The Black Queen Hypothesis: Evolution of Dependencies through Adaptive Gene Loss

ABSTRACT Reductive genomic evolution, driven by genetic drift, is common in endosymbiotic bacteria. Genome reduction is less common in free-living organisms, but it has occurred in the numerically dominant open-ocean bacterioplankton Prochlorococcus and “Candidatus Pelagibacter,” and in these cases the reduction appears to be driven by natural selection rather than drift. Gene loss in free-living organisms may leave them dependent on cooccurring microbes for lost metabolic functions. We present the Black Queen Hypothesis (BQH), a novel theory of reductive evolution that explains how selection leads to such dependencies; its name refers to the queen of spades in the game Hearts, where the usual strategy is to avoid taking this card. Gene loss can provide a selective advantage by conserving an organism’s limiting resources, provided the gene’s function is dispensable. Many vital genetic functions are leaky, thereby unavoidably producing public goods that are available to the entire community. Such leaky functions are thus dispensable for individuals, provided they are not lost entirely from the community. The BQH predicts that the loss of a costly, leaky function is selectively favored at the individual level and will proceed until the production of public goods is just sufficient to support the equilibrium community; at that point, the benefit of any further loss would be offset by the cost. Evolution in accordance with the BQH thus generates “beneficiaries” of reduced genomic content that are dependent on leaky “helpers,” and it may explain the observed nonuniversality of prototrophy, stress resistance, and other cellular functions in the microbial world.

[1]  M. Keller,et al.  Dependence of the Cyanobacterium Prochlorococcus on Hydrogen Peroxide Scavenging Microbes for Growth at the Ocean's Surface , 2011, PloS one.

[2]  David M. Paterson,et al.  The Stabilisation Potential of Individual and Mixed Assemblages of Natural Bacteria and Microalgae , 2010, PloS one.

[3]  J. Crawford,et al.  Siderophores from neighboring organisms promote the growth of uncultured bacteria. , 2010, Chemistry & biology.

[4]  Carey D. Nadell,et al.  Emergence of Spatial Structure in Cell Groups and the Evolution of Cooperation , 2010, PLoS Comput. Biol..

[5]  Howard Ochman,et al.  The consequences of genetic drift for bacterial genome complexity. , 2009, Genome research.

[6]  I. Paulsen,et al.  Ecological Genomics of Marine Picocyanobacteria , 2009, Microbiology and Molecular Biology Reviews.

[7]  N. Moran,et al.  The Dynamics and Time Scale of Ongoing Genomic Erosion in Symbiotic Bacteria , 2009, Science.

[8]  R. Breaker,et al.  Unique glycine-activated riboswitch linked to glycine-serine auxotrophy in SAR11. , 2009, Environmental microbiology.

[9]  K. Foster,et al.  The sociobiology of biofilms. , 2009, FEMS microbiology reviews.

[10]  M. Bennett,et al.  Through the looking glass. , 2009, Minnesota medicine.

[11]  M. Church Resource Control of Bacterial Dynamics in the Sea , 2008 .

[12]  S. Giovannoni,et al.  SAR11 marine bacteria require exogenous reduced sulphur for growth , 2008, Nature.

[13]  A. Sangrador-Vegas,et al.  Genome Sequence of Lactobacillus helveticus, an Organism Distinguished by Selective Gene Loss and Insertion Sequence Element Expansion , 2007, Journal of bacteriology.

[14]  Feng Chen,et al.  Patterns and Implications of Gene Gain and Loss in the Evolution of Prochlorococcus , 2007, PLoS genetics.

[15]  C. Obinger,et al.  Phylogenetic distribution of catalase-peroxidases: are there patches of order in chaos? , 2007, Gene.

[16]  R. B. Jackson,et al.  Toward an ecological classification of soil bacteria. , 2007, Ecology.

[17]  M. Loosdrecht,et al.  Heterotrophic Pioneers Facilitate Phototrophic Biofilm Development , 2007, Microbial Ecology.

[18]  A. Halpern,et al.  The Sorcerer II Global Ocean Sampling Expedition: Northwest Atlantic through Eastern Tropical Pacific , 2007, PLoS biology.

[19]  M. Lynch Streamlining and simplification of microbial genome architecture. , 2006, Annual review of microbiology.

[20]  A. Griffin,et al.  Social evolution theory for microorganisms , 2006, Nature Reviews Microbiology.

[21]  Paul G. Blackwell,et al.  Revisiting the catastrophic die-off of the urchin Diadema antillarum on Caribbean coral reefs: Fresh insights on resilience from a simulation model , 2006 .

[22]  J. Gibrat,et al.  The complete genome sequence of Lactobacillus bulgaricus reveals extensive and ongoing reductive evolution. , 2006, Proceedings of the National Academy of Sciences of the United States of America.

[23]  J. Waterbury,et al.  Distribution and Diversity of Natural Product Genes in Marine and Freshwater Cyanobacterial Cultures and Genomes , 2005, Applied and Environmental Microbiology.

[24]  S. Eriksson,et al.  Bacterial genome size reduction by experimental evolution. , 2005, Proceedings of the National Academy of Sciences of the United States of America.

[25]  M. Noordewier,et al.  Genome Streamlining in a Cosmopolitan Oceanic Bacterium , 2005, Science.

[26]  V. Kashyap,et al.  Molecular insight into the genesis of ranked caste populations of western India based upon polymorphisms across non-recombinant and recombinant regions in genome , 2005, Genome Biology.

[27]  D. Karl,et al.  Vertical distributions of nitrogen-fixing phylotypes at Stn ALOHA in the oligotrophic North Pacific Ocean , 2005 .

[28]  C. Trick Hydroxamate-siderophore production and utilization by marine eubacteria , 1989, Current Microbiology.

[29]  T. Cavalier-smith Economy, speed and size matter: evolutionary forces driving nuclear genome miniaturization and expansion. , 2005, Annals of botany.

[30]  Frédéric Partensky,et al.  Accelerated evolution associated with genome reduction in a free-living prokaryote , 2005, Genome Biology.

[31]  Jason Raymond,et al.  The natural history of nitrogen fixation. , 2004, Molecular biology and evolution.

[32]  P. S. Lake,et al.  Invasional 'meltdown' on an oceanic island , 2003 .

[33]  M. Klotz,et al.  The molecular evolution of catalatic hydroperoxidases: evidence for multiple lateral transfer of genes between prokaryota and from bacteria into eukaryota. , 2003, Molecular biology and evolution.

[34]  R. Schwarz,et al.  Oxidative Stress in Synechococcus sp. Strain PCC 7942: Various Mechanisms for H2O2 Detoxification with Different Physiological Roles , 2003, Journal of bacteriology.

[35]  S. Andrews,et al.  Bacterial iron homeostasis. , 2003, FEMS microbiology reviews.

[36]  William A. Siebold,et al.  SAR11 clade dominates ocean surface bacterioplankton communities , 2002, Nature.

[37]  J. Imlay,et al.  Hydrogen Peroxide Fluxes and Compartmentalization inside Growing Escherichia coli , 2001, Journal of bacteriology.

[38]  Richard E. Lenski,et al.  Mechanisms Causing Rapid and Parallel Losses of Ribose Catabolism in Evolving Populations of Escherichia coli B , 2001, Journal of bacteriology.

[39]  Editor Jan Vijg Ph.D. Opinion , 2001, Mechanisms of Ageing and Development.

[40]  T. Gregory,et al.  Coincidence, coevolution, or causation? DNA content, cellsize, and the C‐value enigma , 2001, Biological reviews of the Cambridge Philosophical Society.

[41]  R. Lenski,et al.  Developmental cheating in the social bacterium Myxococcus xanthus , 2000, Nature.

[42]  W. Vermaas,et al.  In Vivo Role of Catalase-Peroxidase inSynechocystis sp. Strain PCC 6803 , 1999, Journal of bacteriology.

[43]  D. Vaulot,et al.  Prochlorococcus, a Marine Photosynthetic Prokaryote of Global Significance , 1999, Microbiology and Molecular Biology Reviews.

[44]  B. Biggs,et al.  SUBSIDY AND STRESS RESPONSES OF STREAM PERIPHYTON TO GRADIENTS IN WATER VELOCITY AS A FUNCTION OF COMMUNITY GROWTH FORM , 1998 .

[45]  Charles Weijer,et al.  Full House: The Spread of Excellence from Plato to Darwin. , 1997 .

[46]  R. Zika,et al.  Hydrogen peroxide lifetimes in south Florida coastal and offshore waters , 1997 .

[47]  P. Falkowski,et al.  Confirmation of iron limitation of phytoplankton photosynthesis in the equatorial Pacific Ocean , 1996, Nature.

[48]  T. Groene Biogenic production and consumption of dimethylsulfide (DMS) and dimethylsulfoniopropionate (DMSP) in the marine epipelagic zone: a review , 1995 .

[49]  R. Lenski,et al.  Long-Term Experimental Evolution in Escherichia coli. I. Adaptation and Divergence During 2,000 Generations , 1991, The American Naturalist.

[50]  J. Pechenik Biology of the Invertebrates , 1991 .

[51]  Robert W. Howarth,et al.  Nitrogen limitation on land and in the sea: How can it occur? , 1991 .

[52]  B. Bebout,et al.  BACTERIAL ASSOCIATIONS WITH MARINE OSCILLATORIA SP. (TRICHODESMIUM SP.) POPULATIONS: ECOPHYSIOLOGICAL IMPLICATIONS 1 , 1989 .

[53]  W. J. Cooper,et al.  Photochemical formation of hydrogen peroxide in natural waters exposed to sunlight. , 1988, Environmental science & technology.

[54]  R. Lenski,et al.  Coexistence of two competitors on one resource and one inhibitor: a chemostat model based on bacteria and antibiotics. , 1986, Journal of theoretical biology.

[55]  L. Chao,et al.  Structured habitats and the evolution of anticompetitor toxins in bacteria. , 1981, Proceedings of the National Academy of Sciences of the United States of America.

[56]  L. V. Valen,et al.  A new evolutionary law , 1973 .

[57]  Eric R. Pianka,et al.  On r- and K-Selection , 1970, The American Naturalist.

[58]  G. E. Hutchinson,et al.  The Balance of Nature and Human Impact: The paradox of the plankton , 2013 .