Journal of Bacteriology, September 2003, p . 5320-5323, Vol . 185, No . 17

Integration Site for Streptomyces Phage BT1 and Development of Site-Specific Integrating Vectors

Matthew A . Gregory, Rob Till, and Margaret C . M . Smith^*

Institute of Genetics, University of Nottingham, Queens Medical Centre, Nottingham NG7 2UH, United Kingdom

Received 3 March 2003/ Accepted 15 June 2003

The organization of the BT1 genome is highly similar to that of C31, and the majority of gene products are closely related (9) . There is evidence, however, of mosaicism between the two genomes where DNA has been inserted and/or deleted in one genome but not in the other, and there are sudden transitions in the level of sequence similarity (9) . One of the most noticeable differences is the relatively poor sequence similarity of int and the three genes upstream, genes 26 to 28 . BT1 integrase and gp26 to gp28 exhibit 26% and 10 to 18% identity to their C31 homologues, respectively . Despite this poor similarity, BT1 integrase is clearly a member of the large serine recombinase family, as it contains conserved motifs present in other members of this group (12) . Furthermore, no significant similarity could be detected between the C31 attP site and any BT1 sequence . These observations strongly suggest that BT1 encodes a site-specific recombination system that has a different specificity from that in C31 and therefore integrates into a different attB site in the S . coelicolor genome . Southern blots of DNA from an S . coelicolor J1929 BT1 lysogen (strain J1929 contains pglY conferring sensitivity to C31 and BT1 [3]) probed with DNA encoding the C31 attB site indicated that C31 attB was intact, suggesting that BT1 was integrated elsewhere in the genome (data not shown) . To test this further and to identify the BT1 attB site, we performed vectorette PCR (Sigma-Genosys) extending outwards from the BT1 DNA into the host DNA in an S . coelicolor BT1 lysogen . This procedure is designed to isolate unknown flanking sequences from a known integrated sequence (1) . One product was obtained using S . coelicolor J1929 BT1 DNA digested with BclI as the original template . The DNA sequence of this product read outwards from the BT1 genome into a segment of the S . coelicolor genome sequence and finally into the vectorette linker sequence . The S . coelicolor genome sequence matched part of cosmid SC5G8 (4) . To confirm the site of BT1 integration, primers were designed against this region of SC5G8 and used to amplify attB from S . coelicolor J1929 DNA and attL and attR from J1929 BT1 lysogen DNA . The attB sequence was most similar to the genomic sequence coordinates 5279863 to 5280017 (contained within SC5G8), and the attL and attR sequences indicated that the recombination had occurred between 9 bp of identical sequence between S . coelicolor coordinates 5279923 to 5279915 and BT1 (Fig . 1) . We confirmed that this locus is the major integration site by Southern blotting of genomic DNA isolated from S . coelicolor J1929 containing integration vector pMS81 or pMS82 described below; no bands other than those predicted as a consequence of integration via the attB site were observed (data not shown) .

 
An alignment of the BT1 attB site and the phage attP site indicated that, like the C31 recombination system, the attB and attP sequences are quite different . The BT1 attP site contains an imperfect inverted repeat centered around the dinucleotide 5'GT within the 9-bp core sequence (Fig . 1) . In other phages or prophages encoding serine integrases, the attP sites also contain imperfect inverted repeats that in C31, TP901-1, and Rv1 are symmetrical around the 2-bp sequence at which crossover occurs (6, 8) .

The BT1 attB site lies approximately 1 Mb to the right of oriC compared to the C31 attB site, which is approximately 90 kbp to the left of oriC . The BT1 attB site lies within SCO4848 coding for a putative integral membrane protein . This protein contains two predicted membrane-spanning alpha helices (Fig . 1) . Analysis of the attL sequence indicates that an alternative protein coding sequence, SCO4848int, is generated after BT1 integration, which still retains an N-terminal putative membrane-spanning alpha helix (Fig . 1) . Thus, if SCO4848int is transcribed, an active gene product may produced even after BT1 integration and which may, therefore, confer a neutral phenotype .

For this reason and in order to provide additional integration vectors, we constructed integrating plasmids similar in design to pSET152 except that they integrate via BT1 attP-int (3) . pRT801 (Fig . 2) was constructed in two steps . PCR was used to amplify the BT1 int-attP region from phage particles in the presence of primers RT26 (5' ATT AGC ATG CTG GCG CCG GAC GGG GCT TCA GAC) and RT27 (5' TAA TGG ATC CGC TCC CTG CCC GCT GTG GTG AC) and Pfu polymerase, using the manufacturer's recommended procedures (Stratagene) . The PCR fragment and pGEM7 (Promega) were cut with BamHI and SphI, ligated to form pRT800, and the attP-int region was sequenced . The BT1 attP-int- containing fragment was then used to replace the C31 attP-int sequences in pSET152 using the restriction sites BamHI and SphI to form pRT801 . The plasmids pRT801 and pSET152 were introduced into the nonmethylating E . coli strain ET12567 (containing pUZ8002, required to provide the transfer functions [10]), and these strains were used as donors in conjugations with S . coelicolor J1929 . Comparable numbers of apramycin-resistant transconjugants of S . coelicolor J1929 were obtained with E . coli ET12567(pUZ8001, pRT801) and with ET12567(pUZ8001, pSET152) (Table 1) .

 
To ensure that the BT1 attP-int-based vectors were compatible with pSET152 and to assay the frequency of integration into the S . lividans genome, pRT802 was constructed containing the aphII gene from Tn5 to replace the apramycin resistance marker (Fig . 2) . pRT802 was constructed by inserting a 1,327-bp fragment from pNRT4 (encoding the aphII gene from Tn5 and kindly provided by P . Herron, University of Swansea) cut with HindIII, blunt ended with Klenow fragment, and then cut with SacI and inserted into pRT801 cut with NruI and SacI . It should be noted that during the construction of pRT802, an approximately 600-bp deletion was introduced in the oriT region (S . Ward, personal communication) . pRT802 and pSET152 were introduced separately into S . lividans TK24 by conjugation from E . coli S17-1(pRT802) or S17-1(pSET152), and similar numbers of kanamycin- and apramycin-resistant colonies were obtained (data not shown) . S . lividans TK24 or TK24(pRT802) was then used as the recipient for the introduction of pSET152 from E . coli S17-1(pSET152), and similar numbers of apramycin-resistant colonies were obtained in both recipients (Table 1) . Thus, the BT1 attP-int-containing vectors are transferred efficiently to both S . coelicolor and S . lividans, and integration of pSET152 is not inhibited by the presence of pRT802 .

The broad host range of pRT801 was demonstrated by conjugation into other streptomycetes using standard methods (8) . Apramycin-resistant transconjugants were recovered for many of the Streptomyces strains investigated, including S . avermitilis, S . cinnamonensis, S . fradiae, S . lincolnensis, S . nogolater, S . roseosporus, and S . venezuelae . To complete the suite of BT1 int/attP vectors, we constructed hygromycin-resistant derivatives of pRT801, pMS81, and pMS82 (Fig . 2) . These plasmids were constructed by ligation of a HpaI fragment encoding hygromycin resistance (derived from Tn5099-10) (13) with the 4,415-bp Ecl136II fragment from pRT801 and differ only in the orientation in which the fragment encoding hygromycin resistance has inserted . The hygromycin resistance marker in S . coelicolor J1929(pMS81) and J1929(pMS82) was confirmed to be stable after two rounds of sporulation in the absence of selection (data not shown) . We believe that all of these vectors will become a useful addition to the genetic toolbox of the streptomycete researcher .

This study was funded by the BBSRC .

Present address: Biotica, 181A Huntingdon Rd., Cambridge, CB3 0DJ, United Kingdom .

1. Allen, M . J., A . Collick, and A . J . Jefferies. 1994 . Use of vectorette and subvectorette PCR to isolate transgene flanking DNA . PCR Methods Appl . 4:71-75.
2. Baltz, R . H. 1998 . Genetic manipulation of antibiotic-producing Streptomyces . Trends Microbiol . 6:76-83.
3. Bedford, D . J., C . Laity, and M . J . Buttner. 1995 . Two genes involved in the phase-variable C31 resistance mechanism of Streptomyces coelicolor A3(2) . J . Bacteriol . 177:4681-4689.
4. Bentley, S . D., K . F . Chater, A . M . Cerdeno-Tarraga, G . L . Challis, N . R . Thomson, K . D . James, D . E . Harris, M . A . Quail, H . Kieser, D . Harper, A . Bateman, S . Brown, G . Chandra, C . W . Chen, M . Collins, A . Cronin, A . Fraser, A . Goble, J . Hidalgo, T . Hornsby, S . Howarth, C . H . Huang, T . Kieser, L . Larke, L . Murphy, K . Oliver, S . O'Neil, E . Rabbinowitsch, M . A . Rajandream, K . Rutherford, S . Rutter, K . Seeger, D . Saunders, S . Sharp, R . Squares, S . Squares, K . Taylor, T . Warren, A . Wietzorrek, J . Woodward, B . G . Barrell, J . Parkhill, and D . A . Hopwood. 2002 . Complete genome sequence of the model actinomycete Streptomyces coelicolor A3(2) . Nature 417:141-147.
5. Bierman, M., R . Logan, K . O'Brien, E . T . Seno, R . N . Rao, and B . E . Schoner. 1992 . Plasmid cloning vectors for the conjugal transfer of DNA from Escherichia coli to Streptomyces spp . Gene 116:43-49.
6. Breuner, A., L . Brondsted, and K . Hammer. 2001 . Resolvase-like recombination performed by the TP901-1 integrase . Microbiology 147:2051-2063.
7. Campbell, A., S . J . Schneider, and B . Song. 1992 . Lambdoid phages as elements of bacterial genomes (integrase/phage21/Escherichia coli K-12/icd gene) . Genetica 86:259-267.
8. Combes, P., R . Till, S . Bee, and M . C . M . Smith. 2002 . The Streptomyces genome contains multiple pseudo-attB sites for the C31-encoded site-specific recombination system . J . Bacteriol . 184:5746-5752.
9. Gregory, M . A. 2000 . Characterisation and evolution of homoimmune Streptomyces phages . Ph.D . dissertation . University of Nottingham, Nottingham, United Kingdom.
10. Kieser, T., M . J . Bibb, M . J . Buttner, K . F . Chater, and D . A . Hopwood. 2000 . Practical Streptomyces genetics . The John Innes Foundation, Norwich, United Kingdom.
11. Rost, B., R . Casadio, P . Fariselli, and C . Sander. 1995 . Transmembrane helices predicted at 95% accuracy . Protein Sci . 4:521-533.
12. Smith, M . C . M., and H . M . Thorpe. 2002 . Diversity in the serine recombinases . Mol . Microbiol . 44:299-307.
13. Solenberg, P . J., and R . H . Baltz. 1994 . Hypertransposing derivatives of the streptomycete insertion sequence IS493 . Gene 147:47-54.

Free Online Full-text Article

What Is Dna?, What Is Prokaryote?, What Is Biofilm?, What Is Water Purification?, What Is Antibiotic?, i, Microbes, s, Microorganisms, e, Bacteria, i, Microbe, i, Microbiology, o, Escherichia coli, s, Microorganisms, n, Streptococcal, n, Activated sludge, n, Staphylococcus aureus, s, Bacteriological, o, Microbiological, n, Culture medium, s, S. cerevisiae, n, Cell cultures, i, Staphylococcus, r, Microorganisms, e, Corynebacter, a, Staphylococcus, i, Bactericidal, a, Fermentations, o, Candida albicans, r, Yeasts, o, S. cerevisiae, o, Denitrifying, s, Propionibacteria




 

© 2005 Transgalactic Ltd (manufacturer of Bioscreen C software) | Privacy Statement | P.O. Box 1393, 00101 Helsinki, Finland, phone: +358 9 85172920, fax: +358 9 8749481, e-mail: microbiology@bionewsonline.com
 

Last modified: May 25, 2005