MEM INST OSWALDO CRUZ, RIO DE JANEIRO, 99(5) August 2004
PAGES: 513-516 DOI: Short communication
HygR and PurR Plasmid Vectors for Episomal Transfection of Trypanosoma cruzi

Otávio T NóbregaI II, Jaime M SantanaI III, Nancy R Sturm, Antônio RL TeixeiraI, David A Campbell +

Department of Microbiology, Immunology and Molecular Biology, David Geffen School of Medicine, University of California, 90095-1489, Los Angeles, CA, US
ILaboratório Multidisciplinar de Pesquisa em Doença de Chagas, Faculdade de Medicina, Universidade de Brasília, Brasília, DF, Brasil

Abstract

This work describes the development and functional testing of two episomes for stable transfection of Trypanosoma cruzi. pHygD contained the 5'- and 3'- flanking regions of the gene encoding the cathepsin B-like protease of T. cruzi as functional trans-splicing and polyadenylation signals for the hygR ORF. Evidence is presented to support extrachromosomal maintenance and organization as tandem repeats in transfected parasites. pPac was derived from pHygD by replacement of the entire hygR ORF with a purR coding region. The ability to modify pHygD and the availability of the complete DNA sequence make these plasmids useful tools for the genetic manipulation of T. cruzi.

Studies on kinetoplastid protozoa have been facilitated by advances in techniques to manipulate their genomes. The methods are based on plasmid constructions that (1) use dominant selectable markers since auxotrophs are generally not available, and (2) provide the elements needed to accomplish mRNA processing in the cell. Most episomes for Trypanosoma cruzi use the neomycin-resistance gene(Kelly et al. 1992, Buckner et al. 1996, Martinez-Calvillo et al. 1997). The hygromycin B phosphotransferase (HPH) gene has been used as marker for T. cruzi transfectants in experiments involving integration (Cooper et al. 1993, Buckner et al. 1997, Thomas & Gonzalez 1997). There are no reports of puromycin N-acetyltransferase (PAC) use in transfection of T. cruzi. Here we describe two plasmids that were maintained extrachromosomally in T. cruzi and provided resistance to hygromycin (hyg) or puromycin (pur) for potential use in genetic manipulation of this parasite.

The sensitivity of the CL Brener strain of T. cruzi to each drug was determined experimentally. The concentration necessary to produce 50% inhibition of growth (IC50) was 100 µg/ml for hyg and 1 µg/ml for pur (data not shown). Both plasmids were originally generated for targeted replacement of the single-copycathepsin B-like protease gene (TCCB) of T. cruzi (Nóbrega et al. 1998). Both selectable markers were flanked by PCR-amplified untranslated regions (UTRs) of a TCCB plasmid previously isolated from a Berenice strain genomic DNA library. Oligonucleotide primers Kpn and Cla were designed to produce a 1260-bp fragment upstream of the TCCB coding region. Primers Not and Sac were used to amplify an 872-bp region downstream of the gene (Fig. 1A, B). Each primer was named for the restriction site added to its 5' end. Following digestion with the cognate enzymes, both 5' and 3' UTRs were cloned into compatible sites present on the starting plasmid pBS HygA (Freedman & Beverly 1993), a pBluescript II SK (pBS) derivative containing the HPH open reading frame (ORF), generating the pHygD plasmid (Fig. 1C). The subsequent restriction and sequencing analysis of the construction revealed the loss of theClaI site along with 175 bp from the 3' end of the 5' UTR. A second plasmid, pHygC, had a 234 bp deletion that removed the majority of a 28-bp polypyrimidine tract present 285 bp upstream of the ATG initiation codon ofTCCB (Fig. 1A). These deletions were likely artifacts of the cloning procedure.

To favor targeted integration of the constructs, both pHygD and pHygC (50 µg) were digested with BssHII, which cuts twice in pBS (Fig. 1C). Each digestion was used to transfect the CL Brener strain of T. cruzi without prior isolation of linear cassettes. Electroporation settings were as described previously (Saito et al. 1994) and selection was performed in LIT growth medium with hyg at 250 µg/ml. Cells transfected with pHygD developed resistance to hyg (hygR); pHygC did not yield living transfectants under a variety of buffer and electroporation conditions. This result suggested that the 28-bp polypyrimidine tract absent from pHygC might function as the trans-splicing site of the TCCB mRNA. This was corroborated by analysis of the 5' UTR of the TCCB transcript by reverse transcriptase-PCR using the T. cruzi spliced leader sequence and part of the ORF as annealing sites for sense (TATTG CTACA GTTTC TGTAC TATAT TG) and antisense (CTCAT GATTC CAGCT GTTCG C) primers, respectively (data not shown). The splice-acceptor site was present 199 bp upstream of the ATG initiation codon ofTCCB.

From the pool of hygR parasites, clonal lines pHygD1, pHygD2, and pHygD3 were derived by limiting dilution. To assess the organization of pHygD in these lines, total DNA was digested with PstI and screened by Southern blotting using the PCR-amplified TCCB 5' UTR as probe. In addition to the chromosomal signal present in the untransfected DNA sample, the resulting profile showed an intense 5.6-kb band in all clonal lines (Fig. 2A), consistent with the linear size of the plasmid and suggesting episomal maintenance rather than the anticipated targeted integration event. No integration events were observed in either clonal or non-clonal (data not shown) populations. The presence of multiple copies of the plasmid was inferred based on the hybridization signal of the episome relative to the genomic signal in each clonal line. Densitometric comparison of the hybridization signals suggested that 20 to 70 copies of the plasmid were present per diploid genomic copy.

Arrangement in multiple, covalently-linked monomers is a common type of episomal structure in transfected trypanosomatids (Kelly et al. 1992, Biebinger & Clayton 1996). Southern blot analysis of pHygD1 DNA partially digested with KpnI was performed using the HPH gene as probe. A digestion time course showed a pattern of high molecular weight forms of episome (uncut lane) that were resolved into bands of multiple sizes, consistent with the linear plasmid as well as dimeric (11.8 kb), trimeric (17.7 kb), tetrameric (23.6 kb) and pentameric (29.5 kb) forms (Fig. 2B). Thus, pHygD was maintained extrachro-mosomally and organized as tandem repeats in T. cruzi. Since electroporations were carried out with digested plasmid, the unexpected episomal organization could have arisen from religation of the DNA fragments in the intracellular milieu. Circularization of linear DNA fragments carrying cohesive ends have been described in vivo as an event that may precede targeted integration in T. cruzi (Chung & Swindle 1997). However, since the elec-troporated DNA was not gel purified, we cannot rule out the possibility that uncut plasmid was present at the time of electroporation.

The second vector was derived from pHygD by replacing the entire HPH ORF with the PAC ORF isolated from pVN3.1 (Lacalle et al. 1989). To ligate the PAC ORF between the single SmaI site and the BamHI site downstream of HPH,pVN3.1 was first digested with NotI (which cuts upstream of PAC), blunt ended using Klenow fragment and then digested with BamHI (which cuts downstream of PAC). The 0.8-kb blunted-BamHI fragment was gel purified and ligated to the sites referred to above generating plasmid pPac (Fig. 1D). Due to the results obtained with pHygD transfections, the ability of pPac to generate episomes was tested using the uncut construction. PurRpopulations were obtained following electroporation of the CL Brener strain of T. cruzi with the circular plasmid (50 mg) and selection with pur at 3 µg/ml.

Efficient expression of heterologous genes in try-panosomatids is dependent on functional trans-splicing sites upstream of the gene (Laban & Wirth 1989, Bellofatto et al. 1991). In some cases, providing downstream trans-splicing acceptor sequences was required for polyadenylation of the transcripts (LeBowitz et al. 1993). All these requirements were met for the expression of the selectable markers developed in this study. The strain from which regulatory sequences were derived (Berenice) and the strain into which the plasmids were introduced (CL Brener) belong to different discrete typing units defined among the T. cruzi isolates (Brisse et al. 2000), possibly accounting for the lack of integration due to insufficient UTR homology, as seen in T. brucei (Blundell et al. 1996). The ability to modify pHygD to contain alternative selectable markers or to include reporter genes indicated that both vectors constitute potentially useful tools for the genetic manipulation of T. cruzi.

 

ACKNOWLEDGMENTS

To Dr Stephen Beverley (Washington University) and Dr Juan Ortín (UAM, Spain) for providing us with plasmids pBS HygA and pVN3.1, respectively. To Dr T Guy Roberts and Dr Michael C Yu for comments and suggestions.

 

REFERENCES

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Blundell PA, Rudenko G, Borst P 1996. Targeting of exogenous DNA into Trypanosoma brucei requires a high degree of homology between donor and target DNA. Mol Biochem Parasitol 76: 215-229.

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Nóbrega OT, Santos Silva MA, Teixeira ARL, Santana JM 1998. Cloning and sequencing of TCCB, a gene encoding a Trypanosoma cruzi cathepsin B-like protease. Mol Biochem Parasitol 97: 235-240.

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+Corresponding author: Fax: +1-310-206-5231. E-mail:  This e-mail address is being protected from spambots. You need JavaScript enabled to view it.
IICapes fellowship. Present address: Universidade Católica de Brasília, EPCT QS 7, lote 1, 72030-170, Águas Claras, DF, Brasil
IIIFrom whom plasmids should be requested.
Received 23 December 2003
Accepted 26 May 2004
Financial support: CNPq
The sequence data reported herein have been submitted to GenbankTM and assigned the accession numbers AF529182 and AF529183.

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