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Immuno-PCR for detection of antigen to Angiostrongylus cantonensis circulating fifth-stage worms.

Angiostrongylus cantonensis, a nematode that is the most common infectious cause of eosinophilic meningitis and meningoencephalitis both worldwide and in areas of Southeast Asia and many Pacific Islands, is one of the most important zoonotic parasites in Taiwan (1, 2). Definitive diagnosis of angiostrongyliasis is established by the detection of A. cantonensis-specific worms in the cerebrospinal fluid (CSF) [4] of patients suffering from meningitis or meningoencephalitis (3). The diagnostic process is challenging; even with the advent of an improved spinal-tap technique, which enhances recovery of A. cantonensis, the worm is detected in the CSF of only 50% of infested patients (4).

This low detection rate has prompted efforts to develop immunologically based detection methods. The suitability of a various antigens for the detection of serum antibodies has been explored, including antigens associated with the adult worm, the third- or fifth-stage larvae of A. cantonensis ([AcL.sub.3] and [AcL.sub.]5, respectively), and certain metabolic processes (5-11). Most methods have not displayed sufficient antigenic specificity to be of reliable diagnostic value. To avoid the diagnostic liability of antigenic cross-reactivity between A. cantonensis and other helminthic species, partially purified and purified A. cantonensis antigens have been used to detect angiostrongyliasis-affected patients (12-17). The purification of these antigens, typically accomplished by column chromatography, is a time-consuming process because crude antigens typically require passage through several columns to appropriately prepare them for immunodiagnostic use. In another approach, specific monoclonal antibodies (mAbs) against antigens of the [AcL.sub.3] or [AcL.sub.]5 larval stages of A. cantonensis have been prepared and used to detect circulating antigen in a double-antibody sandwich ELISA (18,19). The specificity of this method is high, but the detection sensitivity remains unsuitably low.

In seeking an alternative approach, we have considered the use of immuno-PCR. The immuno-PCR assay is similar in operation to the ELISA; both detect an antigen-antibody reaction. However, instead of an enzyme conjugated to an antibody, as is used in ELISA, immuno-PCR uses a reporter DNA target that is amplified to diagnostic concentrations by PCR (20, 21). To date, immuno-PCR has been used for the sensitive immunodetection of a variety of soluble protein molecules from infectious pathogens and compounds, including Helicobacter pylori and Clostridium botulinum exotoxin A (22-24). The present study was initiated with the aim of using immuno-PCR to detect [AcL.sub.5] circulating antigen in the serum of patients with eosinophilic meningitis or meningoencephalitis and to estimate the diagnostic accuracy of the method.

Materials and Methods


[AcL.sub.3] was collected from infested Biomphalaria glablata snails after they were mechanically minced and digested with use of artificial gastric juice (17). Hybrid mice were individually infested with 50 larvae via an oral stomach tube. The mice were raised in an air-conditioned laboratory animal center (22 [+ or -] 1 [degrees]C and 50% [+ or -] 10% relative humidity). Three weeks after infestation, each mouse was sacrificed with an excess of ether, and [AcL.sub.5] were recovered from the brain. Larval components were extracted with cold 0.15 mol/L phosphate-buffered saline (PBS; pH 7.2) and delipidated with ether as described previously (25). The extracts were stored at -70 [degrees]C.


The hybridomas AcJ1 and AcJ20 were used. AcJ1 secretes IgG2a, and AcJ20 secretes IgG1. Both antibodies recognize specific [AcL.sub.5] antigens with a molecular mass of 204 kDa (17). These hybridomas were injected into the peritoneum of pristane-primed BALB/c mice. Antibody-enriched ascites were collected and purified through a protein A-Sepharose CL4B immunosorbent column (Pharmacia Fine Chemicals AB), with 0.1 mol/L sodium citrate-citric acid buffers (pH 4.5 and 6.5) used to elute IgG2a and IgG1, respectively. Antibody-containing eluates were immediately pooled and neutralized with 1 mol/L Tris to pH 7.0, then desalted by passage through a prepacked PD-10 column (Sephadex G-25; Pharmacia Fine Chemicals). mAbs were concentrated by lyophilization and then adjusted to a concentration of 10 mg/L with 0.15 mol/L PBS.


[AcL.sub.5] antigen was purified by an immuno-adsorption technique (26). Briefly, purified mAb was mixed with swollen, cyanogen bromide-activated Sepharose 4B gel and incubated for 2 h. Gels were packed into a 2 x 15 cm column, and were washed and mixed with 1 mol/L ethanolamine (pH 8.0) for 1 h. Noncovalently adsorbed proteins were washed out with 0.15 mol/L PBS. [AcL.sub.5] extracts were eluted with PBS at a flow rate of 8 mL/h until the eluate was free of extract. The bound components were then eluted with cold 0.1 mol/L glycine-hydrochloric acid buffer, neutralized with 0.15 mol/L glycine solution (pH 11.0), and dialyzed with PBS. The protein concentration of the purified antigen was detected by a specific protein assay (Bio-Rad). Aliquots of antigen were stored at -70 [degrees]C until required.


Patients in the Department of Pediatrics at Chong-Ho Memorial Hospital, Kaohsiung Medical University (Taiwan, ROC), with eosinophilic meningitis or meningoencephalitis with clinical syndromes including severe headache, stiffness of the neck, and intermittent fever and eosinophil counts >8% of leukocytes in CSF smears were involved in this study. Serum specimens were acquired during March 2000 and November 2002 from 60 consecutive patients, 21 females and 39 males [mean (SD) age, 7.0 (1.7) years]. In 30 patients, worms were found in the CSF. Control sera were collected from 30 healthy volunteers [13 females and 17 males; 7.2 (2.6) years]. All serum samples were randomly assigned numbers and stored at -70 [degrees]C until used.


The IgG1 mAb of the AcJ20 hybridoma was biotinylated as described by Hnatowich et al. (27). We reacted 1 mg of IgG1 mAb with 0.1 mg of sulfo-N-hydroxysuccinimide-Lc-biotin in 1 mL 0.15 mol/L PBS for 30 min at room temperature. After termination of the reaction, biotinylated IgG1 mAb was obtained by dialysis of the reactants.


Biotinylated DNA was prepared as described by Sano et al. (20). The biotinylated pUC 19 was a linear 2.67-kb HindIII-Acct fragment in which one biotin molecule had been incorporated at its HindIII terminus by a filling-in reaction with Sequenase version 2.0 DNA Polymerase (United States Biological) in the presence of a biotinylated nucleotide (biotin-14-deoxyadenosine triphosphate; BRL). The product was purified by use of a G-50 column (Pharmacia Fine Chemicals).


The double-antibody sandwich ELISA technique described in detail elsewhere (25) was used to detect circulating antigens of A. cantonensis. Briefly, IgG2a mAb secreted by the AcJ1 hybridoma was adjusted to a concentration of 10 mg/L and applied to the wells of a microtiter plate (cat. no. 3912; Falcon). Adhesion of the antibody occurred during an overnight incubation at 4 [degrees]C. Unbound antibody was removed by washing with PBS containing 0.5 mL/L Tween 20. The reaction was then terminated by blocking with 10 g/L bovine serum albumin.

In the ELISA procedure, diluted serum or a preparation of purified antigen was added and incubated for 1 h. After a wash to remove unbound components, biotinylated IgG1 diluted to 1 mg/L was added to each well and incubated for 1 h. Unbound antibody was removed by washing each well eight times. After the final wash, a streptavidin-alkaline phosphatase conjugate diluted 1:1000 was added to each well. After incubation for 1 h, the wells were washed four times, and p-nitrophenyl phosphate substrate was added. The plates were incubated for 15 min in the dark to allow for color development of the enzymatically cleaved substrate, and the absorbances of the well contents were read at 405 run with a colorimeter (MR 5000; Dynatech).


Immuno-PCR was carried out according to the description of Sano et al. (20). The analysts were blinded to the whether samples came from patients and controls when evaluating all serum specimens by immuno-PCR. A schematic representation of this method is shown in Fig. 1. Briefly, purified IgG2a mAb (10 mg/L) was coated on the surface of wells of flat-bottomed immuno-PCR plates (Model 6511; Costar Corporation) overnight at 4[degrees]C. Unbound antibody was removed by washing with Trisbuffered saline, wells were blocked for 1 h at 37[degrees]C with 10 g/L bovine serum albumin in Tris-buffered saline containing 0.1 mmol/L EDTA and 1 g/L salmon-sperm DNA. The plates were then washed five times with the above buffer containing 1 mL/L Tween 20 (TETBS), after which, a 1:20 dilution of serum or purified antigen diluted with TETBS containing 1 g/L bovine serum albumin and 0.1 g/L salmon-sperm DNA were then applied to wells for 1 h at 37[degrees]C. After the wells were washed 12 times with TETBS, biotinylated IgG1 (1 mg/L) was added for 1 h at 37[degrees]C. After 12 washes with TETBS, streptavidin (1 mg/ L) was added for 1 h at 37[degrees]C. After another 12 washes with the same buffer, 1 x [10.sup.-19] mol/ [micro]L biotinylated PUC 19 was added for 30 min at room temperature. Wells were washed with TETBS 25 times and distilled water 3 times, and then 25 [micro]L of distilled water was added to each well, followed by 5 [micro]L of the PCR mixture, 5 [micro]L of 1.25 mol/L deoxyribonucleoside triphosphates, 5 [micro]L of 20 [micro]mol/L 3' primer (5'-GTT TTC CCA GTC ACG AC-3'), 5 [micro]L of 20 [micro]mol/L 5' primer (5'-AGC GGA TAA CAA TTT CAC ACA GGA-3'), and 5 [micro]L (0.5 U) of Taq DNA polymerase mixture, We then layered of 25 [micro]L of mineral oil on the top of the mixture in each well and subjected the mixtures to PCR under the following conditions: denaturation at 94[degrees]C for 15 s, 35 cycles of annealing at 55[degrees]C for 10 s and extension at 74[degrees]C for 30 s, and a final extension for 5 min at 74[degrees]C. We then electrophoresed 5 [micro]L of the PCR product on a 3% agarose gel containing ethidium bromide.



All concentrations of [AcL.sub.5] antigen in serum specimens detected by immuno-PCR are given as the mean (SD). The statistical significance of the differences in concentrations between patients with eosinophilic meningitis or meningoencephalitis and controls was assessed by means of Wilcoxon rank-sum test. Analysis of difference were also carried out between parasitologically confirmed patients and patients who displayed only clinical syndromes. P <0.05 was considered significant. The sensitivity and specificity for immunodiagnosis of patients with angiostrongyliasis by immuno-PCR were assessed according to the methods of Newcombe (28) for 95% confidence intervals. Three samples of known concentration were tested in 20 replicates at one time to assess intraassay precision.



Because all samples in this study were analyzed at one time, the intraassay precision of immuno-PCR for detection of circulating [AcL.sub.5] antigen in patients was estimated previously. The means (SD) of known antigen concentrations were 5 (0.14), 60 (1.44), and 120 (3.6) ng/L, respectively. The CV for this assessment were 2.8%, 2.4%, and 3.0%, respectively.


In this immuno-PCR system, a single 150-bp DNA band was routinely evident (Fig. 2A) with 0.1 ng/L purified antigen. No DNA product was observed for the negative controls. By contrast, the ELISA (Fig. 2B) did not detect antigen concentrations <10 ng/L. A high-circulating-antibody-titer serum from a patient suffering from angiostrongyliasis was tested in both assays.

As seen in Fig. 3A, immuno-PCR successfully detected antibody in dilutions up to [10.sup.5], whereas the ELISA failed to detect antibody in dilutions >[10.sup.2] (Fig. 3B).


A calibration curve for the [AcL.sub.5] 204-kDa antigen is shown in Fig. 4. The concentrations of antigen in patients known to harbor the parasite were 3-600 ng/L, whereas they were <0.1-120 ng/L in those suspected of harboring the parasite. Sera from noninfested controls contained <0.1 ng/L (Fig. 5).

The median (range) circulating antigen concentrations, as shown in Table 1, were 25 (3-600) ng/L and 39 (<0.1-120) ng/L in parasitologically confirmed patients and symptomatic patients, respectively. Antigen concentrations in both groups of patients were significantly higher than in the noninfested control group (P <0.001). Additionally, the antigen concentrations in parasitologically confirmed and symptomatic patients were significantly different (P <0.05).




At a cutoff of 0.1 ng/L, all controls were negative, and 59 of 60 patients (98%) were positive, including all 30 patients in whom parasite had been identified in the CSF. The 95% confidence intervals for sensitivity and specificity were 91-99% and 93-100%, respectively.


When ingested by humans, [AcL.sub.3] penetrate the intestinal wall and then migrate to the brain and spinal cord within a period of 12 h. The speed of progression of the infestation necessitates rapid detection of the parasite if meaningful therapy is to be commenced. A definitive diagnosis for patients with this parasitic infestation can be based on the presence of worms in the CSF. This diagnosis requires a highly trained physician to collect the sample. Even then, the method of collection by lumbar puncture poses a risk to the patient. Furthermore, because A. cantonensis larvae can develop into AcL, in the brain ventricle, serum antigen concentrations may remain very low, hampering diagnosis.



The diagnostic challenges posed by CSF collection and a low antigen concentration in the serum of patients have spurred efforts to develop alternative, sensitive methods for the detection of A. cantonensis. Sano et al. (20) developed a highly sensitive serum antigen detection system that combines an ELISA and several DNA oligonucleotide reporters for exponential amplification by PCR. We exploited this hybrid technology to detect patients with angiostrongyliasis cantonensis. The method was successful in detecting the strikingly increased concentrations of soluble antigens characteristic of A. cantonensis infestation, relative to noninfested controls.

In this study, the AcJ1 mAb was used to capture the circulating antigen in serum, after which the biotinylated AcJ20 mAb bound to the antigen. Free streptavidin was then used to attach biotinylated DNA to the biotinylated AcJ20 mAb. Finally, this complex was amplified by PCR to quantities resolvable by agarose gel electrophoresis. Development of this immuno-PCR technique to aid in the diagnosis of angiostrongyliasis cantonensis was technically challenging. Initially, even the negative control for the first mAb occasionally generated some nonspecific amplification (29), which likely arose as a consequence of the concentration of the biotinylated DNA used for the reaction. A serial 10-fold dilution of the reactive biotinylated DNA revealed that if the DNA concentration exceeded 1 x [10.sup.-19] mol/[micro]L, nonspecific amplification occurred. Thus, this concentration became the optimum.

The sensitivity and specificity of ELISA is influenced by insufficient blocking, and this nonspecific binding may be minimized by saturating the remaining adsorptive surfaces of the assay plate with blocking proteins, such as those in nonfat dry milk (30). Consistent with these observations, we found that signal-to-noise ratios improved when fetal calf serum was used as a blocking reagent in the assay. To minimize nonspecific binding, we used bovine serum albumin plus salmon-sperm DNA as blocking agents. These agents have been used for the same purpose by others (20, 31-33). As reported by others (20, 24, 31), we also minimized the signal-to-noise ratio by extensively washing assay plate wells with detergent-containing buffer during experimental manipulations.

The choice of pUC 19 DNA as a reporter molecule was based on an earlier study (20). The recombinant nature of pUC 19, which contains an ampicillin resistance gene, lacZ, and a restriction enzyme site, makes the chance of encountering the vector or a closely related sequence in human biological specimens virtually zero. This aids in preventing DNA cross-contamination problems. Furthermore, the specificity of immuno-PCR is dependent on the quality of the first antibody used in the process. In our study, we used the AcJ1 mAb, which is highly specific for the [AcL.sub.5] antigen, as the capture antibody.

Sensitivity and specificity are the most important factors in the evaluation of the reliability of a diagnostic technique for parasitic infestations (34). High sensitivity (91%) and specificity (98%) for detecting serum antibodies in patients with eosinophilic meningitis or meningoencephalitis have been obtained by an ELISA incorporating a purified [AcL.sub.5] antigen with a molecular mass of 204 kDa and a corresponding mAb (17). However, delays in the appearance of antibodies after infestation and the persistence of antibodies after cure have restricted the diagnostic reliability of serum antibody detection in patients with these parasitic diseases (18).

The abilities and limitations of mAbs, as described above, led to the adaptation of a double-antibody sandwich ELISA technique as a means of detecting circulating antigens in patient specimens. In an immunoprecipitation analysis, a 204-kDa [AcL.sub.5] antigen could be detected by circulating antibodies in the serum of rats in early stages of experimental infestation (35). Indeed, two mAbs recognizing this antigen have been prepared previously (36) and have been applied for detection of circulating antigen in patients (19). A sandwich ELISA using these mAbs for detection of circulating antigen in the serum of patients achieved high specificity (100%). However, the sensitivity, only 81%, was problematic (19).

In conclusion, in the present study, immuno-PCR, like ELISA, detected circulating 204-kDa [AcL.sub.5] antigens in the serum of patients with eosinophilic meningitis or meningoencephalitis with 100% specificity. In contrast to the ELISA, however, the sensitivity of the immuno-PCR was 100% (95% confidence interval, 93-100%) for patients known to have the parasitic worm in CSF specimens and 96.7 (83-99)% for patients who displayed only clinical syndromes. Thus, the double-determinant immuno-PCR system demonstrates greater sensitivity than appears to be the case for any existing antigen detection system and may become the assay of choice for the routine diagnosis of patients with A. cantonensis infestation.

This study was supported by Grant DOH-89-TS-1003 from the Department of Health, Executive Yuan of the Republic of China. We thank Dr. Shun-Jen Chang (Department of Public Health, Kaohsiung Medical University) for statistical assistance.


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[1] Department of Medical Technology, Fooyin University, 151 Chinhsuen Road, Ta-Liao Hsiang, Kaohsiung, Taiwan, ROC.

Departments of [2] MedicoGenomic Research Center and [3] Parasitology, Kaohsiung Medical University, Shih-Chuan 1st Road, Kaohsiung 807, Taiwan, ROC.

[4] Nonstandard abbreviations: mAb, monoclonal antibody; [AcL.sub.3] and [AcL.sub.5], third- and fifth-stage larvae, respectively, of A. cantonensis; CSF, cerebrospinal fluid; PBS, phosphate-buffered saline; and TETBS, Tris-buffered saline containing EDTA and Tween 20.

* Author for correspondence. Fax 886-7-3218309; e-mail Chmiye@cc.kmu.

Received April 25, 2003; accepted October 1, 2003.

Previously published online at DOI: 10.1373/clinchem.2003.020867
Table 1. Antigen concentration in serum specimens from
patients with eosinophilic meningitis or
meningoencephalitis and control individuals.

 Serum antigen
Group concentration, ng/L P
All patients (n = 60)
 Median 30
 Range <0.1-600
Controls (n = 30) <0.1 <0.001
Parasitologically confirmed
 patients (n = 30)
 Median 25
 Range 3-600
Patients with only clinical
 syndromes (n = 30)
 Median 39 <0.05
 Range <0.1-120
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Article Details
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Title Annotation:Molecular Diagnostics and Genetics
Author:Chye, Soi-Moi; Lin, Shiu-Ru; Chen, Ya-Lei; Chung, Lee-Yi; Yen, Chuan-Min
Publication:Clinical Chemistry
Article Type:Clinical report
Date:Jan 1, 2004
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