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Figures
Figure 1
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Figure 1. Overview of the differential digestion and TOPO cloning procedure...



Tables
Table 1
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Table 1. Best-hit BLAST homologues of sequences from the Swa I and Bsa AI libraries...



Table 2
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Table 2. Expectation of average fragment lengths generated by restriction enzymes in random sequences...




Extracting single genomes from heterogenous DNA samples: A test case with Carsonella ruddii, the bacterial symbiont of psyllids (Insecta)

Colin Dale1, Helen Dunbar2, Nancy A. Moran2, and Howard Ochman1

1Department of Biochemistry and Molecular Biophysics, University of Arizona, Tucson, Arizona 85721, USA
2Department of Ecology and Evolutionary Biology, University of Arizona, Tucson, Arizona 85721, USA
nmoran@email.arizona.edu

Received 9 June 2004
Accepted 18 September 2004
Published 16 March 2005

Cite this paper as:
Dale C, Dunbar H, Moran N, Ochman H. 2005. Extracting single genomes from heterogenous DNA samples: A test case with Carsonella ruddii, the bacterial symbiont of psyllids (Insecta). 6pp. Journal of Insect Science, 5:3, Available online: insectscience.org/5.3
Keywords
bacterial genome, base composition, endosymbiont, Homoptera, Pachypsylla venusta, shotgun cloning

ABSTRACT

Introduction
Materials and Methods
Results
Discussion
Acknowledgements
References
Analysis of many bacterial genomes is impeded by the inability to separate individual species from complex mixtures of cells or to propagate cells in pure culture. This problem is an obstacle to the study of many bacterial symbionts that live intracellularly in insects and other animals. To recover bacterial DNA from complex samples, we devised a method that facilitates the cloning of DNA fragments of distinctive G+C contents in order to generate shotgun DNA libraries enriched in inserts having a specific base composition. DNA preparations are first treated with a restriction enzyme having a common cleavage site in a particular genome and then shotgun cloned following size-fractionation. This method was applied to whole bacteriomes of the psyllid, Pachypsylla venusta, which harbors the bacterial symbiont Candidatus Carsonella ruddii. The resulting libraries were highly enriched in bacterial sequences. Through the use of alternate enzymes and partial digests, this technique can be adapted to yield virtually pure DNA libraries for individual bacterial species.

INTRODUCTION

Abstract
Materials and Methods
Results
Discussion
Acknowledgements
References

Due to their small size and low genetic complexity, bacterial genomes are highly amenable to complete sequence determination. But because relatively large (i.e., microgram) quantities of purified DNA are needed for most shotgun cloning procedures, bacterial genome sequencing projects have focused primarily on organisms that have been propagated in pure culture. The problem of obtaining purified DNA presents an obstacle for the vast numbers of bacterial species that have not yet been cultured in vitro, such as those that live in structured communities with other microorganisms or as obligate symbionts residing exclusively in the tissues of animal and plant hosts. There is a recognized need to develop culture-independent approaches that will permit access to the genomes of bacteria that are environmentally or medically important (DeLong and Pace 2001; Cummings and Relman 2002).

One method of obtaining information about individual genomes from complex assemblages of organisms is by cloning heterogeneous DNA samples into large insert BAC libraries (Beja et al. 2000). This method was first used to recover DNA from a mixed microbial population collected at a depth of 200 meters in the Pacific Ocean (Stein et al. 1996). In that study, BAC clones containing microbial DNA were identified by the presence of archetypal ribosomal DNA sequences, and an entire BAC insert, in this case derived from an uncultivated planktonic archaeon, was sequenced.

Bacteria that live symbiotically within the cells or tissues of another organism present additional problems for genome analysis. Because the amount of symbiont DNA present in whole organism preparations is usually rather low in comparison with the amount of host DNA, bacteria must be physically separated from host tissues and other cellular components to facilitate DNA isolation for genome studies. Such enrichment has been achieved previously by buoyant density gradient centrifugation (Sasaki and Ishikawa 1995) and by dissecting out symbiont-laden organs (called "bacteriomes") and tissues prior to DNA purification. However, even when these procedures are applied, there is often a considerable amount of host DNA contamination in the resulting samples. For example, during the recent complete genome sequencing of the insect-associated endosymbionts, Buchnera aphidicola (Tamas et al. 2002) and Wigglesworthia glossinidia (Akman et al. 2002), the majority of shotgun clones contained host DNA, even though bacterial cells were extensively purified prior to DNA extraction.

In this study, we devised a method for recovering essentially pure DNA samples from host-contaminated preparations by taking advantage of the fact that symbiotic bacteria, aside from having very reduced genomes sizes, have among the lowest genomic G+C contents of any organisms (Moran 2002). Our procedure employs a strategy that facilitates enriched cloning of DNA fragments of distinctive base composition. The utility of this method is demonstrated by the selective cloning of host and symbiont DNA from whole bacteriomes of the psyllid, Pachypsylla venusta, which harbor the symbiont Candidatus Carsonella ruddii (Clark et al. 2001). Using the methods described in this study, we constructed a shotgun library composed entirely of Candidatus C. ruddii DNA sequences.

MATERIALS AND METHODS

Abstract
Introduction
Results
Discussion
Acknowledgements
References


Insect collection and bacteriome DNA preparation

P. venusta was chosen as the focus for this study because only a single endosymbiont, Candidatus C. ruddii, has been identified in this species (Clark et al. 2001). Galls containing 4th instar P. venusta were collected during October from hackberry trees in Tucson, Arizona. Insects were removed from galls and dissected in bacteriological saline (0.85% w/v NaCl). Candidatus C. ruddii lives within the cytoplasm of host cells that are packaged into a single orange-colored bacteriome within each larval insect (Thao et al. 2000). The entire bacteriome was removed from each insect and rinsed three times in bacteriological saline. DNA was prepared from approximately 100 bacteriomes using the DNeasy tissue kit (Qiagen Inc., www.qiagen.com).

Restriction enzyme digestion

To produce enriched shotgun DNA libraries, we selected restriction enzymes generating blunt ends that were most likely to cut host and symbiont DNA at substantially different frequencies, while producing fragments of a suitable size for TOPO cloning (Figure 1). The choice of restriction enzymes was based on estimates of the genomic base composition using previously published sequences for Candidatus C. ruddii (19.9% G+C; Clark et al. 2001) and its psyllid host (37.5% G+C from the limited sequence available; Thao et al. 2000). On average, the SwaI recognition site (ATTTˆAAAT) is predicted to occur once every 1.5-kbp in the genome of Candidatus C. ruddii and once every 11-kbp in the genome of the psyllid host, based on the assumption that the genomic composition is homogeneous in each genome and that the available sequence is representative. This assumption is less reliable for the host genome because bacterial genomes are relatively homogeneous in composition (Sueoka 1962). The BsaAI recognition site (YACˆGTR) is predicted to occur once every 2.5-kbp in the Candidatus C. ruddii genome and once every 1.1-kbp in the psyllid genome, based on these same assumptions.

P. venusta-bacteriome DNA was digested in separate reactions with SwaI (ATTTˆAAAT) and BsaAI (YACˆGTR). For digestion with SwaI, 4 µg of DNA was digested with 4 units of restriction enzyme in a 100 µl reaction volume at 25 °C for 30 min. For digestion with BsaAI, 4 µg of DNA was digested with 25 units of restriction enzyme in a 100 µl reaction at 25 °C for 30 min. After electrophoresis through 1% agarose gels, the 0.5–1.5-kbp fraction of SwaI- and BsaAI-digested DNA were excised from the gel and recovered with Quik-Pik electroelution capsules (Stratagene, www.stratagene.com).

Topoisomerase-mediated cloning

Restriction enzyme-digested DNA was purified by phenol extraction and concentrated by ethanol precipitation. Prior to cloning, DNA was dephosphorylated with shrimp alkaline phosphatase (Promega, www.promega.com) according to the enzyme manufacturer's recommendations. After heat inactivating the phosphatase at 65 °C for 15 min, cloning was performed with the Zero-Blunt TOPO PCR Cloning Kit (Invitrogen, www.intergenco.com), using 200 ng of dephosphorylated insert DNA, according to the manufacturer's instructions. TOPO cloning reactions were transformed into electrocompetent TOP10 cells (Invitrogen) to achieve a high yield of recombinant clones.

DNA sequencing and data analysis

Plasmid DNA inserts from the TOPO cloning reactions were sequenced at the University of Arizona sequencing facility, using M13 forward and reverse primers. To determine the relative abundance of symbiont and host DNA in the P. venusta bacteriome DNA preparation, we sequenced 33 clones from the DNA library generated from BsaAI-digested DNA, and 46 clones from the library generated from SwaI-digested DNA. To identify putative homologs, we applied tBLASTx, in which nucleotide sequences are translated into all six putative reading frames and subjected to BLAST search (Altschul et al. 1990) against a similarly translated database. Because Candidatus C. ruddii has such an extreme G+C content, resulting in the substantial enrichment of peptide sequences with amino acids corresponding to low G+C codons, tBLASTx searches tend to return matches from other low G+C genomes, regardless of actual homology or evolutionary relationship. Because our aim was to determine whether a given clone was sampled from the symbiont versus host genome, it was appropriate to use a database most suited to discriminate between these two choices and not a much larger database that would be likely to yield many random alignments. To facilitate the recovery of true homologs (as opposed to chance matches to sequences from similarly low G+C genomes or portions of genomes), BLAST searches were limited to the complete eubacterial and insect nucleotide sequence databases as defined within the nonredundant public databases at NCBI (www.ncbi.nlm.nih.gov:80/entrez) under the taxonomic categories (Insecta = txid50557 and Bacteria = txid2). We used a probability cutoff value of less than e-2 for recognition as a significant match. (The e-value is an approximate measure of the likelihood of a alignment of this degree of similarity or higher given a sequence database of a certain size; the chosen value corresponds to approximately a 1% chance or less.) In cases where sequences matched a structural or transfer RNA, overall levels of similarity and significance are based on nucleotide sequences.

RESULTS

Abstract
Introduction
Materials and Methods
Discussion
Acknowledgements
References


To test the efficacy of our method in recovering symbiont-specific DNA, we used BLAST to identify the source (i.e., bacterial symbiont or insect host) of each sequenced insert from the size-fractionated SwaI and BsaAI libraries of P. venusta bacteriome DNA (Table 1). Of the 46 clones sequenced from the SwaI library, 27 contained inserts that shared significant sequence similarity with bacterial sequences, and none had significant hits with insect sequences in the available database. Of the 33 clones sequenced from the BsaAI library, eight had significant matches with bacterial sequences and two with insect sequences.

Because the current insect database is not as robust as that for bacteria, and because few sequences for insects closely related to the psyllid host of Candidatus C. ruddii have been deposited, we lowered the stringency in our BLAST searches to uncover any additional matches to sequences from our libraries. For the SwaI libraries, there were two additional matches, both to bacterial symbiont sequences; and among the sequenced BsaAI inserts, there were five additional matches to insect sequences, using the less stringent cutoff of e-1. Still, over half of the sequences generated from our BsaAI libraries had no significant matches in the databases and likely represent highly diverged insect sequences.

The base composition of inserts differed markedly between the SwaI and BsaAI libraries reflecting, in part, the differential representation of host and symbiont sequences in the two libraries. In the SwaI library, the base composition of sequenced inserts ranged from 1 to 25% G+C (mean = 13.7% G+C) and from 11 to 25% G+C for those with significant matches to sequences in the databases. In contrast, the base composition of sequenced inserts from the BsaAI library ranged from 16 to 41% G+C (mean = 31.1% G+C), with sequences originating from the symbiont and the insect host both displaying high and low G+C contents. In the BsaAI library, there is not complete discrimination of insect host and bacterial symbiont clones based on base composition: in fact, the sequenced BsaAI insert having the highest G+C contents (39%) corresponded to a portion of the 23S rRNA gene of Candidatus C. ruddii. Based on full genome sequences of other low G+C bacteria, the rRNA operon is likely to be the region with the highest G+C content in this organism.

Based on BLAST similarity searches, most sequences are of bacterial origin in both the SwaI and BsaAI libraries. Still, over half of the sequenced inserts (19/46 from the BsaAI library and 25/33 from the SwaI library) displayed no significant match to bacterial or insect genes. Due to the low G+C content of the genome of Candidatus C. ruddii, many of the genes recovered were found to be most similar to the few sequences of this organism or of other low G+C symbionts (e.g., Buchnera spp.) already deposited in Genbank, as opposed to their true homologs in other bacterial genomes. Several of the sequenced inserts from both the BsaAI and SwaI libraries showed a significant hit to the same sequence in the queried databases (Table 1). In some of these cases (e.g., for SwaI clones 8, 9, 23, 24, 25, 26, 27), the identical restriction fragment was cloned and sequenced, whereas others accommodate different inserts harboring genes with small, distinct regions of similarity to one portion of a reference sequence. The BsaAI sequences with no matches are likely to represent sequences from the insect nucleus, based on their relatively high G+C content and on the likelihood of a very low G+C content in the entire symbiont genome apart from the structural RNA genes.

DISCUSSION

Abstract
Introduction
Materials and Methods
Results
Acknowledgements
References


We describe an approach that takes advantage of genome-wide differences in base composition to generate enriched shotgun libraries from samples that contain mixed populations of DNA. Such libraries can facilitate the recovery of genome sequences from organisms that have not been isolated or propagated in pure culture, and is especially useful for host-associated bacteria, whose small genomes have been shown to have extreme bias in base composition (Akman et al. 2002; Andersson et al. 1998; Fraser et al. 1995; Fraser et al. 1997; Moran and Wernegreen 2000; Shigenobu et al. 2000). Moreover, the technique is very efficient and requires very little starting material: the described methodology was performed with a total of less than four micrograms of DNA.

By selecting restriction enzymes that cleave with very different frequencies in the source genomes and by cloning restriction fragments of a specific size class, we generated shotgun DNA libraries enriched for inserts that have a very restricted base composition. Our goal was to construct a shotgun library enriched with DNA from the low G+C bacterial symbiont, Candidatus C. ruddii, which lives within a specialized organelle, the bacteriome, in the hackberry psyllid, P. venusta. The DNA extracted from P. venusta bacteriomes was initially digested with BsaAI, and most of the clones (25/33) gave no significant hits to the databases, as expected if most clones in this library are host insert sequences. It is notable that of the few hits to Candidatus C. ruddii, several are to rRNA genes, which are always the regions of highest GC content in AT-biased bacterial genomes. In contrast, the library derived from the SwaI digestion of bacteriome DNA contained only inserts that have an extremely low G+C content which is typical of Candidatus C. ruddii. Of these, a majority (27/46) showed significant similarity to bacterial sequences in the database. Only a few of these are hits to Candidatus C. ruddii, as expected since very little sequence has previously been determined from this symbiont genome (Thao et al. 2000; Clark et al. 2001).

The most important factor in this procedure is the choice of restriction enzyme(s) prior to cloning, and this depends on the base composition of target and contaminating DNAs. To facilitate efficient cloning using the TOPO vector, restriction enzymes need to generate target DNA fragments in the range of 0.5 to 4 kbp. This size range is optimal for cloning in the TOPO vector and presents an optimum size for sequencing. Given the base composition of target and contaminating DNAs, suitable restriction enzymes can be identified by estimating the probability of site frequency, under the assumption of random occurrence of bases around the genome (Table 2). Because bacterial genomes are relatively homogeneous in base composition compared to eukaryotic genomes, the values in Table 2 give a relatively accurate representation of fragment sizes from each enzyme. In circumstances where insufficient blunt-cutting restriction enzymes are available, it is also possible to use enzymes that generate an overhang by applying a polymerase fill-in step prior to cloning. Note that the use of enzymes having degenerate site specificities, such as BsaAI, serves as a control in the procedure because their cutting frequencies vary little with the base composition of the target DNA.

Although highly enriched for bacterial symbiont sequences, the resulting libraries are not expected to encompass the entire Candidatus C. ruddii genome. Even given a very small genome size as in other insect symbionts (Akman et al. 2002; Moran et al. 2003; Tamas et al. 2002; van Ham et al. 2003), one would not expect to sample an identical clone insert multiple times in a survey of only 80 clones in random shotgun libraries. The repeated recovery of the same clone, particularly from the SwaI library, could be due to the instability of the low G+C DNA of Candidatus C. ruddii. In a previous study it was noted that certain lambda-ZAP clones carrying Candidatus C. ruddii DNA were unstable when transformed into E. coli (Clark et al. 2001). If such instabilities are manifested in low copy number phage vectors such as lambda-ZAP, we would expect this problem to be exacerbated in high copy number plasmid vectors such as the pTOPO Zero Blunt vector. The representation bias in the Candidatus C. ruddii library could also be due to the fact that the size-fractionated DNA used to construct this library contained mostly products of complete enzyme digestion. For more complete coverage and to facilitate whole genome sequencing, additional libraries would need to comprise products of partial digestions and/or additional restriction enzymes with different site specificities.

Because bacterial genomes have relatively homogenous base compositions (Sueoka 1962), there is expected to be relatively little intrinsic bias in restriction site frequency throughout individual genomes. Exceptions might include regions introduced through lateral transfer (termed 'islands') and regions encoding structural RNAs, which often have base compositions that differ from the genome as a whole (Galtier and Lobry 1997; Wang and Hickey 2002).

Beyond the examination of low G+C genomes of endosymbionts, the approach described in this study can be used for enrichment in any situation imposing the need to recover and clone individual DNA species from mixed populations that have differences in base composition bias.

ACKNOWLEDGEMENTS

Abstract
Introduction
Materials and Methods
Results
Discussion
References

This research was supported by NSF grant 9981432 to H.O. and NSF grant 9978518 to N.A.M.

REFERENCES

Abstract
Introduction
Materials and Methods
Results
Discussion
Acknowledgements


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