Tài liệu Báo cáo khoa học: Modulation of oat arginine decarboxylase gene expression and genome organization in transgenic Trypanosoma cruzi epimastigotes docx

cruzi epimastigotes are unable Keywords free episome; genome organization; heterologous ADC gene expression; plasmid integration; Trypanosoma cruzi transformation Correspondence I.. cruz

and genome organization in transgenic Trypanosoma cruzi epimastigotes

Marı´a P Serra, Carolina Carrillo, Ne´lida S Gonza´lez and Israel D Algranati

Fundacio´n Instituto Leloir, Buenos Aires, Argentina

Trypanosoma cruzi, the etiological agent of Chagas’

disease, is a parasitic protozoan with a digenetic life

cycle involving an insect vector and a mammalian

host The parasite undergoes major morphological

and biochemical changes during the different stages of

its life cycle The epimastigote form is noninfective and

proliferates extracellularly in the insect gut where it

differentiates into metacyclic trypomastigotes, which

can then infect the mammalian host cells and replicate

intracellularly after transforming into amastigotes [1–4]

Epimastigotes from different wild-type strains of

T cruziare able to grow continuously in vitro in a rich culture medium [5], but proliferation stops after a few passages in a semidefined medium, which contains only traces of polyamines [6,7] T cruzi remain viable for several weeks in the defined medium and are able to resume normal growth only upon the addition of exo-genous polyamines to the culture [7] These results confirm previous reports from our and other laborat-ories indicating that T cruzi epimastigotes are unable

Keywords

free episome; genome

organization; heterologous ADC gene

expression; plasmid integration;

Trypanosoma cruzi transformation

Correspondence

I D Algranati, Fundacio´n Instituto Leloir,

Avenue Patricias Argentinas 435 (1405),

Buenos Aires, Argentina

Fax: +5411 5238 7501

Tel: +5411 5238 7500

E-mail: ialgranati@leloir.org.ar

(Received 24 November 2005, accepted

12 December 2005)

doi:10.1111/j.1742-4658.2005.05098.x

We have previously demonstrated that wild-type Trypanosoma cruzi epi-mastigotes lack arginine decarboxylase (ADC) enzymatic activity as well as its encoding gene A foreign ADC has recently been expressed in T cruzi after transformation with a recombinant plasmid containing the complete coding region of the oat ADC gene In the present study, upon modulation

of exogenous ADC expression, we found that ADC activity was detected early after transfection; subsequently it decreased to negligible levels between 2 and 3 weeks after electroporation and was again detected

 4 weeks after electroporation After this period, the ADC activity increased markedly and became expressed permanently These changes of enzymatic activity showed a close correlation with the corresponding levels

of ADC transcripts To investigate whether the genome organization of the transgenic T cruzi underwent any modification related to the expression of the heterologous gene, we performed PCR amplification assays, restriction mapping and pulse-field gel electrophoresis with DNA samples or chromo-somes obtained from parasites collected at different time-points after trans-fection The results indicated that the transforming plasmid remained as free episomes during the transient expression of the foreign gene After-wards, the free plasmid disappeared almost completely for several weeks and, finally, when the expression of the ADC gene became stable, two or more copies of the transforming plasmid arranged in tandem were integra-ted into a parasite chromosome (1.4 Mbp) bearing a ribosomal RNA locus The sensitivity of transcription to a-amanitin strongly suggests involvement

of the protozoan RNA polymerase I in the transcription of the exogenous ADCgene

Abbreviations

ADC, arginine decarboxylase; G418, geneticin; ODC, ornithine decarboxylase; PFGE, pulse-field gel electrophoresis.

to synthesize putrescine, as a result of the absence

of ornithine and arginine decarboxylases (ODC and

ADC) [7–10], which catalyse the first steps of both

possible pathways of putrescine biosynthesis [11] In

accordance with this conclusion we have observed that

the addition of ornithine or arginine to the culture

medium cannot support the continuous growth of

T cruziin the defined medium, as proliferation in the

presence of these amino acids is arrested at the same

time as in unsupplemented cultures [9] In all these

cases, growth can be resumed by the addition of

putrescine, cadaverine or spermidine On the other

hand, all our attempts to detect ODC or ADC

enzy-matic activities in various strains of wild-type T cruzi

epimastigotes, by adding radioactive ornithine or

arginine to intact parasites or cell extracts, gave

negli-gible values [7,9,10] These results could be attributed

neither to a deficient uptake of the amino acids by

the parasites [12] nor to the presence of ODC or ADC

inhibitors in the protozoan internal medium [7,10]

Studies carried out in order to correlate the parasite

growth under different conditions with the

correspond-ing intracellular levels of polyamines have shown that

the proliferation of wild-type T cruzi epimastigotes

depends exclusively on the endogenous concentrations

of spermidine or aminopropylcadaverine [13,14] In

fact, when polyamine-depleted cultures of T cruzi

epi-mastigotes in synthetic media were supplemented with

putrescine, together with cyclohexylamine (a known

inhibitor of putrescine conversion into spermidine)

[15,16], the parasites were unable to resume growth,

even though the putrescine levels increased markedly

inside the protozoa, because the spermidine

concentra-tions remained low [13]

We have recently investigated whether the failure to

detect ODC and ADC activities in wild-type T cruzi

epimastigotes could be caused by the absence of the

corresponding genes in the parasite genome

Bioinfor-matic analyses based on available data from the

T cruzigenome project, and hybridization assays with

specific probes homologous to conserved regions of

ODCor ADC genes from many organisms, have

indi-cated the absence of ODC- and ADC-like nucleotide

sequences in the wild-type T cruzi genome [10,17]

As the described results show that wild-type T cruzi

behaves as a natural deletion mutant for ODC and

ADCgenes, we used these polyamine auxotrophic

par-asites as recipients of foreign ODC or ADC genes to

study their expression and the eventual suppression of

polyamine auxotrophy [7,10]

We have previously transformed wild-type T cruzi

epimastigotes with a recombinant plasmid containing

the oat ADC cDNA coding region [10] In the present

work we used ADC-transgenic protozoa to follow the time-course modulation of foreign gene expression and to investigate whether this modulation can be explained by the concomitant changes occurring in the parasite genome organization

Results and Discussion

Expression of the oat ADC gene in T cruzi

In order to study the expression of the foreign ADC gene in T cruzi epimastigotes, we transformed wild-type parasites with the recombinant plasmid, pADC-8 [10], bearing the complete coding region of the oat ADCgene cloned in the sense orientation, in the vector pRIBOTEX This vector contains a ribosomal promo-ter region, derived from a T cruzi rRNA locus, ligated upstream of the multiple cloning sequence [18] It has been previously shown that this promoter region of pRIBOTEX and related vectors induces the transcrip-tion of genes cloned downstream of the promoter and their chromosomal integration [19] After 48 h of transfection, geneticin (G418) was added to the cul-tures of transformed parasites to select plasmid-containing protozoa The time course of ADC gene expression was followed by northern hybridization analysis and measurements of the new enzymatic activ-ity Total RNA was extracted from transformed para-sites at different time-points after electroporation and analysed with a labelled probe specific for the oat ADC gene (Fig 1A), using a ribosomal RNA probe as

a loading control (Fig 1B) The relative intensities of the hybridization bands corresponding to ADC tran-scripts and ribosomal RNA showed that the concen-tration of ADC mRNA ( 2.2 kb long) reached an early maximum at 1 week after transfection, decreased markedly between 2 and 4 weeks after electroporation, and then increased again, attaining high levels after

‡ 6 weeks (Fig 1C)

Transgenic T cruzi showed a significant ADC activity as early as 48 h after transfection, as previ-ously reported [10] This activity has been character-ized by its products, the reaction stoichiometry and the specific inhibition by a-difluoromethylarginine [10] In the present work we observed that, initially, the enzymatic activity of cell extracts increased up to

a maximum value at  1 week after electroporation and then decreased to almost undetectable levels after 2–3 weeks (Fig 1D) These results, and the sim-ilar time-course variation of ADC RNA levels, con-firm previously published data indicating an initially transient expression of the foreign gene [10] ADC mRNA and the corresponding enzymatic activity

increased again when transformed T cruzi were

cul-tured for longer time-periods in the presence of

G418 (Fig 1A–D) At this point, the ADC gene

became permanently expressed at rather high levels

in the transgenic parasites

It is worthy of note that although these parasites

contain high enzymatic activities of ADC, they are

unable to overcome T cruzi auxotrophy for

polyam-ines, as previously reported [10] These results indicate

that agmatine cannot fulfill the physiological roles of

polyamines, and at the same time strongly suggest that

T cruzi does not contain agmatinase activity that

would convert agmatine into putrescine

We have also observed that transformed parasites

cultured in the absence of G418 showed only a

tran-sient period of ADC activity (Fig 1D)

Previous results from our laboratory have shown that

the complete elimination of untransformed parasites

by G418 under our experimental conditions occurs

in  1 month; therefore, in the 1 month time-period

between transfection and elimination, the parasite cul-tures are variable mixcul-tures of transformed and untrans-formed cells However, the correlation of RNA transcripts with the enzymatic activity levels for each time-point is relevant and allowed us to detect the tran-sient and stable periods of exogenous gene expression

Genome organization of transformed parasites

In order to explain the described changes of ADC mRNA levels and the corresponding enzymatic activi-ties after T cruzi transformation, we investigated the genome organization of transgenic parasites at differ-ent time-points after transfection To ascertain whe-ther the recombinant plasmid used for transformation was integrated into the parasite genome or remained free as extrachromosomal elements, we performed PCR amplification assays using two different sets of primers, as described in the Experimental procedures

If the recombinant plasmid remained as a free

A

B

D C

Fig 1 Time-course of arginine decarboxylase (ADC) RNA levels and enzymatic activities in transfected Trypanosoma cruzi Northern blot analysis of total RNA samples (20 lg) prepared from ADC-transformed T cruzi epimastigotes harvested at different time-points after electro-poration Hybridization bands with ADC- and rRNA-specific probes are shown in (A) and (B), respectively (C) Relative intensities of ADC mRNA bands normalized to the rRNA loading controls Lane 1, RNA from wild-type T cruzi; lanes 2, 3, 4, 5 and 6 correspond to RNA pre-pared from transgenic parasites 2 days and 1, 2, 4 and 24 weeks after transfection, respectively (D) ADC-specific activities in transgenic

T cruzi epimastigotes at different time-points postelectroporation All samples correspond to parasites harvested at the early logarithmic phase of growth, and ADC activity values are the average of assays carried out in duplicate Transformed parasites were cultured in the absence of geneticin (G418) (s) or with the antibiotic added 48 h after electroporation (d).

episome (either a circular single copy or a multimeric

form), only one of both PCR reactions should

pro-duce a DNA segment of 2030 bp when using primers

T7 (specific for the promoter region of pRIBOTEX

vector) and ADC2 (specific for an internal segment of

the ADC coding region) (Fig 2A) On the other

hand, if total integration of one plasmid copy has

occurred by homologous recombination, presumably

at a ribosomal RNA locus of the parasite genome,

the amplification assay with primers T7 and RIB

(spe-cific for the ribosomal locus of the wild-type T cruzi

genome) should give a DNA segment of 890 bp

(Fig 2B), and no other product from the PCR

reac-tion with the set of primers T7 and ADC2

Further-more, we could expect that the integration in the

parasite genome of two or more units of tandemly

amplified plasmid molecules should give rise to both

segments (2030 and 890 bp) by the described PCR

amplifications (Fig 2C) In order to study these

possi-bilities, total DNA was obtained from samples of

transfected parasites collected at different time-points

after electroporation, and all these preparations were used in PCR amplification reactions with the two sets

of primers described above Gel electrophoresis analy-ses of the PCR products indicated that during the first 15 days after transfection, the transforming plas-mid remained as free episomes, as only a 2030 bp DNA segment was detected after both PCR assays (Fig 3A, lanes 5 and 6) Two weeks after electropora-tion, the free plasmid had almost disappeared (Fig 3A, lanes 7 and 8) The faint PCR band of

 3500 bp detected in Fig 3A (lane 8), in addition to the expected 2030 bp PCR product, might be gener-ated by a partial DNA rearrangement inside the pADC-8 plasmid molecule During the subsequent period, the integration of ‡ 2 units of the transfected plasmid into the parasite genome seemed to occur, as shown by the production of both DNA segments after ‡ 4 weeks of transformation (Fig 3A, lanes 9– 12) We obtained the same results (890 and 2030 bp segments) with DNA samples from transformed

T cruzi 6 months after electroporation (Fig 3A,

Fig 2 Schematic diagrams to predict the fate of the recombinant plasmid after parasite transformation (A) Free episome elements; (B) integration of one plasmid copy into the parasite genome; (C) integration of two plasmid copies arranged in tandem The hatched horizontal segments represent the expected PCR amplification products for each type of genome organization when the corresponding DNA samples were assayed as described in the Experimental procedures The primer annealing sites are indicated by arrows The cutting sites of NheI and SalI enzymes used for the restriction mapping are also shown.

lanes 13 and 14), indicating that a stable genome

structure has probably been reached However, we

cannot exclude that a small portion of the

recombin-ant plasmid could remain free, even after stable

trans-formation

The described patterns of genome organization after

transfection are in good correlation with the

time-course of ADC gene expression (transcription and

translation) found in the transformed parasites and

depicted in Fig 1

The integration of the transforming plasmid

‡ 4 weeks after electroporation has also been

demon-strated by digestion of total DNA from transfected

T cruzi with restriction enzymes that cut twice inside

the pADC-8 sequence, as shown in Fig 2A–C The

subsequent hybridization analyses using the described

labelled probe, specific for the ADC gene, gave the

results predicted The radioactive bands obtained in

the corresponding Southern blot assay (Fig 3B) could

only be explained by the integration, into the parasite

genome, of ‡ 2 units of the plasmid pADC-8 arranged

in a head-to-tail tandem, as previously suggested for

the pRIBOTEX vector [18]

In order to confirm the tandem arrangement of the integrated copies of pADC-8 plasmid, we performed two different digestion reactions of DNA from para-sites, harvested after 6 months of transfection, with the restriction enzymes SstII or BstBI, each with a single cutting site near the 5¢ or the 3¢ end of the pADC-8 sequence, respectively, but outside the ADC ORF After hybridization of the digestion products with the ADC-specific probe, both experiments showed a com-mon hybridizing fragment similar in size to that of the pADC-8 plasmid ( 7.9 kbp), as depicted in Fig 4A This result strongly supports the conclusion that the stable transformed protozoa contain two or more cop-ies of plasmid pADC-8 in a head-to-tail tandem integ-rated without rearrangements nor gaps The additional

23 kbp-labelled band, seen in lane 2, was probably caused by the fact that the restriction enzyme, BstBI, only produced partial digestion of the DNA samples

On the other hand, the absence of a second hybridiza-tion band in lane 1 might be the result of insufficient sensitivity of our assay Rehybridization of the mem-brane shown in Fig 4A with a labelled probe specific for the neomycin-resistance gene gave the same

Fig 3 Genome organization of transformed Trypanosoma cruzi assayed by PCR amplification (A) or by Southern hybridization after digestion with restriction enzymes (B) (A) Total DNA was prepared from transgenic parasites harvested after different times of transfection Each DNA sample was used as template in PCR amplification reactions with two pairs of primers – (a) T7 and ADC2, and (b) T7 and RIB – under the conditions described in the Experimental procedures PCR products were analysed by electrophoresis on agarose gels containing ethi-dium bromide and observed under UV light Lanes 1 and 2 correspond to the assay carried out with DNA from untransformed wild-type

T cruzi as template; lanes 3 and 4, correspond to the assay carried out with purified recombinant plasmid pADC-8; and lanes 5–14 corres-pond to the assay carried out with DNA samples obtained from transformed parasites after 2 days and 2, 4, 6 and 24 weeks after transfec-tion Lanes 1, 3, 5, 7, 9, 11 and 13 show the PCR products obtained using the primer pair T7 and RIB Lanes 2, 4, 6, 8, 10, 12 and 14 show the PCR products obtained using the primer pair T7 and ADC2 Lane 15, 1 kb DNA ladder standard (B) DNA obtained from arginine decarb-oxylase (ADC)-transformed parasites harvested 6 months after transfection was completely digested with NheI or SalI restriction enzymes After gel electrophoresis, the digestion products were blotted onto a nylon membrane and hybridization analysis was carried out with the radioactive ADC-specific probe Southern hybridization bands correspond to digestion with NheI (lane 1) or SalI (lane 2).

active bands (Fig 4B), providing further support for

the integration of entire molecules of the transforming

plasmid, pADC-8

To investigate further the fate of the transforming

plasmid after electroporation and the integration site

within the parasite genome, we performed pulse-field

gel electrophoresis (PFGE) of chromosomes obtained

at different time-points after parasite transformation,

followed by hybridization assays with the ADC-specific

probe The results were in complete agreement with

those obtained by PCR and restriction digestion

experiments shown in Fig 3A,B Early after

electropo-ration, the ADC gene appeared almost exclusively in a

hybridization band at the origin of the gel, indicating

that the transforming plasmid remained as

extrachro-mosomal elements during this period (Fig 5A, lane 2)

It is relevant to mention that when a small amount of

purified pADC-8 plasmid was added to intact

wild-type parasites before the preparation of

chromosome-containing agar blocks for the PFGE experiments, we

obtained a very similar pattern of radioactive bands

after hybridization (Fig 5A, lane 5) One week after

transformation we were able to detect only a faint

band corresponding to the ADC gene at the origin of

the gel (Fig 5A, lane 3) suggesting an almost complete

destruction of free pADC-8 plasmid After 3 months, a

small amount of episome was still detectable and the

ADC gene was mainly at a radioactive band with the same mobility as the 1.4 Mbp parasite chromosome, which bears a ribosomal RNA locus, as shown in Fig 5A (lane 4) and Fig 5B [19] Therefore, insertion

of the exogenous gene was probably not specific at an ADC-like sequence, but rather targeted to the parasite ribosomal RNA locus by the ribosomal promoter region included in the vector pRIBOTEX [18,19]

Effect of a-amanitin on exogenous ADC

transcription in transformed T cruzi

We also studied the a-amanitin sensitivity of the ADC gene transcription For this purpose we carried out dot-blot hybridization analyses with membranes con-taining DNA spots (5 lg each) corresponding to inter-nal fragments of ADC or cruzipain genes The latter (used as a control) is a housekeeping gene that encodes the main cysteine proteinase of T cruzi [20] Prelimin-ary experiments have shown that transcription of the

Fig 4 Arrangement of plasmid pADC-8 copies integrated into the

transformed parasite genome DNA from stably transformed

para-sites collected 6 months after transfection was digested with the

restriction enzymes SstII (lane 1) or BstBI (lane 2) After gel

electro-phoresis of the digestion products and blotting onto a nylon

mem-brane, hybridization analysis was performed with the specific

probes for arginine decarboxylase (ADC ) (A) or neomycin-resistance

(neo) (B) genes All other details are as described in the

Experimen-tal procedures.

Fig 5 Southern blot analysis of chromosomes prepared from untransformed and transformed parasites collected at different time-points after transfection Trypanosoma cruzi chromosomes were separated by pulse-field gel electrophoresis (PFGE) and analysed by Southern blot hybridization with labelled arginine decarboxylase (ADC) (A) or rRNA (B) specific probes Lanes 1, 2, 3 and 4 in panel A correspond to parasites before transformation, or

48 h, 1 week or 3 months after transfection, respectively Lane 5 is

a control of chromosomes from wild-type parasites with the addition

of 10 ng of purified pADC-8 plasmid Panel B shows a duplicate of lane 4 in panel A hybridized with the radioactive rRNA 24Sa probe.

cruzipain gene is inhibited by a-amanitin (I D

Algra-nati, unpublished results) The hybridization assays

were performed with radioactive RNA synthesized by

transformed parasites that were permeabilized and

then incubated in the presence of different

concentra-tions of a-amanitin Figure 6 shows that transcription

of the ADC gene did not decrease, even at very high

levels of a-amanitin (500 lgÆmL)1), while the synthesis

of cruzipain mRNA was markedly reduced It has

been reported that trypanosomes contain three

differ-ent RNA polymerases: RNA Pol I (which synthesizes

ribosomal RNA); RNA Pol II (responsible for the

transcription of most protein-coding genes); and RNA

Pol III (which transcribes tRNA and 5SRNA) RNA

Pol II is the only one sensitive to a-amanitin [21]

According to these data, our results strongly suggest

the involvement of RNA Pol I in ADC gene

transcrip-tion and RNA pol II in cruzipain transcriptranscrip-tion Our

conclusion, that the ADC gene of transformed

para-sites was transcribed by RNA Pol I, is also in

agree-ment with the fact that the transforming plasmid

bearing the foreign gene contains a strong rRNA pro-moter region

Conclusions

Our studies, on the modulation of oat ADC gene expression in T cruzi epimastigotes, have shown an early period of transient expression during which the transforming recombinant plasmid remained as a free element undergoing transcription and translation (Figs 1 and 3) This episome was probably almost completely degraded between 2 and 4 weeks after transfection However, the continuous selection pres-sure of the antibiotic, G418, allowed stable expression

of the ADC gene, presumably after recombination and integration into the parasite genome of two or more pADC-8 copies arranged in tandem ADC transcripts and the corresponding enzymatic activities followed a similar pattern of modulation (Fig 1) When the selec-tion drug, G418, was omitted after parasite transfor-mation, we could only detect transient expression of the ADC gene

Previous results obtained in our laboratory with the ODC gene, and data reported by other authors with several genes, have indicated a fast plasmid integration after transfection when using the same pRIBOTEX or

a related expression vector, pTREX [18,19] On the contrary, in the present work we found a late plasmid integration into the T cruzi genome and a concomit-ant stable gene expression, despite the fact that we also used the pRIBOTEX vector We speculate that an as-yet not well understood mechanism requiring plasmid duplication during integration, the particular structure of plasmid pADC-8 and⁄ or the involvement

of putative intermediate forms of the transforming plasmid might explain the different pattern of expres-sion observed in our experiments

Experimental procedures

Materials and reagents Brain–heart infusion, liver infusion broth, tryptose and yeast extracts were obtained from Difco Laboratories (Detroit,

MI, USA) Minimal essential medium (SMEM), amino acids and vitamins were obtained from Gibco BRL (Gaithersburg,

MD, USA) Bases, haemin, pyridoxal 5¢-phosphate, poly-amines, Hepes buffer and antibiotics were purchased from Sigma (St Louis, MO, USA) Fetal calf serum was from Natocor (Carlos Paz, Cordoba, Argentina), and L-[U-14C] arginine (305 CiÆmol)1), [32P]dCTP[aP] (3000 CiÆmmol)1) and [32P]UTP[aP] (3000 Ci mmol)1) were from Amersham Life Sciences (Bucks., UK)

Fig 6 Sensitivity to a-amanitin of the transcription of arginine

decarboxylase (ADC) and cruzipain genes in transformed

Trypano-soma cruzi Permeable parasites were preincubated at 0
C for

5 min in the absence or presence of different concentrations of

a-amanitin Transcription was performed for 30 min at 30
C in the

presence of [ 32 P]UTP[aP], and purified radioactive RNA was

ana-lysed by dot-blot hybridization, as described in the Experimental

procedures The amount of specific RNA hybridized to each dot

was measured by scintillation counting and expressed as a

percent-age of the corresponding value obtained in the absence of

a-aman-itin ADC-specific (s) or cruzipain-specific (d) transcripts All values

are the average of experiments carried out in duplicate.

Parasite cultures

T cruziepimastigotes, strains Tulahuen 2 [22] and RA [23],

were cultured at 28
C in rich (BHT) or semidefined

(SDM-79) media [6] supplemented with haemin (20 mgÆL)1), 10%

(v⁄ v) heat inactivated fetal bovine serum and antibiotics

(100 lgÆmL)1streptomycin and 100 UÆmL)1penicillin)

Parasite growth was followed by cell counting The

doub-ling time for wild-type T cruzi proliferation was 18–24 h

All cultures were diluted weekly to 8–12· 106

cellsÆmL)1 using fresh medium with the indicated additions

Parasite extracts and ADC assay

T cruzi were harvested by centrifugation for 5 min at

3500 g, and after washing with NaCl⁄ Pi they were

resus-pended at 1· 109 cellsÆmL)1 in the reaction solution

con-taining 50 mm Hepes buffer, pH 7.5, 0.5 mm EDTA, 1 mm

dithiothreitol and 0.1 mm pyridoxal 5¢-phosphate Cells

were disrupted by three cycles of freeze–thawing, followed

by a brief sonication to break the DNA After

centrifuga-tion at 12 000 g for 15 min at 4
C, the supernatant fluid

was used to measure the enzyme activity in a total volume

of 50 lL with the addition of radioactive arginine

(0.25 lCi, 1 mm final concentration) All measurements of

ADC activity were carried out using cell extracts from

transformed T cruzi collected at the early or

mid-logarith-mic phase of growth (cell concentration 20–30· 106

para-sites per mL), as the enzymatic specific activity decreased

markedly at late exponential or stationary phase (I D

Algranati, results not shown) Therefore, ADC activities

were obtained using parasite cultures diluted with fresh

medium, to 10–15· 106 cells per mL, 24 h before the

collection of each sample The enzymatic assays were

carried out under linear conditions for protein

concentra-tion and reacconcentra-tion time ADC activities were calculated by

measuring the radioactive CO2 released during the

reac-tions [24] Protein concentrareac-tions of enzyme preparareac-tions

were determined by Bradford’s method [25], with BSA as

the standard

Construction of the recombinant plasmid pADC-8

and parasite transfection

A cDNA fragment containing the complete coding region

of the oat ADC gene was cloned in the pRIBOTEX

expres-sion vector [18], as previously described [10] The

recombin-ant plasmid pADC-8 (with the ADC coding region inserted

in the sense orientation) was selected after analysis by

restriction mapping and nucleotide sequencing Wild-type

T cruzi epimastigotes collected at the early exponential

phase of growth were transfected by electroporation using

3· 108

parasites resuspended in 350 lL of liver infusion

tryptose medium [26] without fetal bovine serum After the

addition of 20–100 lg of pADC-8 recombinant plasmid, electroporation was performed essentially as described by Hariharan et al [27] using 2 mm gap cuvettes Parasites were then diluted with rich medium containing 10% fetal calf serum and incubated at 28
C for 48 h before the addi-tion of G418 (500 lgÆmL)1) in order to select transformed

T cruzi during the subsequent period of culture Control electroporation assays were carried out with buffer solution

or pRIBOTEX vector instead of the recombinant plasmid Samples of parasite culture were collected at different time-points after electroporation to measure ADC enzymatic activities and to prepare DNA and RNA for hybridization analyses

Southern and northern blot hybridization Total DNA from wild-type and transformed parasites was prepared according to Medina-Acosta & Cross [28] With this method it is possible to recover genomic DNA as well

as free episomes After digestion with different restriction enzymes, the DNA fragments were separated by electro-phoresis on 1% agarose gels and transferred to nylon mem-branes (Hybond N+; Amersham)

Total RNA from parasites, before and after transforma-tion, was obtained using TRIzol LS reagent (Invitrogen, Carlsbad, CA, USA) [29] Samples containing 20 lg of total RNA were fractionated by electrophoresis on a 1% agarose gel, containing 2.2 m formaldehyde, and blotted onto nylon membranes

Southern and northern hybridization assays were per-formed with 32P-labelled probes specific for oat ADC [10], ribosomal RNA or neomycin resistance (neo) genes The radioactive specific probe for the latter gene was prepared

by PCR amplification with the plasmid pADC-8 as tem-plate and the forward and reverse primers pNeo 1 (5¢-CCGGAATTCTGAATGAACTGCAGGACGAGGCAG-3¢) and pNeo 2 (5¢-CCGGAATTCCGGCCATTTTCCACCAT GATATTC-3¢), respectively The labelled probe specific for rRNA 24Sa was obtained by PCR amplification of a DNA segment of this gene with the forward and reverse primers 75 (5¢-GCAGATCTTGGTTGGCGTAG-3¢) and

76 (5¢-GGTTCTCTGTTGCCCCTTTT-3¢), respectively, kindly provided by A Schijman (INGEBI, Buenos Aires, Argentina)

PCR analyses of DNA from transformed T cruzi Samples containing 50–100 ng of total DNA prepared from parasites collected at different time-points after electropora-tion were amplified by PCR using two sets of primers: (a) the forward primer T7 promoter primer (Promega, Madison,

WI, USA) and the reverse primer ADC2 (5¢-CCGGAATT CCAGCTTGGAAGAGAGATCGCGGAT-3¢) with a nuc-leotide sequence complementary to an internal segment of

the ADC coding region [30], and (b) T7 primer and the

reverse primer, RIB, complementary to an internal sequence

of a parasite ribosomal RNA locus [19] PCR amplifications

were performed for 30 cycles at the following cycle

parame-ters: 94
C, 30 s; 50
C, 1 min; and 72
C, 2 min PCR

prod-ucts were separated by electrophoresis on agarose gels and

detected by ethidium bromide staining

PFGE

Agarose blocks containing 2· 107 untransformed or

transformed parasites harvested at different time-points

after transfection were prepared as described by Cano

et al [31], and chromosomes were separated by PFGE in

a Bio-Rad Lab (Hercules, CA, USA) apparatus using 1%

agarose gels, 0.5· TBE electrophoresis buffer (89 mm

Tris-borate, pH 8.2, 2 mm EDTA) and the running

condi-tions indicated by Lorenzi et al [19] After blotting onto

nylon membranes (Hybond N+; Amersham), hybridization

analyses were carried out with radioactive probes specific

for oat ADC or rRNA 24Sa genes

Transcription in transformed T cruzi

Parasites collected at the early logarithmic phase of growth

6 months after transfection with the pADC-8 recombinant

plasmid were permeabilized with

palmitoyl-l-a-lysophos-phatidylcholine (Sigma), as previously described [32,33]

After transcription in the presence of [32P]UTP[aP] and

dif-ferent concentrations of a-amanitin, radioactive RNA was

isolated [29] and then hybridized to dot-blots prepared with

5 lg of DNA segments corresponding to ADC [10] or

cruzi-pain [20] genes The latter DNA was obtained by PCR

amplification using a recombinant plasmid containing the

cruzipain gene as template and primers A (5¢-ATGT

CTGGCTGGGCGCG-3¢; forward) and B (5¢-GAGGCG

ACGATGACGGC-3¢; reverse) Radioactive spots on the

membranes were cut and counted in a scintillation counter

Acknowledgements

We thank Dr Sara H Goldemberg for helpful

discus-sions and Edith Trejo and Carlos Zadikian for

techni-cal assistance We are indebted to Drs J J Cazzulo

and C Labriola for their generous gifts of a

cruzipain-containing plasmid and primers A and B This work

was partially supported by grants from The National

Research Council (CONICET, Argentina) and the

University of Buenos Aires

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