Stable propagation of ‘selfish’ genetic elements

Extrachromosomal or chromosomally integrated genetic elements are common among prokaryotic and eukaryotic cells. These elements exhibit a variety of ‘selfish’ strategies to ensure their replication and propagation during the growth of their host cells. To establish long-term persistence, they have to moderate the degree of selfishness so as not to imperil the fitness of their hosts. Earlier genetic and biochemical studies together with more recent cell biological investigations have revealed details of the partitioning mechanisms employed by low copy bacterial plasmids. At least some bacterial chromosomes also appear to rely on similar mechanisms for their own segregation. The 2 μm plasmid ofSaccharomyces cerevisiae and related yeast plasmids provide models for optimized eukaryotic selfish DNA elements. Selfish DNA elements exploit the genetic endowments of their hosts without imposing an undue metabolic burden on them. The partitioning systems of these plasmids appear to make use of a molecular trick by which the plasmids feed into the segregation pathway established for the host chromosomes.     

Homology among nearly all plasmids infecting three Bacillus species.

We have surveyed naturally occurring plasmids in strains of Bacillus subtilis and the closely related species B. mojavensis and B. licheniformis. Previous studies have failed to find host-benefitting functions for plasmids of these species, suggesting that these plasmids are nonmutualistic. Only one type of plasmid was found in each plasmid-bearing strain, suggesting that most of the plasmids infecting these Bacillus species are in the same incompatibility group. A sample of 18 plasmids from these species ranged in size from 6.9 to 16 kb, with all but 6 plasmids falling into three size groups. These groups differed in the sizes of their host ranges and geographical ranges. All but 1 of the 18 plasmids from these three host species are homologous with one another. The cryptic plasmids from these three species are far less diverse than are plasmids (from other species) that are known to benefit their bacterial hosts. The low-level diversity among these cryptic plasmids is consistent with the hypothesis that host-benefitting adaptations play an important role in fostering the coexistence of plasmid populations, but other explanations for the low-level plasmid diversity are possible. Comparison of the phylogenies of the plasmids with those of their hosts suggests that Bacillus plasmids are horizontally transferred in nature at a low rate similar to that found for the colicin plasmids of Escherichia coli.     

人α1型干扰素克隆菌的表达研究：Ⅱ.宿主细胞对质粒表达的影响

干扰素（IFN）是某些生物体细胞抗病毒感染的一类蛋白质,可用于治疗病毒性疾病和某些癌症。但由人血液获得的干扰素其量极微,目前已能通过基因工程大量生产。编码干扰素的基因已能在大肠杆菌~[1,3]、醇母~[4,5]和哺乳动物细胞表达。~[6]但仍需对工程菌的表达规律作进一步研究,特别要弄清各种因素对被克隆的外源基因表达的影响。     

Bacterial plasmid stability

Bacterial plasmids are ubiquitous ‘minichromosomes’ that have major importance in clinical microbiology, as agents of pathogenicity and as carriers of antibiotic resistance, and in molecular genetics, through their role as vectors in gene manipulation. Plasmids carry a wide range of dispensable, transiently useful and often bizarre functions.¹ Naturally occurring plasmids, in addition to modifying the host cell phenotype, carry genes involved in the control of their own vegetative replication, plasmid copy number² and stable inheritance. They may also carry determinants for the conjugal transfer of DNA between bacteria.³ Whereas low-copy-number plasmids must be partitioned by some active process during cell division, the evidence suggests that multicopy plasmids are distributed randomly between daughter cells. Two independent determinants are necessary for the stable inheritance of multicopy plasmids, and both of these appear to act by maximizing the number of independent plasmid molecules.     

Long-term episomal maintenance of bovine papillomavirus type 1 plasmids is determined by attachment to host chromosomes, which Is mediated by the viral E2 protein and its binding sites

Papillomavirus genomes are stably maintained as extrachromosomal nuclear plasmids in dividing host cells. To address the mechanisms responsible for stable maintenance of virus, we examined nuclear compartmentalization of plasmids containing the full-length upstream regulatory region (URR) from the bovine papillomavirus type 1 (BPV1) genome. We found that these plasmids are tightly associated with the nuclear chromatin both in the stable cell lines that maintain episomal copies of the plasmids and in transiently transfected cells expressing the viral E1 and E2 proteins. Further analysis of viral factors revealed that the E2 protein in trans and its multiple binding sites in cis are both necessary and sufficient for the chromatin attachment of the plasmids. On the other hand, the BPV1 URR-dependent plasmid replication and chromatin attachment processes are clearly independent of each other. The ability of the plasmids to stably maintain episomes correlates clearly with their chromatin association function. These data suggest that viral E2 protein-mediated attachment of BPV1 genomes to the host cell chromatin could provide a mechanism for the coupling of viral genome multiplication and partitioning to the host cell cycle during viral latent infection.     

Regions on the F plasmid which affect plasmid maintenance and the ability to segregate into Escherichia coli minicells

Certain derivative mini-F plasmids were found to segregate into Escherichia coli minicells, in contrast to the intact mini-F plasmid which does not. Segregation was not related to the presence or absence of the normal origin of vegetative replication, but appeared to be affected by regions of F which encode replication, incompatibility, copy number control, and partitioning functions. Segregation of mini-F plasmids into minicells was not random; the plasmid concentration in minicells did not correlate with the plasmid concentration in cells. Genes, or gene products, of F from the region spanning the sequences 44.1–49.3F appeared to affect the ability of mini-F plasmids to segregate into minicells. Segregation of mini-F plasmids into minicells was not directly related to stable plasmid inheritance. These results argue for the sequestration of mini-F plasmids in host cells.     

The evolution of a conjugative plasmid and its ability to increase bacterial fitness

Conjugative plasmids are extra-chromosomal DNA elements that are capable of horizontal transmission and are found in many natural isolated bacteria. Although plasmids may carry beneficial genes to their bacterial host, they may also cause a fitness cost. In this work, we studied the evolution of the R1 plasmid and we found that, in spite of the R1 plasmid conferring an initial cost to its host, after 420 generations the cost disappeared in all five independent evolution experiments. In fact, in two of these five experiments evolved conjugative plasmids actually conferred a fitness advantage to their hosts. Furthermore, the relative fitness of the ancestral clone bearing one of the evolved plasmids is significantly higher than both the plasmid-free ancestral cells and the evolved cells carrying the evolved plasmid. Given that the R1 plasmid may spread among different species of enterobacteria, we wondered what the effect of the evolved plasmid would be inside Salmonella enterica cells. We found that the evolved plasmid is also able to dramatically increase the relative fitness of these cells. Our results suggest that even if general usage of antibiotics is halted, conjugative plasmids that have been selected with antibiotics in previous years can still persist among bacterial populations or even invade new strains.     

Functions antagonistic to plasmid formation by lambda N- chromosomes

It was concluded in the preceding paper that lambda N- cI- genomes probably failed to form plasmids within infected Escherichia coli cells because they leakily express functions that act to destabilize the plasmid state. This prediction was investigated by examining the effect upon plasmid-forming ability of the loss of possible anti-plasmid functions. The loss of Ter function was found to allow long-term plasmid formation, although the efficiency of initial plasmid formation and the heritable stability without selection were low. The combined loss of the int, red and gam gene functions also promoted plasmid growth, although the absence of Ter lambda was necessary. In contrast, the presence of Ter80 (due to an h80 substitution) did not prevent plasmid formation when the int, red and gam genes were absent, indicating that Ter80 does not attack the closed-circular form of the lambda chromosome. The combined loss of the ter, int, red and gam gene functions facilitated fully efficient inheritance of the lambda N- cI- plasmids in the absence of selection, although the efficiency of initial plasmid formation remained low. However, cells harbouring such plasmids suffered a decline in viability, indicating that the plasmids expressed a function (or more than one) that acts to debilitate the host cells--presumably an effect that is increased with this genotype because the modified lambda N- cI- plasmids are inherently more stable. The possible involvement of the lambda S and kil functions in destabilization is discussed.     

Community-wide plasmid gene mobilization and selection

Plasmids have long been recognized as an important driver of DNA exchange and genetic innovation in prokaryotes. The success of plasmids has been attributed to their independent replication from the host''s chromosome and their frequent self-transfer. It is thought that plasmids accumulate, rearrange and distribute nonessential genes, which may provide an advantage for host proliferation under selective conditions. In order to test this hypothesis independently of biases from culture selection, we study the plasmid metagenome from microbial communities in two activated sludge systems, one of which receives mostly household and the other chemical industry wastewater. We find that plasmids from activated sludge microbial communities carry among the largest proportion of unknown gene pools so far detected in metagenomic DNA, confirming their presumed role of DNA innovators. At a system level both plasmid metagenomes were dominated by functions associated with replication and transposition, and contained a wide variety of antibiotic and heavy metal resistances. Plasmid families were very different in the two metagenomes and grouped in deep-branching new families compared with known plasmid replicons. A number of abundant plasmid replicons could be completely assembled directly from the metagenome, providing insight in plasmid composition without culturing bias. Functionally, the two metagenomes strongly differed in several ways, including a greater abundance of genes for carbohydrate metabolism in the industrial and of general defense factors in the household activated sludge plasmid metagenome. This suggests that plasmids not only contribute to the adaptation of single individual prokaryotic species, but of the prokaryotic community as a whole under local selective conditions.     

Integration of plasmid RP1 with the chromosome of Escherichia coli K-12 recA. 2 classes of Hfr strains

Integration of broad host range RP1 plasmid into the chromosome of Escherichia coli K-12 recA- cells has been studied. Using temperature-sensitive for replication plasmids pVD1 and pVD3, the derivatives of RP1, it has been shown that integration of RP1 into the bacterial chromosome results in formation of two classes of Hfr strains. Properties of these Hfrs have been examined. From the data obtained, it has been concluded that the plasmid integration and formation of one of the Hfrs classes appear to be mediated by transposon Tn1 residing on RP1. The other class of Hfr strains is formed due to a stable integration of RP1. In the course of analysis of R+ transconjugants arising at low frequency in crosses between stable Hfrs and E. coli rec+ recipients, it has been found that the significant part of them contain plasmid-chromosome hybrids (R-prim plasmids). On the basis of the latter results, a new simple method for R' plasmids selection has been proposed. Using restriction endonuclease analysis, the structure of plasmids that were excised from chromosomes of the stable Hfr strains and were comparable in their size to RP1, has been investigated. Probable mechanisms of the stable Hfr strains formation are discussed.     

Genetic analysis of the inter-relationship between plasmid replication and incompatibility

Summary The relationship between replication control and plasmid incompatibility has been investigated using a composite replicon, pPM1, which consists of the pSC101 plasmid ligated to another small multicopy plasmid, RSF1050. Since pPM1 can utilise the replication system of either of the two functionally distinct components, propagation of the composite plasmid can occur in the presence of a mutation of one of its moieties. Such mutants are detected by their inability to rescue the composite plasmid under conditions not permissive for replication of the other moiety. Mutations in incompatibility functions can be detected by the failure of the composite replicon to exclude co-existing plasmids carrying a replication system identical to the one on pPM1.The inability of the composite plasmid to replicate at 42° in a host synthesizing temperature-sensitive DNA polymerase I, which is required by the RSF1050 replication system, was used to isolate pPM1 mutants defective in replication of the pSC101 component. Mutants defective in the incompatibility functions of pSC101 were obtained by selecting derivatives that allow the stable coexistence of a second pSC101 replicon in the same cell. Analysis of these two classes of mutants indicates that plasmids selected for defective pSC101 replication ability nevertheless retain pSC101 incompatibility. In contrast, plasmid mutants that have lost incompatibility functions were found always to be defective in replication ability.     

Plasmid segregation: how to survive as an extra piece of DNA

Non-essential extra-chromosomal DNA elements such as plasmids are responsible for their own propagation in dividing host cells, and one means to ensure this is to carry a miniature active segregation system reminiscent of the mitotic spindle. Plasmids that are maintained at low numbers in prokaryotic cells have developed a range of such active partitioning systems, which are characterized by an impressive simplicity and efficiency and which are united by the use of dynamic, nucleotide-driven filaments to separate and position DNA molecules. A comparison of different plasmid segregation systems reveals (i) how unrelated filament-forming and DNA-binding proteins have been adopted and modified to create a range of simple DNA segregating complexes and (ii) how subtle changes in the few components of these DNA segregation machines has led to a remarkable diversity in the molecular mechanisms of closely related segregation systems. Here, our current understanding of plasmid segregation systems is reviewed and compared with other DNA segregation systems, and this is extended by a discussion of basic principles of plasmid segregation systems, evolutionary implications and the relationship between an autonomous DNA element and its host cell.     

Frequent conjugative transfer accelerates adaptation of a broad-host-range plasmid to an unfavorable Pseudomonas putida host

IncP-1 plasmids are known to be promiscuous, but it is not understood if they are equally well adapted to various species within their host range. Moreover, little is known about their fate in bacterial communities. We determined if the IncP-1beta plasmid pB10 was unstable in some Proteobacteria, and whether plasmid stability was enhanced after long-term carriage in a single host and when regularly switched between isogenic hosts. Plasmid pB10 was found to be very unstable in Pseudomonas putida H2, and conferred a high cost (c. 20% decrease in fitness relative to the plasmid-free host). H2(pB10) was then evolved under conditions that selected for plasmid maintenance, with or without regular plasmid transfer (host-switching). When tested in the ancestral host, the evolved plasmids were more stable and their cost was significantly reduced (9% and 16% for plasmids from host-switched and nonswitched lineages, respectively). Our findings suggest that IncP-1 plasmids can rapidly adapt to an unfavorable host by improving their overall stability, and that regular conjugative transfer accelerates this process.     

T-DNA fragments of hairy root plasmid pRi8196 are distantly related to octopine and nopaline Ti plasmid T-DNA

Agrobacterium Ti (tumor-inducing) and Ri (root-inducing) plasmids transform dicot plant cells by insertion of a specific plasmid sector called T-DNA (transferred DNA) into host plant nuclear DNA. The mannopine-type Ri plasmid pRi8196 contains four BamHI fragments that encompass core T-DNA. We report Southern hybridization studies that show that these four fragments have no strong homology to octopine-, nopaline-, or agropine-type Ti plasmids. We detected and mapped very weak homology regions, most of which are assignable to opine synthase or opine catabolic functions on the Ti plasmid. We found no homology between Ri T-DNA and the region of Ti T-DNA that encodes tumor morphology functions.     

New R-plasmids in strains of Serratia marcescens with multiple drug resistance

In 4 S. marcescens polyresistant strains isolated from patients conjugative plasmids transferred to Escherichia coli have been detected. Two of these strains carry each one plasmid which codes resistance to 10 different antibiotics, including aminoglycosides which rarely occur in our country, and belongs to group IncC. The third strain is the host of 2 plasmids. One of them is similar to the above-mentioned 2 plasmids with respect to the incompatibility group and a set of markers, but additionally codes resistance to cephalosporins; the second plasmid has been determined as belonging to group IncM, unstable and capable of rendering the cells highly resistant only to aminoglycosides. And, finally, the fourth strain also carries 2 plasmids: one of them is unstable and belongs, supposedly, to group IncI alpha, and the second plasmid is stable and belongs to group IncM. The plasmid of group IncI alpha differs from all other plasmids of our Serratia by its capacity of rendering the cells highly resistant to chloramphenicol.     

Essential gene acquisition destabilizes plasmid inheritance

Extra-chromosomal genetic elements are important drivers of evolutionary transformations and ecological adaptations in prokaryotes with their evolutionary success often depending on their ‘utility’ to the host. Examples are plasmids encoding antibiotic resistance genes, which are known to proliferate in the presence of antibiotics. Plasmids carrying an essential host function are recognized as permanent residents in their host. Essential plasmids have been reported in several taxa where they often encode essential metabolic functions; nonetheless, their evolution remains poorly understood. Here we show that essential genes are rarely encoded on plasmids; evolving essential plasmids in Escherichia coli we further find that acquisition of an essential chromosomal gene by a plasmid can lead to plasmid extinction. A comparative genomics analysis of Escherichia isolates reveals few plasmid-encoded essential genes, yet these are often integrated into plasmid-related functions; an example is the GroEL/GroES chaperonin. Experimental evolution of a chaperonin-encoding plasmid shows that the acquisition of an essential gene reduces plasmid fitness regardless of the stability of plasmid inheritance. Our results suggest that essential plasmid emergence leads to a dose effect caused by gene redundancy. The detrimental effect of essential gene acquisition on plasmid inheritance constitutes a barrier for plasmid-mediated lateral gene transfer and supplies a mechanistic understanding for the rarity of essential genes in extra-chromosomal genetic elements.     

Maintenance of the bacteriocinogenic plasmid Clo DF13 in Escherichia coli cells. II. Specific recombination functions involved in plasmid maintenance

Summary Clo DF13 plasmids that are present at high copy-number in bacterial cells, such as Clo DF13 cop1 Ts, cop2 and cop3 are not stably inherited in the progeny, when certain plasmid DNA regions have been deleted. We have localized two Clo DF13 DNA regions involved in stable maintenance through accurate partitioning (par) namely parA, located between 71% and 72% and parB, located between 45% and 50% on the Clo DF13 genome. The instability of these cop plasmids which is accompanied by the formation of high amounts of multimeric DNA molecules, could be abolished by the insertion of transposon Tn901 into the plasmid genome. In particular that part of Tn901, that encodes for the site-specific recombination/ resolution system, appeared to be essential for stabilizing plasmid molecules. Wild-type parA^- and/or parB^- Clo DF13 plasmids, in contrast to cop mutants lacking these regions, are stably maintained during subsequent cell division, indicating that other (host specified) functions contribute to plasmid stability. Analysis of the role of host recombination systems in plasmid partitioning revealed that the recA function has no influence and recBC contributes only weakly to plasmid stability. With respect to the recE pathway, however, we found that in a recE proficient host all plasmids, even those lacking parA and/or parB, are stably maintained, indicating that the function of parA and parB can be replaced not only by the site-specific resolution functions of transposon Tn901, but also by the recE system. The possible role of plasmid specified and host specified functions in plasmid partitioning will be discussed.     

Coexistence of incompatible plasmids in a bacterial population living under a feast and famine regime

A model is formulated to examine the possibility of (co)existence of plasmids of the same incompatibility and surface exclusion group in a bacterial population living under a feast-and-famine regime. The condition is given under which a growth rate decreasing plasmid can invade a bacterial population. It appears that in case only one plasmid type is present, the frequency of plasmid bearers will tend to a stable equilibrium if the food supply at each growth site gets exhausted and if both plasmid-free and plasmid-bearing bacteria need an equal quantity of food per cell division. If these two conditions are not satisfied, the frequency of plasmid-bearers might oscillate. Two plasmids will sometimes be able to coexist, but only if they follow different survival strategies; one with a high conjugational transfer rate and a lower fitness of its host, and the other with a low transfer rate and a higher host fitness. Coexistence of three plasmids of the same surface exclusion group is impossible.     

High frequency excision of Ty elements during transformation of yeast.

Yeast (Saccharomyces cerevisiae) transposons (Ty elements) are excised from up to 20% of supercoiled plasmids during transformation of yeast cells. The excision occurs by homologous recombination across the direct terminal repeats (deltas) of the Ty element, leaving behind a single delta in the transforming plasmid. Only the initial transforming plasmid is susceptible to excision, and no high frequency excision is observed in plasmids that have become established in transformed cells or in plasmids that are resident in cells undergoing transformation. High frequency excision from plasmids during yeast transformation is not specific for Ty elements and can be observed with other segments of plasmid DNA bounded by direct repeats. The frequency of Ty excision from supercoiled plasmids is greatly reduced when the host yeast cells contain the rad52 mutation, a defect in double-strand DNA repair. When linear or ligated-linear plasmid DNAs containing a Ty element are used for transformation, few or no excision plasmids are found among the transformant colonies. These results suggest that when a yeast cell is transformed with a supercoiled plasmid, the plasmid DNA is highly susceptible to homologous recombination for a short period of time.     

Expansion of the IncX plasmid family for improved identification and typing of novel plasmids in drug-resistant Enterobacteriaceae

IncX plasmids are narrow host range plasmids of Enterobactericeae that have been isolated for over 50years. They are known to encode type IV fimbriae enabling their own conjugative transfer, and to provide accessory functions to their host bacteria such as resistance towards antimicrobial agents and biofilm formation. Previous plasmid-based replicon typing procedures have indicated that the prevalence of IncX plasmids is low among members of the Enterobacteriaceae. However, examination of a number of IncX-like plasmid sequences and their occurrence in various organisms suggests that IncX plasmid diversity and prevalence is underappreciated. To address these possible shortcomings, we generated additional plasmid sequences of IncX plasmids of interest and compared them to the genomes of all sequenced IncX-like plasmids. These comparisons revealed that IncX plasmids possess a highly syntenic plasmid backbone, but that they are quite divergent with respect to nucleotide and amino acid similarity. Based on phylogenetic comparisons of the sequenced IncX plasmids, the IncX plasmid group has been expanded to include at least four subtypes, IncX1-IncX4. A revised IncX plasmid replicon typing procedure, based upon these sequences and subtypes, was then developed. Use of this revised typing procedure revealed that IncX plasmid occurrence among bacterial populations is much more common than had previously been acknowledged. Thus, this revised procedure can be used to better discern the occurrence of IncX type plasmids among enterobacterial populations.