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Dionisio, F.; Domingues, C.; Rebelo, J.; Monteiro, F.; Nogueira, T. The Role of Commensal and other Non-Pathogenic Bacteria. Encyclopedia. Available online: https://encyclopedia.pub/entry/40892 (accessed on 06 September 2024).

Dionisio F, Domingues C, Rebelo J, Monteiro F, Nogueira T. The Role of Commensal and other Non-Pathogenic Bacteria. Encyclopedia. Available at: https://encyclopedia.pub/entry/40892. Accessed September 06, 2024.

Dionisio, Francisco, Célia Domingues, João Rebelo, Francisca Monteiro, Teresa Nogueira. "The Role of Commensal and other Non-Pathogenic Bacteria" Encyclopedia, https://encyclopedia.pub/entry/40892 (accessed September 06, 2024).

Dionisio, F., Domingues, C., Rebelo, J., Monteiro, F., & Nogueira, T. (2023, February 06). The Role of Commensal and other Non-Pathogenic Bacteria. In Encyclopedia. https://encyclopedia.pub/entry/40892

Dionisio, Francisco, et al. "The Role of Commensal and other Non-Pathogenic Bacteria." Encyclopedia. Web. 06 February, 2023.

Copy Citation The Role of Commensal and other Non-Pathogenic Bacteria This entry is adapted from the peer-reviewed paper 10.3390/ijms24031967

Not only pathogenic bacteria are reservoirs of antibiotic resistance and virulence genes. Opportunistic pathogenic bacteria, commensal bacteria, and mutualistic bacteria (here named non-pathogenic for simplification) may also carry resistance and virulence genes. However, contrary to pathogenic strains, which are the target of the immune system, non-pathogenic bacteria can colonize hosts for prolonged periods because hosts do not need to be rid of them. Thus, the basic reproductive number of a non-pathogenic bacterial strain, a measure of the strain’s fitness and denoted as R 0, is likely to be much higher than one. That is, the expected number of colonized hosts by a single colonized host in a population not yet colonized by that strain is higher than one, which implies that this strain can spread exponentially among hosts. This spread has peculiar consequences for the spread of virulence and resistance genes. For example, computer models that simulate the spread of these genes have shown that their diversities should correlate positively throughout microbiomes. Bioinformatics analysis with real data corroborates this expectation.

antibiotic resistance virulence microbiome metagenomics R0 Epidemiology bacteria commensal mutualistic pathogens gene pool

1. Brief Review of the R0, the Basic Reproductive Number

A central concept in the epidemiology of infectious disease transmission is the basic reproductive number: also called the basic reproduction number or basic reproduction ratio. It is the expected number of infected individuals by a single infected individual in a susceptible population. Denoted as R 0, this number is a measure of the pathogen’s fitness but is also a threshold that characterizes the epidemic potential of the disease because: if R 0 > 1 , the pathogen continues its propagation through susceptible hosts, with the number of infected hosts increasing exponentially; if R 0 < 1 , the number of infected hosts decreases exponentially, and the pathogen is extinct. The number of infected hosts is stable in the unlikely case where R0 equals one [1] [2] .

R0 is a dimensionless number defined as R0 = β ⋅ c ⋅ d , where β is the probability of infection if an infected individual contacts a susceptible one, c is the number of contacts between infected and susceptible individuals per time unit, and d is the duration of the infectious period. Its mathematical formula shows that R0 is proportional to the mean duration of infections d . This period decreases when the intrinsic mortality (i.e., mortality not caused by the pathogen) increases, the pathogen-induced mortality increases, and the rate at which the host recovers (e.g., through immunity) increases. When the colonizing agents are pathogens, typically, either the hosts die or manage to clear the pathogen. If the host’s death or recovery is quick, the R 0 of the pathogen is lower than if the pathogen remains a long time in the host. Therefore, there is something peculiar about non-pathogenic microorganisms with public-health consequences.

Non-pathogenic agents do not cause host death, and the hosts do not need to eliminate them. Consequently, commensal or mutualistic bacteria, including those harboring drug resistance or even a few virulence genes, may colonize their hosts for longer, so their R 0 is prone to be larger than one. This conclusion may impact public health because an R 0 larger than one implies that the microorganism may spread through the host population, and as mentioned above, non-pathogenic bacteria may harbor non-housekeeping genes and mobile genetic elements such as virulence and resistance genes.

Even if newly arrived non-pathogenic bacterial cells cannot persist in a microbiome for more than a few days, its mobile genetic elements can have several opportunities to transfer to one of the other established cells in that microbiome [3] [4] [5] , and may thus remain there for a long time. This is possible due to the presence of hundreds of bacterial species in many microbiomes, including the human gut, and because bacteria can receive foreign DNA through three primary mechanisms: (i) transformation, where bacteria directly uptakes DNA from the surroundings [6] ; (ii) transduction, where bacteriophages bring DNA from their previous hosts [7] ; and (iii) bacterial conjugation, where bacteria receive conjugative plasmids or integrative conjugative elements from neighboring cells [8] . A bacterial cell can uptake DNA from phylogenetically distant bacteria cells, and conjugative plasmids can transfer between cells belonging to different bacterial species [9] . Therefore, pathogenic and non-pathogenic bacteria can share a gene pool that includes virulence and resistance genes.

Moreover, some bacterial populations containing neither mobile genetic elements nor virulence or resistance genes can become great “amplifiers” of these genes after receiving some plasmids. Some bacterial strains are excellent donors of conjugative plasmids being able to “amplify” it among them while quickly transmitting the plasmid to other cells in a microbiome [10] [11] . These amplifiers are present among strains of Escherichia coli and other enterobacterial species [10] , among soil bacteria [11] , and most probably in the majority of microbiomes.

2. The Human Network of Physical Contacts

2.1. Brief Review of Small-World Networks

People establish many networks involving physical contact with each other through family relationships, friendships, sexual relationships, and many others. Networks have nodes (or vertices) and edges (connections). For example, consider the “handshaking” network in which each node is a person, and two persons are connected in this network if they had at least a handshaking, e.g., last year. In a typical network established by people, each person connects to a tiny subset of another person included in that network.

In some networks involving people, if a given person connects to two others, these two persons are likely connected to each other, but each person can reach most people (through the network’s connections) by a small number of connections. The last sentence sounds somewhat contradictory, but it is not – strikingly, many networks established by people are similar to this –the so-called small-world networks– and it will be discussed how that is relevant to understanding microorganisms’ spread.

Researchers first consider a regular network and then change it to make it a small-world network. Consider, for example, the network of friendships. For clarification, let people assume that individuals in a population are organized in alphabetic order in a very large circle: A, B, C, …, Y, Z, AA, AB, … and that all individuals have precisely four friends. In this network, each individual has someone else on his/he right and his/her left. Frequently, if individual C is a friend of two individuals on his/her right, A and B, and the two individuals on his/her left, D and E, then probably B and D are friends of each other, and A and B or D and E.

Meanwhile, D is a friend of B, C (right), E, and F (left), so B and C are friends to each other, as well as E and F, and so on. Therefore, the clustering of these networks’ nodes (people) is high. If all friendships were similar to this, the friendships’ network would be regular. In such a network, if, for example, individual G has an exciting gossip, it takes nine steps to reach, say, individual X. These nine steps are the following: G first informs I, which would transmit the story to K, then M, O, Q, S, U, V, X. Of course, some exceptions to the regular network of friendships may substantially impact information spread. For example, according to the rule described above, individual K may be a friend of I, J, and L. Nevertheless, in this new network version, the fourth K’s friend is Z, not M. With this exception, the network is no longer a regular one. In this case, a gossip would take just four steps to progress from G to X (G => I => K => Z => X). With a few more changes in other individuals, such as the one researchers introduced in K, the network becomes a “small-world” network. In small-world networks, the clustering of nodes (people) is high, but the path of friendships between any human being is short. Rumors may spread in regular networks, but the speed would be much higher in small-world networks [12] .

What makes small-world networks so relevant to epidemiology? As mentioned above, if people organize themselves in small-world networks, the spread of information is fast because, although most people do not have direct contact with each other, most can be reached in a few steps. Suppose physical proximity or even contact is involved in these networks. In that case, microorganisms may quickly spread because the typical distance between two randomly chosen people (the network nodes) grows proportionally to its logarithm [12] instead of the number of people in the network as in regular networks. This difference is relevant because the logarithm function grows much slower than a linear function. For example, when a given variable X increases from one to a billion (i.e., from 1 to 10 9 ), Log10X goes from zero to nine only. Therefore, in small-world networks, the path between two random persons is low, even if the network contains millions or billions of people.

Of course, people spontaneously build other contact networks. For example, people in working place are not necessarily friends, but you contact them daily. These networks, which usually involve physical proximity or sharing a working environment, may be relevant concerning the microorganisms’ evolution or spread. For example, previous studies have shown that the shorter path lengths in small-world networks increase the effectiveness of natural selection while maintaining the fittest clones in bacterial populations because the probability of encounters between individuals is higher than in regular networks [13] [14] .

Liljeros et al. studied the web of human sexual connections among 2810 adult Swedish people and found that those connections defined a scale-free network [15] [16] . In scale-free networks, the distribution of links in each node follows a power law [17] . In the case of the network of sexual contacts, p ( k ) describes the proportion of people with k sexual contacts in the previous year, p ( k ) ≈ c ⋅ k − α , where c and α are positive parameters. Therefore, all people in that Swedish database had at least one sexual partner in the previous year, but a lower fraction had two partners; an even lower fraction, some people had three sexual partners, and so on. Power-law distributions characteristically decreased slowly, so some individuals had 20 partners in the previous year. These few individuals are “hubs” of this network, which is relevant, for example, for sexually transmitted diseases [16] .

2.2. Power-Laws and Scale-Free Networks

Power-laws are mathematical functions such as x q , where x is the independent variable and q is a negative or positive constant. They are common in physical laws; for example, the gravitational force between two bodies decreases with distance d according to a power law proportional to d −2 . Similarly, the electric force between two charged bodies falls with d −2 .

In microbiology, researchers also find power laws. For example, the mutation rate per replication per nucleotide of DNA-based microorganisms decreases with the genome size according to μ ≈ c ⋅ G − β . Because β ≈ 1 , this equation means that the mutation rate per replication per nucleotide is inversely proportional to the genome size (that is μ ≈ c ⋅ G − 1 or μ=c/G or μ ⋅ G ≈ c ) so that the mutation rate per replication per genome is a constant ( c is around 0.003 or 0.004 ) : this is Drake’s rule [18] [19] [20] . Another example of power-las in microbiology concerns the death rate of persister bacterial populations in the presence of a bactericidal antibiotic. Some authors have argued that the death rate of persister populations of some strains follows a power law with an exponent close to −2 [21] [22] . A power-law decay is slower than an exponential decay, which means that bacterial cells under antibiotic exposure decay according to a power law can persist alive for longer, sometimes causing health problems and persistent food contamination.

Concerning the spread of microorganisms through human-contact networks (i.e., with people as nodes), it is relevant to know if the networks are scale-free, that is, if the proportion of people with a k connection follows a power-law distribution. That would mean that a non-negligible proportion of people have many connections, as it is seen with the web of sexual contacts [15] . However, there are more examples of scale-free networks relevant to epidemiology.

In 2006, Brockmann et al. found something striking concerning the dispersal of banknotes in the USA. They studied banknote dispersion as a proxy of people traveling. As intuitively expected, most banknotes travel less than 10 km in four days; also, according to intuition, the number of banknotes detected further away decreases when the distance increases. Gaussian or Exponential distributions would mostly predict that none or very few banknotes travel more than a few hundred kilometers. However, contrary to common intuition, many banknotes travel thousands of kilometers in those four days. Banknote traveling follows a decreasing power law [23] . The transactions of these banknotes may be twofold in their relevance to epidemiological studies: (i) banknotes move between physically close people, enabling cross-contagion with microorganisms; (ii) banknotes may carry microorganisms, so a person may contaminate another one without being physically close.

Tracking the position of 100,000 mobile phones for six months provides a similar distribution [24] . Most mobile phones only travel a few kilometers, and the proportion of phones traveling decays when the distance increases. A non-negligible number of cell phones traveled hundreds of kilometers. As it is seen for banknotes, the overall traveling of mobile phones follows a decreasing power law. These long-distance traveling people (measured through their banknotes and mobile phones) may constitute relevant microorganism spreaders.

As it is seen, networks where the proportion of people with k connections decreases according to p ( k ) ≈ k − α , where α is a positive fixed number, are epidemiologically relevant. However, concerning the diseases’ spread, some are even more relevant such as those power laws where the parameter α is between two and three. Researchers have seen above that a suitable parameter commonly discussed in epidemiological studies is that of R0 , which informs people how many people a single infected person will transmit the infection to on average in a fully susceptible population. Strikingly, there is no such threshold in networks whose connections between people follow a decreasing power-law distribution with 2 < α < 3 . Therefore, an epidemic spread may occur even with low rates of disease transmission between the hosts [25] [26] . Networks with α < 3 have very high standard deviations in terms of the number of connections to each node. Therefore, in the context of the equation R 0 = β ⋅ c ⋅ d , the number of contacts between infected and susceptible individuals per time unit, c , may also be extremely high.

If the human population network structure (small word, sometimes following a power-law distribution) somewhat facilitates microorganism spread, why do novel pathogens not almost instantly infect humans worldwide? In the case of scale-free networks, the α parameter mentioned above is sometimes lower than two or above three. For example, it is seen above that, in the case of sexual partners in the previous year, that α is slightly higher than three [15] [16] . With the α parameter outside that interval, the network is still a small world, but there is an epidemic transition value [27] . Moreover, real-life scale-free networks are finite (i.e., have a limited number of people), which implies that, even if the α parameter falls between two and three, there is a non-null epidemic threshold.

Moreover, humans do not become infectious immediately after contagion, which may take a few days, depending on the disease. Furthermore, people are not permanently in contact with each other, particularly if they feel ill. Additionally, people, medical doctors, and the government commonly implement measures to halt disease spread. Even so,it is seen that with, for example, the COVID-19 pandemic, and despite arduous efforts employed by the governments of several countries, two and a half months (between December 2019 and the first days of March 2020) were sufficient to spread the SARS-CoV-2 virus to most countries worldwide. Governments employed compulsory confinements and other demanding measures because COVID-19 would kill many people and cause morbidity to many others [28] .

3. Selection and weak Counter-Selection of Virulence and Resistance Genes

Proteins encoded by virulence genes—e.g., toxins and cell surface proteins that enable bacterial attachment to host tissues, among others—can help bacteria colonize hosts [29] . Therefore, newly acquired virulence genes may not affect fitness or confer immediate advantages to bacteria, while recently acquired resistance determinants often impose a fitness cost on the bacterial cell. Therefore, these gene types may have different effects on their new hosts when newly acquired. However, the claim that resistant determinants are costly is somewhat complex.

The fitness costs of drug resistance determinants may evolve towards lower values or even become zero. For example, compensatory mutations often arise and diminish or even eliminate the deleterious effects of resistance mutations [30] [31] [32] [33] [34] [35] [36] [37] [38] [39] [40] . Moreover, resistance determinants (mutations or plasmids) can decrease the fitness cost of other resistant determinants, e.g., through epistatic interactions [41] [42] [43] . Furthermore, plasmid–plasmid interactions may facilitate plasmid transfer [44] [45] [46] , sometimes compensating for plasmid costs [47] [48] .

Sometimes compensatory mutations arise in the resistance-encoding mobile genetic element, not the bacterial chromosome. In this case, when moving into another bacterial host, this genetic element carries both the resistance gene and the compensatory mutations, therefore imposing no cost on its new host [36] [49] .

A recent study involved 9275 patients during hospital stays over two years at the Ramon y Cajal University Hospital (Madrid, Spain). Alonso-del Valle et al. measured the cost of pOXA-48_K8 : a naturally isolated plasmid. This plasmid was the most successful pOXA-48 -like plasmid in an extensive collection of extended-spectrum ß-lactamase- and carbapenemase-producing enterobacteria isolated from the gut of 105 out of those 9275 patients (1.13%). The authors introduced this plasmid in 25 isolates of Klebsiella pneumoniae and 25 of Escherichia coli naïve to the pOXA-48_K8 plasmid to determine the distribution of fitness effects on the plasmid in those 50 strains. These strains were isolated from patients coinciding on the hospital ward with others colonized with bacteria harboring pOXA-48 -like plasmids [50] .

As expected, the plasmid imposed a fitness cost to bacterial cells: a mean cost of 2.9%. Although small, this effect is statistically significant. However, individual values varied considerably. Most fitness effects were null, and the authors only observed a fitness cost in 14 strains (28%). Interestingly, the plasmid conferred a fitness advantage to the host in seven strains (14%) [50] . It is crucial to note that, even if the plasmid decreases bacterial fitness in 28% of the strains, the plasmid can succeed and “amplify” in the other 58% of the strains where the plasmid is neutral or among the 14% where the plasmid confers a fitness benefit [10] [11] [51] .

Alonso-del Valle et al. measured the fitness of plasmid-bearing strains through competition assays. This method is appropriate because it mimics the real competition taking place between plasmid-bearing and plasmid-free cells in the gut microbiota. These competition assays were performed in agitated liquid media to avoid plasmid transfer into the competitor [50] .

All the accumulated knowledge about the cost of resistant determinants points in the same direction: even if plasmid-encoded resistance determinants impose a fitness cost to naïve recipient cells, soon the cost diminishes or disappears. Therefore, resistant cells may avoid being outcompeted by sensitive cells after a critical adaptation period to a resistance-encoding gene.

One must remember that human tissues and the gut are structured media with minimal or no agitation. In such environments, plasmids can transfer to neighboring naïve cells. Possibly, the plasmid imposes a fitness cost to their neighbors, leaving resources to the donor cells. Therefore, even if plasmids are costly in the donor cells, these may succeed by imposing fitness costs on adjacent competitors, acting as harmful agents [52] . This harming behavior is advantageous to donor cells for the following reasons [52] : (i) donor cells have already adapted to the plasmid presence due, for example, to compensatory mutations [40] ; (ii) the plasmid transfers to recipient cells (transconjugant cells); (iii) these cells are not adapted to the plasmid presence because they never harbored it; (iv) these non-adapted transconjugant cells replicate slower and use fewer resources than before the plasmid arrival; (v) donor cells may uptake the unused nutrients and replicate.

Furthermore, it is interesting to note that, just because they are transferable (and not due to the gain of additional genes), conjugative plasmids may have an adaptive value to their hosts, not only as harmful agents, as explained above [52] , but also as promoters of bacterial biofilms, which confer protection against antimicrobials [47] [53] [54] .

Therefore, epidemiological or evolutionary studies of antibiotic resistance must assume that resistance genes are widespread worldwide. For over eight decades, tons of antibiotics have been used and thrown into the environment [55] . The prolonged use of these drugs has promoted the clonal expansion of resistant cells and the worldwide spread of resistant clones and putative mobile genetic elements carrying resistance genes. Not surprisingly, nowadays, many metagenomes, including human and environmental ones, contain resistance genes; sometimes, this includes a diverse set of those genes as well as virulence genes [56] .

4. The Diversity of Virulence and Resistance Genes across Microbiomes

Researchers have argued above that non-housekeeping genes are somewhat free to spread within and between microbiomes (namely between people). Some people may use antibiotics, which select virulence genes that are present in resistant cells and resistance genes but counter-select other genes, including those that confer resistance to unrelated antibiotics and virulence genes encoded in bacterial cells susceptible to the used drug.

The use of antibiotics by sick people may select antibiotic-resistant pathogens, which, by definition, encode virulence genes. Perhaps this is why several studies have shown antibiotic and virulence genes co-occurrence in bacterial genomes [57] [58] [59] . In general, one could predict that the continuing use of tons of antibiotics through the decades would co-select virulence and resistance genes. However, it is also manifest that the administration of antibiotics hits several other bacteria, namely commensal and mutualistic bacteria, in the human microbiome [60] [61] [62] . Moreover, the use of antibiotics as growth promoters in livestock and agriculture or with prophylactic purposes may select resistant cells independently of whether or not they encode virulence genes [63] .

Paradoxically, however, the diversity of resistance genes correlates positively with the diversity of virulence genes across human and environmental microbiomes [56] : microbiomes with a high diversity of one class of genes tend to have a high diversity of the other class. However, Darmancier et al. studied 16,632 bacterial genomes and concluded that no such positive correlation exists at the level of genomes, neither across chromosomes nor across plasmids [64] . The results of these two studies (references [56] [64] ) are compatible if, and only if, metagenomes with a high diversity of both gene types have those genes mostly located in different genomes. Why should there be a positive correlation at the level of metagenomes but not at the genome level?

In the previous two sections, it has been argued that virulence and resistance genes have conditions to remain in metagenomes for a long time. Each person receives diverse genes of both types during this period, accumulating them in their microbiomes, although not necessarily in the same bacterial cells. Meanwhile, pathogenic bacteria circulate through the human population. Some of those ill people take an antibiotic, which selects cells resistant to it but kills susceptible cells, including those resistant to other drugs. Therefore, a consequence of taking the antibiotic is a decrease in the diversity of drug-resistance genes [65] . Moreover, virulence genes are present in dead cells, decreasing their diversity. This process implies that people who took antibiotics recently are those with the lowest diversity of both resistant and virulence cells [66] . On the other hand, those that took antibiotics a long time ago have the highest diversity of both gene types [66] . The overall result is a positive correlation between the diversities of both gene types across human microbiomes [56] [66] .

What if there is a misuse (and overuse) of antibiotics, where some people use them even if they are not infected by a bacterial pathogen (or are randomly in contact with antibiotics from environmental contamination)? The process is very similar to the one described above, and the overall result is the same: a positive correlation of both genes’ diversities. These are the predictions if the probability that a metagenome loses resistance determinants is lower than the transmission probability between people [66] . It has been seen above how unlikely it is that metagenomes lose resistance determinants, so the transmission probability between people must prevail or even the contamination of people from the environment or, for example, non-cooked vegetables [67] .

A computer model enabled the analysis and corroboration of the above predictions [66] . The model simulated the transfer of pathogenic bacteria and one hundred categories of resistance and virulence genes. Simulations ran with different network types (regular, small-world, and random), and the results were always similar (the only difference being that the simulations reached stable results much sooner in small-world and random networks than in the regular network as expected, and according to explanations given above). Control simulations included changing the number of interacting people, the number of virulence and resistance genes, the relative probabilities of losing genes and acquiring them through contacts, or even changing the initial number of people already containing virulence and resistant genes, providing similar results [66] . The main findings of these simulations were:

(i) People that have used antibiotics recently have a lower diversity of drug-resistance genes and virulence genes in their microbiome;

(ii) Antibiotic overuse decreases the diversity of antibiotic resistance and virulence genes in the human microbiome;

The discussion above predicts the co-location of resistance and virulence genes in the same microbiome, mainly in people that used antibiotics a long time ago. These simulations, however, make no predictions about the co-location of virulence and resistance genes in bacterial genomes. Indeed, one should note that the computer model did not need to postulate their co-location to explain the positive correlation between the resistance and virulence genes’ diversities in microbiomes observed over human microbiomes. However, one must ask whether the last eighty years of intensive antibiotic use have put virulence and resistance genes together. As mentioned above, there is no correlation between resistance and virulence genes’ diversities throughout genomes [64] . Nevertheless, there are indirect signs of the selection of antibiotic-resistant pathogens, given that some categories of resistance and virulence genes preferentially occur in the same genome [64] . For example, Darmancier et al. observed the co-occurrence between type VII secretion systems and fusidic acid resistance genes [64] : fusidic acid is used, e.g., to treat methicillin-resistant S. aureus infections, and is also active against tuberculosis [68] [69] .

References

  1. Anderson, R.M.; May, R.M. Infectious Diseases of Humans: Dynamics and Control; Oxford University Press: Oxford, UK; New York, NY, USA, 1992; ISBN 978-0-19-854040-3.
  2. Frank, S.A. Models of Parasite Virulence. Q. Rev. Biol. 1996, 71, 37–78.
  3. Zeng, X.; Lin, J. Factors influencing horizontal gene transfer in the intestine. Anim. Health Res. Rev. 2017, 18, 153–159.
  4. McInnes, R.S.; McCallum, G.E.; Lamberte, L.E.; van Schaik, W. Horizontal transfer of antibiotic resistance genes in the human gut microbiome. Curr. Opin. Microbiol. 2020, 53, 35–43.
  5. Brito, I.L. Examining horizontal gene transfer in microbial communities. Nat. Rev. Microbiol. 2021, 19, 442–453.
  6. Johnston, C.; Martin, B.; Fichant, G.; Polard, P.; Claverys, J.-P. Bacterial transformation: Distribution, shared mechanisms and divergent control. Nat. Rev. Microbiol. 2014, 12, 181–196.
  7. Smillie, C.; Garcillán-Barcia, M.P.; Francia, M.V.; Rocha, E.P.C.; de la Cruz, F. Mobility of Plasmids. Microbiol. Mol. Biol. Rev. 2010, 74, 434–452.
  8. Sessions, S.K. Genome Size. In Brenner’s Encyclopedia of Genetics, 2nd ed.; Maloy, S., Hughes, K., Eds.; Elsevier: London, UK, 2013; Volume 3, pp. 144–151. ISBN 978-0-08-096156-9.
  9. McGowan, J.E.; Tenover, F.C. Confronting bacterial resistance in healthcare settings: A crucial role for microbiologists. Nat. Rev. Genet. 2004, 2, 251–258.
  10. Dionisio, F.; Matic, I.; Radman, M.; Rodrigues, O.R.; Taddei, F. Plasmids Spread Very Fast in Heterogeneous Bacterial Com-munities. Genetics 2002, 162, 1525–1532.
  11. Hall, J.P.J.; Wood, A.J.; Harrison, E.; Brockhurst, M.A. Source–sink plasmid transfer dynamics maintain gene mobility in soil bacterial communities. Proc. Natl. Acad. Sci. USA 2016, 113, 8260–8265.
  12. Watts, D.J.; Strogatz, S.H. Collective dynamics of ‘small-world’ networks. Nature 1998, 393, 440–442.
  13. Combadão, J.; Campos, P.R.A.; Dionisio, F.; Gordo, I. Small-world networks decrease the speed of Muller’s ratchet. Genet. Res. 2007, 89, 7–18.
  14. Campos, P.R.A.; Combadão, J.; Dionisio, F.; Gordo, I. Muller’s ratchet in random graphs and scale-free networks. Phys. Rev. E 2006, 74, 42901.
  15. Liljeros, F.; Edling, C.R.; Amaral, L.A.N.; Stanley, H.E.; Åberg, Y. The web of human sexual contacts. Nature 2001, 411, 907–908.
  16. Liljeros, F.; Edling, C.R.; Stanley, H.E.; Åberg, Y.; Amaral, L.A.N. Sexual contacts and epidemic thresholds. Nature 2003, 423, 606.
  17. Amaral, L.A.N.; Scala, A.; Barthélémy, M.; Stanley, H.E. Classes of small-world networks. Proc. Natl. Acad. Sci. USA 2000, 97, 11149–11152.
  18. Drake, J.W. A constant rate of spontaneous mutation in DNA-based microbes. Proc. Natl. Acad. Sci. USA 1991, 88, 7160–7164.
  19. Drake, J.W. The Distribution of Rates of Spontaneous Mutation over Viruses, Prokaryotes, and Eukaryotes. Ann. N. Y. Acad. Sci. 1999, 870, 100–107.
  20. Sung, W.; Ackerman, M.S.; Miller, S.F.; Doak, T.G.; Lynch, M. Drift-barrier hypothesis and mutation-rate evolution. Proc. Natl. Acad. Sci. USA 2012, 109, 18488–18492.
  21. Şimşek, E.; Kim, M. Power-law tail in lag time distribution underlies bacterial persistence. Proc. Natl. Acad. Sci. USA 2019, 116, 17635–17640.
  22. Rebelo, J.S.; Domingues, C.P.F.; Monteiro, F.; Nogueira, T.; Dionisio, F. Bacterial persistence is essential for susceptible cell survival in indirect resistance, mainly for lower cell densities. PLoS ONE 2021, 16, e0246500.
  23. Brockmann, D.; Hufnagel, L.; Geisel, T. The scaling laws of human travel. Nature 2006, 439, 462–465.
  24. Gonzalez, M.C.; Hidalgo, C.A.; Barabasi, A.L. Understanding individual human mobility patterns. Nature 2008, 453, 779–782.
  25. Pastor-Satorras, R.; Vespignani, A. Epidemic Spreading in Scale-Free Networks. Phys. Rev. Lett. 2001, 86, 3200–3203.
  26. Boguñá, M.; Pastor-Satorras, R.; Vespignani, A. Absence of Epidemic Threshold in Scale-Free Networks with Connectivity Correlations. Phys. Rev. Lett. 2003, 90, 28701.
  27. Newman, M.E.J. Spread of epidemic disease on networks. Phys. Rev. E 2002, 66, 16128.
  28. Schlosser, F.; Maier, B.F.; Jack, O.; Hinrichs, D.; Zachariae, A.; Brockmann, D. COVID-19 lockdown induces disease-mitigating structural changes in mobility networks. Proc. Natl. Acad. Sci. USA 2020, 117, 32883–32890.
  29. Klemm, P.; Schembri, M.A. Bacterial adhesins: Function and structure. Int. J. Med. Microbiol. 2000, 290, 27–35.
  30. Modi, R.I.; Adams, J. Coevolution in bacterial-plasmid populations. Evolution 1991, 45, 656–667.
  31. Levin, B.R.; Lipsitch, M.; Perrot, V.; Schrag, S.; Antia, R.; Simonsen, L.; Walker, N.M.; Stewart, F.M. The Population Genetics of Antibiotic Resistance. Clin. Infect. Dis. 1997, 24, S9–S16.
  32. Schrag, S.J.; Perrot, V.; Levin, B.R. Adaptation to the fitness costs of antibiotic resistance in Escherichia coli. Proc. R. Soc. B Biol. Sci. 1997, 264, 1287–1291.
  33. Björkman, J.; Nagaev, I.; Berg, O.G.; Hughes, D.; Andersson, D.I. Effects of Environment on Compensatory Mutations to Ameliorate Costs of Antibiotic Resistance. Science 2000, 287, 1479–1482.
  34. Dahlberg, C.; Chao, L. Amelioration of the Cost of Conjugative Plasmid Carriage in Eschericha coli K12. Genetics 2003, 165, 1641–1649.
  35. Maisnier-Patin, S.; Andersson, D.I. Adaptation to the deleterious effects of antimicrobial drug resistance mutations by compensatory evolution. Res. Microbiol. 2004, 155, 360–369.
  36. Dionisio, F.; Conceição, I.; Marques, A.C.; Fernandes, L.; Gordo, I. The evolution of a conjugative plasmid and its ability to increase bacterial fitness. Biol. Lett. 2005, 1, 250–252.
  37. Nilsson, A.I.; Zorzet, A.; Kanth, A.; Dahlström, S.; Berg, O.G.; Andersson, D.I. Reducing the fitness cost of antibiotic resistance by amplification of initiator tRNA genes. Proc. Natl. Acad. Sci. USA 2006, 103, 6976–6981.
  38. Hall, J.P.J.; Wright, R.C.T.; Guymer, D.; Harrison, E.; Brockhurst, M.A. Extremely fast amelioration of plasmid fitness costs by multiple functionally diverse pathways. Microbiology 2020, 166, 56–62.
  39. Sørensen, M.E.S.; Wood, A.J.; Cameron, D.D.; Brockhurst, M.A. Rapid compensatory evolution can rescue low fitness symbioses following partner switching. Curr. Biol. 2021, 31, 3721–3728.e4.
  40. Brockhurst, M.A.; Harrison, E. Ecological and evolutionary solutions to the plasmid paradox. Trends Microbiol. 2022, 30, 534–543.
  41. Trindade, S.; Sousa, A.; Xavier, K.B.; Dionisio, F.; Ferreira, M.G.; Gordo, I. Positive Epistasis Drives the Acquisition of Multi-drug Resistance. PLoS Genet. 2009, 5, e1000578.
  42. Silva, R.F.; Mendonça, S.C.M.; Carvalho, L.M.; Reis, A.M.; Gordo, I.; Trindade, S.; Dionisio, F. Pervasive Sign Epistasis between Conjugative Plasmids and Drug-Resistance Chromosomal Mutations. PLoS Genet. 2011, 7, e1002181.
  43. Millan, A.S.; Heilbron, K.; MacLean, R.C. Positive epistasis between co-infecting plasmids promotes plasmid survival in bacterial populations. ISME J. 2014, 8, 601–612.
  44. Gama, J.A.; Zilhão, R.; Dionisio, F. Co-resident plasmids travel together. Plasmid 2017, 93, 24–29.
  45. Gama, J.A.; Zilhão, R.; Dionisio, F. Multiple plasmid interference—Pledging allegiance to my enemy’s enemy. Plasmid 2017, 93, 17–23.
  46. Gama, J.A.; Zilhão, R.; Dionisio, F. Conjugation efficiency depends on intra and intercellular interactions between distinct plasmids: Plasmids promote the immigration of other plasmids but repress co-colonizing plasmids. Plasmid 2017, 93, 6–16.
  47. Gama, J.A.; Fredheim, E.G.A.; Cléon, F.; Reis, A.M.; Zilhão, R.; Dionisio, F. Dominance between Plasmids Determines the Extent of Biofilm Formation. Front. Microbiol. 2020, 11, 2070.
  48. Gama, J.A.; Zilhão, R.; Dionisio, F. Plasmid Interactions Can Improve Plasmid Persistence in Bacterial Populations. Front. Microbiol. 2020, 11, 2033.
  49. Zwanzig, M.; Harrison, E.; Brockhurst, M.A.; Hall, J.P.J.; Berendonk, T.U.; Berger, U. Mobile Compensatory Mutations Promote Plasmid Survival. mSystems 2019, 4, e00186-18.
  50. Valle, A.A.-D.; León-Sampedro, R.; Rodríguez-Beltrán, J.; DelaFuente, J.; Hernández-García, M.; Ruiz-Garbajosa, P.; Cantón, R.; Peña-Miller, R.; Millán, A.S. Variability of plasmid fitness effects contributes to plasmid persistence in bacterial communities. Nat. Commun. 2021, 12, 2653.
  51. Dionisio, F.; Nogueira, T.; Carvalho, L.M.; Mendes-Soares, H.; Mendonça, S.C.; Domingues, I.; Moreira, B.; Reis, A.M. What Maintains Plasmids among Bacteria. In Horizontal Gene Transfer in Microorganisms; Caister Academic Press: Norwich, UK, 2012; pp. 131–154.
  52. Domingues, C.P.F.; Rebelo, J.S.; Monteiro, F.; Nogueira, T.; Dionisio, F. Harmful behaviour through plasmid transfer: A successful evolutionary strategy of bacteria harbouring conjugative plasmids. Philos. Trans. R. Soc. B Biol. Sci. 2022, 377, 20200473.
  53. Ghigo, J.-M. Natural conjugative plasmids induce bacterial biofilm development. Nature 2001, 412, 442–445.
  54. Reisner, A.; Höller, B.M.; Molin, S.; Zechner, E.L. Synergistic Effects in Mixed Escherichia coli Biofilms: Conjugative Plasmid Transfer Drives Biofilm Expansion. J. Bacteriol. 2006, 188, 3582–3588.
  55. Davies, J.; Davies, D. Origins and Evolution of Antibiotic Resistance. Microbiol. Mol. Biol. Rev. 2010, 74, 417–433.
  56. Escudeiro, P.; Pothier, J.; Dionisio, F.; Nogueira, T. Antibiotic Resistance Gene Diversity and Virulence Gene Diversity Are Correlated in Human Gut and Environmental Microbiomes. mSphere 2019, 4, e00135-19.
  57. Beceiro, A.; Tomás, M.; Bou, G. Antimicrobial Resistance and Virulence: A Successful or Deleterious Association in the Bacterial World? Clin. Microbiol. Rev. 2013, 26, 185–230.
  58. Deng, Y.; Xu, L.; Liu, S.; Wang, Q.; Guo, Z.; Chen, C.; Feng, J. What drives changes in the virulence and antibiotic resistance of Vibrio harveyi in the South China Sea? J. Fish Dis. 2020, 43, 853–862.
  59. Pan, Y.; Zeng, J.; Li, L.; Yang, J.; Tang, Z.; Xiong, W.; Li, Y.; Chen, S.; Zeng, Z. Coexistence of Antibiotic Resistance Genes and Virulence Factors Deciphered by Large-Scale Complete Genome Analysis. mSystems 2020, 5, e00821-19.
  60. Canteón, R. Antibiotic resistance genes from the environment: A perspective through newly identified antibiotic resistance mechanisms in the clinical setting. Clin. Microbiol. Infect. 2009, 15, 20–25.
  61. Martinez, J.L. The role of natural environments in the evolution of resistance traits in pathogenic bacteria. Proc. R. Soc. B Biol. Sci. 2009, 276, 2521–2530.
  62. Allen, H.K.; Donato, J.; Wang, H.H.; Cloud-Hansen, K.A.; Davies, J.; Handelsman, J. Call of the wild: Antibiotic resistance genes in natural environments. Nat. Rev. Microbiol. 2010, 8, 251–259.
  63. Castanon, J.I.R. History of the Use of Antibiotic as Growth Promoters in European Poultry Feeds. Poult. Sci. 2007, 86, 2466–2471.
  64. Darmancier, H.; Domingues, C.P.F.; Rebelo, J.S.; Amaro, A.; Dionísio, F.; Pothier, J.; Serra, O.; Nogueira, T. Are Virulence and Antibiotic Resistance Genes Linked? A Comprehensive Analysis of Bacterial Chromosomes and Plasmids. Antibiotics 2022, 11, 706.
  65. Cho, I.; Blaser, M.J. The human microbiome: At the interface of health and disease. Nat. Rev. Genet. 2012, 13, 260–270.
  66. Domingues, C.P.F.; Rebelo, J.S.; Pothier, J.; Monteiro, F.; Nogueira, T.; Dionisio, F. The Perfect Condition for the Rising of Superbugs: Person-to-Person Contact and Antibiotic Use Are the Key Factors Responsible for the Positive Correlation between Antibiotic Resistance Gene Diversity and Virulence Gene Diversity in Human Metagenomes. Antibiotics 2021, 10, 605.
  67. Valentino, V.; Sequino, G.; Cobo-Díaz, J.F.; Álvarez-Ordóñez, A.; De Filippis, F.; Ercolini, D. Evidence of virulence and antibiotic resistance genes from the microbiome mapping in minimally processed vegetables producing facilities. Food Res. Int. 2022, 162, 112202.
  68. Carr, W.; Kurbatova, E.; Starks, A.; Goswami, N.; Allen, L.; Winston, C. Interim Guidance: 4-Month Rifapentine-Moxifloxacin Regimen for the Treatment of Drug-Susceptible Pulmonary Tuberculosis—United States. MMWR. Morb. Mortal. Wkly. Rep. 2022, 71, 285–289.
  69. Chambers, H.F.; DeLeo, F.R. Waves of resistance: Staphylococcus aureus in the antibiotic era. Nat. Rev. Microbiol. 2009, 7, 629–641.

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