| scholarly article | Q13442814 |
| P50 | author | Stuart A. West | Q7627224 |
| Angus Buckling | Q68686810 | ||
| Andy Gardner | Q42874404 | ||
| P2860 | cites work | A CONSIDERATION OF PATTERNS OF VIRULENCE ARISING FROM HOST-PARASITE COEVOLUTION | Q60492178 |
| Trade-offs and the evolution of virulence of microparasites: do details matter? | Q61659145 | ||
| Sub-lethal effects of pathogens can lead to the evolution of lower virulence in multiple infections | Q73011592 | ||
| Cooperation, virulence and siderophore production in bacterial parasites | Q73011626 | ||
| Reproductive effort in viscous populations | Q74149772 | ||
| Population structure and the evolution of virulence in nematode parasites of fig wasps | Q81088711 | ||
| Extraordinary Sex Ratios | Q22065584 | ||
| Isolation, sequence, and expression of the gene encoding halocin H4, a bacteriocin from the halophilic archaeon Haloferax mediterranei R4 | Q24679756 | ||
| The viral killer system in yeast: from molecular biology to application | Q28217066 | ||
| Extraordinary sex ratios. A sex-ratio theory for sex linkage and inbreeding has new implications in cytogenetics and entomology | Q28258362 | ||
| Local dispersal promotes biodiversity in a real-life game of rock-paper-scissors | Q31096211 | ||
| Chemical warfare between microbes promotes biodiversity | Q32059349 | ||
| The ecological role of bacteriocins in bacterial competition | Q33594391 | ||
| Kin selection and parasite evolution: higher and lower virulence with hard and soft selection | Q33919564 | ||
| The ecology of genetically diverse infections | Q34250505 | ||
| Structured habitats and the evolution of anticompetitor toxins in bacteria | Q34276495 | ||
| Models of parasite virulence | Q34407463 | ||
| Bacteriocins: evolution, ecology, and application | Q34762780 | ||
| Does multiple infection select for raised virulence? | Q34825830 | ||
| The scope for virulence management: a comment on Ewald's view on the evolution of virulence | Q40953467 | ||
| Mixed strain schistosome infections of snails and the evolution of parasite virulence | Q43405434 | ||
| A phylogenetic approach to assessing the targets of microbial warfare | Q43749555 | ||
| Selfish and spiteful behaviour in an evolutionary model | Q44156558 | ||
| The evolution of cytoplasmic incompatibility or when spite can be successful | Q45214825 | ||
| Imperfect vaccines and the evolution of pathogen virulence | Q47896350 | ||
| How to make a kin selection model. | Q51016048 | ||
| Inclusive fitness arguments in genetic models of behaviour. | Q51025156 | ||
| A kin selection model for the evolution of virulence. | Q52407898 | ||
| A game-theoretical model of parasite virulence. | Q52708353 | ||
| Killer-sensitive coexistence in metapopulations of micro-organisms. | Q55440103 | ||
| P433 | issue | 1547 | |
| P1104 | number of pages | 7 | |
| P304 | page(s) | 1529-1535 | |
| P577 | publication date | 2004-07-01 | |
| P1433 | published in | Proceedings of the Royal Society B | Q2625424 |
| P1476 | title | Bacteriocins, spite and virulence. | |
| P478 | volume | 271 |
| Q93019750 | A general framework for modelling the impact of co-infections on pathogen evolution |
| Q39853603 | A new biofilm-associated colicin with increased efficiency against biofilm bacteria. |
| Q51819158 | A nutrient mediates intraspecific competition between rodent malaria parasites in vivo. |
| Q41874911 | A polychromatic 'greenbeard' locus determines patterns of cooperation in a social amoeba |
| Q52752565 | Alternative paths to success in a parasite community: within-host competition can favor higher virulence or direct interference. |
| Q37707713 | Altruism, spite, and greenbeards. |
| Q29614265 | An ecological and evolutionary perspective on human-microbe mutualism and disease |
| Q51722507 | An evolutionary analysis of the relationship between spite and altruism. |
| Q42123599 | An experimental study of strong reciprocity in bacteria. |
| Q42016983 | Antagonistic competition moderates virulence in Bacillus thuringiensis |
| Q47922192 | Antagonistic interactions of soil pseudomonads are structured in time |
| Q34206819 | Antagonistic interactions peak at intermediate genetic distance in clinical and laboratory strains of Pseudomonas aeruginosa. |
| Q34388208 | Antimicrobial activity and genetic profile of Enteroccoci isolated from hoopoes uropygial gland |
| Q37405315 | Bacterial viruses enable their host to acquire antibiotic resistance genes from neighbouring cells |
| Q36382256 | Bacteriocin-mediated interactions within and between coexisting species. |
| Q37625706 | Bet-hedging in bacteriocin producing Escherichia coli populations: the single cell perspective |
| Q91792088 | Biofilms facilitate cheating and social exploitation of β-lactam resistance in Escherichia coli |
| Q35684956 | Building the microbiome in health and disease: niche construction and social conflict in bacteria |
| Q52320391 | Cell adhesion and fluid flow jointly initiate genotype spatial distribution in biofilms. |
| Q38187125 | Co-infection and super-infection models in evolutionary epidemiology |
| Q46482802 | Competition sensing: the social side of bacterial stress responses |
| Q33759831 | Competition, cooperation among kin, and virulence in multiple infections |
| Q35018612 | Competitive interactions in Escherichia coli populations: the role of bacteriocins |
| Q51916481 | Continuous model for the rock-scissors-paper game between bacteriocin producing bacteria. |
| Q33249315 | Cooperation and virulence in acute Pseudomonas aeruginosa infections |
| Q34086431 | Cooperative secretions facilitate host range expansion in bacteria |
| Q51935146 | Demography, altruism, and the benefits of budding. |
| Q26786950 | Ecology of Anti-Biofilm Agents I: Antibiotics versus Bacteriophages |
| Q51696196 | Effect of dispersal and nutrient availability on the competitive ability of toxin-producing yeast. |
| Q26853416 | Enhancing stress-resistance for efficient microbial biotransformations by synthetic biology |
| Q51342034 | Everybody loses: intraspecific competition induces tragedy of the commons in Allenby's gerbils. |
| Q37339473 | Evolution and evolvability: celebrating Darwin 200. |
| Q42004584 | Evolution and the microbial control of insects |
| Q39322429 | Evolution of bacterial virulence |
| Q37543691 | Evolution of microbial markets |
| Q31141821 | Evolution of pathogens in a man-made world. |
| Q41890675 | Evolutionary ecology of microbial wars: within-host competition and (incidental) virulence |
| Q38599733 | Evolutionary games, climate and the generation of diversity. |
| Q40132346 | Experimental evolution with a multicellular host causes diversification within and between microbial parasite populations-Differences in emerging phenotypes of two different parasite strains |
| Q24812444 | Exploitative and hierarchical antagonism in a cooperative bacterium |
| Q40294253 | Fast-killing parasites can be favoured in spatially structured populations. |
| Q37696306 | First principles of Hamiltonian medicine. |
| Q57152490 | Friendly foes: The evolution of host protection by a parasite |
| Q41119781 | From within-host interactions to epidemiological competition: a general model for multiple infections |
| Q34018885 | Global comparison of warring groups in 2002-2007: fatalities from targeting civilians vs. fighting battles |
| Q40918298 | Higher relatedness mitigates mortality in a nematode with lethal male fighting. |
| Q33706531 | Influence of multiple infection and relatedness on virulence: disease dynamics in an experimental plant population and its castrating parasite |
| Q38692643 | Integrating Competition for Food, Hosts, or Mates via Experimental Evolution. |
| Q24277443 | Intensive aquaculture selects for increased virulence and interference competition in bacteria |
| Q44040030 | Interference Competition Among Household Strains of Pseudomonas |
| Q51551330 | Intraguild predation provides a selection mechanism for bacterial antagonistic compounds. |
| Q48176580 | Kin Selection in the RNA World. |
| Q35101226 | Kin competition promotes dispersal in a male pollinating fig wasp. |
| Q89703646 | Kin discrimination, negative relatedness, and how to distinguish between selfishness and spite |
| Q37062919 | Kin selection and the evolution of virulence |
| Q55644687 | Kin selection, quorum sensing and virulence in pathogenic bacteria. |
| Q55300080 | Local competition increases people's willingness to harm others. |
| Q35102583 | Male-male aggression peaks at intermediate relatedness in a social spider mite |
| Q34167878 | Mechanisms of pathogenesis, infective dose and virulence in human parasites. |
| Q39187216 | Microbe-mediated host defence drives the evolution of reduced pathogen virulence |
| Q37798606 | Microbial communication and virulence: lessons from evolutionary theory |
| Q47690996 | Multicoloured greenbeards, bacteriocin diversity and the rock-paper-scissors game |
| Q38076466 | Multiple infections and the evolution of virulence. |
| Q26744020 | Multiple-genotype infections and their complex effect on virulence |
| Q57145025 | Mutual fitness benefits arise during coevolution in a nematode-defensive microbe model |
| Q37956420 | Nuclease colicins and their immunity proteins |
| Q34340481 | On the evolution of harming and recognition in finite panmictic and infinite structured populations |
| Q37341276 | Persistence of colicinogenic Escherichia coli in the mouse gastrointestinal tract |
| Q90726470 | Plastic responses to competition: Does bacteriocin production increase in the presence of nonself competitors? |
| Q34179233 | Polymicrobial challenges to Koch's postulates: ecological lessons from the bacterial vaginosis and cystic fibrosis microbiomes |
| Q51313228 | Presence of a loner strain maintains cooperation and diversity in well-mixed bacterial communities. |
| Q36493255 | Programming stress-induced altruistic death in engineered bacteria |
| Q59055297 | Promiscuity and the evolutionary transition to complex societies |
| Q33268529 | Resolving the tragedy of the commons: the feedback between intraspecific conflict and population density |
| Q55498865 | Signal diffusion and the mitigation of social exploitation in pneumococcal competence signalling. |
| Q41817819 | Social evolution in micro-organisms and a Trojan horse approach to medical intervention strategies. |
| Q36538101 | Social evolution theory for microorganisms. |
| Q56269052 | Social semantics: how useful has group selection been? |
| Q35938628 | Spite and the scale of competition |
| Q37153678 | Spite and virulence in the bacterium Pseudomonas aeruginosa |
| Q41813528 | Spite versus cheats: competition among social strategies shapes virulence in Pseudomonas aeruginosa |
| Q42014666 | Spiteful interactions between sympatric natural isolates of Xenorhabdus bovienii benefit kin and reduce virulence. |
| Q38674860 | Support for redistribution is shaped by compassion, envy, and self-interest, but not a taste for fairness |
| Q36792183 | Synergy and group size in microbial cooperation |
| Q35011529 | Systematic approach to Escherichia coli cell population control using a genetic lysis circuit |
| Q34639543 | Temperate bacterial viruses as double-edged swords in bacterial warfare. |
| Q50026012 | The ColM Family, Polymorphic Toxins Breaching the Bacterial Cell Wall. |
| Q36919489 | The adaptive evolution of virulence: a review of theoretical predictions and empirical tests |
| Q35152296 | The components of kin competition |
| Q45292271 | The evolutionary dynamics of spite in finite populations |
| Q34087539 | The relevance of marine chemical ecology to plankton and ecosystem function: an emerging field |
| Q43184264 | The role of 'soaking' in spiteful toxin production in Pseudomonas aeruginosa. |
| Q37837472 | The sociobiology of molecular systems. |
| Q33304939 | The tragedy of the commons in evolutionary biology |
| Q28533167 | The weak shall inherit: bacteriocin-mediated interactions in bacterial populations |
| Q93011681 | Toxin production spontaneously becomes regulated by local cell density in evolving bacterial populations |
| Q54392839 | Translocator hunt comes full Cir-Col. |
| Q90571692 | Understanding the evolution of interspecies interactions in microbial communities |
| Q34160528 | Virulence evolution in response to anti-infection resistance: toxic food plants can select for virulent parasites of monarch butterflies |
| Q36701266 | What can microbial genetics teach sociobiology? |
| Q35246646 | What traits are carried on mobile genetic elements, and why? |
| Q26700138 | Within-host competitive interactions as a mechanism for the maintenance of parasite diversity |
| Q34318373 | Within-host dynamics of multi-species infections: facilitation, competition and virulence. |
| Q59341411 | Within-host parasite cooperation and the evolution of virulence |
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