Nucleic Acids Research

Nucleic Acids Research Advance Access originally published online on May 14, 2008
Nucleic Acids Research 2008 36(10):e62; doi:10.1093/nar/gkm1170

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Nucleic Acids Research, 2008, Vol. 36, No. 10 e62
© 2008 The Author(s)
This is an Open Access article distributed under the terms of the Creative Commons Attribution Non-Commercial License (http://creativecommons.org/licenses/by-nc/2.0/uk/) which permits unrestricted non-commercial use, distribution, and reproduction in any medium, provided the original work is properly cited.

Methods Online

Terminal proteins of Streptomyces chromosome can target DNA into eukaryotic nuclei

Hsiu-Hui Tsai¹, Chih-Hung Huang², Alan M. Lin¹ and Carton W. Chen^1,*

¹Department of Life Sciences and Institute of Genome Sciences, National Yang-Ming University, Shih-Pai, Taipei 112 and ²Institute of Biotechnology, National Taipei University of Technology, Taipei 106, Taiwan

*To whom correspondence should be addressed. Tel: +1 886 2 2826 7040; Fax: +1 886 2 2826 4930; Email: cwchen{at}ym.edu.tw

Received November 2, 2007. Revised December 18, 2007. Accepted December 19, 2007.

	ABSTRACT

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

 
Streptomyces species are highly abundant soil bacteria that possess linear chromosomes (and linear plasmids). The 5' ends of these molecules are covalently bound by terminal proteins (TPs), that are important for integrity and replication of the telomeres. There are at least two types of TPs, both of which contain a DNA-binding domain and a classical eukaryotic nuclear localization signal (NLS). Here we show that the NLS motifs on these TPs are highly efficient in targeting the proteins along with covalently bound plasmid DNA into the nuclei of human cells. The TP-mediated nuclear targeting resembles the inter-kingdom gene transfer mediated by Ti plasmids of Agrobacterium tumefaciens, in which a piece of the Ti plasmid DNA is targeted to the plant nuclei by a covalently bound NLS-containing protein. The discovery of the nuclear localization functions of the Streptomyces TPs not only suggests possible inter-kingdom gene exchanges between Streptomyces and eukaryotes in soil but also provides a novel strategy for gene delivery in humans and other eukaryotes.

	INTRODUCTION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

 
The linear chromosomes and plasmids of Streptomyces species are capped by terminal proteins (TPs) at the 5' ends of the DNA (1). The TP provides protection against exonuclease attack on the DNA, and functions as a primer for DNA synthesis to patch the single-stranded gaps at the 3' ends during replication (2).

Several Streptomyces TPs have been isolated or identified from genome sequences. Most of them (designated Tpg) are highly conserved in sequences and size (184–185 aa) (3,4). On Streptomyces chromosomes, the tpg gene forms an operon with a tap gene, which encodes another protein essential for end-patching DNA synthesis (5). Bao and Cohen (5) showed that the Tap protein of S. coelicolor (Tap^Sco) interacts with Tpg of S. coelicolor (Tpg^Sco) and the single-stranded telomere DNA, and proposed that Tap^Sco recruits and positions Tpg^Sco at the telomere during its replication. In an in vitro system, Yang et al. (6) demonstrated that Tpg^Sco was specifically deoxynucleotidylated by dCMP (the first nucleotide of the S. coelicolor chromosome) at a Thr residue.

A monopartite nuclear localization signal (NLS) motif was predicted downstream of and adjacent to a helix-turn-helix DNA-binding domain at the N-terminus of Tpg^Sco and the identical Tpg of S. lividans, Tpg^Sli (4). As more Tpg homologs were identified, NLS motifs were also found in all of them except perhaps that of pSCL2 plasmid and the predicted pseudogene products (Fig. 1A). All these NLS motifs contain the consensus K(K/R)X(K/R) sequence for the basic core of monopartite NLS (7). Initially, this discovery was regarded as fortuitous, because: (i) NLSs often overlap with a DNA-binding domain, and sometimes are used for DNA binding (8,9); and (ii) a nuclear localization function of a TP would appear incongruous in streptomycetes that lack a nucleus.

View larger version (58K): [in this window] [in a new window] [Download PowerPoint slide]   Figure 1. Potential NLS sequences in TPs of Streptomyces. (A) The archetypal Tpg family. The plasmid-encoded Tpgs are designated by the plasmid names, and the chromosome-encoded Tpgs are designated by three-letter abbreviations of the species (Sav, S. avermitilis; Sco, S. coelicolor; Sli, S. lividans; Sro, S. rochei; Ssc, S. scabies). For those Tpgs that are encoded by the same replicon, they are distinguished by their gene numbers. Sources of the sequences are: S. coelicolor chromosome (4), S. lividans chromosome (3), S. avermitilis chromosome and SAP1 plasmid (38), pSV2 plasmid (pSV2.82) in S. violaceoruber (GenBank accession number NC_004934 [GenBank] ), pSLV45 plasmid S. lavendulae (39), pFRL1 plasmid in Streptomyces sp. FR1(40), S. rochei chromosome and pSLA2-L and pSLA2-M plasmids (41), SLP2 plasmid in S. lividans (4), S. scabies chromosome (http://www.sanger.ac.uk/Projects/S_scabies/), pSCL2 plasmid in S. clavuligerus (GenBank accession number AAQ93595 [GenBank] ), pNO33 plasmid in S. albulus (GenBank accession number YP_170689). The locations of the DNA-binding HTH domain and potential NLS sequences are depicted by the open and filled box, respectively, on the prototype TpgSco. The potential NLS in various Tpgs (except the putative pseudogene products) are shaded in yellow. Within this region, the basic aa's are in red and Pro in blue. The length (in aa) of the Tpg proteins is indicated at the right. Conceptually translated products of proven pseudogenes (TpgSLP2.39; Yang, C.-C., unpublished results) or putative pseudogenes (widely divergent sequence and/or anomalous length) are placed below the dashed line. (B) Tpc of SCP1 plasmid. The labels are as in (A).

 
Recently, a novel TP (designated Tpc) encoded by linear plasmid SCP1 of S. coelicolor was isolated and characterized (10). Tpc is distinct from Tpgs in both aa sequence and size (259 versus 184–185 aa), and represents the product of convergent evolution. Tpc also contains a predicted NLS (Fig. 1B), which, however, differs from that on Tpg^Sco and Tpg^Sli in being separate from the DNA-binding domain, and in being bipartite. The finding of two distinct types of NLSs in two different types of TP suggested that their occurrences were not coincidental, and that they serve a real biological function.

In this study, we showed that the NLSs on both types of TP (Tpgs and Tpc) are functional in nuclear targeting. When fused to a triple green fluorescence protein concatemer (EGFP3), they could target the fusion protein into human nuclei. These TPs could also carry covalently attached DNA into the nuclei. TPs with a mutation in NLS are defective in nuclear localization, but remain competent in supporting end-patching and capping of linear replicons. This suggests that the nuclear targeting function of TPs has evolved independently of the end-patching function. All these findings indicate that the nuclear targeting of the TP-capped linear replicons of Streptomyces is biologically significant, and may mediate inter-kingdom gene transfer in soil.

	MATERIALS AND METHODS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

 
Growth and genetic manipulations of bacterial cultures and plasmids
Bacterial cultures and plasmids are listed in Table 1. Basic microbiological and molecular biological procedures were according to Kieser et al. (11) and Sambrook et al. (12). S. lividans TK64 (13) and MR04 (14) was used for propagation of Streptomyces plasmids. Mutations in cloned genes were generated by site-directed mutagenesis by PCR.

View this table: [in this window] [in a new window]   Table 1. Bacterial cultures and plasmids used in this study

 
Construction of EGFP3 fusion proteins
Tpg and Tpc genes and their NLS-deleted sequences were obtained by PCR, and oligonucleotides containing the NLS sequences were commercially synthesized. These sequences were inserted between the SacI and EcoRI sites upstream of EGFP3 (encoding a triple green fluorescence protein concatemer under the control of the CMV immediate-early promoter) on pEGFP3 (15) to generate TP-EGFP3 and NLS-EGFP3 fusion proteins, respectively.

Construction of mini linear plasmids
The 3.4 kb SacI-HindIII fragment spanning the tap^Sco-tpg^Sco operon was generated by PCR, and inserted between the SacI and HindIII sites of pLUS966 to generate pLUS986. The tap^Sco-tpg^Sco operon containing the K3A or R4A mutations was created by PCR using appropriate primer sets (listed in Supplementary Data), and used to replace the tap^Sco-tpg^Sco operon on pLUS986 to generate pLUS986(K3A) and pLUS986(R4A), respectively.

Mini linear plasmid pLUS892L containing the tas and tpc genes, the pSLA2 ARS, and a pair of SCP1 telomeres and its circular progenitor pLUS892 were described previously (10). The tac-tpc sequence containing the ARVRRR) mutation in tpc was created by PCR using appropriate primer sets (listed in Supplementary Data), and used to replace the corresponding HindIII fragment of pLUS892 to generate pLUS892 (ARVRRR). HindIII-linearized pLUS966 and AseI-linearized pEGFP3 were filled in by DNA polymerase I to create blunt ends, and ligated by T4 DNA ligase to create pLUS966-EGFP3.

Generation of linear plasmids from the circular progenitor plasmids followed the general procedure of Qin and Cohen (16). The circular plasmid DNA was linearized by AseI in the ColE1 vector sequence and used to transform S. lividans TK64 or MR04. Linear plasmids were isolated from thiostrepton-resistant transformants, and confirmed by restriction analysis.

Transfection of human cell cultures
HeLa and HEK 293T human cell lines were grown in DMEM medium supplemented with 10% (vol/vol) fetal bovine serum. They were transfected using lipofectamine according to the procedure specified by the manufacturer (Invitrogen). Fluorescent transfected cells were scored under a fluorescence microscope. To prepare TP-capped linear plasmid DNA for transfection, Streptomyces cultures containing the plasmid were grown in YEME medium to exponential phase, harvested by centrifugation, treated with lysozyme (1 mg/ml) at 37° for 30 m, and osmotically lyzed by dilution in 10 vol of TE buffer. The lysate was electrophoresed in 0.8% agarose gel containing 0.05% SDS. Linear plasmid DNA was visualized by ethidium bromide staining and eluted electrophoretically.

NLS prediction
NLSs were predicted using the PredictNLS server (http://cubic.bioc.columbia.edu/predictNLS) based on Cokol et al. (9).

	RESULTS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

 
Tpgs and their NLSs are functional in nuclear targeting
To test the nuclear localization function, we fused the Tpg^Sco and Tpg^Sav sequences to the reporter gene EGFP3 (encoding a triple green fluorescence protein concatemer) under the control of the CMV immediate-early promoter (P_CMVIE) on pEGFP3 (15) (Fig. 1A), and introduced the constructed plasmids, pEGFP3-Tpg^Sco and pEGFP3-Tpg^Sav, into HeLa and/or HEK 293T human cells by transfection using the lipofectamine procedure. Green fluorescence was produced in 80% of the transfected cells in 16 h after transfection, and the fluorescence accumulated in the nuclei of these cells (Fig. 2A). In contrast, in cells transfected by the pEGFP3 vector, fluorescence was present mainly in the cytosol. These results indicated that the Tpg^Sco and Tpg^Sav sequences were functional in nuclear targeting.

View larger version (46K): [in this window] [in a new window] [Download PowerPoint slide]   Figure 2. Nuclear localization function of Tpgs. (A) NLS in Tpgs. The vector used for transfection was pEGFP3. The Tpg sequences fused in-frame to the N-terminus of EGFP3 are listed to the left. The residues in TpgSav and TpgpSLA2-L/TpgpSLA2-M that differ from those in TpgSco are underlined, and the mutant residue is in red. The nuclear localization test results (‘–’, negative; ‘+’, positive) are shown in the fluorescent microscopic images of a representative transfected cell in the middle. The original source of the sequence and the plasmid construct are listed to the right. (B) ‘Alanine Scan’ mutant variants of TpgSco. The mutant decapeptides are listed to the left, and the introduced alanine is in red.

 
To test the role of the putative NLS of Tpg^Sco in nuclear localization, the predicted NLS motif (KRPRP) was fused to the N-terminus of EGFP3 (Fig. 2A). HeLa cells transfected by the resulting plasmid, pEGFP3-NLS5C, displayed green fluorescence mainly in the cytosol. On the other hand, Tpg^Sco with a deletion of the pentapeptide lost its nuclear localization function when fused to EGFP3 (pEGFP3-Tpg^ScoNLS5C; Fig. 2A). When an expanded NLS motif-containing decapeptide, EIKRPRPDLA, was fused to EGFP3 (pEGFP3-NLS10C), the fused protein was concentrated in the nuclei of transfected HeLa cells (Fig. 2A). EGFP3 fused to Tpg^Sco lacking this decapeptide was localized mainly in the cytosol (pEGFP3-Tpg^ScoNLS10C). These results indicated that the EIKRPRPDLA decapeptide was necessary and sufficient for the nuclear targeting function of Tpg^Sco.

The putative NLS motif-containing decapeptide QIKKPRPDLA in Tpg^Sav, which differs from that in Tpg^Sco by two aa residues (Fig. 1A), could also target EGFP3 into the nuclei (pEGFP3-NLS10A; Fig. 2A). Moreover, a putative NLS motif-containing decapeptide, KLKRPRQDLR, in Tpg^pSLA2-M and Tpg^pSLA2-L of S. rochei (3,17), which differs from that in Tpg^Sco by four aa residues (Fig. 1A), was also competent for nuclear localization (pEGFP3-NLS10R, Fig. 2A). These results suggested that the predicted NLS sequences in all of the Tpgs (except perhaps that of pSCL2) might be functional.

The ‘alanine scanning’ mutation procedure (18) was employed to test the functionality of the decapeptide EIKRPRPDLA of Tpg^Sco. Changes of the first two aa of the decapeptide to A (E1A and I2A mutations) did not affect the nuclear localization function (Fig. 2B). Alteration of the third (K3A), fourth (R4A) or sixth (R6A) aa to A blocked nuclear localization. This result confirmed the essential role of key basic aa in the NLS.

The bipartite NLS in Tpc is also functional
Tpc, the TP of the SCP1 plasmid of S. coelicolor, is distinct from Tpgs in both sequence and size (10). Its central region contains a predicted bipartite NLS motif of a common [RK]{3,}?x{8,16}[RK]{4,}? pattern found in nearly 200 nuclear proteins (9). Tpc-EGFP3 fusion protein (pEGFP3-Tpc) was concentrated in the nuclei of transfected HeLa cells, indicating that Tpc was also capable of nuclear targeting (Fig. 3). A 27-aa polypeptide spanning the predicted NLS motif of Tpc (pEGFP3-NLS27S) was sufficient for targeting the fused EGFP3 to the nuclei of HeLa cells. This 27-aa polypeptide contains two separate putative basic aa clusters—ARVRRR and RRRKKWT. Deletion of this polypeptide from Tpc on pEGFP3-Tpc(NLS27S) blocked nuclear localization. Deletion of either of the basic clusters on pEGFP3-Tpc(ARVRRR) and pEGFP3-Tpc(RRRKKWT) also blocked nuclear localization (Fig. 3), confirming the bipartite nature of this NLS.

View larger version (19K): [in this window] [in a new window] [Download PowerPoint slide]   Figure 3. Bipartite NLS in Tpc. The sequences fused in-frame to EGFP3 are listed at the left. The two NLS clusters are underlined. The plasmid constructs are listed to the right. The nuclear localization results (‘–’, negative; ‘+’, positive) are shown in the fluorescent microscopic images of a representative transfected cell.

 
NLS-defective TP is functional in replicating linear plasmids
While the NLS motifs in the TPs function in nuclear localization, are they also important for replication of the linear replicons? To answer this question, linear plasmids were constructed following the procedure of Qin and Cohen (16). First, an E. coli plasmid pLUS986 was constructed that contained the tap^Sco-tpg^Sco operon and an autonomously replicating sequence (ARS) from linear plasmid pSLA2 (19) flanked by a pair of S. lividans chromosomal telomeres. Such replication-proficient sequences containing telomeres, when linearized at the bracketing adventitious DNA and introduced by transformation into Streptomyces, can generate functional linear plasmids (16,20). The (tap^Sli-tpg^Sli) mutant MR04 of S. lividans (14) transformed with pLUS986 DNA that had been linearized by AseI digestion (at the E. coli vector sequence) harbored an11.7 kb linear plasmid (designated pLUS986L) with the expected size and the expected SacI restriction fragments (Fig. 4A). In this assay, linear plasmids that do not encode a functional TP and necessary accessory protein(s) cannot replicate in MR04, and only circular form may be found in transformants. Circular pLUS986 DNA possessing a single SacI site would produce only a single (linear) SacI fragment on digestion. Next, the K3A and R4A mutations in NLS (above) were each introduced into the tpg^Sco gene on pLUS986 to give rise to plasmids pLUS986(K3A) and pLUS986(R4A), respectively. Transformation of MR04 with these plasmids linearized by AseI also produced linear plasmids [designated pLUS986(K3A)L and pLUS986(R4A)L, respectively] with the expected size and SacI fragments (Fig. 4B). These results indicate that a functional NLS in Tpg^Sco is not necessary for performing the end patching role.

View larger version (43K): [in this window] [in a new window] [Download PowerPoint slide]   Figure 4. NLS-defective TPs are functional in replication. (A) Mini linear plasmids constructed. pLUS986L contains a pair of S. lividans telomeres (filled arrows) capped by the TpgSco proteins (filled circles) encoded by the tpgSco it carries. pLUS986(K3A)L and pLUS986(R4A)L are pLUS986L containing the K3A and R4A mutation in the NLS of TpgSco (Fig. 2B), respectively. pLUS892 contains a pair of SCP1 telomeres (terminal open arrows) capped by Tpc proteins (open circles) encoded by the tpc it carries (10). pLUS892(ARVRRR)L is a derivative of pLUS892L containing the (ARVRRR) mutation in the NLS of Tpc (Fig. 3). The SacI (Sc) restriction site and the size of the expected restriction fragments are indicated. ARS, autonomously-replicating sequence of pSLA2. (B) NLS-defective TPs cap mini linear plasmids. S. lividans strains (see text) were transformed by the circular progenitor of the five mini linear plasmids, pLUS986, pLUS986(K3A), pLUS986(R4A), pLUS892, and pLUS892(ARVRRR) that had been digested by AseI. Thiostrepton-resistant transformants were isolated, and DNA extracted from the transformants, digested by SacI (‘+’, with digestion; ‘–'without digestion), and electrophoresed. The number and size of the SacI fragments of the plasmids were as expected from the linear plasmids. Circular plasmids would give only a single SacI fragment.

 
Using the same procedure, the (ARVRRR) mutation was introduced into the tpc gene on a mini linear plasmid, pLUS892L (10), which contained the essential tac and tpc gene pair, the pSLA2 ARS, and a pair of SCP1 telomeres. The resulting plasmid, pLUS892(ARVRRR)L, capped by the NLS-defective Tpc also replicated as a linear DNA in TK64 (Fig. 4B). These results indicated that a functional NLS in Tpc was also not essential for end patching.

The finding that two different classes of Streptomyces TPs contains different types of NLS motifs, which are functional in nuclear targeting but not required for replication, indicates that the nuclear localization functions have not emerged coincidentally, but have evolved convergently in two different systems for an identical biological role.

TPs carried covalently bound DNA into the nuclei
To determine whether TP may lead covalently linked DNA into the nuclei a linear plasmid, pLUS966-EGFP3L, was constructed that contained a pair of S. lividans telomeres and the EGFP3 gene under the control of the CMV promoter (Fig. 5A and B). In cells transfected with the Tpg^Sco-capped pLUS966-EGFP3L DNA, transient expression of EGFP3 was observed after 6 h in HeLa (Fig. 5C) and HEK 293T cells and reached a maximum of 70% (Fig. 5D). In comparison, in transfection by the progenitor circular plasmid pLUS966-EGFP3 and proteinase K-treated pLUS966-EGFP3L DNA, fluorescent cells were seen after 12 h and reached a lower maximum (60%).

View larger version (52K): [in this window] [in a new window] [Download PowerPoint slide]   Figure 5. Delivery of TP-capped DNA into the nuclei. (A) pLUS966-EGFP3 containing a linear plasmid sequence with an EGFP3 gene under the control of the CMV promoter. The promoters and genes are indicated by the open arrows, and the S. lividans telomeres by filled arrows. tsr, thiostrepton resistance gene; rep1 and rep2, replication genes of pSLA2 (19); neo-r, neomycin resistance gene. (B) Linear plasmid pLUS966-EGFP3-L capped by TpgSco (filled circles) obtained by transformation of S. lividans by AseI-linearized pLUS966-EGFP3 DNA. (C) Transfer and expression of EGFP3 in transfected cells. After transfection, fluorescent cells were photographed and counted under fluorescence microscope. Representative bright-field and fluorescence photographs of transfected HeLa cells at 6 and 14 h after transfection are shown. 1, pLUS966-EGFP3L DNA; 2, pLUS986(K3A)-EGFP3L DNA; 3, proteinase K-treated pLUS966-EGFP3L DNA; 4, pLUS966-EGFP3 DNA. (D) Comparison of efficiency of EGFP3 transfer and expression. Upper panel, HeLa cells; lower panel, HEK 293T cells. Fluorescent cells were counted after transfection. Filled circles, pLUS966-EGFP3L DNA; open circles, pLUS986(K3A)-EGFP3L DNA; open triangles, proteinase K-treated pLUS966-EGFP3L DNA; filled triangles, pLUS966-EGFP3 DNA.

 
The high efficiency of gene delivery by the Tpg^Sco-capped linear DNA might be due to either active nuclear targeting conferred by the TP or protection against cellular exonuclease attack. To resolve this issue, EGFP3 was placed on pLUS986(K3A)L, which was capped by an NLS-defective (K3A) Tpg^Sco. Transfection using the resultant plasmid produced similar results as the circular DNA and uncapped linear DNA in both HeLa and HEK 293T cells, i.e. later appearance and lower numbers of fluorescent transformants than the linear DNA capped by normal Tpg^Sco (Fig. 5D). This result indicated the higher efficiency of delivery by Tpg^Sco was mainly conferred by the active nuclear targeting function of its NLS.

	DISCUSSION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

 
New NLS motifs in Tpgs
We have demonstrated that the predicted monopartite NLS in Tpg^Sco, Tpg^Sli, Tpg^Sav and Tpg^pSLA2-L/Tpg^pSLA2-M were functional in nuclear targeting either as separate domains or as part of the Tpg proteins. The predicted bipartite NLS motif on Tpc, which is found in nearly 200 nuclear proteins, is also functional in nuclear targeting, and the basic residues in both of its two clusters are essential for function.

The laboratory-observed nuclear targeting function of the NLSs in Tpgs and Tpc, which is not essential for the end-patching function, strongly suggests a role in nature. However, there is no nucleus in bacteria, hence what would be the biological function of these NLSs?

Nuclear transport of proteins bearing an NLS is mediated by the importin /β heterodimer in eukaryotes. It is possible that Tpgs and Tpc interact with a similar system and perform an unknown biological process in Streptomyces. To investigate this possibility, we used the importins and β sequences from human, mouse, Drosophila melanogaster and Arabidopsis thaliana as query in blastp and psi-blast searches against the S. coelicolor and S. avermitilis genomic databases. No significant homologous hit (E-values < 0.1) was found. Therefore, either the NLS motifs in Tpgs and Tpc interact with a heterologous system in Streptomyces, or they interact with a system outside of Streptomyces.

TP-mediated transfer is similar to T-DNA transfer
TP-mediated DNA transfer is analogous to the transfer of T-DNA by Agrobacterium tumefaciens. During conjugation with a plant cell, a Ti plasmid-encoded VirD2 protein in A. tumefaciens nicks at a border of the T-DNA sequence and remains covalently bound to the 5' end. A rolling circle-type replication initiated at the nick, followed by a second nick, removes a single-strand stretch of T-DNA, which is transported into the plant cell. Inside the plant cells, the T-DNA is bundled by another T-DNA-encoded protein, VirE2, and led by the VirD2 protein into the plant nuclei, where integration takes place. VirD2 contains a monopartite and a bipartite NLS, which are required for nuclear targeting (21). VirD2 is attached to the T-DNA at a Tyr residue (22), whereas Tpg^Sco is attached to the Streptomyces DNA at a Thr residue (6).

Both being soil bacteria, agrobacteria and streptomycetes may have more genetic interactions than have been noted. First, Kelly and Kado (23) recently reported that T-DNA may be transferred and integrated by Agrobacterium into the chromosome of Streptomyces. Second, the linear plasmid SLP2 of S. lividans contains a pair of homologs of two hypothetical genes, ymg and yme, which are present on an octopine-type Ti plasmid of A. tumefaciens in an identical arrangement (24). Codon usage analysis suggests that these two genes were horizontally acquired, perhaps through gene exchanges between a linear plasmid of Streptomyces and the Ti-plasmid of A. tumefaciens.

We propose that TP-capped linear DNA of Streptomyces, like the Ti plasmids of A. tumefaciens, is also involved in inter-kingdom gene transfer in soil. The target of such proposed transfer is not clear. Streptomyces species are highly abundant in soil, and the likely eukaryotic targets for transfer include plants and fungi. Such transfer, if real, would be of great evolutionary and ecological significance.

The existence of many genes of bacterial origin in the genomes of plants and other eukaryotes (25) has been suggested to result from horizontal gene transfer mediated by bacterial systems such as the Ti-plasmids (26). The TP-capped linear DNA system may also be involved in such inter-kingdom gene transfer.

The Streptomyces TP as a gene delivery tool
The Ti-plasmids of Agrobacterium are the most effective gene delivery tool in plant biotechnology (review in 27). They have also been adopted for gene transfer for other targets such as human nuclei (28) and mammalian mitochondria (29). In addition, NLSs have been used in various systems to aid non-viral gene delivery in human gene therapy (reviewed by 30–32). In these schemes, the positively charged NLSs are coupled with the negatively charged DNA, or covalently coupled with a carrier component/condensing agent or the phosphate–sugar backbone of the DNA.

The disadvantage of non-covalent coupling of NLS-containing peptides is that dissociation of the complex can occur during intracellular trafficking. The non-specific covalent coupling of NLS peptides to plasmid DNA does not markedly enhance nuclear uptake or increase reporter gene expression, while the covalent attachment of NLS peptides may inhibit intended gene expression. To prevent such inhibition, NLS peptides are coupled with specific locations in the plasmid DNA—primarily at the termini. Zanta et al. (33) reported a 10- to 1000-fold increase (depending on the cell types used) in gene expression using a linear DNA construct with a SV40-derived NLS peptide coupled with one of the hairpin ends compared with the DNA construct without the NLS peptide cap. However, similar attempts (for example, 34,35) met with little or no success.

In comparison to the existing NLS-aided gene delivery systems, the TP-capped Streptomyces replicons offer an efficient alternative. The TP caps offer both an active nuclear localization function and protection from cellular exonucleases, which is one of the gene delivery barriers (36). TP capping is biological and complete, and does not require elaborate physical and chemical procedures. Only standard molecular cloning techniques in E. coli and Streptomyces are required for production of TP-capped linear DNA for transfection. The size of inserts is limited by that of the cloning systems. E. coli plasmid vectors generally can accommodate inserts of tens of kb, and linear Streptomyces plasmids reach 1 Mb. Such a promising gene delivery system requires vigorous study and development. Notably, while this article was being prepared, the idea of using TP-capped linear DNA as ‘a potential new strategy for assembly of synthetic therapeutic gene vector’ was proposed by Tolmachov and Coutelle (37).

	ACKNOWLEDGEMENTS

 
We thank David Hopwood for critical reading of the manuscript and suggestions for improvement. This study was funded by research grants from National Science Council, R. O. C. to C.-H.H. (NSC94-2311-B027-002) and C.W.C. (NSC94-2321-B010-005, NSC94-2321-B010-002), a grant (Aim for the Top University Plan) from the Ministry of Education, R. O. C. to C.W.C., and a National Health Research Institute postdoctoral fellowship award (PD91006N) to C.-H.H. Funding to pay the Open Access publication charges for this article was provided by National Science Council, R. O. C.

Conflict of interest statement. None declared.

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TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

 

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