Isolation of Broad-Host-Range Replicons from Marine Sediment Bacteria

Naturally occurring plasmids isolated from heterotrophic bacterial isolates originating from coastal California marine sediments were characterized by analyzing their incompatibility and replication properties. Previously, we reported on the lack of DNA homology between plasmids from the culturable bacterial population of marine sediments and the replicon probes specific for a number of well-characterized incompatibility and replication groups (P. A. Sobecky, T. J. Mincer, M. C. Chang, and D. R. Helinski, Appl. Environ. Microbiol. 63:888–895, 1997). In the present study we isolated 1.8- to 2.3-kb fragments that contain functional replication origins from one relatively large (30-kb) and three small (<10-kb) naturally occurring plasmids present in different marine isolates. 16S rRNA sequence analyses indicated that the four plasmid-bearing marine isolates belonged to the α and γ subclasses of the class Proteobacteria. Three of the marine sediment isolates are related to the γ-3 subclass organisms Vibrio splendidus and Vibrio fischeri, while the fourth isolate may be related to Roseobacter litoralis. Sequence analysis of the plasmid replication regions revealed the presence of features common to replication origins of well-characterized plasmids from clinical bacterial isolates, suggesting that there may be similar mechanisms for plasmid replication initiation in the indigenous plasmids of gram-negative marine sediment bacteria. In addition to replication in Escherichia coli DH5α and C2110, the host ranges of the plasmid replicons, designated repSD41, repSD121, repSD164, and repSD172, extended to marine species belonging to the genera Achromobacter, Pseudomonas, Serratia, and Vibrio. While sequence analysis of repSD41 and repSD121 revealed considerable stretches of homology between the two fragments, these regions do not display incompatibility properties against each other. The replication origin repSD41 was detected in 5% of the culturable plasmid-bearing marine sediment bacterial isolates, whereas the replication origins repSD164 and repSD172 were not detected in any plasmid-bearing bacteria other than the parental isolates. Microbial community DNA extracted from samples collected in November 1995 and June 1997 and amplified by PCR yielded positive signals when they were hybridized with probes specific for repSD41 and repSD172 replication sequences. In contrast, replication sequences specific for repSD164 were not detected in the DNA extracted from marine sediment microbial communities.  The maintenance and horizontal transfer of extrachromosomal elements provide one mechanism by which microbial communities can rapidly adapt to changes in environmental conditions. This adaptation can be in the form of plasmid rearrangements and duplications (18, 40), a change in the plasmid copy number (40, 54), or lateral or horizontal movement of plasmids within bacterial populations. An example demonstrating the importance of plasmid-mediated genetic adaptation in natural microbial communities, likely caused by lateral transfer, is the increased frequencies (2- to 10-fold) of catabolic plasmids reported in bacterial isolates obtained from polluted marine and freshwater environments compared to isolates from nonpolluted or less impacted ecosystems (8, 23, 43). Plasmids also play a major role in promoting the widespread distribution of antibiotic resistance genes attributed to the intense and increased use of antibiotics (42).The ability of plasmids to self-transfer or to be mobilized by transfer-proficient plasmids and the ability to replicate in different bacterial hosts are key factors in the spread of plasmid-encoded genes within microbial communities. Plasmids which are considered to have broad host ranges in nature have the potential to significantly affect the microbial community structure and function due to their ability to replicate and be maintained in members of distantly related genera. Thus, to better understand gene flux in natural systems and hence the potential role of plasmids in promoting horizontal transfer within microbial communities, knowledge of the distribution, diversity, and host ranges of naturally occurring plasmids is necessary.At present, most indigenous plasmids from marine and freshwater systems have been only partially characterized with respect to host range, replication mechanisms, incompatibility groups, and conjugal abilities. Plasmids containing similar or related replication systems are considered incompatible if they cannot coexist in a host cell (12, 41). This trait has facilitated the grouping of plasmids from gram-negative bacteria, mainly members of the family Enterobacteriaceae, into more than 30 different incompatibility groups (3). While molecularly based plasmid classification or replicon typing by using DNA sequences of replication origins and incompatibility loci of well-characterized plasmids has been useful in classifying plasmids from bacterial isolates of medical importance (9, 10, 14), plasmids from various marine microbial communities, including sediments, biofilms, bulk water, and the marine air-water interface, have been recently shown to contain incompatibility and replication regions unrelated to those currently defined (11, 53).The present study was undertaken to characterize, at the molecular level, the replication and incompatibility loci of naturally occurring plasmids isolated from gram-negative marine heterotrophs for use as replicon probes to classify and type, at the molecular level, plasmids present in bacterial populations of marine sediments. Replication origins were obtained from plasmids ranging in size from 6 to 30 kb isolated from culturable bacteria of coastal California marine sediments (53). Phylogenetic analysis indicated that the plasmids were initially isolated from bacteria belonging to the α and γ-3 subclasses of the class Proteobacteria. Although a sequence and hybridization analysis of the replication origins from the marine plasmids confirmed the lack of homology with previously described plasmids, the replication regions contained features commonly found in previously characterized plasmid replication origins. The replication origins of the naturally occurring plasmids appear to have a broad host range, as indicated by their ability to replicate in members of diverse gram-negative marine genera. In addition to molecular characterization of the indigenous plasmids, the persistence of the replicons in marine sediment bacterial populations was determined by PCR amplification of microbial community DNA extracted on different dates and examined for the presence of homologous plasmid replication sequences.