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Previous Article | Next Article 
Journal of Clinical Microbiology, April 2001, p. 1316-1318, Vol. 39, No. 4
0095-1137/01/$04.00+0 DOI: 10.1128/JCM.39.4.1316-1318.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
Epidemiological Usefulness of Anti-Opacity Factor
Antibody Screening in Schoolchildren
Sunjoo
Kim1 and
Nam Yong
Lee2,*
Department of Clinical Pathology, Gyeongsang
National University School of Medicine, Chinju,1
and Department of Clinical Pathology, Samsung Medical Center,
Sungkyunkwan University School of Medicine,
Seoul,2 Korea
Received 18 October 2000/Returned for modification 2 December
2000/Accepted 11 January 2001
 |
ABSTRACT |
The presence of the anti-opacity factor (anti-OF) antibody (Ab) in
the serum used for identifying the OF antigen (Ag) type represents
previous or current infection with group A streptococci (GAS) of the OF
Ag type. Throat cultures were taken from 172 elementary schoolchildren
in Chinju, Korea, and venous blood samples were collected at the same
time to screen for the frequency of the anti-OF Ab. After isolation of
GAS, the OF Ag of each GAS was identified by inhibition of the opacity
reaction with recognized anti-OF sera. The anti-OF Abs in the sera were
screened with the six most common OF Ag types. OF22 and OF28 were high
in prevalence (28.2 and 20.5%, respectively) among OF Ag types, while
anti-OF types 4, 28, and 22 were frequently identified (39.5, 29.7, and 15.7%, respectively) in the sera. Thirty-two of 39 (82.1%) OF Ag-producing GAS carriers, 25 of 34 (73.5%) GAS carriers not producing OF Ag, and 72 of 99 (72.7%) throat culture-negative children harbored the anti-OF Ab. Forty-five (26.2%) of 172 children had two different anti-OF Abs, and 11 (6.4%) had more than three anti-OF Abs.
Seventy-five percent of 172 elementary schoolchildren were shown to be
previously or currently infected with GAS. The percentages of children
positive for the anti-OF Ab were very high regardless of the result of throat culture or OF Ag production of GAS. We could also demonstrate (i) that the prevalent strains of GAS changed according to the time
span by determining the difference between the frequencies of OF Ag and
anti-OF Ab and (ii) that repeated infections were not uncommon in
schoolchildren, as one-third had more than two different anti-OF Abs.
| |
INTRODUCTION |
There has been a remarkable increase
in the number of reports of severe invasive infections caused by group
A streptococci (GAS) during the last decade (3).
Serotypings are important not only for surveying the epidemiology of
GAS infections but also for understanding the mechanism of invasive
infections. Opacity factor (OF), a cell wall component of GAS, makes
horse serum opaque (5, 20). The physicochemical properties
of OF are almost similar to those of M protein (21).
Generally OF-positive strains do not stimulate an immune response in a
rabbit. OF is an apolipoproteinase which is inhibited by pepsin or
trypsin but which is not affected by HCl or heating (6,
18). Recently Kreikemeyer et al. revealed that OF is sfbII, a
fibronectin binding surface protein of GAS (11). OF
antigen (Ag) has type specificity, and the OF type is concordant with
the M type (20, 21). There are currently about 80 recognized and confirmed M types (8, 9). Of these, 27 are
known to produce OF. More M types make it likely that we will identify
more OF producers (4). OF typing is useful in the
identification of new M types as well as in simplifying M typing by
saving time, labor, and valuable sera. The OF type of the strain is
determined by inhibition of the serum opacity reaction (SOR) after
mixing OF protein and type-specific human anti-OF sera. We isolated GAS
from healthy schoolchildren by throat culture and T, OF, and M
serotypings to characterize the GAS carrier status. When someone is
infected with GAS, he or she can make either anti-M or anti-OF antibody
(Ab), depending on the serotype of the strain. The Ab seems to persist
lifelong and to protect from reinfection with the same serotype
(12). Detection of the anti-M Ab in the sera is very hard
to perform. The anti-OF Ab type is rather easily determined in the same
way as the OF Ag type is determined. The presence of the anti-OF Ab
indicates previous or current GAS infection (12). The
presence of multiple anti-OF Abs indicates that the person was infected
several times with different serotypes. To evaluate the immune status
of GAS infections, blood samples drawn from the same children were
screened for anti-OF Abs. Most of the previous epidemiological studies
have been performed with throat culture and serotypings (10,
17). The epidemiological usefulness of the anti-OF Ab for
surveying the degree of past or present infection of GAS in the
schoolchildren was compared with that of throat culture.
| |
MATERIALS AND METHODS |
Bacterial isolation and serotyping.
Throat cultures were
taken from 172 healthy schoolchildren (ages 7 to 12) without any
symptoms or signs of pharyngitis in Chinju, Korea. After incubation of
the blood agar plate overnight at 37°C, beta-hemolytic streptococci
were identified with a bacitracin disk (0.04 U) and a latex
agglutination test (A Strep AD; Denka Seiken, Tokyo, Japan). After the
T type of GAS was screened with anti-T sera (Sevac, Prague, Czech
Republic) (1), cell wall protein extracted either by the
Lancefield hot-acid method or with 1% sodium dodecyl sulfate was used
for SOR screening (7). If the cell wall protein was SOR
positive, it was mixed with type-specific human anti-OF sera. Anti-OF
sera used included types 2, 4, 9, 11, 13, 22, 25, 28, 48, 49, 58 to 64, 66, 68, 73, 75 to 78, and 81 (1). Identification of OF Ag
types was performed by a microwell technique using horse serum (Gibco
Laboratories, Grand Island, N.Y.) according to the result of T Ag
typing (8). Opacity was spectrophotometrically measured at
450 nm. If cell wall extract was SOR negative, M types were identified
by Ouchterlony double immunodiffusion (19). The anti-M
sera used were 1 to 6, 8, 12, 14, 15, 17 to 19, 22 to 26, 28, 36 to 41, 43, 47, 49, 51 to 53, 58, 60, 75, and 76.
Anti-OF Ab typing.
The sera of children were reacted with
six representative OF Ags of GAS, which were commonly isolated from
Chinju, including T4/OF4, T11/OF78, T12/OF22, T12/M nontypeable (NT),
T13/OF13, and T28/OF28. The anti-OF Ab type was identified by a
microwell technique (8). We classified the children into
three groups: group I, children with OF-positive GAS; group II,
children with OF-negative GAS; group III, children without GAS in the
throats. The frequency and numbers of anti-OF Ab types in the sera were analyzed for each group of children. The percentages of children positive for anti-OF Abs for all school grades were compared.
| |
RESULTS |
Serotyping.
Cultures from 73 (42.4%) of 172 children tested
grew GAS, of which 39 (53.4%) strains were SOR positive (Table
1). OF22 (28.2%) and OF28 (20.5%) were
the most common OF types (chi square = 18.1; P = 0.0029). T types of 13 (33.3%) OF-NT strains were as follows: 6 were T12, 2 were T4, 1 was T28, and 4 were NT. Of the 34 SOR-negative strains, M12 (52.9%) was predominant and M6 (17.9%) was the next most
common (chi square = 35.9; P = 0.0001). OF types
4, 13, and 78 were rare.
Anti-OF Ab typing.
The frequencies of anti-OF Ab types are
shown in Table 2. Anti-OF types 4 and 28 were predominant in all three groups. The frequencies of anti-OF types
4 and 28 were 39.5 and 29.7%, respectively. Anti-OF type 22 is more
common (22.2%) in group III than in other groups. Anti-OF types 22, 78, and 13 were not common (likelihood chi square = 21.1;
P = 0.0205).
Thirty-two (82.1%) of the children in group I had the
anti-OF Ab (Table 3).
Percentages of children positive for the anti-OF Ab in group II and
group III were 73.5 and 72.7%, respectively (chi-square test;
P > 0.05). Forty-five (26.2%) had two anti-OF types,
while 11 (6.4%) harbored more than three anti-OF types.
Sixty-two percent of the first-grade schoolchildren had the anti-OF Ab
(Table 4). The percentages of children
positive for the anti-OF Ab in the other school grades ranged from 70.4 to 82.8%, which showed no significant differences according to school grade (chi-square test; P > 0.05).
| |
DISCUSSION |
Although we do not know the full biological significance of the OF
protein, OF Ag typing has been used for the epidemiological study of
GAS infections, especially when the strains do not produce an immune
reaction in a rabbit. The anti-OF Ab in the serum of a patient is a
marker for a past or current infection with the specific OF type strain
and has a preventive role for reinfection with the same type
(13). There have as yet been no reports on the frequency
of the anti-OF Ab, as analyzed either by the results of throat cultures
or by the nature of cell wall protein of GAS in schoolchildren.
Screening anti-OF Abs in the sera was very useful to elucidate
previously widespread strains and the degree of infections in the
community (14, 15). On the basis of the results for the
distribution of anti-OF Abs in Chinju, Korea, OF types 4 and 28 might
have been the most prevalent in the past. On the basis of the
serotyping data, we assumed that an OF type 4 strain had been very
common in the past but is now rare. Infections with OF type 28 were
common in the past and continue to be. The most common OF types of GAS
were OF22 (28.2%) and OF28 (20.5%), but the frequency of anti-OF22
(15.7%) did not use to be so high, which suggests that infections with
OF22 are more frequent now than in the past. Many authors reported that
the serotypings of GAS changed annually, which might be due to a change
in bacterial invasiveness or host immunity (2). In the
distribution of M types of SOR-negative strains, M12 (52.9%) was
predominant. Group II had either anti-OF type 28 (32.4%) or 4 (26.5%)
commonly. Group III frequently contained anti-OF types 4 (42.4%), 28 (23.2%), and 22 (22.2%), while anti-OF types 13 and 78 were less
common (10.1%). Although group III showed no GAS in the throats,
unexpectedly 72.7% have been infected with various types of GAS. There
is no significant difference in the number of anti-OF types among the three groups. The percentage of children positive for the anti-OF Ab in
the first grade was 62.3%, indicating that many children were already
infected with GAS before admission to elementary school. But the
percentages of samples positive for the anti-OF Ab in the other school
grades did not significantly increase. Infections with a new serotype
of GAS might not occur frequently in this age group. Anti-OF Ab
screening of schoolchildren detected GAS infection in three-fourths of
those tested. On the basis of throat cultures, the carrier rate of GAS
in schoolchildren ranged from 10 to 20%. Although their population and
OF Abs studied are different from ours, Prakash and Dutta demonstrated
that 39% of 235 subjects had at least one type of OF Ab
(16). They found that ~48% had two or more Abs and that
certain types of Abs were prevalent in rheumatic fever or acute
glomerulonephritis patients. Differences among studies may be due to
the populations investigated and are not due to the methods employed.
Considering that we did not detect the anti-M Ab in the sera, it is
probable that the percentage of those actually infected with GAS is
greater than 75%. One-third (32.6%) of schoolchildren were infected
with more than two different OF types, which indicates that multiple
infections were not uncommon in schoolchildren.
In conclusion, GAS infections were quite common in Korean
schoolchildren. The spectra of previously prevalent strains were different from those of the currently widespread ones. Multiple infections were not uncommon. Sixty-two percent of the first-grade schoolchildren were already infected with GAS. Screening the anti-OF Ab
was quite valuable for understanding the epidemiology of GAS infections. Because anti-OF Ab screening is simpler and easier to
perform than the serotyping of GAS, screening anti-OF Abs can be
effectively used for the epidemiological study of GAS in the community.
| |
ACKNOWLEDGMENTS |
We appreciate the technical advice from and provision of anti-OF
and anti-M sera by Dwight R. Johnson and Edward L. Kaplan at the
Department of Pediatrics and World Health Organization Collaborating
Center for References and Research on Streptococci, University of
Minnesota Medical School.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Department of
Clinical Pathology, Samsung Medical Center, Sungkyunkwan University
School of Medicine, 50, Ilwon-Dong, Kangnam-Ku, Seoul, Korea 135-710. Phone: 82-2-3410-2706. Fax: 82-2-3410-2719. E-mail:
mrmicro{at}samsung.co.kr.
| |
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Journal of Clinical Microbiology, April 2001, p. 1316-1318, Vol. 39, No. 4
0095-1137/01/$04.00+0 DOI: 10.1128/JCM.39.4.1316-1318.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
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Abstract
Introduction
