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Clinical and Diagnostic Laboratory Immunology, July 1998, p. 474-478, Vol. 5, No. 4
Department of Molecular Parasitology,
Received 11 December 1997/Returned for modification 4 February
1998/Accepted 19 March 1998
In 40 cases of human paragonimiases caused by Paragonimus
westermani (20 cases), P. miyazakii (10 cases), and
P. skrjabini (10 cases), responses of serum immunoglobulin
G (IgG), IgG subclasses, and IgE were analyzed by immunoblotting with
crude antigens prepared from egg, 4-week-old juvenile, and adult forms
of P. westermani. The 32- and 35-kDa proteins in the adult
extracts showed specific reactions regardless of the causative species
(39 of 40 cases; 98%). Sera of patients infected with P. westermani and P. miyazakii reacted strongly with the
28-, 46-, and 94-kDa proteins of egg extracts, while those from
patients infected with P. skrjabini reacted faintly.
No sera from patients with other trematodiases (0 of 15 cases),
cestodiases (0 of 20 cases), or lung cancer (0 of 5 cases) or from
healthy controls (0 of 10 individuals) showed positive reactions.
Analysis by IgG subclass revealed that IgG4 (33 of 40 cases; 83%) and
IgG1 (29 of 40 cases; 73%) antibodies in the patient sera recognized
the 32- and 35-kDa proteins predominantly. IgG3 reaction was found in
50% (10 of 20 cases) and 30% (3 of 10 cases) of the sera of patients
infected with P. westermani and P. miyazakii,
respectively. In an IgE immunoblot, 83% (33 of 40 cases) of the sera
from paragonimiasis patients reacted with the 32- and 35-kDa proteins
while no sera from patients with heterologous diseases and healthy
controls showed a positive reaction. Both 32- and 35-kDa proteins in
adult extracts of P. westermani were highly reliable for
serodiagnosis of human paragonimiases.
Paragonimus westermani,
type species of the genus Paragonimus, is an important cause
of chronic inflammatory diseases of the lung, central nervous system,
and abdominal cavity (24). In addition, P. miyazakii and P. skrjabini elicit pleural and
subcutaneous lesions in infected individuals in Japan and China and
P. heterotremus causes lung infections in Southeast Asia.
Lung infections caused by the parasites should be differentiated from
tuberculosis, especially in East and Southeast Asia, where both
diseases are endemic (24, 29, 31).
Raising a suspicion of paragonimiasis is the first step leading to the
diagnosis, which can be confirmed by egg detection. Egg examination is
not, however, highly sensitive due to intermittent discharge in many
patients. Furthermore, for extrapulmonary lesions, parasitological
diagnosis is impossible unless a biopsy is carried out. The antibody
test, developed to overcome these difficulties, has been proven to be
effective in diagnosis of paragonimiasis. Enzyme-linked immunosorbent
assays or immunoblots showed a high degree of reliability and were
shown to be applicable to sera, pleural effusions, or cerebrospinal
fluid (2, 3, 7, 9, 12, 15, 22, 26).
Crude extracts of adult worms were shown to be most effective in
serodiagnosis because these extracts contain many compartmental proteins which could detect the polyclonal antibody produced by the
patients (2, 4, 9, 11, 12, 26). Meanwhile, excretory-secretory products, partially purified cysteine proteases, and egg extracts have been used to detect specific antibody and appear
to be highly useful diagnostic antigens for paragonimiasis (7, 10,
14, 18, 22, 23, 27). However, their antigenic properties are yet
to be properly evaluated, especially in sera of patients infected with
different species of Paragonimus (16). Moreover,
little information on the analysis of immunoglobulin G (IgG) subclasses
and IgE immune responses in paragonimiasis is available. In this study,
we evaluated the antigenicity of crude extracts from egg, juvenile, and
adult stages of P. westermani and compared antibody
responses to these extracts in sera of patients infected with P. westermani, P. miyazakii, and P. skrjabini.
Preparation of crude extracts of P. westermani.
Cats
and dogs were infected with metacercariae, which were collected from
freshwater crayfish, Cambaroides similis. Four weeks after
infection, the juvenile worms were harvested from the peritoneal and
thoracic cavities of cats. At 16 weeks after infection, adult worms
were collected from dog lungs (5). Eggs of P. westermani, obtained either by incubating the adult worms in
physiological saline overnight at 37°C or by flushing the infected
dog lung, were purified as described previously (13). The
eggs, juveniles, and adults were ground with a Teflon
pestle-homogenizer in physiological saline and centrifuged at 500 × g for 5 min followed by 20,000 × g for
1 h at 4°C. The resulting supernatants were used as the crude
extracts and stored at Serum samples.
A total of 40 serum samples from patients
with paragonimiasis, consisting of 10 patients each infected with
Paragonimus westermani from Korea and Japan (10 patients
from each country), P. miyazakii (Japan), and P. skrjabini (China), was used. Three patients in Korea were
diagnosed by egg detection, and seven patients were diagnosed by their
histories of eating crabs, radiological findings, and positive antibody
tests by enzyme-linked immunosorbent assay when hemoptysis, chronic
cough, or chest pain had been manifested for 10 months to 2 years
(4, 8). Japanese patients with P. westermani and
P. miyazakii infections were diagnosed by positive differential double immunodiffusion and complement fixation tests and
by their histories of eating freshwater crabs (Eriocheir
japonicus and/or Geothelphusa dehaani). All patients
manifested pulmonary symptoms such as pleuritic pain, hemoptysis,
and/or dyspnea for a maximum 3 years. Peripheral eosinophilia and
elevation of serum IgE levels were observed in all cases. P. skrjabini infection was diagnosed by finding of migratory
subcutaneous nodules, a history of ingestion of raw freshwater crabs,
and positive antibody tests. The interval between the detection of
subcutaneous nodules and diagnosis was not available on an individual
basis. As negative controls, five serum samples each from patients with
Schistosoma japonicum schistosomiasis (patients from China),
clonorchiasis (Korea), fascioliasis (Japan), cysticercosis (Korea),
alveolar echinococcosis (China), cystic echinococcosis (Jordan),
sparganosis (Korea), and cytology-proven lung cancer were used. In
addition, 10 healthy controls (students of Gifu University, Gifu,
Japan) who denied exposure to any possible infection sources were
included in the study. All serum samples were stored at Immunoblot for IgG and IgG subclasses.
Sodium dodecyl
sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) on a commercially
available precast 4- to 20% gradient gel (no. 01-102, -106, -020, and
-026; SDS-PAGE Mini; TEFCO, Tokyo, Japan) was carried out as described
elsewhere (17). The resolved proteins were electroblotted
onto polyvinylidene difluoride (PVDF) microporous membrane (Millipore,
Bedford, Mass.). Patient sera, diluted 1:200, were probed overnight.
Peroxidase-conjugated anti-human IgG (heavy- and light-chain specific;
Cappel, West Chester, Pa.) and monoclonal antibodies against human IgG
subclasses (IgG1, -G2, -G3, and -G4; Zymed, San Francisco, Calif.) were
diluted 1:1,000 and incubated for 2 h. The blots were developed
with 0.03% (wt/vol) 4-chloro-1-naphthol (4C1N) containing 0.03%
H2O2 in phosphate buffer (0.1 M, pH 7.4).
IgE immunoblot.
SDS-PAGE and transfer-blot to PVDF membrane
were performed as described above. The patient sera were diluted 1:25
and probed overnight. Peroxidase-conjugated anti-human IgE ( Figure 1 shows immunoblot findings
obtained with crude extracts of egg (lanes Egg), 4-week-old juvenile
(lanes 4-wk), and 16-week-old adult (lanes 16-wk) stages of P. westermani. The pooled sera from groups of 10 patients, each group
infected with P. westermani (Fig. 1, panels PwJ and PwK) or
P. miyazakii (panel Pm), revealed strong immunoreactive
bands at 28, 46, and 94 kDa with the egg extracts, whereas sera from
patients infected with P. skrjabini (panel Ps) reacted
weakly. The juvenile extracts reacted strongly with sera of patients
with paragonimiasis, but they showed cross-reactions with other patient
sera, especially those of patients with fascioliasis and
schistosomiasis, with 30- and 31-kDa bands (Fig. 1, lanes 4-wk of
panels Fh and Sj). In adult extracts, bands at 6, 17, 26, 27, 28, 32, 35, 46, and 94 kDa exhibited strong reactions to sera of patients
infected with the three different Paragonimus species. Of
these, the 32- and 35-kDa bands showed the strongest and most frequent
reactions. The diagnostic sensitivity and specificity of these paired
bands were 98% (39 of 40 patients) and 100% (0 of 50 patients),
respectively.
The cross-reactivity of the adult extracts was further examined by
employing individual infection sera (Fig.
2). Sera of patients infected with
S. japonicum, Clonorchis sinensis, and
Fasciola hepatica exhibited nonspecific positive reactions
to several bands, including those of 6, 17, 30, 31, and over 100 kDa,
while no sera showed positive reactions to the 32- and 35-kDa bands.
The sera of patients with cysticercosis, alveolar echinococcosis,
cystic echinococcosis, and sparganosis showed a few reactions to the antigenic bands below 10 kDa. The sera from patients with lung cancer
and healthy controls did not show positive reactions (immunoblots of
lung cancer patients are not shown).
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Copyright © 1998, American Society for Microbiology. All rights reserved.
Immunoglobulin G (IgG) Subclass and IgE Responses in Human
Paragonimiases Caused by Three Different Species
ABSTRACT
Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References
INTRODUCTION
Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References
MATERIALS AND METHODS
Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References
70°C until use. Protein content was measured
by using bovine serum albumin as a standard (20).
70°C until
use.
-chain
specific; Cappel), diluted 1:500, was further incubated for 4 h.
The blots were developed as described above by using 4C1N.
RESULTS
Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References
View larger version (67K):
[in a new window]
FIG. 1.
Immunoblot analysis of crude extracts from egg (lanes
Egg), juvenile (lanes 4-wk), and adult (lanes 16-wk) stages of P. westermani. Pooled sera of 10 patients each infected with P. miyazakii (panel Pm), P. westermani (panel PwJ
[Japanese patients] and panel PwK [Korean patients]), and P. skrjabini (panel Ps) were reacted, together with sera from
patients with S. japonicum schistosomiasis (panel Sj),
clonorchiasis (panel Cs), and fascioliasis (panel Fh) and sera from
uninfected controls (panel Normal). With human paragonimiasis samples,
bands at 28, 46, and 94 kDa in the egg extracts and 32 kDa ( 
) and 35 kDa (
) in the adult extracts showed specific reactions. S. japonicum schistosomiasis and fascioliasis sera exhibited
cross-reactions with bands at 30 and 31 kDa in juvenile extracts.
Mr, molecular mass (in kilodaltons).
View larger version (109K):
[in a new window]
FIG. 2.
Cross-reactivity of adult extracts by immunoblot. The
individual sera from patients with schistosomiasis (panel Sj),
clonorchiasis (panel Cs) and fascioliasis (panel Fh) exhibited
nonspecific reactions to several bands, including those at 6, 17, 30, 31, and over 100 kDa. The sera of patients with alveolar echinococcosis
(panel AE), cystic echinococcosis (panel CE), cysticercosis (panel Cy),
and sparganosis (panel Sp) showed negligible reactions.
Mr, molecular mass (in kilodaltons); P, positive
control. The letters a to e each represent a different patient.
Figure 3 demonstrates recognition by IgG subclasses of adult extracts of P. westermani. The sera from patients infected with P. westermani and P. miyazakii reacted mainly to both 32- and 35-kDa bands with IgG4 (18 of 20 [90%] for patients with P. westermani paragonimiasis; 8 of 10 [80%] for patients with P. miyazakii paragonimiasis) and IgG1 (16 of 20 [80%] for patients with P. westermani paragonimiasis; 9 of 10 [90%] for patients with P. miyazakii paragonimiasis). Sera of patients with P. skrjabini infections reacted weakly to 32- and 35-kDa bands with IgG4 (7 of 10 [70%]) and IgG1 (4 of 10 [40%] (panel Ps in Fig. 3). In addition, sera of patients infected with P. westermani (10 of 20, 50%) or P. miyazakii (3 of 10, 30%) showed IgG3 antibody reaction, while those of patients infected with P. skrjabini showed minimal reactions (1 of 10, 10%). IgG2 subclass reaction was observed in only 8% (3 of 40) of the sera examined.
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When specific IgE reactions against the adult extracts were analyzed by immunoblot, sera of patients with P. westermani and P. miyazakii infections were found to react to 17-, 26-, 28-, 32-, and 35-kDa bands. Those of patients infected with P. skrjabini reacted mainly to the 32- and 35-kDa bands and faintly to those of 17, 26, and 28 kDa (Fig. 4). The 32- and 35-kDa bands exhibited the most specific and strongest reactions to paragonimiasis sera, irrespective of the species (18 of 20 [90%] for patients with P. westermani paragonimiasis, 8 of 10 [80%] for patients with P. miyazakii paragonimiasis, and 7 of 10 [70%] for patients with P. skrjabini paragonimiasis; overall positivity rate 83%). A few sera of patients with other parasitic diseases and the normal control showed weak reactions to either the 6-, 14-, or 17-kDa band, as shown in Fig. 4.
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DISCUSSION |
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Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References
|
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In this study, crude extracts from egg, juvenile, and adult stages of P. westermani were examined for their ability to be captured by specific IgG, IgG subclasses, and IgE antibodies in sera of patients infected with P. westermani, P. miyazakii, and P. skrjabini. Irrespective of the causative species, all the patient sera tested exhibited specific reactions to 32- and 35-kDa proteins in extracts of adult P. westermani, with IgG4 being the predominant reactive antibody (Fig. 3). These two bands were shown to elicit strong reactions when extracts were obtained from adults after 8 weeks of experimental paragonimiasis (18). An IgE immunoblot demonstrated also that most sera examined (83%) revealed specific reactions to these two bands (Fig. 4). Taken together, both the 32- and 35-kDa proteins in the adult extracts were highly specific and sensitive for diagnosis of paragonimiasis from the early stage to chronic infection and shared common antigenic epitopes for IgG and IgE. The present result is partly in agreement with results of analyses of antigenic epitopes in P. heterotremus, in which the 31.5-kDa protein was found to be specific for homologous sera (21-23).
While the sera of patients infected with P. westermani and P. miyazakii reacted strongly to 28-, 46-, and 94-kDa proteins in the egg extracts, those of patients infected with P. skrjabini reacted weakly (Fig. 1 and 3). This result suggested that P. miyazakii matures in the human host, though the eggs were hardly detectable due to the organism's location in the given host. Because P. skrjabini infections were recognized as subcutaneous nodules before the worms had grown to adult form, antibody responses against the egg antigen might be either absent or weak. It was also shown that sera of patients with P. westermani and P. miyazakii paragonimiases revealed similar levels of serum antibody to the partially purified antigen of adult P. westermani (7).
The paragonimiasis sera recognized the 32- and 35-kDa proteins strongly with IgG4. In addition, 50 and 30% of the sera infected with P. westermani and P. miyazakii showed IgG3 responses, while those from patients with P. skrjabini infection showed negligible IgG3 reactions. Because IgG4 isotype switching was correlated with the duration of infection and clinical manifestation (19, 28), the present result matched well with the common clinical characteristics of chronic and persistent infections, which continued stimulation of the host immune system. In patients with P. westermani and P. miyazakii paragonimiases, pulmonary symptoms were long-standing, being manifested for 8 months to 3 years. A chronic course of infection in paragonimiasis patients was also associated with elevation of IgG4 subclass levels. High IgG4 responses have been described to occur in patients with chronic schistosomiasis and other cestode infections (1, 6, 25). It is yet to be determined whether a relatively weak IgG4 response in P. skrjabini paragonimiasis reflects an early infection or a difference in antibody recognition in the patient sera.
In this study, the juvenile extracts showed cross-reactions with sera from patients with fascioliasis and S. japonicum infections, whereas the adult extract exhibited negligible cross-reactions. On dilution to 1:100, sera from patients with fascioliasis, schistosomiasis, and clonorchiasis revealed cross-reactions even with the adult extracts (data not shown). The cross-reactions, however, disappeared when the sera were diluted 1:200, as shown in Fig. 1. This demonstrated clearly that serum dilution was one of the crucial factors in determining the specificity of the antibody test by immunoblotting as reported previously (30).
In conclusion, monitoring reactions with 32- and 35-kDa proteins by IgG, IgG4, or IgE on an immunoblot using adult extracts of P. westermani would be a highly reliable method for serodiagnosis of paragonimiasis, regardless of the causative species. Specific reactions with these two bands can differentiate paragonimiasis from chronic infections caused by other parasites and from malignant diseases of the lung.
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ACKNOWLEDGMENTS |
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We thank L. Ma, Department of Parasitology, Gifu University School of Medicine, for his technical assistance.
This work was supported by research grants for Basic Medical Sciences, Ministry of Education, Korea (1996-1998), and also by the Korea-Japan Exchange Program (1997), by an exchange between the Japan Society for Promotion of Science (JSPS) and Korea Science and Engineering Foundation (KOSEF).
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FOOTNOTES |
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* Corresponding author. Mailing address: Department of Molecular Parasitology, College of Medicine, Sung Kyun Kwan University, Suwon 440-746, Korea. Phone: (82-331) 290-7961. Fax: (82-331) 290-7909. E-mail: kongy{at}yurim.skku.ac.kr.
Present address: Department of Environmental Studies, Faculty of
Regional Sciences, Gifu University, Gifu 501, Japan.
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Abstract
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Discussion
References
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Clinical and Diagnostic Laboratory Immunology, July 1998, p. 474-478, Vol. 5, No. 4
1071-412X/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.
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