Nepal Journal of Biotechnology. D e c .  2 0 1 5  Vol. 3, No. 1:22-28    ISSN 2091-1130 (Print) / ISSN 2467-9319 (online) 

 

ORIGINAL RESEARCH ARTICLE 

©NJB, Biotechnology Society of Nepal   22       Nepjol.info/index.php/njb 

Heat Shock Protein 70 (HSP70) Expression in Antimony 
Susceptible/Resistant Clinical Isolates of Leishmania donovani 

Mahendra Maharjan1,2* and Rentala Madhubala2 
1Central Department of Zoology, Tribhuvan University, Kirtipur, Kathmandu, Nepal 

2 School of Life Sciences, Jawahar Lal Nehru University, New Delhi, India 

Abstract  
Pentavalent antimonials have long been the first line of defence against leishmaniasis, but resistance has been 
reported in different parts of the world. Pentavalent antimony is reduced into trivalent form in the cells and is 
a potential inducer of HSP70 in L. donovani. Expression profile of HSP70 in antimony susceptible and resistant 
L. donovani isolates were characterized by Southern blot, Northern blot and western blot analysis. HSP70 gene 
copy number, gene expression and HSP70 protein expression was found uniform in both antimony sensitive 
and resistant clinical isolates. In laboratory condition, Leishmania cells respond to antimonial drug stress by 
three fold over expression of the HSP70 protein. The observed results indicated that HSP70 play important role 
in stress tolerance against antimonial drug without differential expression in antimony sensitive and resistance 
clinical isolates of L. donovani. 

Keywords: Pentavalent antimony; HSP70; visceral leishmaniasis; drug resistance; PFGE; hybridization 

*Corresponding Author 
Email: mmaharjan@cdztu.edu.np 

Introduction 
Visceral leishmaniasis is a protozoan parasitic disease 

caused by Leishmania donovani. Leishmaniasis 

constitutes a major public health problem with 

increasing pattern of disease burden [1,2]. It is a 

neglected tropical disease (NTD) which affects mainly 

the poor population groups, primarily in rural areas. 

Unfortunately, there is still lack of effective, affordable 

and easy-to-use drugs for leishmaniasis treatment. 

Since vaccine against leishmaniasis is still under 

development, the control lies solely on chemotherapy 

[3]. However, emergence of drug resistance in parasitic 

protozoa is becoming a major public health problem. 

Heat shock proteins (HSPs) are highly conserved 

proteins found in both prokaryotic and eukaryotic 

cells. HSP70 is a molecular chaperone which plays an 

important role in protein folding and assembly of 

polypeptides within the cell. When cells are exposed to 

the stressed condition, the proportion of misfolded 

proteins (MFPs) suddenly increases and the cell reacts 

by synthesizing HSPs to assist those proteins in 

refolding. The stress response is controlled primarily at 

the transcription level by a heat shock factor (HSF) [4].  

It has been shown that transcript level of HSP70 

increased in L. major and in L. infantum, in response to 

elevated temperature conditions [5, 6, 7]. Besides 

elevated temperature, metals are also known to be 

important stress inducers in the cells. Antimonial 

compounds; Pentostam and Glucantime are still the 

drug of choice in the treatment against all forms of 

Leishmania infections [8, 9]. Since, antimonial drug 

resistance is becoming a common problem in many 

leishmaniasis endemic regions, extensive studies have 

been carried out to investigate the mechanism of drug 

resistance in the laboratory mutants. One of the 

mechanisms of resistance is postulated to be HSP70. L. 

tarentolae cells transfected with HSP70 gene showed 

resistance to SbIII or arsenite [10]. This suggests that 

HSP70 has a role in antimony resistance mechanism. In 

the present study, we have characterized the 

expression of Heat Shock Protein 70 in antimony 

sensitive and resistant clinical isolates of L. donovani. 

Materials and Methods 
Parasite and culture condition 
 Promastigotes of Indian Leishmania donovani clones 

AG83-S (MHOM/IN/1983/AG83), GE1 (MHOM/IN 

/80/ GE1F8R) and three untyped strains 2001, NS2, 

and 41 were isolated from patients with visceral 

leishmaniasis (VL) and were routinely cultured at 22C 

in M-199 medium (Sigma, USA) supplemented with 

10% heat inactivated fetal bovine serum (FBS, 

Gibco/BRL, Life Technologies, Scotland, UK) and 13 

mg/ml penicillin and streptomycin (Sigma, USA) [11]. 



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Clinical isolates obtained from VL patients who 

responded to SAG chemotherapy were designated as 

SAG-S (SAG sensitive) whereas VL patients that did 

not respond to SAG were designated as SAG-R (SAG 

resistant). Accordingly, SAG sensitive isolate used in 

this study is 2001-S whereas the four SAG-R isolates 

are 41-R, NS2-R, and GE1-R. The SAG-resistant isolates 

were maintained in the absence of drug pressure in 

vitro. The isolates have been passage through hamsters 

or BALB/c mice to retain their virulence and 

importantly their chemo-sensitivity profiles have 

remained unchanged.  

Cloning of heat shock protein 70 (HSP70) 

gene from L. donovani. 
 A 1962-bp DNA fragment was amplified from the 

genomic DNA using a sense primer with a flanking 

BamHI site, 5’-

CGCGGATCCATGACATTCGACGGCGCCATC-3’, at 

position 1-21, and the antisense primer with a flanking 

HindIII site, 5’ – 

CCCAAGCTTTTAGTCGACCTCCTCGACCTTGG – 3’, 

including the stop codon, at position 1939-1962. 

Polymerase chain reaction (PCR) was performed in 50 

µl reaction volume containing 100 ng of genomic DNA, 

25 pmol each of gene-specific forward and reverse 

primers, 200 µmol of each dNTP, 2 mM MgCl2, 5U Taq 

DNA polymerase (MBI Fermentas) and 5% DMSO. The 

PCR conditions were as follows: 940C for 10 min, 940 C 

for 45 sec, 620C for 30 seconds, 720C for 2 min and 35 

cycles. Final extension was carried for 10 min at 720. A 

single 1.9 kb PCR product was obtained and cloned 

into the BamHI - HindIII site of pET-30a (Figure 1) 

vector (Novagen). The recombinant construct was 

transformed into BL21 (DE3) strain (Figure 2) of 

Escherichia coli and subjected to automated sequencing..  

Expression and purification of HSP70 

protein. 

Expression of HSP70 protein from the construct 

pET30a - LdHSP70 was induced at OD of 0.7 with 50  

µM, 100 µM and 500 µM isopropylthiogalactoside 

(IPTG) (Sigma) at 37C for different time periods. All 

the steps of purification were carried out at 4C as 

mentioned in general materials and methods. 

 

 
Figure 1: Restriction map of vector pET-30a(+).The HSP70 

PCR product (1.9 kb) was cloned into the BamHI and HindIII 

restriction site of pET-30a vector. 

 
Figure 2 : Cloning strategy of heat shock protein (HSP70) in 

pET-30a expression vector 

Protein determination 
Protein concentration was determined by Bradford’s method 

using bovine serum albumin (BSA) as standard [12]. 

Antibody production 
The purified recombinant HSP70 protein (20 µg) was 

subcutaneously injected in mice using Freund’s complete 



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adjuvant followed by two booster doses of recombinant 

HSP70 protein (15 µg) with incomplete adjuvant at two-

week intervals to produce the polyclonal antibody against 

the recombinant HSP70 protein. The mice were bled two 

weeks after the second booster dose and sera was collected 

for Western blot analysis.  

Isolation of genomic DNA and total RNA. 
 Genomic DNA was isolated from ~ 2 x 109 cells from 

10-15 ml culture (mid log phase promastigotes) as 

described in general materials and methods.  5 µg of 

genomic DNA was digested overnight with HindIII 

and subjected to electrophoresis in 0.8% agarose gels. 

The gel was run at a constant voltage of 30V overnight. 

Total RNA was isolated from 2  108 promastigotes 

using TRI reagentTM (Sigma) according to 

manufacturer’s instructions. The isolated RNA was 

stored in diethyl pyrocarbonate (DEPC) treated water 

in small aliquots at –800C. For Northern blot analysis, 

15 g of total RNA was fractionated by denaturing 

agarose gel electrophoresis and transferred to nylon 

membrane following the standard procedure.  

Pulse Field Gel Electrophoresis (PFGE) 

Leishmania chromosomes were separated by PFGE. 

Low melting agarose blocks, containing embedded 

cells (108 log phase promastigotes/ml) were 

electrophoresed in a contour clamped homogenous 

electric field apparatus (CHEF DRIII, Bio-Rad) in 0.5  

TBE with buffer circulation at a constant temperature 

of 14ºC. Saccharomyces cerevisiae chromosomes were 

used as chromosomal size markers. Pulse field gel 

electrophoresis (PFGE) running conditions were as 

follows: initial switch time, 60 s; final switch time, 120 

s; run time, 24 h; current 6V/cm; including angle 120º. 

The transfer of PFGE separated chromosomes from 

agarose gels to nylon membrane was achieved by 

capillary method as described by [13]. 

Hybridization of Northern, Southern and PFGE blot 

Pre-hybridization was done at 65°C for 4 hours in a 

buffer containing 0.5 M sodium phosphate; 7% SDS; 

1mM EDTA (pH 8.0) and 100 µg/ml sheared 

denatured salmon sperm DNA. The blots were 

hybridised with denatured α-[P32]-dCTP-labelled DNA 

probe (PCR probe described for the L. donovani HSP70 

coding region) at 106cpm/ml. The probe was labeled 

by random priming (NEB Blot®Kit, New England 

Biolabs, Inc.). Membranes were washed sequentially as 

follows: 2 SSC, 0.1% SDS; 1 SSC, 0.1% SDS; 0.5 SSC, 

0.1% SDS; 0.2 SSC, 0.1% SDS for 10 min each at 65°C 

until the non-specific counts had substantially reduced. 

Membranes were air-dried and exposed to imaging 

plate. The image was developed by PhosphorImager 

(Fuji film FLA-5000, Japan) using Image Quant 

software. 

Western blot analysis 

Late log phase promastigotes (1  108) were harvested 

and the resultant cell pellet was lysed by sonication 

and cell supernatants were prepared by centrifugation 

at 20,000 x g. 50 µg of protein from each cell line were 

fractionated by SDS-polyacrylamide gel 

electrophoresis and blotted on nitrocellulose 

membrane using electrophoretic transfer cell (BIO-

RAD). Western Blot analysis was done using the ECL 

kit (Amersham Pharmacia Biotech) according to the 

manufacturer’s protocol. Polyclonal antibody to 

purified recombinant L. donovani HSP70 generated in 

mice was used for the Western blot analysis. 

Autoradiograms were analyzed by using model FLA 

5000 imaging densitometer (Fuji, Japan). The results 

shown are from a single experiment typical of at least 

three giving identical results. 

Results 
Heat shock protein 70 (HSP70) sequence 
analysis 
The gene encoding the heat shock protein 70 kDa 

(HSP70) nucleotide sequence was retrieved from 

EMBL sequence data bank under the accession no. 

X52314. In order to clone the full length gene encoding 

HSP70, polymerase chain reaction (PCR) was 

performed using specific oligonucleotides. The sense 

primer was 5'-CGCGGATCCATG 

ACATTCGACGGCGCCATC-3’ at position 1-21 and 

the antisense primer with a flanking HindIII site, 5’-

CCCAAGCTTTTAGTCGACCTCCTCGACCTTGG- 3’ 

including the stop codon at position 1939-1962. 

Genomic DNA from L. donovani AG83 

(MHOM/IN/1983/AG83) promastigotes was used as 

a template. A single full length 1962-bp PCR product 

was obtained. The PCR fragment was purified from the 

gel and double digested with BamH1 and HindIII 

restriction enzymes. The digested product was ligated 

with pET30a cloning vector at 160C overnight. The 

ligated product was transformed into DH5α competent 

cells. The positive clones were confirmed by colony 

PCR. Further, the cloned HSP70 PCR fragment was 

confirmed by sequencing. A single open reading frame 

consisting of 1962-bp was isolated. No variation in the 

coding sequence was found from the sequence 

described earlier. 



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Over-expression and purification of full-
length L. donovani HSP70 in E. coli 
 In order to overexpress and purify recombinant 

protein, the encoding L. donovani HSP70 sequence was 

cloned inframe in pET-30a expression vector. The 

resultant pET-30a -LdHSP70 construct was 

transformed into E. coli and protein over expression 

was induced using IPTG (Figure 3A and 3B) as 

described in general materials and method. A protein 

with a molecular weight that matched the estimated 70 

kDa according to amino acid composition of L. 

donovani HSP70 with His6 tag and S-tag present at its 

N-terminal end was also induced. The recombinant 

protein was purified by Ni2+-NTA affinity 

chromatography column  Purification of His-tagged L. 

donovani HSP70 by metal affinity chromatography 

(Figure 3C) yielded ~200 µg of purified protein from 1-

litre bacterial culture. 

 
Figure 3: Overexpression and purification of L. donovani HSP70 
protein. (A) Coomassie blue staining of SDS–PAGE showing 
overexpression of full-length L. donovani HSP70 protein in E. coli. The 
pET-30a bacterial extract before induction (lane 2 and 6) and after 
induction (lanes 3-5 and 7-9) of two positive clones at 1, 2, and 3 h, 
respectively with 1 mM IPTG. Arrow shows the induced 
recombinant HSP70 protein. Broad range protein MW marker (MBI-
Fermentas) was used to identify the size of the recombinant protein 
(Lane 1). ( B) The pET30a bacterial extract before induction (lane 1), 
molecular marker (lane 3) and three hour after induction (lane 2, 4, 5 

and 6) with 50 M, 100 M, 200 M and 500 M  IPTG respectively. 
(C) Purification profile of soluble form of HSP70 protein by Ni- NTA 
affinity bead affinity chromatography resin. Lane 1 flow through, 
lanes 2 and 3, washes with 20 mM and 60 mM immidazole, Lane 4-7 
elutes using 100 mM, 150 mM, 200 mM, and 250 mM immidazole, 
Lane 8 Ni- beads, lane 9- blank. All the purification fractions were 
run along with the molecular weight protein marker (lane M). 

Polyclonal antibody production and 

Western blotting 
Western blot using size-fractionated parasite protein, 

antiserum could detect a band of anticipated L. 

donovani HSP70 size ~70 kDa in promastigote extracts.  

In antimony resistant L. tarentolae mutants, HSP70 was 

reported to increase more than 4-fold compared to the 

wild-type cells [10]. The overexpression of HSP70 

remained stable in L. tarentolae mutants after several 

hundreds of passages without drug [10]. To test the 

link between HSP70 expression and resistant 

phenotype in antimony resistant L. donovani field 

isolates, we performed Western blot analysis using 

polyclonal antibody. A Western blot using equal 

amount of parasite protein (50 µg each) extract from 

antimony sensitive (AG83-S and 2001-S) and resistant 

(GE1-R, 41-R and NS2-R) field isolate did not show any 

differential expression of HSP70 protein (Figure 4).  

 
Figure 4. Western blotting using anti-His-HSP70 antibody raised 

against LdHSP70 in BALB/C mice. HSP70 protein in fractionated 
extracts obtained from SAG-S and SAG-R cultures harvested after 48 

h of growth. The same blots were reprobed with antibody against β-

tubulin protein to normalize the loading on to each lane of the gel.  

Southern blot hybridization of HSP70 gene 
The copy number of HSP70 gene varies considerably 

among various Leishmania species [6, 10, 14]. To 

determine HSP70 gene copy number in L. donovani 

field isolates, Southern blot analysis was performed 

using 1.9 Kb HSP70 PCR product as a probe as 

described under general materials and methods. 

HindIII which digests outside the gene producing a 10 

kb restriction fragment (expected size) was used to 

check the copy number of the gene. The probe 

hybridized to a single fragment of 10 kb in all the field 

isolates (Figure 5) indicating that HSP70 exists as a 

single copy gene in these strains. Further, we checked 

the chromosomal localization of HSP70 gene by 

Southern blot hybridization of PFGE blot. The HSP70 

probe hybridized to a single chromosomal band of 1.2 

Mb region that corresponds to the chromosome 

number 28 of the L. infantum genome database (Figure 

6). 



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Figure 5. Southern blot analysis of HSP70 gene in SAG–S and SAG–R 
Leishmania donovani field isolates. Total genomic DNA of Leishmania 
strains were isolated and digested with HindIII restriction enzyme. 
The blot was probed with 1.9 Kb full length HSP70 gene. The blot 
was reprobed with α-tubulin to monitor the amount of digested DNA 
layered on the gel. 
 

  
Figure 6. PFGE analysis of SAG-S and SAG-R L. donovani isolates 
indicating chromosomal localization of HSP70 gene. Chromosomes 
of L. donovani isolates were separated by CHEF and Southern blots 
were hybridized with the HSP70 probe. The size of hybridizing band 
was identified using chromosomes of S. Cerevisae as marker 

 
Figure 7. Expression analysis of HSP70 gene in L. donovani Northern 

blot analysis of mRNA from SAG-S and SAG-R isolates (log phase 

culture). 15 µg of total RNA was loaded per lane, transferred and 

hybridized with HSP70 probe. A α-tubulin probe and was used to 

monitor the amount of RNA layerd on the gel. The rRNA stained 

with ethidium bromide was used to normalize the RNA loading.  

Northern blot hybridization of HSP70 gene  
Since, we couldn’t find any difference in HSP70 protein 

expression and copy number of gene in between SAG-

S and SAG-R L. donovani field isolates, we checked 

transcript level of HSP70 gene expression. Northern 

blotting of SAG-S and SAG-R L. donovani field isolates 

revealed a single transcript of ~ 3.5 kb in all the strains 

(Figure 7). Densitometric analysis of hybridizing bands 

corresponds to the internal control α-tubulin showed 

similar expression of HSP70 gene in between SAG 

sensitive and resistant field isolates. 

Induction of HSP70 by SbIII in promastigote 
of L. donovani field isolate 
Leishmania cells respond to SbIII exposure by 

increasing HSP70 protein [10]. Induction of HSP70 was 

found more than four (>4) fold in L. tarentolae and L. 

infantum cells when incubated for 24 hours at IC50 

concentration of the drug [10]. To test whether strain 

were incubated with 15 µM (IC50 concentration of 

AG83-S) SbIII for 24 hours. A time dependent increase 

of HSP70 protein expression in L. donovani field isolates 

was observed. Protein expression increased by more 

than > 1.7 fold at 12 hours and more than three (>3) 

fold after 24 hours compared to the cells incubated 

without drug (Figure 8A and 8B). 

trivalent antimony could induce the expression of 

HSP70 protein in L. donovani field isolates, we used 

polyclonal antibody raised against HSP70 antigen in 

BALB/C mice. Promastigotes of L. donovani (AG83-S) 

Discussion 
Physiological role of the HSP70 as a molecular 

chaperon has been well described [15]. Induction of 

HSP70 can protect cells by binding to misfolded 

proteins in variety of adverse conditions [16]. Besides 

its physiological cytoprotective role an increased 

expres 

  
Figure 8. Effect of SbIII on HSP70 protein expression at different time 
points. (A) Western blot analysis of HSP70 in L. donovani 
promastigotes after treatment with 15 µM SbIII for 0 h, 12 h and 24 h. 
The same blot was reacted with antibody against β-tubulin protein to 
normalize the loading on to each lane of the gel. (B) Densitometric 
scanning of the western blot in A. The bands were quantified by 
scanning on a densitometer and fold difference in signal intensities 
relative to the zero control were plotted.  



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expression of HSP70 protein in antimony resistant L. 

tarentolae and L. infantum laboratory mutants and the 

increased expression of HSP70 was stable after 

hundreds of passages without the drug [10]. If the 

linkage between HSP70 overexpression and antimony 

resistant phenotype observed in those laboratory 

mutants is also true for L. donovani field isolates, HSP70 

gene could be one of the important biomarker for 

monitoring antimony resistance in the field conditions. 

With this hypothesis we have cloned the HSP70 gene 

in bacterial expression vector, purified the recombinant 

protein and raised the polyclonal antibody against 

HSP70 antigen in BALB/C mice. We checked the 

HSP70 protein expression in two antimony sensitive 

(AG83-S and 2001-S) and three natural antimony 

resistant (41-R, CK2-R and NS2-R) L. donovani clinical 

isolates using Western blotting. We found constitutive 

expression of HSP70 protein in both SAG-S and SAG-R 

clinical isolates. No difference in HSP70 protein 

expression was observed in antimony sensitive and 

resistant field isolates.  

Further, we characterized the HSP70 gene in SAG-S 

and SAG-R L. donovani Indian field isolates to check the 

chromosomal localization and copy number of the 

gene. The copy number of HSP70 gene has been 

reported to be considerably varied among different 

trypanosomatids such as single copy in L. braziliensis, 2 

copies in L. tarentolae, 4 copies in L. major, 6 copies in L. 

infantum, 7 copies in L. amazonensis and T. cruzi [5, 6, 

10, 14, 17, 18]. In L. donovani Indian field isolates, the 

copy number of HSP70 gene was found to be single 

copy. No difference in gene copy number was 

observed in between SAG-S and SAG-R field isolates.  

To further verify the HSP70 gene amplification, we 

performed Southern blot hybridization of PFGE blot. 

HSP70 probe hybridized to a highly amplified single 

band at the 1.2 Mb region which corresponds to the 28 

chromosome of the L. infantum genome database.  

Transcript level of the HSP70 gene has been shown to 

be transiently induced by environmental stress such as 

exposure to heat shock or heavy metals [19]. During 

heat shock, HSP70 transcription rate increases rapidly 

and then decline slowly [20]. Increased HSP70 

transcript level has been shown in Leishmania when 

cells were exposed to heat [6]. The transcription 

mechanism has shown to be controlled at the 

posttranscriptional level specifically by the 3’-

untranslated region of the gene in contrast to most 

other organisms [7, 21]. Similar regulation has also 

been described in the related parasite T. brucei [5]. 

Increased expression of HSP70 has been reported in 

antimony resistant L. tarentolae and L. infantum mutants 

compared to wild type cells [10]. The increased 

expressions of HSP70 in laboratory mutant were found 

to be stable after hundreds of passages without the 

drug [10]. Earlier studies indicated that HSP70 

overexpression in antimony resistant mutants was the 

stable phenotype. To check whether similar 

mechanism is operating in field condition, we 

performed Northern blot hybridization of HSP70 gene 

in between natural antimony resistant L. donovani 

clinical isolates to that of the antimony sensitive 

parasites. No difference in HSP70 transcript level was 

found between SAG-S and SAG-R clinical isolates.  

Arsenite and Sb III have been described as the known 

inducer of the HSP70 in Leishmania [10, 22, 23]. By gene 

transfection experiment, it has been shown that HSP70 

contribute first line of defense against Sb III [10] 

suggesting the role of HSP70 in antimonial drug 

resistance. In the present study, we checked HSP70 

protein expression in promastigotes of L. donovani 

(AG83-S) in presence of Sb III. Interestingly, we could 

find considerable over expression of HSP70 protein 

when cells were incubated in IC50 concentration of Sb 

III. Protein over expression was about 1.7 fold at 12 

hours that increased up to 3 fold at 24 hours time 

period. The observed results suggest that Leishmania 

cells respond to antimonial drug stress by over 

expression of the HSP70 protein. 

Acknowledgements  
The authors thank University Grants Commission, 

New Delhi, India for providing JRF/SRF to Mahendra 

Maharjan to conduct this study. 

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