Báo cáo khoa học: Human recombinant prolidase from eukaryotic and prokaryotic sources Expression, purification, characterization and long-term stability studies pptx
Tài liệu hạn chế xem trước, để xem đầy đủ mời bạn chọn Tải xuống
1
/ 13 trang
THÔNG TIN TÀI LIỆU
Thông tin cơ bản
Định dạng
Số trang
13
Dung lượng
708,83 KB
Nội dung
Humanrecombinantprolidasefromeukaryotic and
prokaryotic sources
Expression, purification,characterizationandlong-term stability
studies
Anna Lupi*, Sara Della Torre*, Elena Campari, Ruggero Tenni, Giuseppe Cetta, Antonio Rossi and
Antonella Forlino
Department of Biochemistry ‘Alessandro Castellani’, University of Pavia, Italy
Extracellular and intracellular proteases perform essen-
tial functions in all living organisms by both mediating
nonspecific protein hydrolysis and acting as processing
enzymes that perform highly selective, limited and effi-
cient cleavage of specific substrates that influence many
biological processes. In recent years, the availability of
the human genome sequences, together with the devel-
opment of powerful tools, such as genomics, proteo-
mics and bioinformatics, has provided new possibilities
for investigating the degradome, the complete set of
proteases expressed at a specific moment or under cer-
tain circumstances by a cell, tissue or organism. In a
relatively recent review, Puerte et al. [1] listed 553
genes encoding proteases or homologous proteases in
Keywords
histidine tag; humanrecombinant prolidase;
long-term enzyme stability; on-column tag
removal; prolidase deficiency
Correspondence
A. Forlino, Department of Biochemistry
‘Alessandro Castellani’, Section of Medicine
and Pharmacy, University of Pavia, Via
Taramelli 3 ⁄ B, 27100 Pavia, Italy
Fax: +39 0382 423108
Tel : +39 0382 987235
E-mail: aforlino@unipv.it
*These authors contributed equally to this
work
(Received 27 June 2006, revised 10 October
2006, accepted 16 October 2006)
doi:10.1111/j.1742-4658.2006.05538.x
Prolidase is a Mn
2+
-dependent dipeptidase that cleaves imidodipeptides
containing C-terminal proline or hydroxyproline. In humans, a lack of
prolidase activity causes prolidase deficiency, a rare autosomal recessive
disease, characterized by a wide range of clinical outcomes, including severe
skin lesions, mental retardation, and infections of the respiratory tract. In
this study, recombinantprolidase was produced as a fusion protein with an
N-terminal histidine tag in eukaryoticandprokaryotic hosts and purified
in a single step using immobilized metal affinity chromatography. The
enzyme was characterized in terms of activity against different substrates,
in the presence of various bivalent ions, in the presence of the strong inhib-
itor Cbz-Pro, and at different temperatures and pHs. The recombinant
enzyme with and without a tag showed properties mainly indistinguishable
from those of the native prolidasefrom fibroblast lysate. The protein yield
was higher from the prokaryotic source, and a detailed long-term stability
study of this enzyme at 37 °C was therefore undertaken. For this analysis,
an ‘on-column’ digestion of the N-terminal His tag by Factor Xa was per-
formed. A positive effect of Mn
2+
and GSH in the incubation mixture and
high stability of the untagged enzyme are reported. Poly(ethylene glycol)
and glycerol had a stabilizing effect, the latter being the more effective. In
addition, no significant degradation was detected after up to 6 days of
incubation with cellular lysate. Generation of the prolidase in Escheri-
chia coli, because of its high yield, stability, and similarity to native proli-
dase, appears to be the best approach for future structural studies and
enzyme replacement therapy.
Abbreviations
CHO, Chinese hamster ovary; IMAC, Ni ⁄ nitrilotriacetate-immobilized metal affinity chromatography; PD, prolidase deficiency; PEG,
poly(ethylene glycol).
5466 FEBS Journal 273 (2006) 5466–5478 ª 2006 The Authors Journal compilation ª 2006 FEBS
the human genome and catalogued 53 diseases caused
by mutations in protease genes, mainly recessive loss
of function mutations. Our understanding of the path-
ophysiology of these diseases and the development of
therapeutic approaches are based on a knowledge of
the exact structure, function and regulation of the
pathologically relevant proteases under physiological
conditions.
Prolidase (EC 3.4.13.9) is a member of the metallo-
peptidase family, and the lack of prolidase activity,
due to mutations in the prolidase gene, is responsible
in humans for the recessive inherited disease prolidase
deficiency (PD). Patients with PD are characterized by
intractable skin ulceration, mainly on the lower limbs,
various levels of mental retardation, and recurrent
infections of the respiratory tract [2]. Sixteen mutations
have been described as causes of PD [3–17], but the
basis of the clinical outcome and the genotype ⁄ pheno-
type relationship are still unclear and no definitive cure
for the disease is available.
Prolidase is widespread in nature and has been isola-
ted from mammals [2], bacteria, such as Lactobacillus
[18] and Xanthomonas [19], andfrom the archeon
Pyrococcus furiosus [20]. Humanprolidase is a man-
ganese-dependent exopeptidase. It is a unique enzyme
being the only one able to hydrolyze the peptide bond
in iminodipeptides containing C-terminal proline or
hydroxyproline, because of the specific conformation
that the peptide chain assumes in the presence of the
pyrrolidine side chain of proline residues [21]. The
structure of prolidaseand its catalytic site, as well as
the catalytic mechanism of the mammalian enzyme,
have not yet been defined.
Prolidase is involved in the final stage of the cata-
bolism of proline-rich and hydroxyproline-rich dietary
and endogenous proteins, such as collagen. It supplies
and recycles proline for protein synthesis and cell
growth [2]. It has also been reported that prolidase
guarantees proline availability as a substrate for gener-
ating reactive oxygen species by proline oxidase during
proline-induced apoptosis [22–24]. Phang and cowork-
ers recently demonstrated that NO stimulates prolidase
activity and suggested an interaction between inflam-
matory signalling pathways and regulation of the ter-
minal step of matrix degradation [25].
Furthermore, prolidase has a biotechnological rele-
vance not related to its physiological function. It can
be used as a cheese-ripening agent, as proline released
from proline-containing peptides in cheeses reduces
their bitterness, making this enzyme particularly
appealing to the dietary industry [26]. It has also
been reported that prolidase is similar to organophos-
phorus acid anhydrolase which hydrolyses highly toxic
organophosphorus acetylcholinesterase inhibitors,
including various chemical warfare agents and pesti-
cides. This function makes the enzyme relevant in
detoxification strategies [27,28].
Here we describe the synthesis, purification and bio-
chemical characterization of humanrecombinant proli-
dase fromeukaryoticandprokaryotic hosts and
compare the enzyme with the endogenous prolidase of
human fibroblasts. The similarity of the recombinant
and endogenous prolidase in terms of substrate specif-
icity, optimal pH and temperature for activity, and
metal dependence is discussed, and a detailed analysis
of long-term enzyme stability at 37 °C is presented.
These properties are particularly important for struc-
tural studiesand developing strategies for enzyme
replacement therapy for PD.
Results
Recombinant humanprolidase expression and
purification fromeukaryoticand prokaryotic
sources
Total cellular RNA from cultured normal human
fibroblasts was reverse-transcribed, and prolidase
cDNA was amplified by PCR with specific primers.
The amplified product was subcloned into the eukary-
otic expression vector pcDNA4 ⁄ HisMax (pcDNA4 ⁄
HisMax-prol) and into the prokaryotic expression vec-
tor pET16b (pET16b-prol) (Fig. 1A,B).
Chinese hamster ovary (CHO) cells were transfected
using Lipofectamine. Stable transfected cells were
obtained after selection with Zeocin for 8 days.
Escherichia coli cells were transformed by heat shock,
following a standard protocol. Ampicillin was used as
antibiotic for selection.
CHO culture conditions were optimized to obtain
the highest yield of recombinant enzyme. For this,
2 · 10
6
stable transfected CHO cells were plated in
T175 flasks and harvested after 24, 48, 96 and 120 h at
37 °C and 5% CO
2
. We observed a progressive
increase in the total protein content over time
(0.19 mgÆmL
)1
at 24 h, 0.45 mgÆmL
)1
at 48 h,
4.8 mgÆmL
)1
at 96 h and 7.45 mgÆmL
)1
at 120 h), but
the highest prolidase activity was observed after 96 h
(3.42 lmol Gly-Pro idrolÆh
)1
ÆmL
)1
); all purifications
were therefore performed after 96 h of growth. As the
recombinant protein contained an N-terminal His tag
with 6 histidine residues, we used Ni ⁄ nitrilotriacetate-
immobilized metal affinity chromatography (IMAC)
with an imidazole step gradient from 50 to 500 mm to
purify the enzyme. Recombinantprolidase was elu-
ted at an imidazole concentration of 200–300 mm,
A. Lupi et al. Humanrecombinantprolidasefrom CHO and E. coli
FEBS Journal 273 (2006) 5466–5478 ª 2006 The Authors Journal compilation ª 2006 FEBS 5467
accounting for 14% of total prolidase activity. The
fractions containing the recombinant enzyme were dia-
lysed for 24 h against 50 mm Tris ⁄ HCl (pH 7.8) ⁄ 4mm
2-mercaptoethanol at 4 °C to eliminate imidazole and
NaCl, which acted as prolidase inhibitors at the con-
centrations used (data not shown).
The recombinant protein was identified by western
blotting using an HisG antibody (Fig. 2A,B). The
recombinant enzyme had a molecular mass of 58 kDa.
Escherichia coli BL21 (DE3) bacteria transformed
with the prokaryotic vector pET16b-prol, allowed us
to obtain large amounts of the recombinant enzyme;
from 1 L bacterial culture we purified about 8 mg
recombinant prolidase able to hydrolyze 18 g Gly-Pro
dipeptide in 1 h. Upon cell growth, bacteria were pell-
etted, lysed as described in Experimental procedures,
and loaded on to an IMAC column for purification as
the recombinant enzyme expressed in bacteria also had
an N-terminal His tag. Recombinantprolidase was
recovered at high imidazole concentrations (250 and
300 mm), because of the presence of 10 His residues in
the tag. We recovered about 20% of the total lysate
prolidase activity. Fractions containing the recombin-
ant enzyme were pooled and dialysed for 24 h against
50 mm Tris ⁄ HCl, pH 7.8, containing 4 mm 2-merca-
ptoethanol at 4 °C to eliminate imidazole and NaCl.
The elution fractions were analyzed by SDS ⁄ PAGE
with Coomassie Blue staining, and the purified protein
was identified by western blotting using an Penta-His
antibody (Fig. 2C–E). The recombinant enzyme had a
molecular mass of 57 kDa.
His-tag cleavage of recombinanthuman prolidase
To evaluate the influence of the His-tag on enzyme
activity and stability, we characterized the recombinant
A
BDE
C
Fig. 2. (A, C) Recombinanthumanprolidase purification. Elution profile of recombinantprolidase obtained from CHO (A) and E. coli (C).
j, prolidase activity; r, gradient of imidazole. (B, D) Western blotting of recombinantprolidase obtained from CHO (B) and E. coli (D) using
antibody against the histidine tag. (E) Coomassie blue-stained SDS ⁄ polyacrylamide gel of purified recombinantprolidasefrom E. coli.
Fig. 1. Expression vectors for recombinant prolidase. (A) Eukaryotic expression vector pcDNA4 ⁄ HisMax containing an N-terminal His tag and
the sequence for the enterokinase cleavage site (EK site) in-frame with the humanprolidase sequence under the control of the cytomegalo-
virus (CMV) promoter and the SP163 enhancer. (B) Prokaryotic expression vector pET16b containing an N-terminal His tag and the sequence
for the Factor Xa cleavage site in-frame with the humanprolidase sequence under the control of the T7 promoter.
Human recombinantprolidasefrom CHO and E. coli A. Lupi et al.
5468 FEBS Journal 273 (2006) 5466–5478 ª 2006 The Authors Journal compilation ª 2006 FEBS
enzyme in both the presence and absence of the poly-
histidine tag. The tag was removed from the recombin-
ant enzymes obtained from CHO cells and E. coli cells
by enterokinase and by Factor Xa digestion, respect-
ively, using in-batch digestion, as described in Experi-
mental procedures. Western blotting analysis using a
specific antibody against the His tag was performed to
evaluate the cleavage (Fig. 3A,B).
To produce higher amounts of untagged recombin-
ant protein for the stability study, we optimized an
‘on-column’ digest of the recombinant prolidase
obtained from E. coli. About 6 mg tagged protein was
loaded on a column containing 1 mL Ni ⁄ nitrilotriace-
tate resin. Then 24 U Factor Xa was added, and the
column was incubated at 35 °C for 72 h. The elution
was performed with an imidazole step gradient (20–
500 mm). The cleaved protein was eluted at 20–50 mm
imidazole as shown by SDS ⁄ PAGE and western blot-
ting using a specific Penta-His antibody (Fig. 3C,D).
The total cleavage efficiency was > 80%, and the first
three fractions contained 100% of the digested proli-
dase detectable by SDS ⁄ PAGE, but not western blot-
ting (Fig. 3C,D). The < 20% uncleaved enzyme was
digested more than 50% with a second digestion
performed using the same conditions.
N-Terminal sequence
The sequence of the N-terminal 25 amino acids of the
recombinant prolidase purified from E. coli was
unequivocally determined by automated Edman degra-
dation. We analyzed the enzyme both with and with-
out histidine tag. Comparison of the first 25 amino
acids of the tagged purified protein (GHHHHHHHH
HHSSGHIEGRHMAAAT) with that of the His-
tagged humanrecombinant prolidase, predicted from
the nucleotide sequence, revealed an exact match for
92% of the total protein analysed. Furthermore, the
N-terminal sequence of the first 25 amino acids of the
His tag-cleaved protein (HMAAATGPSFWLGNE
TLKVPLALFA) showed an exact match with the
expected residues.
The same analysis was attempted for the prolidase
purified from CHO cells, but no clear results were
obtained because of the limited amount of purified
protein.
Substrate specificity, inhibitory effect of Cbz-Pro,
optimum temperature, pH and metal dependence
We compared functional properties of the recombinant
prolidases (purified from CHO cells or E. coli both
with a His tag and after His tag cleavage) with endo-
genous humanprolidasefrom fibroblast lysate.
Substrate specificity studies confirmed Gly-Pro as the
preferred substrate for prolidase. Both recombinant
enzymes and wild-type prolidase hydrolysed the proline
dipeptides tested with at least the same efficiency (Gly-
Pro > Ala-Pro > Phe-Pro > Leu-Pro) (Table 1).
Cbz-Pro is a well known in vitro and in vivo human
prolidase inhibitor [29]. Activity studies confirmed
A
B
C
D
Fig. 3. Western blotting analysis of the removal of the polyhistidine
tag fromrecombinantprolidase obtained from CHO (A) and from
E. coli (B). +His, control samples; –His, cleaved samples.
SDS ⁄ PAGE (C) and western blotting (D) of the fractions eluted after
digestion ‘on-column’ by Factor Xa of the N-terminal His tag of the
recombinant prolidase obtained from E. coli. FT, Flow through, con-
taining 20 m
M imidazole; 50, 100 and 250 mM imidazole concentra-
tions were used for the elution.
Table 1. Recombinantand wild-type prolidase activity tested against different substrates. The percentage was calculated taking as 100%
prolidase activity against Gly-Pro. Data represent the mean ± SD from three independent determinations. CHOprol + His, CHOprol ) His,
recombinant prolidasefrom CHO cells with and without the His tag; E. coliprol + His, E. coliprol ) His , recombinantprolidasefrom E. coli
with and without the His tag; FBprol, endogenous fibroblast prolidase.
Prolidase activity (%)
CHOprol + His CHOprol – His E. coliprol + His E. coliprol – His FBprol
Ala-Pro 56.25 ± 1.820 71.89 ± 4.925 31.71 ± 2.276 33.16 ± 1.798 44.34 ± 1.438
Phe-Pro 23.39 ± 3.339 20.74 ± 1.254 17.53 ± 3.783 27.66 ± 5.492 20.20 ± 4.452
Leu-Pro 5.12 ± 1.262 4.68 ± 0.190 0.88 ± 0.433 0.28 ± 0.158 5.69 ± 0.564
A. Lupi et al. Humanrecombinantprolidasefrom CHO and E. coli
FEBS Journal 273 (2006) 5466–5478 ª 2006 The Authors Journal compilation ª 2006 FEBS 5469
Cbz-Pro as an inhibitor also of the recombinant
enzymes. No significant differences were revealed
between recombinant tagged and untagged and wild-
type prolidase with a 1 : 4 Cbz-Pro⁄ Gly-Pro molar
ratio (Table 2).
A temperature ⁄ activity profile was constructed by
measuring enzyme activity towards Gly-Pro substrate
over a range of 60 °C (at 20, 37, 50, 70, 80 °C), with
the optimum activity at 50 °C (the activity at this tem-
perature was assumed to be 100%). At 37 °C, the
activity of the recombinant His-tagged enzyme was
50% of the maximum activity measured at 50 °C, and
the activity of the same enzyme without the tag was
60–70%, closer to the 80% activity of the endogenous
enzyme (Fig. 4A).
The maximum activity of the recombinantand wild-
type enzyme, determined by measuring enzyme activity
towards Gly-Pro as substrate, was at pH 7.8 (the activ-
ity at this pH was assumed to be 100%) (Fig. 4B).
The effect of various bivalent ions (Ca
2+
,Co
2+
,
Mg
2+
,Mn
2+
and Zn
2+
) on prolidase activity was tes-
ted only for the recombinant enzyme produced in
E. coli because of difficulties in obtaining sufficient
amounts of pure protein from the eukaryotic source
without MnCl
2
preactivation. The maximum activity
was obtained with Mn
2+
(assumed to be 100%). Less
than 30% of the activity was obtained with the other
metals tested (Fig. 4C).
Long-term stability at 37 °C
Owing to the higher amount of the recombinant proli-
dase obtained from E. coli, the simple purification
method described, and its potential use for replace-
ment therapy, we focused on the long-term thermosta-
bility at 37 °C of this enzyme. We tested both tagged
and untagged enzymes to study whether the His tag
affected the activity over time. The recombinant proli-
dase was preactivated for 1 h at 50 °C in presence of
MnCl
2
and GSH and incubated at 37 °C. The activity
was evaluated daily using Gly-Pro as substrate; the
activity on day 0 was considered to be 100%.
On day 1, the untagged prolidase had a higher activ-
ity (70%) than the tagged enzyme (47%) (P<0001),
but both enzymes had lost almost total activity by
day 2. No significant difference was detected at this
time between the tagged and untagged prolidase (7%
and 13%, respectively, P ¼ 0.103) (Fig. 5A).
To improve enzyme activity over time, we incubated
the preactivated recombinant enzymes at 37 °C in pres-
ence of GSH or of GSH and MnCl
2
. The presence of
GSH partially recovered the loss of enzyme activity
previously detected. In fact, on day 2, the tag-
ged enzyme had 55% of the initial activity and the
untagged prolidase 66% (Fig. 5B).
The addition of MnCl
2
and GSH showed the most
promising effects in stabilizing and activating the
enzyme. Both tagged and untagged enzymes showed
an increase in activity on day 1 (160% and 154%,
respectively, P ¼ 0.395). On day 2, the activity of the
tagged enzyme was 87%, whereas the untagged recom-
binant prolidase had conserved 159% of the activity
(P<0.001). By day 3, the activity of the tagged
enzyme was only 27%, whereas the activity of the
untagged enzyme was significantly higher (127%;
P<0.001) (Fig. 5B).
In an attempt to stabilize further the recombinant
prolidase obtained from E. coli, we tested the effects of
two molecules often used as stabilizing agents
[poly(ethylene glycol) (PEG)200 and glycerol], gener-
ating, respectively, hydrophobic and hydrophilic inter-
action with the protein [30,31]. We focused on the
untagged enzyme because the experiments described
above showed that it was more active for a long time
and because of the potential, although not demonstra-
ted, for the immunological reaction caused by the tag
to be used in future therapeutic applications. While
PEG reproduced the effect of Mn
2+
and GSH incuba-
tion, the glycerol had a strong activating effect up to
day 6 (561% of the initial activity) (Fig. 5C).
We next tested in vitro the long-termstability at
37 °C of the untagged enzyme in the presence of a cel-
lular lysate without proteinase inhibitors, collected
from a prolidase-deficient patient and lacking endo-
genous prolidase activity. No significant difference was
detected at any time (from day 1 to day 6) between the
activity of the recombinantprolidase in the presence
or absence of the intracellular lysate (Fig. 6).
Table 2. Inhibitory effect of Cbz-Pro on recombinantand wild-type prolidase activity. A 1 : 4 Cbz-Pro ⁄ Gly-Pro molar ratio was used. The per-
centage was calculated taking as 100% prolidase activity against Gly-Pro. Data represent the mean ± SD from three independent determina-
tions.
Prolidase activity (%)
CHOprol + His CHOprol – His E. coliprol + His E. coliprol – His FBprol
Cbz-Pro ⁄ Gly-Pro 34.48 ± 9.966 36.34 ± 7.992 36.85 ± 2.474 33.81 ± 2.259 42.39 ± 7.998
Human recombinantprolidasefrom CHO and E. coli A. Lupi et al.
5470 FEBS Journal 273 (2006) 5466–5478 ª 2006 The Authors Journal compilation ª 2006 FEBS
Finally, we tested the long-term thermostability of
the recombinantprolidase obtained from CHO cells
and the endogenous fibroblast prolidase, using the con-
ditions found to be optimal for the enzyme produced
in E. coli (37 °C in the presence of MnCl
2
and GSH).
After 8 days, the activity of the endogenous enzyme
and the tagged and untagged recombinant prolidase
was close to the activity measured on day 1 (123%,
90% and 85%, respectively).
Prolidase localization
Cellular localization was evaluated in stable transfect-
ed CHO cells. Cytoplasmic and nuclear fractions
were separated by centrifugation, and both fractions
were treated to purify recombinantprolidase by
affinity chromatography as previously described. The
fractions eluted at 300 mm, which should contain the
recombinant enzyme, were pooled and dialysed.
Activity was mainly detected in the fractions
obtained from the cytosolic samples. We also
analyzed the eluted cytosol and nuclei samples by
western blotting with the HisG antibody. The recom-
binant prolidase was present mainly in the cytosol
(Fig. 7).
Discussion
This paper describes the purification and characteriza-
tion of a dipeptidase, humanrecombinant prolidase,
expressed in eukaryoticandprokaryotic hosts. We
compared the substrate specificity, optimum tempera-
ture and pH, the inhibitory effect of Cbz-Pro, the
metal dependence, and the long-term activity at 37 °C
of the recombinant enzymes and the endogenous proli-
dase present in cellular fibroblast lysates.
The recombinant enzymes from both sources were
obtained as fusion proteins with an N-terminal poly
His tag, which allowed a one-step purification proce-
dure by affinity chromatography, but which could
compromise the enzyme properties and ⁄ or its potential
therapeutic use, as pointed out by Jenny et al. [32]. All
the characterization experiments were performed on
enzymes with the histidine tag (tagged) and after speci-
fic tag cleavage (untagged).
Two different methods were used for tag removal.
For small-scale production, a digestion was per-
formed in-batch with enterokinase for the recombin-
ant prolidasefromeukaryotic cells, and with Factor
Xa for the protein synthesized in E. coli. For large-
scale production of untagged recombinant enzyme,
required for the stabilitystudiesand for future struc-
tural and pharmacological applications, we optimized
an ‘on-column’ digestion of the prolidase produced in
E. coli using Factor Xa. It is the first report of this
method applied to an N-terminal tagged protein
using this enzyme. Cleavage of the affinity tags while
the target protein was still bound to the affinity
column allowed us to obtain over 80% of the com-
pletely (100%) cleaved protein in a single chromato-
graphic step.
By SDS ⁄ PAGE, the purified enzymes from CHO
cells and E. coli were shown to have a molecular mass
Fig. 4. Effect of temperature (A), pH (B) and metals (C) on the
activity of recombinantprolidasefrom CHO cells with or without
the His tag (CHOprol + His, CHOprol ) His), recombinant prolidase
from E. coli with and without the His tag (E. coliprol + His, E. colip-
rol ) His) and endogenous fibroblast prolidase (FBprol). Data are
expressed as mean ± SD from three experiments.
A. Lupi et al. Humanrecombinantprolidasefrom CHO and E. coli
FEBS Journal 273 (2006) 5466–5478 ª 2006 The Authors Journal compilation ª 2006 FEBS 5471
of 58 kDa and 57 kDa, respectively, both very close
to the values of 58.094 kDa and 57.121 kDa estimated
by the SwissProt DataBase based on the enzyme
sequences, and to the molecular mass reported for
human prolidasefrom different sources [33–35].
The amount of recombinant enzyme obtained from
CHO cells was not quantifiable at the protein level,
and its activity, expressed as mmol Gly-Pro hydro-
lyzed in 1 h on total proteins present in the cellular
lysate, was 1000-fold lower than that of recombinant
prolidase obtained from E. coli (0.85 · 10
)3
±
1.2 · 10
)3
mmolÆh
)1
Æmg
)1
and 1.315 ± 0.525 mmolÆ
h
)1
Æmg
)1
, respectively).
This difference may be due to the different promo-
ter used, the different copy number of the exogenous
DNA, or the fact that eukaryotic cells could tolerate
only a limited amount of prolidase in their cyto-
plasm.
From literature data, mammalian prolidase is min-
imally (0.5%) glycosylated and up-regulated by phos-
phorylation at serine ⁄ threonine ⁄ tyrosine residues [25].
Although because of the low amount of prolidase
obtained from the eukaryotic host, we were unable to
Fig. 5. Activity of recombinantprolidase pro-
duced in E. coli after long-term incubation at
37 °C. (A) Percentage of activity of tagged
(+ His) and untagged (– His) enzyme;
(B) percentage of activity of tagged and
untagged enzyme incubated in the presence
of GSH (+ His ⁄ GSH, – His ⁄ GSH) or GSH
and Mn
2+
ions (+ His ⁄ GSH, Mn
2+
,
– His ⁄ GSH, Mn
2+
); (C) percentage of activity
of the untagged enzyme in the presence of
glycerol and PEG200 (– His ⁄ GSH, Mn
2+
,
25% glycerol; – His ⁄ GSH,Mn
2+
, 25% PEG).
The activity on day 0 is assumed to be
100%. Data are expressed as mean ± SD
from three experiments. d, Day of
incubation.
Fig. 6. Long-term activity of the untagged recombinant prolidase
obtained from E. coli in the absence and presence of PD fibroblast
cellular lysate. Data are expressed as mean ± SD from three
experiments. d, Day of incubation.
Fig. 7. Western blotting analysis using HisG antibody to evaluate
the cellular localization of recombinantprolidase produced in trans-
fected CHO cells. C, Cytosol; N, nucleus.
Human recombinantprolidasefrom CHO and E. coli A. Lupi et al.
5472 FEBS Journal 273 (2006) 5466–5478 ª 2006 The Authors Journal compilation ª 2006 FEBS
test directly the effect of post-translational modifica-
tions on enzyme activity, our data on the recombinant
enzyme suggest that the lack of glycosylation and
phosphorylation does not greatly reduce prolidase
activity, making possible its production in a prokary-
otic host in high amounts and at low cost.
The substrate specificity of both tagged and
untagged enzymes obtained fromeukaryoticand prok-
aryotic sources was indistinguishable from that of
endogenous fibroblast prolidase, the preferred sub-
strate being Gly-Pro, followed by Ala-Pro. This is in
accordance with data previously reported for human
endogenous prolidasefrom fibroblasts and erythro-
cytes [33–40].
The catalytic activity of both recombinant and
endogenous prolidase showed virtually identical
responses to changes in temperature and pH. All
enzymes showed a temperature optimum for activity of
50 °C and a pH optimum of 7.8. However, at the phy-
siological temperature of 37 °C, higher activity was
detected for the endogenous enzyme, and the tagged
recombinant prolidase showed the lowest activity,
although the differences were not significant.
Human prolidase isolated from different tissues
requires Mn
2+
ions [33], and this metal cannot be
effectively replaced by other metals. Similarly, our
recombinant enzyme showed highest activity in the
presence of MnCl
2
, with activities of less than 30% in
the presence of Ca
2+
,Co
2+
,Mg
2+
and Zn
2+
. Fur-
thermore, preactivation with Mn
2+
before purification
by IMAC was a requirement for the enzyme synthes-
ized in CHO cells; no binding to the Ni
2+
was possible
without preactivation (data not shown). The amount
of purified recombinantprolidasefrom E. coli was
increased by including MnCl
2
in the culture medium
and preactivating the enzyme with Mn
2+
before
IMAC purification. These observations suggest that
the metal is not only necessary for enzyme activity but
also involved in its folding.
The native andrecombinant form of human fibro-
blast prolidase exhibited essentially equivalent physical
and catalytic properties, but, considering the high
yield, properties, and low cost of the enzyme from
E. coli, the recombinantprolidase obtained from this
prokaryotic source appeared more attractive for struc-
tural studiesand therapeutic purposes, so a detailed
investigation of its stability was undertaken. We dem-
onstrated that the addition of GSH and Mn
2+
ions
had both a stabilizing and activating effect, which per-
sisted up to 3 days for the untagged enzyme. Further
investigation showed that the enzyme without a His
tag was stabilized and stimulated by PEG, a stabilizer
often used for protein replacement therapy, but better
results were obtained using glycerol. The presence of
3.2 m glycerol allowed an activity of 561% with
respect the initial tested activity after 6 days of incuba-
tion at 37 °C.
As enzyme replacement therapy implies that the
therapeutic molecules will be in contact with the intra-
cellular environment, we also tested the stability of our
recombinant enzyme ex vivo and demonstrated that
it is not digested by endogenous proteinase present in
fibroblast lysate up to 6 days.
Few attempts have been made so far to develop
an enzyme replacement therapy for PD. Genta et al.
[41] encapsulated porcine kidney prolidase stabilized
by MnCl
2
, GSH and BSA in a biodegradable micro-
sphere. This system allowed greater release of the
enzyme in vitro after 20 h of incubation at 37 °C,
but basically no activity was detected after 40 h. In
an ex vivo experiment in the presence of fibroblast
cell lysate, the activity was detectable only up to
4 days. Interestingly, pig prolidase was not stable at
all without micro-encapsulation, losing its activity
both in vitro and ex vivo in 4 h [41]. The same
approach was used to deliver the enzyme in human
cultured fibroblasts from controls and patients with
PD [42]: a 49% increase in prolidase activity after
3 days of incubation was detected. Recently, porcine
kidney prolidase was encapsulated in liposomes to
deliver the enzyme to cultured fibroblasts: the maxi-
mum release of enzyme activity was on day 6 of
incubation [43].
On the basis of these data, the availability of a new
recombinant prolidase with the same human sequence,
easily produced in high amounts, without need of exo-
genous BSA as a stabilizer, offers a new valuable tool
for testing both the delivery systems already under
study and for developing new ones.
Furthermore, the recombinant enzyme will allow
detailed structural studies, which should lead to a bet-
ter understanding of prolidase function and regulation.
Experimental procedures
Cell strains and culture conditions
Primary dermal control fibroblasts and CHO cells were
purchased from International Pbi SpA (Milan, Italy) and
American Type Culture Collection (ATCC), respectively.
Cells were grown at 37 °C in the presence of 5% CO
2
in
Dulbecco’s modified Eagle’s medium or RPMI 1640,
respectively (Sigma, St Louis, MO, USA), supplemented
with 10% fetal calf serum (Euroclone, Pero, Italy).
Fibroblasts were used between the fourth and tenth
passage.
A. Lupi et al. Humanrecombinantprolidasefrom CHO and E. coli
FEBS Journal 273 (2006) 5466–5478 ª 2006 The Authors Journal compilation ª 2006 FEBS 5473
Escherichia coli BL21 (DE3) [F
–
ompT hsdS
B
(r
B
–
m
B
–
)gal
dcm (DE3)] bacteria were grown in Luria-Bertani medium
in an orbital incubator at 37 °C agitated at 190 r.p.m.
Construction of eukaryotic expression vector
and CHO cell transfection
Total cellular RNA, isolated from cultured human control fi-
broblasts, was extracted by TriReagent (Molecular Research,
Cincinnati, OH, USA); 1 lg was reverse-transcribed using
the Gene Amp Gold RNA PCR kit according to the manu-
facturer’s protocol. The forward primer 5¢-AGGTACCT
ATGGCGGCGGCCACCGGACCCT-3¢ (nucleotides 17–
38) and the reverse primer 5¢-GATCTAGATGATTCT
GGGTGCCGTCTCTCGCTAC-3¢ (nucleotides 1582–1607),
carrying 5¢ overhang sequences containing the restriction
sites for KpnI and XbaI, respectively, were used to amplify
by PCR the humanprolidase cDNA (GenBank
NM_000285). PCR amplification was carried out at 94 °C
for 2 min, 35 cycles at 94 °C for 30 s, 65 °C for 30 s, and
68 °C for 2 min, and a final extension step at 72 °C for
10 min. The amplified product was gel-purified using Nucleo
Spin Extract (Macherey-Nagel, Du
¨
ren, Germany), digested
at 37 °C with 10 U KpnI and XbaI (Invitrogen), ligated into
KpnI ⁄ XbaI-digested pcDNA4 ⁄ HisMax eukaryotic expres-
sion vector (Invitrogen, Carlsbad, CA, USA) using T4-DNA
ligase, and transformed into E. coli TOP10 competent cells.
This vector contains the strong cytomegalovirus (CMV) pro-
moter and a SP193 enhancer, the sequence coding for an
N-terminal polyhistidine tag, and the sequence for the enter-
okinase-recognition site 5¢- to the polylinker site. The vector
also contains the genes for resistance to Zeocin. The inserted
sequence was confirmed by sequencing (see below for
details).
CHO cells were plated at 3 · 10
5
cell density in 60-mm
Petri dishes and transfected with 8 lg pcDNA4 ⁄ HisMax-
prol using Lipofectamine 2000 Reagent (Invitrogen) follow-
ing the manufacturer’s suggestion. Transfected cells were
selected with 0.3 mgÆmL
)1
Zeocin for 8 days to obtain a
stable transfected cell line.
Construction of prokaryotic expression vector
and E. coli BL21 (DE3) transformation
Total cellular RNA from cultured human control fibroblasts
(1 lg) was reverse-transcribed using the Gene Amp Gold
RNA PCR kit as previously described. The forward primer
5¢-AGGCATATGGCGGCGGCCACCGGACCCT-3¢ (nu-
cleotides 17–38) and the reverse primer 5¢-GACGGATC
CATTCTGGGTGCCGTCTCTCGCTAC-3¢ (nucleotides
1582–1607), carrying 5¢ overhang sequences containing the
restriction sites for NdeI and BamHI, respectively, were used
to amplify the prolidase cDNA (GenBank NM_000285) by
PCR. PCR amplification was carried out under the condi-
tions described above. The amplified product was gel-puri-
fied using Nucleo Spin Extract, digested with 10 U NdeI and
BamHI, ligated into the prokaryotic-expressing plasmid
pET16b (Novagen, San Deigo, CA, USA), previously diges-
ted with the same restriction enzymes. This vector contains
the strong T7 promoter, the sequence coding for an N-ter-
minal polyhistidine tag followed by the sequence for the
Factor Xa-recognition site 5¢- to the polylinker site. The vec-
tor also contains the gene for ampicillin resistance. The
inserted sequence was confirmed by sequencing.
Escherichia coli BL21 (DE3) cells were then transformed
by heat shock for protein expression and purification.
DNA sequencing
DNA sequencing was performed with the ABI-Prism Big-
Dye Terminator Cycle Sequencing Ready Reaction Kit
(Perkin–Elmer, Monza, Italy). An automatic sequencer
ABI-Prism 310 (Perkin–Elmer) was used.
Purification of CHO recombinant human
prolidase
Stable transfected CHO cells were plated at 2 · 10
6
cell
density in T175 flasks and grown for 96 h in RPMI 1640
supplemented with 10% fetal bovine serum. Upon medium
removal and three NaCl ⁄ P
i
washes, the cell layer was
mechanically removed. Pelleted cells were suspended in
50 mm Tris ⁄ HCl (pH 7.8) ⁄ 4mm 2-mercaptoethanol, soni-
cated on ice, and centrifuged at 16 000 g for 30 min at
4 °C. The lysate was incubated with 0.75 mm GSH and
1mm MnCl
2
for 12 h at 4 °C, then dialysed overnight at
4 °C against 50 mm Tris ⁄ HCl (pH 7.8) ⁄ 4mm 2-mercapto-
ethanol. Imidazole and NaCl were added to a final concen-
tration of 0.01 m and 0.3 m, respectively.
An aliquot of 1 mL of 50% Ni ⁄ nitrilotriacetate agarose
(Qiagen, Milan, Italy) slurry was added to the lysate and
mixed gently by shaking at 4 °C for 60 min. Then the col-
umn flow-through was collected, and a wash step was per-
formed using 50 mm Tris ⁄ HCl, 300 mm NaCl, 4 mm
2-mercaptoethanol (elution buffer) and 20 mm imidazole.
For elution of recombinant protein, the following step gra-
dient from 50 mm to 500 mm imidazole in elution buffer
was used: 3 mL elution buffer with 50 mm imidazole, 1 mL
elution buffer with 100 mm imidazole, three aliquots of
0.33 mL of the same buffer with 200 mm imidazole, three
aliquots of 0.33 mL of elution buffer with 300 mm imidaz-
ole, and finally two aliquots of 0.5 mL of elution buffer
containing 500 mm imidazole. Prolidase activity was deter-
mined for each fraction collected. Enzyme-containing frac-
tions were pooled and dialysed for 24 h against 50 mm
Tris ⁄ HCl (pH 7.8) ⁄ 4mm 2-mercaptoethanol at 4 °C. The
purified enzyme was stored at )80 °C in 0.3-mL aliquots in
LoBind tubes (Eppendorf, Milan, Italy).
Human recombinantprolidasefrom CHO and E. coli A. Lupi et al.
5474 FEBS Journal 273 (2006) 5466–5478 ª 2006 The Authors Journal compilation ª 2006 FEBS
Purification of E. coli BL21 (DE3) recombinant
human prolidase
Escherichia coli BL21 (DE3)-transformed bacteria were
grown in Luria-Bertani medium containing 50 lgÆmL
)1
ampicillin and 1 mm MnCl
2
at 37 °C in an orbital incuba-
tor and agitated at 190 r.p.m. At A
600
¼ 0.6, the cells were
induced with 1 mm isopropyl b-d-1-thiogalactopyranoside
for 2 h at 37 °C.
Bacteria were pelleted by centrifugation at 5000 g
for 15 min (RC5C Plus centrifuge, SS34 rotor, Sorvall, New-
town, CT, USA) and washed twice in 10 mm Tris ⁄ HCl
(pH 7.8) ⁄ 150 mm NaCl ⁄ 1mm EDTA ⁄ 4mm 2-mercaptoeth-
anol ⁄ 4mm benzamidine and resuspended in 2 mL of the
same buffer. Cells were treated with lysozyme (100 mgÆmL
)1
)
on ice for 1 h, then lysed by addition of N-laurylsarcosine to
1.3% final concentration. After being vortex-mixed for 5 s,
cells were sonicated, then Triton X-100 was added to 2%
final concentration. The lysate was clarified by centrifugation
for 60 min at 23 500 g at 4 °C. Supernatants were filtered on
0.22-lm filters and diluted fivefold with 20 mm Tris ⁄ HCl
(pH 7.8) ⁄ 4mm 2-mercaptoethanol. The solution containing
the recombinantprolidase was preactivated by incubation
with GSH (0.75 mm) and MnCl
2
(1 mm) for 1 h at 50 °C.
The Mn
2+
excess was eliminated by dialysing the sample
for 24 h at 4 °C against 20 mm Tris ⁄ HCl (pH 7.8) ⁄ 4mm
2-mercaptoethanol. Imidazole and NaCl were added to a
final concentration of 0.01 m and 0.3 m, respectively.
Ni ⁄ nitrilotriacetate agarose was used to purify the recom-
binant protein using an imidazole step gradient as previ-
ously described. Protein content andprolidase activity were
evaluated for each fraction collected. Enzyme-containing
fractions were pooled and dialysed for 24 h against 50 mm
Tris ⁄ HCl (pH 7.8) ⁄ 4mm 2-mercaptoethanol at 4 °C. The
purified enzyme was stored at )80 °C in 0.3-mL aliquots in
LoBind tubes (Eppendorf).
Endogenous prolidase
Control fibroblasts were plated at a cell density of 8 · 10
5
in T75 tissue culture flasks and grown for 8 days in
DMEM. After medium removal, the cell layer was washed
with NaCl ⁄ P
i
, mechanically removed in 50 mm Tris ⁄ HCl
(pH 7.8) ⁄ 4mm 2-mercaptoethanol, and sonicated. The
lysate was then centrifuged at maximum speed, and the
supernatant used as source of endogenous prolidase.
His-tag cleavage
His-tag digestion of purified recombinantprolidase from
CHO cells was performed with recombinant enterokinase
(Invitrogen) at 20 °C for 16 h; the recombinant entero-
kinase was removed with EKapture agarose (Invitrogen)
following the manufacturer’s suggestions. Digested and
undigested prolidase were analyzed by western blotting (see
below for details).
His-tag digestion of purified recombinant prolidase
obtained from E. coli was performed with Factor Xa (Nov-
agen) at 35 °C for 16 h, and the Factor Xa was removed
with Xarrest agarose (Novagen) following the manufac-
turer’s suggestions. Digested and undigested prolidase were
analyzed by western blotting (see below for details).
For long-termstability studies, on-column digestion was
performed modifying the method of Abdullah & Chase [44].
Briefly Ni ⁄ nitrilotriacetate agarose was equilibrated with
20 mm Tris ⁄ HCl (pH 7.8) ⁄ 300 mm NaCl (IMAC buf-
fer) ⁄ 20 mm imidazole. E. coli recombinant protein ( 6 mg)
in 50 mm Tris ⁄ HCl (pH 7.8) ⁄ 4mm 2-mercaptoethanol was
added with NaCl, CaCl
2
and imidazole to a final concentra-
tion of 100 mm,5mm and 20 mm, respectively, and loaded
on the column in the presence of 4 UÆmg
)1
Factor Xa. The
column was incubated at 35 °C with shaking for 72 h. At
the end of the incubation, the flow-through was collected
followed by a step gradient of imidazole (50 mm, 100 mm ,
250 mm and 500 mm) in IMAC buffer. The flow-through
and fractions containing the untagged prolidase were identi-
fied by SDS ⁄ PAGE and western blotting. The Factor Xa
was removed with Xarrest agarose.
Prolidase assays
Prolidase activity was determined by the procedure of
Myara et al. [45]. Commercially available proline was used
for the standard curve. Briefly, prolidase activity in cell
extract was assayed in 50 mm Tris ⁄ HCl, pH 7.8, after incu-
bation with 1 mm MnCl
2
, 0.75 mm GSH and 100 mm gly-
cyl-l-proline (Gly-Pro; MP Biomedicals, Milan, Italy) at
37 °C for 1 h.
To evaluate the substrate specificity, a variety of sub-
strates (ICN Biomedicals, Illkirch, France) were used:
100 mm glycyl-l-proline, 100 mm alanyl-l-proline, 100 mm
leucyl-l-proline, 25 mm phenylalanyl-l -proline.
To evaluate the inhibitory effect on prolidase, N-benzyl-
oxycarbonyl-l-proline (Cbz-Pro; ICN Biomedicals) was
used at a final concentration of 25 mm in the presence of
100 mm Gly-Pro.
The following buffers substituted for standard assay buf-
fer for determination of the enzyme’s pH ⁄ activity profile:
50 mm sodium acetate (pH 4.0), 50 mm sodium phosphate
(pH 5.6), 50 mm Tris (pH 9.0).
The temperature of optimum activity was evaluated by
performing the assay at different temperatures (20, 37, 50,
70, 80 °C).
Metal ion dependence was determined by incubating with
different bivalent ions [Ca
2+
,Co
2+
,Mg
2+
,Mn
2+
and
Zn
2+
(salt stock solution 100 mm)] the enzyme obtained
from E. coli without preactivation with Mn
2+
and fibroblast
lysate.
A. Lupi et al. Humanrecombinantprolidasefrom CHO and E. coli
FEBS Journal 273 (2006) 5466–5478 ª 2006 The Authors Journal compilation ª 2006 FEBS 5475
[...]... compilation ª 2006 FEBS 5477 Humanrecombinantprolidasefrom CHO and E coli A Lupi et al 28 Wang SH, Zhi QW & Sun MJ (2005) Purification andcharacterization of recombinanthuman liver prolidase expressed in Saccharomyces cerevisiae Arch Toxicol 79, 253–259 29 Lupi A, Rossi A, Vaghi P, Gallanti A, Cetta G & Forlino A (2005) N-Benzyloxycarbonyl-l-proline: an in vitro and in vivo inhibitor of prolidase Biochim.. .Human recombinantprolidasefrom CHO and E coli A Lupi et al The thermostability of tagged and untagged recombinantprolidase expressed in E coli was evaluated: (a) by incubating the enzyme preactivated with 1 mm MnCl2 and 0.75 mm GSH for up to 6 days at 37 °C; (b) by adding to the incubation mixture 0.75 mm GSH or (c) 0.75 mm GSH and 1 mm MnCl2; (d) by supplementing... manganese-activated prolidase in control and prolidase- deficient cultured skin fibroblasts J Inherit Metab Dis 7, 32–34 38 Nakayama K, Awata S, Zhang J, Kaba H, Manabe M & Kodama H (2003) Characteristics of prolidasefrom the erythrocytes of normal humans and patients with prolidase deficiency and their mother Clin Chem Lab Med 41, 1323–1328 5478 39 Butterworth J & Priestman DA (1985) Presence in human cells and tissues... the same family J Med Genet, in press Fernandez-Espla MD, Martin-Hernandez MC & Fox PF (1997) Purification andcharacterization of a prolidasefrom Lactobacillus casei subsp casei IFPL 731 Appl Environ Microbiol 63, 314–316 Suga K, Kabashima T, Ito K, Tsuru D, Okamura H, Kataoka J & Yoshimoto T (1995) Prolidasefrom Xanthomonas maltophilia: purification andcharacterization of the enzyme Biosci Biotechnol... & Matsuda I (1989) Primary structure and gene localization of humanprolidase J Biol Chem 264, 4476– 4481 15 Wang H, Kurien BT, Lundgren D, Patel NC, Kaufman KM, Miller DL, Porter AC, D’Souza A, Nye L, Tumbush J, et al (2006) A nonsense mutation of PEPD in Humanrecombinantprolidasefrom CHO and E coli 16 17 18 19 20 21 22 23 24 25 26 27 four Amish children with prolidase deficiency Am J Med Genet A... peroxide labelled anti-mouse IgG (Amersham Biosciences) at 1 : 5000 dilution ECL Plus (for CHO prolidase) and ECL (for E coli prolidase) reagents (Amersham Biosciences) were used for detection Identification of recombinanthumanprolidase The N-terminal sequence of E coli recombinant prolidase, both tagged and untagged, was determined by automated N-terminal Edman degradation on a Hewlett–Packard (Milan,... Biochem 59, 2087– 2090 Ghosh M, Grunden AM, Dunn DM, Weiss R & Adams MW (1998) Characterization of native andrecombinant forms of an unusual cobalt-dependent proline dipeptidase (prolidase) from the hyperthermophilic archaeon Pyrococcus furiosus J Bacteriol 180, 4781–4789 Myara I, Charpentier C & Lemonnier A (1984) Prolidaseandprolidase deficiency Life Sci 34, 1985–1998 Donald SP, Sun XY, Hu CA, Yu J,... obtained from a patient with PD and thus lacking endogenous prolidase activity (1 : 2.5) Prolidase activity was determined as described above from day 0 to day 6 Protein determination Protein concentration was measured by the Lowry method [46] using BSA as standard SDS ⁄ PAGE and western blotting analysis SDS ⁄ PAGE was performed in 10% acrylamide gels by the method of Laemmli under denaturing and reducing... Forlino A (2004) Characterization of a new PEPD allele causing prolidase deficiency in two unrelated patients: natural-occurrent mutations as a tool to investigate structure-function relationship J Hum Genet 49, 500–506 11 Ohhashi T, Ohno T, Arata J, Sugahara K & Kodama H (1990) Characterization of prolidase I and II from erythrocytes of a control, a patient with prolidase deficiency and her mother Clin... Clin Chem Lab Med 41, 1323–1328 5478 39 Butterworth J & Priestman DA (1985) Presence in human cells and tissues of two prolidases and their alteration in prolidase deficiency J Inherit Metab Dis 8, 193–197 40 Endo F, Matsuda I, Ogata A & Tanaka S (1982) Human erythrocyte prolidaseandprolidase deficiency Pediatr Res 16, 227–231 41 Genta I, Perugini P, Pavanetto F, Maculotti K, Modena T, Casado B, Lupi . Human recombinant prolidase from eukaryotic and
prokaryotic sources
Expression, purification, characterization and long-term stability
studies
Anna. PD.
Results
Recombinant human prolidase expression and
purification from eukaryotic and prokaryotic
sources
Total cellular RNA from cultured normal human
fibroblasts