, Greening C, Vanwonterghem I, et al. Atmospheric trace gases support primary production in Antarctic desert surface soil. Nature, 2017, 552: 400-403
|
[36] |
Spring S, Bunk B, Spröer C, et al. Characterization of the first cultured representative of Verrucomicrobia subdivision 5 indicates the proposal of a novel phylum. The ISME Journal, 2016, 10: 2801-2816
|
[37] |
Ruiz-Cooley RI, Markaida U, Gendron D, et al. Stable isotopes in jumbo squid (Dosidicus gigas) beaks to estimate its trophic position: Comparison between stomach contents and stable isotopes. Journal of the Marine Biological Association of the United Kingdom, 2006, 86: 437-445
|