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Clinical and Diagnostic Laboratory Immunology, September 2000, p. 734-738, Vol. 7, No. 5
Labsystems Research Laboratories, Labsystems OY, 00811 Helsinki,1 Laakso City Hospital,
Lääkärikatu 8, 00250 Helsinki,2 and Department of Medical
Microbiology, University of Turku,3 and
National Public Health Institute, Department in
Turku,4 20520 Turku, Finland
Received 31 January 2000/Returned for modification 5 April
2000/Accepted 17 May 2000
Chlamydia pneumoniae and Mycoplasma
pneumoniae immunoglobulin G (IgG) and IgA antibody seroprevalence
rates and antibody levels related to age and gender were studied. The
samples (n = 742) were collected during a nonepidemic
period and analyzed by quantitative enzyme immunoassays (EIAs).
Seroprevalence to C. pneumoniae was found to increase
sharply in young children, and in the 15- to 19-year-old group it
reached levels as high as 70 and 60% for IgG and IgA, respectively.
After adolescence, seroprevalence showed a transient decrease and then
continued to increase, although less dramatically than in early
childhood. In the elderly the seroprevalence of IgG antibodies reached
75 and 100% in women and men, respectively. The corresponding rates of
IgA antibodies were 73 and 100%. When a randomly selected subgroup of
samples (n = 66) was analyzed in parallel by a
microimmunofluorescence test and an EIA for C. pneumoniae
IgA antibodies, similar seroprevalence rates were obtained (36 versus
35%). Seroprevalence to M. pneumoniae was already found to
increase very sharply in 2- to 4-year-old children, reaching 16% for
IgG and 8% for IgA. Seroprevalence to M. pneumoniae also
continued to increase in adolescence, but in contrast to that to
C. pneumoniae, the increase leveled off at about 40 to 50%
in adulthood. In subjects aged over 65 years, prevalence did not exceed
60% for IgG or 35% for IgA. The seroprevalence patterns as well as
the medians and variations of levels of C. pneumoniae and
M. pneumoniae IgG antibodies were similar to those of
corresponding IgA antibodies. Compared to IgG antibodies, IgA antibodies do not seem to be of additional value in the diagnosis of
infections caused by these pathogens when single serum specimens are studied.
Chlamydia pneumoniae and
Mycoplasma pneumoniae are common human pathogens causing
asymptomatic, mild, or, rarely, severe upper and lower respiratory
tract infections. The infections are usually not identified in general
health care, because the etiology of respiratory infections is
investigated in only a small proportion of patients, in cases of
prolonged nonresponsiveness to conventional antimicrobial therapy or
pneumonias requiring hospitalization.
Despite the acknowledged importance of these pathogens, only a few
reports have been published on the seroprevalence of antibodies against
them (2-4). The most extensive study of C. pneumoniae immunoglobulin G (IgG) antibodies, involving sample
size, geographic distribution, and long-term surveillance, has been
carried out in Finland (3). All studies published so far
(2-4) have been carried out using an in-house
microimmunofluorescence assay (MIFA) which, compared to the enzyme
immunoassay (EIA) is subjective, utilizes a noncontinuous scale, and is
highly variable in performance (7). None of the studies has
provided data on the prevalence of C. pneumoniae IgA
antibodies, which have recently received much attention as a possible
marker of chronic C. pneumoniae infection (9,
10). M. pneumoniae infection has been found to account for 15 to 20% of all cases of pneumonia (1). However, to
our knowledge, no population-based study of the seroprevalence of M. pneumoniae IgG and IgA antibodies has been carried out.
The aims of this study were (i) to provide epidemiological data during
a nonepidemic period on the distribution of C. pneumoniae and M. pneumoniae IgG and IgA antibodies in relation to age
and gender using quantitative and comparable EIA techniques, (ii) to
compare the sensitivity of the EIA to C. pneumoniae IgA
antibodies with that of the respective MIFA, and (iii) to detect
differences in the epidemiologies of C. pneumoniae and
M. pneumoniae infections.
Samples.
The sample donors were selected randomly. They
represented different age groups of a predominantly urban Finnish
population. The samples were donated voluntarily, and the donors
reported no heart or respiratory diseases and were otherwise apparently healthy. The National Public Health Institute of Finland did not report
C. pneumoniae or M. pneumoniae epidemics during
the sample collection periods (1996 to 1997 and 1999). Table
1 provides details of the sample groups.
The sera were grouped according to the ages of the donors without
knowledge of their personal identities.
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Prevalence of Chlamydia pneumoniae and
Mycoplasma pneumoniae Immunoglobulin G and A Antibodies in a
Healthy Finnish Population as Analyzed by Quantitative Enzyme
Immunoassays
ABSTRACT
Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
INTRODUCTION
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Abstract
Introduction
Materials and Methods
Results
Discussion
References
MATERIALS AND METHODS
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Abstract
Introduction
Materials and Methods
Results
Discussion
References
TABLE 1.
Distribution of the ages, genders, and geographical
locations of subjects giving serum specimens and the year of sampling
EIA and MIFA. C. pneumoniae IgG and IgA antibodies were measured in a blind fashion using C. pneumoniae IgG and IgA EIAs (Labsystems, Helsinki, Finland). The C. pneumoniae EIAs utilize stabilized C. pneumoniae elementary body as an antigen. The assays measure only antibodies to surface-exposed proteins and not antibodies targeted to the genus-specific lipopolysaccharide of C. pneumoniae. The assays have been proven more sensitive than the in-house MIFAs in defining acute C. pneumoniae infection (7a). The EIAs gave borderline positive results with sera with very high concentrations of C. trachomatis antibodies, whereas they consistently gave negative results with sera with lower C. trachomatis antibody concentrations.
IgA antibodies were also measured in a blind fashion using a C. pneumoniae IgA MIFA (Labsystems) with samples from a randomly selected subgroup of 20- to 29-year-old blood donors. The cut-off for positivity in the MIFA was a dilution of 1:8. The sera were analyzed at a dilution of 1:8 and evaluated as definitely positive, borderline positive, or definitely negative. The IgA antibody prevalence rates were assessed using the MIFA in two ways: either taking into consideration only the definitely positive sera or taking into consideration both the definitely and borderline positive sera. An in-house EIA was developed for the analysis of IgG and IgA antibodies to M. pneumoniae. Enhanced binding plates (Labsystems) were sensitized with 150 µl of enriched P1 antigen of M. pneumoniae (Aalto Bioreagents Ltd., Dublin, Ireland) in a concentration of 0.75 µg/well in 0.1 M phosphate-buffered saline, pH 7.4, containing 0.5% (vol/vol) Tween 20. The serum samples were diluted 1:200 in 0.1 M phosphate-buffered saline, pH 7.5, containing 0.5% bovine serum albumin, 0.02% Tween 20, and proprietary proteins, and were incubated at 37°C for 1 h. After the plates were washed five times with a citrate buffer containing 1% Tween 20, horseradish peroxidase-labeled anti-human IgG or IgA antibodies were incubated in the wells as described above. The plates were washed as described above and then incubated with 100 µl of tetramethyl benzidene substrate for 30 min. The reaction was stopped with 100 µl of 0.5 M sulfuric acid, and optical densities were read at 450 nm (Multiskan Ascent; Labsystems). The same calibrators, containing 100 arbitrary enzyme immunoassay units (EIU), and the same positive controls and cut-off controls were used throughout the study. For comparison, all values were determined in EIUs as the net absorbance of the sample divided by the net absorbance of the respective calibrator multiplied by 100. The positivity thresholds (cut-offs) were adjusted to those of other well-established serologic methods. Thus, the cut-offs in C. pneumoniae IgG and IgA EIAs were comparable to the respective cut-offs in C. pneumoniae IgG and IgA MIFAs. The cut-off for the M. pneumoniae IgG EIA was adjusted to the same level as that of the M. pneumoniae IgG EIA of Sanofi Pasteur (Marnes la Coquette, France), and that of the Mycoplasma IgA EIA was adjusted to the same level as that of the Sero MP IgA EIA from Savyon (Ashdod, Israel).Statistical analysis. One-tailed variance analysis and Student's t test for unpaired samples were applied to the sample groups of subjects over 29 years old to investigate the statistical significance of the differences in antibody levels between males and females.
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RESULTS |
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Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
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Comparison of C. pneumoniae IgA prevalence rates assessed by the MIFA and EIA. The randomly selected subgroup of samples (n = 66) was analyzed by both the MIFA and EIA for C. pneumoniae IgA antibodies. When the MIFA data were analyzed considering both definite positives and borderline positives as positives, the seroprevalence of IgA was 53% (35 of 66). On the other hand, when only definite positives were taken into consideration, the seroprevalence was 36% (24 of 66), which was quite comparable to the respective prevalence of 35% (23 of 66) obtained by the EIA.
Distribution of seroprevalence rates and antibody levels by age and
gender.
Figure 1 shows the
comparative distribution of C. pneumoniae and M. pneumoniae IgG and IgA antibodies in relation to age. The
seroprevalence of IgG and IgA antibodies to C. pneumoniae increased sharply in preschool children, reaching 71% for IgG and 57%
for IgA in teenagers; the prevalence then slightly decreased, to
increase again but not so dramatically as in childhood. In the elderly,
prevalence rates reached 84% for IgG and 85% for IgA.
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DISCUSSION |
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Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
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Our results show that the seroprevalence of IgG and IgA antibodies to C. pneumoniae among healthy Finnish persons above 14 years of age is high, increasing until old age. The prevalence of the corresponding M. pneumoniae antibodies also increases rapidly in young people but levels off at the age of 20. Because the samples analyzed in this study were collected during a nonepidemic period, the results reflect the baseline seroprevalence in a given population. This high seroprevalence emphasizes the necessity of analyzing paired samples in identifying acute infection if only IgG and IgA antibodies are measured. It also emphasizes the importance of caution in the interpretation of results concerning the association between antibodies to C. pneumoniae and noninfectious-disease manifestations.
Seroprevalence figures are dependent on the chosen cut-off levels. In our study, the cut-offs used for diagnostic purposes were selected for the determination of seroprevalence rates. However, the cut-off levels selected are not very important for the study of relative trends of antibody prevalences in relation to age.
As for the pattern of C. pneumoniae IgG antibody seroprevalence related to age and gender, our results are generally in agreement with earlier data (2, 4). We also found that prevalence rates sharply increase in healthy Finnish children until the age of 20 years, continuing to increase in older age groups, although less dramatically. The seroprevalence rates of C. pneumoniae in some groups of young children in our study were higher than those reported earlier from Seattle and Denmark (2, 4). The reason for the difference between Finland and Seattle may be the higher degree of institutionalization of day care in Finland. When sampling is focused on a few kindergartens, unrecognized C. pneumoniae infections, manifesting as local outbreaks of flulike illness, may cause biased results. Our results concerning seroprevalence in Finnish children differ slightly from those published earlier by Saikku (10). In his study, the seroprevalence of C. pneumoniae IgG antibodies was only 0 to 10% among children aged 6 to 10 years. Differences between the sensitivity of the in-house MIFA used by Saikku and that of our EIA may be a reason for the discrepancy. In agreement with the results of earlier studies (2-4), our data show the tendency towards higher seroprevalence rates of IgG and IgA antibodies in males than in females for both pathogens studied, but the difference was not statistically significant. It has been suggested that the higher seroprevalence in males indicates that the transmission of the infection mainly occurs outside the home (2). This speculation may, however, not be valid in the Finnish social setting.
Our study shows a slight decrease in the seroprevalence rates of both IgG and IgA antibodies to C. pneumoniae in people aged 20 to 30 years. This decrease may be an artifact attributable to the limited size of each age group in our study. Another reason for the bias may be that subjects below 20 years of age lived in areas different from the areas where the older subjects lived. The younger subjects were from the southern archipelago, a rural area, and from the town of Rovaniemi in northern Finland, whereas the older subjects were mainly from the metropolitan Helsinki area. On the other hand, the decrease could be real, caused by a complex interplay between immunity and changes in the rate of exposure to C. pneumoniae in early adulthood. Whether the transient decrease occurs or not, it does not negate the fact of a steady increase in seroprevalence towards almost complete saturation in senescence. The increase implies that relatively high antibody levels persist in the elderly. The high seroprevalence rates may be due to repeated reinfections, persistent antigenic stimulus, or long-lasting immunological memory. Long-term follow-up studies on the persistence of IgG and IgA antibodies to C. pneumoniae are needed to clarify the role of the persistence.
The steady increase in antibody seroprevalence has been attributed to multiple exposures to C. pneumoniae during the subjects' lifetimes (2, 4). However, Chlamydia-like organisms, e.g., Simkania negevensis and Parachlamydia acanthamoebae, and the four recently discovered organisms with Chlamydia-like sequences may have some impact on the steady increase in antibodies with age because of their possible antigenic cross-reactivities (5, 6).
Earlier, it was suggested that IgA antibodies to C. pneumoniae, by virtue of their short half-life, can be markers of chronic C. pneumoniae infection (9). However, recent studies of the association between IgA antibodies to C. pneumoniae and ischemic heart disease have provided conflicting results (12; L. von Hertzen, R. Isoaho, S.-L. Kivelä, and P. Saikku, Letter, BMJ 318:1575-1576, 1999). Our results show that the seroprevalence patterns and levels of IgA antibodies to C. pneumoniae were rather similar to those of IgG in all age groups. Further studies are needed to determine how the persistence of antibodies in general and IgA antibodies in particular is related to chronic C. pneumoniae infection.
All earlier seroprevalence data on IgG and IgA antibodies to C. pneumoniae were obtained using in-house MIF methods. We have shown that our IgG EIA gives results compatible with those obtained using MIF methods (2, 4). On the other hand, no comparative data were available for the comparison of IgA MIF methods and IgA EIA. Therefore, these tests were compared in a subgroup of specimens randomly selected from the present material. When only definite positives by the MIFA (Labsystems) were considered, similar seroprevalence rates were obtained with the MIFA and the EIA (36 versus 35%). Thus, we conclude that, with the cut-off selected in the present study, the EIA does not overestimate the seroprevalence of IgA antibodies to C. pneumoniae.
IgG and IgA antibodies to M. pneumoniae were measured by in-house EIAs using the enriched P1 protein of Mycoplasma as an antigen. This 168-kDa protein is an adhesin reported to be a highly immunogenic antigen eliciting a strong antibody response in infected hosts while eliciting a low or negligible response in asymptomatic carriers (8). Our results show that seroprevalence to M. pneumoniae increases more sharply in early childhood than that to C. pneumoniae, but then it levels off above the age of 20 years. This confirms the earlier assumption that M. pneumoniae infection is more prevalent than C. pneumoniae infection among children and adolescents, affecting fewer middle-aged and elderly people.
We used samples left over from other studies. The samples, therefore, did not represent the whole country, nor were they collected simultaneously. Further, the gender and age distributions were not uniform in our groups. Despite these weaknesses, we believe that our data reliably reflect true baseline seroprevalence rates and age-related trends. Our results show that high levels of both IgG and IgA antibodies to C. pneumoniae are relatively common, particularly in old age. Efficient treatment trials and long-term follow-up studies are needed to find out whether these antibody levels are maintained by a persistent C. pneumoniae infection, repeated exposures to the organism itself, or some other microbes cross-reacting antigenically with C. pneumoniae. Our data also confirm that C. pneumoniae and M. pneumoniae infections have different epidemiological patterns.
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ACKNOWLEDGMENTS |
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We thank Jorma Ilonen from the Department of Virology and Jaakko Uksila from the Department of Medical Microbiology, University of Turku, for providing us with the specimens.
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FOOTNOTES |
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* Corresponding author. Mailing address: Labsystems Research Laboratories, Labsystems OY, Sorvaajankatu 15, P.O. Box 208, 00811 Helsinki, Finland. Phone: 358-9-32910484. Fax: 358-9-32910531. E-mail: tamara.tuuminen{at}thermobio.com.
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Clinical and Diagnostic Laboratory Immunology, September 2000, p. 734-738, Vol. 7, No. 5
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Copyright © 2000, American Society for Microbiology. All rights reserved.
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