C. E. Zobell and F. H. Johnson, The influence of hydrostatic pressure on the growth and viability of terrestrial and marine bacteria, J Bacteriol, vol.57, pp.179-189, 1949.

F. Abe and C. Kato, Barophysiology (Piezophysiology), pp.227-248, 1999.

A. A. Yayanos, Microbiology to 10,500 meters in the deep-sea, Annu Rev Microbiol, vol.49, pp.777-805, 1995.

V. Grossi, M. M. Yakimov, A. Ali, B. Tapilatu, Y. Cuny et al., Hydrostatic pressure affects membrane and storage lipid compositions of the piezotolerant hydrocarbon-degrading Marinobacter hydrocarbonoclasticus strain #5, Environ Microbiol, vol.12, pp.2020-2033, 2010.
URL : https://hal.archives-ouvertes.fr/hal-00514541

D. H. Bartlett, M. Wright, A. A. Yayanos, and M. Silverman, Isolation of a gene regulated by hydrostatic pressure in a deep-sea bacterium, Nature, vol.342, pp.572-574, 1989.

C. Kato, T. Sato, F. Abe, E. Ohmae, and H. Tamegai, Protein adaptation in extremophiles Molecular anatomy and physiology of proteins series, pp.167-191, 2008.

F. Abe, C. Kato, and K. Horikoshi, Pressure-regulated metabolism in microorganisms, Trends Biotechnol, vol.7, pp.447-453, 1999.

M. Yamada, K. Nakasone, H. Tamegai, C. Kato, and R. Usami, Pressure regulation of soluble cytochromes c in a deep-Sea piezophilic bacterium, Shewanella violacea, J Bacteriol, vol.182, pp.2945-2952, 2000.

D. H. Bartlett, C. Kato, and K. Horikoshi, High pressure influences on gene and protein expression, Res Microbiol, vol.146, pp.697-706, 1995.

F. M. Lauro, K. Tran, A. Vezzi, N. Vitulo, and G. Valle, Large-scale transposon mutagenesis of Photobacterium profundum SS9 reveals new genetic loci important for growth at low temperature and high pressure, J Bacteriol, vol.190, pp.1699-1709, 2008.

D. H. Bartlett, F. M. Lauro, and E. A. Eloe, Microbial adaptation to high pressure, Physiology and Biochemistry of Extremophiles, pp.333-348, 2007.

E. G. Ruby, E. P. Greenberg, and J. W. Hastings, Planktonic marine luminous bacteria: species distribution in the water column, Appl Environ Microbiol, vol.39, pp.302-306, 1980.

J. W. Hastings, Chemistry and control of luminescence in marine organisms, Bull Mar Sci, vol.33, pp.818-828, 1983.

P. J. Herring, Systematic distribution of bioluminescence in living organisms, J Biolumin Chemilumin, vol.1, pp.147-163, 1987.

A. B. Martin-cuadrado, P. Lopez-garcia, J. C. Alba, D. Moreira, and L. Monticelli, Metagenomics of the deep Mediterranean, a warm bathypelagic habitat, PLoS ONE, vol.2, p.914, 2007.

K. Kita-tsukamoto, M. Wada, K. Yao, A. Kamiya, and S. Yoshizawa, Rapid identification of marine bioluminescent bacteria by amplified 16 S ribosomal RNA gene restriction analysis, FEMS Microbiol Lett, vol.256, pp.298-303, 2006.

G. Gentile, D. Luca, M. Denaro, R. Smedile, F. et al., PCR based detection of bioluminescent microbial populations in marine environment, Deep-Sea Res II, vol.56, pp.763-767, 2009.

A. Vezzi, S. Campanaro, M. D9angelo, F. Simonato, and N. Vitulo, Life at depth: Photobacterium profundum genome sequence and expression analysis, Science, vol.307, pp.1459-1461, 2005.

P. Dunlap and K. Kita-tsukamoto, Luminous bacteria. The prokaryotes, vol.2, pp.863-892, 2006.

A. Ali, B. Garel, M. Cuny, P. Miquel, J. Toubal et al., Luminous bacteria in the deep-sea waters near the ANTARES underwater neutrino telescope (Mediterranean Sea), Chem Ecol, vol.26, pp.57-72, 2010.
URL : https://hal.archives-ouvertes.fr/hal-00455642

K. H. Nealson, Isolation, identification, and manipulation of luminous bacteria, Methods Enzymol, vol.57, pp.153-166, 1978.

C. Kato, T. Sato, M. Smorawinska, and K. Horikoshi, High pressure conditions stimulate expression of chloramphenicol acetyltransferase regulated by the lac promoter in Escherichia coli, FEMS Microbiol Lett, vol.122, pp.91-96, 1994.

C. Kato, S. Suzuki, S. Hata, T. Ito, and K. Horikoshi, The properties of a protease activated by high pressure from Sporosarcina sp. strain DSK25 isolated from deep-sea sediment, Jamstecr, vol.32, pp.7-13, 1995.

M. Yanagibayashi, Y. Nogi, L. Li, and C. Kato, Changes in the microbial community in Japan Trench sediment from a depth of 6,292 m during cultivation without decompression, FEMS Microbiol Lett, vol.170, pp.271-279, 1999.

K. G. Porter and Y. S. Feig, The use of DAPI for identifying and counting aquatic microflora, Limnol Oceanogr, vol.25, pp.943-948, 1980.

P. F. Verhulst, Notice sur la loi que la population suit dans son accroissement, Correspondence Mathematique et Physique, vol.10, pp.113-121, 1838.

. R-core-team, R: A Language and Environment for Statistical Computing. R Foundation for Statistical Computing, 2012.

E. G. Bligh and W. J. Dyer, A rapid method of total lipid extraction and purification, Can J Biochem Physiol, vol.37, pp.911-917, 1959.

W. W. Christie, Gas chromatography and lipids: a practical guide, pp.64-184, 1989.

C. Tamburini, M. Goutx, C. Guigue, M. Garel, and D. Lefèvre, Effects of hydrostatic pressure on microbial alteration of sinking fecal pellets, Deep-Sea Res II, vol.56, pp.1533-1546, 2009.

E. A. Eloe, F. Malfatti, J. Gutierrez, K. Hardy, and W. E. Schmidt, Isolation and characterization of a psychropiezophilic alphaproteobacterium, Appl Environ Microbiol, vol.77, pp.8145-8153, 2011.

J. Fang, L. Zhang, and D. A. Bazylinski, Deep-sea piezosphere and piezophiles: geomicrobiology and biogeochemistry, Trends Microbiol, vol.18, pp.413-422, 2010.

A. A. Yayanos, Evolutional and ecological implications of the properties of deep-sea barophilic bacteria, Proc Natl Acad Sci, vol.83, pp.9542-9546, 1986.

D. H. Bartlett, Microbial life at high-pressures, Sci prog, vol.76, pp.479-496, 1992.

D. H. Bartlett, Pressure effects on in vivo microbial processes, Biochim Biophys Acta (BBA)-Protein Structure and Molecular Enzymology, vol.1595, pp.367-381, 2002.

J. M. Shively, G. C. Cannon, S. Heinhorst, D. A. Bryant, and S. Dassarma, Bacterial and archaeal inclusions, 2001.

R. W. Campbell and J. F. Dower, Role of lipids in the maintenance of neutral buoyancy by zooplankton, Mar Ecol Prog Ser, vol.263, pp.93-99, 2003.

E. F. Delong and A. A. Yayanos, Adaptation of the membrane lipids of a deepsea bacterium to changes in hydrostatic pressure, Science, vol.228, pp.1101-1113, 1985.

K. Kamimura, H. Fuse, O. Takimura, and Y. Yamaoka, Effects of growth pressure and temperature on fatty acid composition of a barotolerant deep-sea bacterium, Appl Environ Microbiol, vol.59, pp.924-926, 1993.

Y. Yano, A. Nakayama, K. Ishihara, and H. Saito, Adaptive changes in membrane lipids of barophilic bacteria in response to changes in growth pressure, Appl Environ Microbiol, vol.64, pp.479-485, 1998.

E. F. Delong, D. G. Franks, and A. A. Yayanos, Evolutionary relationships of cultivated psychrophilic and barophilic deep-sea bacteria, Appl Environ Microbiol, vol.63, pp.2105-2108, 1997.

A. Czyz, B. Wrobel, and G. Wegrzyn, Vibrio harveyi bioluminescence plays a role in stimulation of DNA repair, Microbiology, vol.146, pp.283-288, 2000.

K. H. Nealson, T. Platt, and J. W. Hastings, Cellular control of the synthesis and activity of the bacterial luminescent system, J Bacteriol, vol.104, pp.313-322, 1970.

K. Nealson and J. W. Hastings, Low oxygen is optimal for luciferase synthesis in some bacteria, Arch, vol.112, pp.9-16, 1977.

J. J. Bourgois, F. E. Sluse, F. Baguet, and J. Mallefet, Kinetics of Light Emission and Oxygen Consumption by Bioluminescent Bacteria, J Bioenerg Biomembr, vol.33, pp.353-363, 2001.

D. W. Grogan, Interaction of respiration and luminescence in a common marine bacterium, Arch Microbiol, vol.137, pp.159-162, 1984.

L. R. Hmelo, T. J. Mincer, V. Mooy, and B. , Possible influence of bacterial quorum sensing on the hydrolysis of sinking particulate organic carbon in marine environments, Environ Microbiol Rep, vol.3, pp.682-688, 2011.

D. T. Pooley, Bacterial bioluminescence, bioelectromagnetics and function, Photochem Photobiol, vol.87, pp.324-328, 2010.

S. Haddock, M. A. Moline, and J. F. Case, Bioluminescence in the sea, Annu Rev Mar Sci, vol.2, pp.443-493, 2010.

E. A. Widder, Bioluminescence in the ocean: origins of biological, chemical, and ecological diversity, Science, vol.328, pp.704-708, 2010.

F. Azam, Microbial control of oceanic carbon flux: the plot thickens, Science, vol.280, pp.694-696, 1998.

F. Azam and R. A. Long, Sea snow microcosms, Nature, vol.414, pp.495-498, 2001.

A. L. Alldredge and Y. Cohen, Can microscale chemical patches persist in the sea? Microelectrode study of marine snow, fecal pellets, Science, vol.235, pp.689-691, 1987.

B. Schweitzer, I. Huber, R. Amann, W. Ludwig, and M. Simon, Alpha-and betaProteobacteria control the consumption and release of amino acids on lake snow aggregates, Appl Environ Microbiol, vol.67, pp.632-645, 2001.

H. Ploug and H. Grossart, Bacterial growth and grazing on diatom aggregates: Respiratory carbon turnover as a function of aggregate size and sinking velocity, Limnol Oceanogr, vol.45, pp.1467-1475, 2000.

E. G. Ruby and J. G. Morin, Luminous enteric bacteria of marine fishes: a study of their distribution, densities, and dispersion, Appl Environ Microbiol, vol.38, pp.406-411, 1979.

C. C. Andrews, D. M. Karl, L. F. Small, and S. W. Fowler, Metabolic activity and bioluminescence of oceanic faecal pellets and sediment trap particles, Nature, vol.307, pp.539-541, 1984.

M. Zarubin, S. Belkin, M. Ionescu, and A. Genin, Bacterial bioluminescence as a lure for marine zooplankton and fish, Proc Natl Acad Sci, vol.109, pp.853-857, 2012.