Cyanobacterial Transposons Tn5469 and Tn5541 Represent a Novel Noncomposite Transposon Family

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Journal of Bacteriology, November 1998, p. 6059-6063, Vol. 180, No. 22
0021-9193/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.

Cyanobacterial Transposons Tn5469 and Tn5541 Represent a Novel Noncomposite Transposon Family

Michael R. Schaefer^* and Katherine Kahn

Division of Molecular Biology and Biochemistry, School of Biological Sciences, University of Missouri-Kansas City, Kansas City, Missouri 64110

Received 19 June 1998/Accepted 15 September 1998

	ABSTRACT

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A noncomposite transposon, designated Tn5541, was isolated from strain Fd33 of the filamentous cyanobacterium Fremyella diplosiphonUTEX 481. Sequence analysis showed that Tn5541 is structurallyand genetically very similar to Tn5469, which is also endogenousto F. diplosiphon. Both Tn5469 and Tn5541 encode homologous formsof an unusual composite transposase and a protein of unknown function.DNA hybridization analysis showed that like Tn5469, Tn5541 wasnot widely distributed among cyanobacterial genera. A similaranalysis showed that Tn5469 and Tn5541 were equally limited toand present as multiple genomic copies in three of six distinctstrains comprising the Tolypothrix 1 cluster of heterocyst-formingfilamentous cyanobacteria. These and other distinguishing featuressuggest that Tn5469 and Tn5541 represent a novel noncompositetransposonfamily.

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A feature common to all examined bacterial genomes is the presence of transposable genetic elements. The simplest and most-commonforms are insertion sequence (IS) elements, which range in sizefrom 0.6 to 2.5 kbp and are found in multiplicities from a fewto a few hundred per genome (7, 12). IS elements are characterizedby one or a few genes required for transposition, which are flankedby terminal inverted repeat (IR) sequences. The more-complex transposableelement forms are transposons that range in size from 2.5 to 60kbp (3). Transposons and IS elements share many structural,functional, and genetic features associated with transposition,including generation of short directly repeated duplications ofa target sequence. However, transposons usually possess one ormore genes that confer a phenotype on the bacterial host, suchas resistance to a specific antibiotic. Most bacterial transposonsare typed as composite or noncomposite forms. Composite transposonsare composed of two IS elements of the same type bracketing oneor more genes. In noncomposite forms, the transposition and nontranspositiongenes are clustered and flanked by terminal IR sequences. Becausetransposition can be mutagenic, the activity of these transposableelements can significantly influence genomeevolution.

Little is known about the transposable elements endogenous to the morphologically diverse and widely distributed cyanobacteria.With the exception of transposon Tn5469 (see below), only characteristicIS elements have been isolated from different strains of thislarge eubacterial group. Earlier reports described 14 cyanobacterialIS elements which were isolated from species in the filamentousAnabaena and Calothrix genera (1, 2, 5, 22). Recently,IS elements were isolated from two unicellular Synechocystis species,one from Synechocystis sp. strain BO 8402 (4) and three fromSynechocystis sp. strain PCC 6803 (6). At least three additionalIS element forms reported for Synechocystis sp. strain PCC 6803(19) remain to becharacterized.

We previously characterized transposon Tn5469 (16), which was isolated from strain Fd33 of the filamentous cyanobacteriumFremyella diplosiphon UTEX 481 (also referred to as Calothrixsp. strain PCC 7601). The 4,904-bp Tn5469 is a noncomposite transposonthat encodes a large composite transposase, designated TnpA, andtwo unidentified proteins. Five copies of Tn5469 are present onthe wild-type genome. Like most characterized cyanobacterial ISelements, Tn5469 is not widely distributed among morphologicallydistinct genera. Tn5469 has been implicated as the agent responsiblefor the phenotype of several different pigmentation mutants ofstrain Fd33 (15-17). Each of these mutants was found to possessan extra genomic copy of Tn5469, which facilitated isolation ofthe affected gene in a manner analogous to transposon tagging.During the course of analyzing a putative Tn5469-generated mutant,we identified a Tn5469-like transposon, which was designated Tn5541.Here we show that Tn5541 is very similar to Tn5469 and suggestthat both represent a novel transposonfamily.

Identification of Tn5541. Strain Fd33 is a short-filament mutant of F. diplosiphon UTEX 481 (9) that provides for colonial growth on solid medium.Pigmentation mutant strain FdGM2 was derived from strain Fd33and contains an extra (sixth) genomic copy of Tn5469 (18) localizedto an uncharacterized open reading frame (ORF) temporarily designatedrcaY. A recombinant library of Fd33 genomic DNA was constructedin $lambda$ EMBL3 (13). Clone $lambda$ UMC001 from this library harbors a 15-kbpfragment containing intact rcaY sequences. DNA sequence analysisof a region flanking rcaY on the $lambda$ UMC001 insert indicated thepresence of an ORF predicting a polypeptide that has significantsequence identity with the TnpA transposase encoded by Tn5469.To investigate whether this sequence represented a new transposablegenetic element, corresponding DNA fragments were subcloned fromthe $lambda$ UMC001 insert for sequencing and genetic analysis. This effortrevealed that the $lambda$ UMC001 insert harbors a 4.7-kbp noncompositetransposon, which was designated Tn5541.

General features of Tn5541. The 4,745-bp transposon Tn5541 contains 12-bp near-perfect (9 of 12 bp) terminal IRs that do not match corresponding sequencesfrom known IS elements or transposons. Based on the orientationof two ORFs (see below), the IRs were designated IR_L for the leftend and IR_R for the right end of the element. On the $lambda$ UMC001 insert,Tn5541 is not flanked by a duplicated target sequence; IR_L isflanked by the sequence 5'-TGCTTAT-3', whereas IR_R is flankedby the sequence 5'-GTGTTAT-3'. However, subsequent analysis offour additional genomic copies of Tn5541 in Calothrix sp. strainPCC 7601 (see below) showed that three were flanked by different,duplicated 5-bp target sequences. Presumably, transposition ofTn5541 in F. diplosiphon is accompanied by a characteristic generationof a duplicated target sequence, which in some cases becomes alteredovertime.

The nucleotide sequence of Tn5541 predicts two ORFs arranged in tandem on the element (Fig. 1A). The left ORF (designatedtnpA; nucleotide positions 351 to 3066), which is preceded byan E. coli-like promoter, predicts a 904-residue protein witha molecular mass of 103.2 kDa and a pI of 8.91. A BLAST (tblastn)search of the GenBank database indicated that the 904-residueprotein has sequence identity with a number of transposases, mostsignificantly with the TnpA transposase from Tn5469. The rightORF (designated orf1; nucleotide positions 3069 to 4533) initiates3-bp downstream of tnpA and predicts a 488-residue protein witha molecular mass of 55.0 kDa and a pI of 8.62. This proximityand the lack of distinguishable promoter sequences upstream oforf1 suggest that tnpA and orf1 may be cotranscribed. A BLASTcomparison of the ORF1 polypeptide sequence against the GenBankdatabase revealed no significant matches except the partiallyhomologous ORF1 polypeptide from Tn5469.

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FIG. 1. Physical map of Tn5541 (A) and Tn5469 (B). Horizontal boxes indicate the size and orientation of putative genes and ORFs as determined by sequence analysis. Narrow vertical boxes indicate terminal IR sequences. Internal restriction sites are shown for enzymes used in cloning and generation of probes for DNA hybridization experiments. E, EcoRI; X, XbaI.

Homology between Tn5541 and Tn5469. The TnpA protein encoded by Tn5541 has 43.9% overall amino acid sequence identity with the TnpA transposase from Tn5469. Analignment of the TnpA sequences is presented in Fig. 2A. The twoTnpA proteins are homologous composites of two different and widelydistributed transposase forms; this composite for TnpA from Tn5469was defined earlier (16). The amino-terminal one-third of theshared TnpA protein most resembles the 226-residue ORFN1 transposaseencoded by Lactococcus lactis insertion sequence ISS1 (14) (datanot shown). The ISS1 transposase has significant sequence identitywith transposases encoded by IS elements found in gram-negativeand gram-positive bacteria (27). The carboxyl-terminal two-thirdsof the shared TnpA protein most resembles the transposases encodedby noncomposite transposons Tn5090 (23), Tn552 (25), and Tn7(11) (data not shown). Like the transposases from Tn5090, Tn552,and Tn7, the TnpA proteins contain the invariant D,D(35)E motif(Fig. 2A) that characterizes the members of a superfamily of bacterialtransposases and eukaryotic retroviral and retrotransposon integraseproteins (10, 21). However, in comparison to Tn5090, Tn552,and Tn7, both Tn5541 and Tn5469 are simple in genetic structureand encode a single defined transposition protein. The contrastinggenetic organization and unifying transposase suggest that allof these transposons arose independently but evolved from a commonancestor.

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FIG. 2. Alignment of Tn5541 and Tn5469 TnpA (A) and ORF1 (B) amino acid sequences. Numbering of the amino acids for individual proteins is presented at the right. Identical residues are boxed. For the TnpA sequences, the conserved aspartate (D) and glutamate (E) residues comprising the D,D(35)E motif of the integrase and transposase superfamily (21) are shaded. For the ORF1 sequences, the residues comprising the P-loop ATP-binding motif (26) are shaded.

The ORF1 protein encoded by Tn5541 is partially homologous to the corresponding ORF1 protein encoded by Tn5469. An alignmentof the two ORF1 sequences is presented in Fig. 2B. The amino-terminal336 residues of the Tn5541 ORF1 protein have 31.3% sequence identitywith the amino-terminal 329 residues of the Tn5541 ORF1 protein.Outside of this region, the different-sized ORF1 proteins havelimited sequence identity. A BLAST analysis of the CyanoBase database(19) showed that the ORF1 proteins have domains of sequenceidentity with several Synechocystis sp. strain PCC 6803 proteins(data not shown). The amino-terminal one-third of Tn5541 ORF1(and corresponding region of Tn5469 ORF1) has greatest sequenceidentity with a putative ABC transporter component (CyanoBasedesignation sll0182) and the DnaX component of DNA polymeraseIII (CyanoBase designation sll1360). A feature common to theseproteins is the presence of a P-loop ATP-binding motif ([AG]X₄GK[ST])(26); this motif for the ORF1 proteins is identified in Fig.2B. The central one-third of Tn5541 ORF1 (and corresponding regionof Tn5469 ORF1) has significant sequence identity with two definedClpB proteases (CyanoBase designations slr0156 and slr1641). Finally,the carboxyl-terminal one-third of Tn5541 ORF1 is unique and resemblesan unidentified protein (CyanoBase designation sll0188). The carboxyl-terminalregion of Tn5541 ORF1, as well as the sll0188 protein, containsmany proline and threonine residues and aligns to a number ofeukaryotic glycoproteins in the GenBank database. The fact thatthe homologous ORF1 protein encoded by Tn5541 and Tn5469 has domainsof identity with these unrelated cyanobacterial enzymes is interesting;however, a functional unification of these features is notobvious.

A comparison of terminal nucleotide sequences revealed a structural similarity between the IR regions of Tn5541 and Tn5469.Among the terminal 25 bases containing their respective IR sequences,11 are identical between IR_L and IR_R for Tn5541 (Fig. 3A), whereas23 are identical between IR_L and IR_R for Tn5469 (Fig. 3B). TheIRs of both transposons possess the terminal dinucleotide 5'-TG,which is a distinguishing feature of the prokaryotic and eukaryoticmobile genetic elements encoding transposases characterized bythe D,D(35)E motif described above. Curiously, the sequence ofthe Tn5541 IR_R region shares 17 of the 25 bases comprising theIR_R of Tn5469. In contrast, the Tn5541 IR_L and IR_R regions shareonly 11 of the terminal 25 bases. Thus, the Tn5541 IR_R regionmore closely resembles the terminal IR structure of Tn5469 thanits corresponding IR_L region. The functional significance of thisIR_R sequence similarity is unknown.

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FIG. 3. Nucleotide sequence comparison of Tn5541 and Tn5469 terminal IR regions. (A) Alignment of Tn5541 IR_L and IR_R regions. (B) Alignment of Tn5469 IR_L and IR_R regions. (C) Alignment of Tn5541 and Tn5469 IR_R regions. The numbering of the bases for the individual IR regions is shown at the right. Identical bases within an examined sequence pair are boxed.

Among the transposon sequences deposited in the GenBank database, Tn5541 most resembles Tn5469. Both transposons are approximately5 kb in length and possess similar terminal IRs flanking similartandemly arranged ORFs (Fig. 1). A significant structural differencebetween the two elements is that Tn5469 encodes a second unidentifiedORF (designated orf2) immediately downstream of orf1 (Fig. 1B).Despite this difference, their collective structural and sequencesimilarities suggest that Tn5469 and Tn5541 arose from a commonancestral transposon. Primarily on the basis of their unprecedentedcomposite transposase, but taking into account their uncharacteristicgenetic structure and unidentifiable orf1, we propose that Tn5541and Tn5469 represent a novel noncomposite transposonfamily.

Distribution of Tn5469 and Tn5541. The distribution of Tn5541 among several morphologically distinct strains of cyanobacteria was examined by DNA hybridizationanalysis. The examined strains were from the American Type CultureCollection or the Pasteur Culture Collection and are referredto by their genus names followed by the collection numbers. Ina low-stringency hybridization analysis of total DNA isolatedfrom Anabaena sp. strain PCC 7120, Anabaena sp. strain ATCC 29413,F. diplosiphon UTEX 481, Nostoc sp. strain PCC 8009, Synechococcussp. strain PCC 7942, and Synechocystis sp. strain PCC 6803, aprobe for Tn5541 hybridized only to DNA from F. diplosiphon UTEX481 (data not shown). This result was identical to that determinedearlier for Tn5469 (16), suggesting that like most of the characterizedcyanobacterial IS elements (1, 5, 22), neither Tn5469nor Tn5541 is widely distributed among morphologically distinctgenera.

We similarly examined the distribution of Tn5469 and Tn5541 among six distinct strains comprising the Tolypothrix 1 groupof heterocyst-forming filamentous cyanobacteria (24), whichincludes the F. diplosiphon UTEX 481 culture equivalent, Calothrixsp. strain PCC 7601. Total DNA from Calothrix sp. strain PCC 7601and Tolypothrix sp. strains PCC 7101, PCC 7504, PCC 7708, PCC7710, and PCC 7712 was digested with SpeI and hybridized to aprobe for Tn5469 (3.8-kbp EcoRI-XbaI fragment from pUMC227) orTn5541 (1.8-kbp EcoRI fragment from pUMC334). Among the strainsexamined, DNA from Calothrix sp. strain PCC 7601 and Tolypothrixsp. strains PCC 7504, PCC 7710, and PCC 7712 hybridized to theTn5469 probe (Fig. 4A). In comparison, only DNA from Calothrixsp. strain PCC 7601 and Tolypothrix sp. strains PCC 7710 and PCC7712 hybridized to the Tn5541 probe (Fig. 4B). The weaker hybridizationsignal obtained for Tolypothrix sp. strain PCC 7504 with the Tn5469probe (Fig. 4A, lane 3) most likely reflects the presence of aheterologous, cross-hybridizing transposon or transposase gene.If correct, Tn5541 and Tn5469 appear to be limited to the samethree strains within the Tolypothrix I cluster. The simplest explanationfor this distribution is that Calothrix sp. strain PCC 7601 andTolypothrix sp. strains PCC 7710 and PCC 7712 have a common ancestorthat acquired both Tn5541 and Tn5469 prior to diverging from Tolypothrixsp. strains PCC 7101, PCC 7504, and PCC 7708.

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FIG. 4. Distribution of Tn5469 and Tn5541 among members of the Tolypothrix 1 cluster. Total DNA (5 µg per lane) was digested with SpeI and subjected to DNA hybridization analysis with a probe for Tn5469 or Tn5541. (A) Blot hybridized with the Tn5469 probe. (B) Identical blot hybridized with the Tn5541 probe. DNA from the following strains was analyzed: Calothrix sp. strain PCC 7601 (lane 1), Tolypothrix sp. strain PCC 7101 (lane 2), Tolypothrix sp. strain PCC 7504 (lane 3), Tolypothrix sp. strain PCC 7708 (lane 4), Tolypothrix sp. strain PCC 7710 (lane 5), and Tolypothrix sp. strain PCC 7712 (lane 6).

The DNA hybridization analysis also showed that Calothrix sp. strain PCC 7601 and Tolypothrix sp. strains PCC 7710 and PCC7712 harbor multiple genomic copies of both Tn5469 and Tn5541.Calothrix sp. strain PCC 7601 harbors five genomic copies of Tn5469;each copy is detected as a single fragment in the SpeI digest(Fig. 4A, lane 1). An identical Tn5469 hybridization profile wasobserved for Tolypothrix sp. strain PCC 7710 (Fig. 4A, comparelanes 1 and 5). The Tn5469 hybridization profile for Tolypothrixsp. strain PCC 7712 differed from that of Calothrix sp. strainPCC 7601 and Tolypothrix sp. strain PCC 7710 only by the absenceof the hybridizing 15-kbp SpeI fragment (Fig. 4A, compare lane6 with lanes 1 and 5). With the Tn5541 probe, five hybridizingfragments of high signal intensity and several fragments of lowsignal intensity were detected for Calothrix sp. strain PCC 7601(Fig. 4B, lane 1). A similar analysis of the same DNA digestedwith ClaI or XbaI (data not shown) supported five genomic copiesof Tn5541 for this strain. For both Tolypothrix sp. strains PCC7710 and PCC 7712, five genomic copies of Tn5541 were detected(Fig. 4B, lanes 5 and 6). The Tn5541 hybridization profiles forthe three host strains appeared to have some common fragments(Fig. 4B, compare lanes 1, 5, and 6); however, in contrast towhat was observed for Tn5469, the Tn5541 hybridization profilefor Calothrix sp. strain PCC 7601 was not identical to that forTolypothrix sp. strain PCC 7710 (Fig. 4B, compare lanes 1 and5). In addition, whereas the Tn5469 hybridization profile forTolypothrix sp. strain PCC 7710 differed from that of Tolypothrixsp. strain PCC 7712 by the presence of the 15-kbp hybridizingfragment (Fig. 4A, compare lanes 5 and 6), the Tn5541 hybridizationprofiles for these two strains differed only by the size of thelargest hybridizing fragment (Fig. 4B, compare lanes 5 and6).

The similar Tn5469 and Tn5541 hybridization profiles support a close phylogenetic relationship between the three host strainsin terms of genome structure. We recently determined nearly identicalDNA sequences for the five genomic copies of Tn5469 isolated fromCalothrix sp. strain PCC 7601 (8), suggesting that all rapidlyradiated from a single form. The multiple genomic copies of Tn5541were presumably achieved by a similar process. An intriguing possibilityis that Tn5541 and Tn5469 were simultaneously acquired by an ancestralhost, and that because of their relatedness, the two elementsmultiplied in parallel via a common transposition mechanism; Calothrixsp. strain PCC 7601 and Tolypothrix sp. strains PCC 7710 and PCC7712 would have subsequently arisen from this ancestralhost.

The narrow host range of Tn5469 and Tn5541 supports the utility of either element as a genetic tool for mutagenic analysisof nonhost cyanobacterial strains. The development of such a toolwould facilitate molecular genetic studies on strains which, likeF. diplosiphon, are not amenable to characterized transposon mutagenesisprotocols. Toward this end, we have initiated the developmentof an assay for Tn5469 transposition in several morphologicallydistinct strains that may allow us to determine if a selectableform of the element can serve as an agent for transposontagging.

Common transposition mechanism for Tn5469 and Tn5541? Little is known regarding the transposition of Tn5469 or Tn5541. For the better-characterized Tn5469, a replicative transpositionmechanism was hypothesized (16) based on the following observations:(i) the source strain Fd33 harbors five genomic copies of theelement, (ii) Fd33-derived primary and secondary mutants respectivelyharboring six and seven genomic copies of Tn5469 have been characterized,and (iii) no decrease in Tn5469 copy number or change in locationof a preexisting element has been observed. However, a nonreplicativetransposition event followed by the loss of the donor moleculecan lead to transposon accumulation (20). Because F. diplosiphonharbors multiple cellular copies of its genome (28), a nonreplicativemechanism for Tn5469 cannot be ruled out. Tn5541 has in commonwith Tn5469 the property of genomic multiplicity; however, anincrease in Tn5541 multiplicity has not been documented for anymutant or host strain in our collection. Nevertheless, their geneticand structural relatedness suggests that Tn5541 and Tn5469 havea common, and probably replicative, transposition mechanism. Ofparticular interest is whether the transposase from Tn5541 cansponsor transposition of Tn5469 or viceversa.

Nucleotide sequence accession number. The nucleotide sequence of Tn5541 has been deposited in the GenBank database under accession no. AF072896.

	ACKNOWLEDGMENTS

We thank P. Shubert and J. Salamasina for excellent technical assistance and N. Tandeau de Marsac and R. Rippka for providingcyanobacterial strains. We are grateful to W. K. Thomas for helpfuldiscussions andcomments.

This research was supported by National Science Foundation grant MCB-9513660. K.K. was supported by a UMKC Chancellor's InterdisciplinaryPh.D.Fellowship.

	FOOTNOTES

^* Corresponding author. Mailing address: University of Missouri-Kansas City, School of Biological Sciences, 5100 Rockhill Rd.,Kansas City, MO 64110. Phone: (816) 235-2573. Fax: (816) 235-5595.E-mail: mschaefer{at}cctr.umkc.edu.

Present address: Sainsbury Laboratory, John Innes Centre, Norwich NR4 7UH, UnitedKingdom.

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1.	Alam, J., J. M. Vrba, Y. Cai, J. A. Martin, L. J. Weislo, and S. E. Curtis. 1991. Characterization of the IS895 family of insertion sequences from the cyanobacterium Anabaena sp. strain PCC 7120. J. Bacteriol. 173:5778-5783[Abstract/Free Full Text].
2.	Bancroft, I., and C. P. Wolk. 1989. Characterization of an insertion sequence (IS891) of novel structure from the cyanobacterium Anabaena sp. strain M-131. J. Bacteriol. 171:5949-5954[Abstract/Free Full Text].
3.	Bennett, P. M. 1991. Transposable elements and transposition in bacteria, p. 323-364. In U. N. Streips, and R. E. Yasbin (ed.), Modern microbial genetics. Wiley Publishers, New York, N.Y.
4.	Brass, S., A. Ernst, and P. Boger. 1996. An insertion element prevents phycobilisome synthesis in N₂-fixing Synechocystis sp. strain BO 8402. Appl. Environ. Microbiol. 62:1964-1968[Abstract].
5.	Cai, Y. 1991. Characterization of insertion sequence IS892 and related elements from the cyanobacterium Anabaena sp. strain PCC 7120. J. Bacteriol. 173:5771-5777[Abstract/Free Full Text].
6.	Cassier-Chauvat, C., M. Poncelet, and F. Chauvat. 1997. Three insertion sequences from the cyanobacterium Synechocystis PCC 6803 support the occurrence of horizontal DNA transfer among bacteria. Gene 195:257-266[Medline].
7.	Charlebois, R. L., and W. F. Doolittle. 1989. Transposable elements and genome structure in halobacteria, p. 297-307. In D. J. Berg, and M. M. Howe (ed.), Mobile DNA. American Society for Microbiology, Washington, D.C.
8.	Cleveland, L., and M. R. Schaefer. Unpublished results.
9.	Cobley, J. G., E. Zerweck, R. Reyes, A. Mody, J. R. Seludo-Unson, H. Jaeger, S. Weerasuriya, and S. Navankasattusas. 1993. Construction of shuttle plasmids which can be efficiently mobilized from Escherichia coli into the chromatically adapting cyanobacterium, Fremyella diplosiphon. Plasmid 30:90-105[Medline].
10.	Fayet, O., P. Ramond, P. Polard, M. F. Prere, and M. Chandler. 1990. Functional similarities between retroviruses and the IS3 family of bacterial insertions sequences? Mol. Microbiol. 4:1771-1777[Medline].
11.	Flores, C. C., M. I. Qadri, and C. P. Lichtenstein. 1990. DNA sequence analysis of five genes, tnsA, tnsB, tnsC, tnsD, and tnsE, required for Tn7 transposition. Nucleic Acids Res. 18:901-911[Abstract/Free Full Text].
12.	Galas, D. J., and M. Chandler. 1989. Bacterial insertion sequences, p. 109-162. In D. E. Berg, and M. M. Howe (ed.), Mobile DNA. American Society for Microbiology, Washington, D.C.
13.	Grossman, A. R. Personal communication.
14.	Haandrikman, A. J., C. Van Leeuwen, J. Kok, P. Vos, W. M. de Vos, and G. Venema. 1990. Insertion elements on lactococcal proteinase plasmids. Appl. Environ. Microbiol. 56:1890-1896[Abstract/Free Full Text].
15.	Kahn, K., D. Mazel, J. Houmard, N. Tandeau de Marsac, and M. R. Schaefer. 1997. A role for cpeYZ in cyanobacterial phycoerythrin biosynthesis. J. Bacteriol. 179:998-1006[Abstract/Free Full Text].
16.	Kahn, K., and M. R. Schaefer. 1995. Characterization of transposon Tn5469 from the cyanobacterium Fremyella diplosiphon. J. Bacteriol. 177:7026-7032[Abstract/Free Full Text].
17.	Kahn, K., and M. R. Schaefer. 1997. rpbA controls transcription of the constitutive phycocyanin gene set in Fremyella diplosiphon. J. Bacteriol. 179:7695-7704[Abstract/Free Full Text].
18.	Kahn, K., and M. R. Schaefer. Unpublished results.
19.	Kaneko, T., S. Sato, H. Kotani, A. Tanaka, E. Asamizu, Y. Nakamura, N. Miyajima, M. Hirosawa, M. Sugiura, S. Sasamoto, T. Kimura, T. Hosouchi, A. Matsuno, A. Muraki, N. Nakazaki, K. Naruo, S. Okumura, S. Shimpo, C. Takeuchi, T. Wada, A. Watanabe, M. Yamada, M. Yasuda, and S. Tabata. 1996. Sequence analysis of the genome of the unicellular cyanobacterium Synechocystis sp. strain PCC 6803. II. Sequence determination of the entire genome and assignment of potential protein-coding regions. DNA Res. 3:109-136[Abstract].
20.	Kleckner, N. 1989. Transposon Tn10, p. 227-268. In D. E. Berg, and M. M. Howe (ed.), Mobile DNA. American Society for Microbiology, Washington, D.C.
21.	Kulkosky, J., K. S. Jones, R. A. Katz, J. P. G. Mack, and A. M. Skalka. 1992. Residues critical for retroviral integrative recombination in a region that is highly conserved among retroviral/retrotransposon integrases and bacterial insertion sequence transposases. Mol. Cell. Biol. 12:2331-2338[Abstract/Free Full Text].
22.	Mazel, D., C. Bernard, R. Schwarz, A. M. Castets, J. Houmard, and N. Tandeau de Marsac. 1991. Characterization of two insertion sequences, IS701 and IS702, from the cyanobacterium Calothrix species PCC 7601. Mol. Microbiol. 5:2165-2170[Medline].
23.	Radstrom, P., O. Skold, G. Swedberg, J. Flensburg, P. H. Roy, and L. Sundstrom. 1994. Transposon Tn5090 of plasmid R751, which carries an integron, is related to Tn7, Mu, and the retroelements. J. Bacteriol. 176:3257-3268[Abstract/Free Full Text].
24.	Rippka, R. 1988. Recognition and identification of cyanobacteria. Methods Enzymol. 167:28-67.
25.	Rowland, S.-J., and K. G. H. Dyke. 1990. Tn552, a novel transposable element from Staphylococcus aureus. Mol. Microbiol. 4:961-975[Medline].
26.	Saraste, M., P. R. Sibbald, and A. Wittinghofer. 1990. The P-loop $---$ a common motif in ATP- and GTP-binding proteins. Trends Biochem. Sci. 15:430-434[Medline].
27.	Schafer, A., A. Jahns, A. Geis, and M. Teuber. 1991. Distribution of the IS elements ISS1 and IS904 in lactococci. FEMS Microbiol. Lett. 80:311-318.
28.	Tandeau de Marsac, N. Personal communication.