Clinical and Diagnostic Laboratory Immunology, January 1998, p. 70-73, Vol. 5, No. 1
1071-412X/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.
Heterogeneity of Immunoglobulin G Response to
Helicobacter pylori Measured by the Unweighted Pair
Group Method with Averages
Kathryn
Mayo,1
Stefano
Pretolani,2
Giovanni
Gasbarrini,2
Giancarlo
Ghironzi,3 and
Francis
Megraud1,*
Laboratoire de Bactériologie-Enfants,
Hôpital Pellegrin, Bordeaux, France1;
I Pathologica Medica, Policlinico S Orsoloa, Bologna,
Italy2; and
Divisione di Medicina
Generale, Istituto di Sicurezza Sociale, Republic of San
Marino3
Received 21 April 1997/Returned for modification 31 July
1997/Accepted 1 October 1997
 |
ABSTRACT |
The heterogeneity of the immune response to Helicobacter
pylori has always been noticed but has never been evaluated by
obtaining a quantitative measure. For this purpose, sera were tested by enzyme-linked immunosorbent assay, and 207 positive serum specimens were subsequently tested by immunoblotting. The presence or absence of
six specific bands was noted. The homology of the different profiles of
bands was measured by calculating the Dice coefficient, and a
dendrogram was constructed. Thirty-four profiles were found, with each
profile containing from 1 to 43 serum specimens. At a level of 72%
similarity, 115 of the serum specimens studied fell into eight
profiles. At a level of 48% similarity, 186 of the serum specimens
studied fell into 22 profiles. The difference in immunoblot profiles
was probably linked to the host immune response, but infection with
strains carrying different antigens cannot be ruled out.
| |
INTRODUCTION |
Helicobacter
pylori causes gastritis and plays a major role in the pathogenesis
of peptic ulcer (16) and gastric cancer (13).
Because of its uneven distribution on the gastric mucosa, some cases of
H. pylori infection can be missed by culture of biopsy
samples (3). Serological tests are useful because they circumvent this problem in that infected patients develop elevated serum immunoglobulin G (IgG) and possibly IgA antibodies as well as a
local immune response (10, 24). Serological techniques provide a relatively noninvasive method for the diagnosis of H. pylori-associated diseases (12, 22) and are
particularly well suited to seroepidemiological studies
(14). A number of different techniques, i.e.,
hemagglutination, complement fixation, coagglutination, indirect
immunofluorescence, and latex agglutination, have been used. Most
studies, however, have used enzyme-linked immunosorbent assay (ELISA)
and/or immunoblotting (Western blotting) (22).
The immune response to H. pylori in humans has been well
studied qualitatively by using immunoblotting (1). This
technique has not previously been used to compare individual patient
responses quantitatively. In the present study, sera collected for an
epidemiological study were analyzed by ELISA. The sera with results
considered positive and in the "grey zone" were then analyzed by
immunoblotting. The presence or absence of 6 of the 13 possible bands
(2) revealed by immunoblotting were compared by the
unweighted pair group method with averages (UPGMA) (20), and
a dendrogram was constructed to illustrate the similarity between the
immunoblot profiles of strains from different patients. The goal was to
determine how many different profiles could be found and how they were
related.
| |
MATERIALS AND METHODS |
Collection of sera.
The sera used for this study were
collected for a cross-sectional epidemiological study of H. pylori infection in the Republic of San Marino (9).
Subjects were selected from among the adults in the National Register
after a random stratified sampling with proportional allocation by age,
sex, and district. The 2,237 serum specimens collected were tested by
ELISA, and all sera with results considered positive or in the grey
zone were tested by immunoblotting. Of the 1,137 serum specimens which
tested positive for antibodies to H. pylori by
immunoblotting, 207 were chosen at random for study of the
heterogeneity of the IgG response.
The ELISA was performed as described previously (18). The
antigen used in this assay was a centrifuged sonicated extract of two
strains identified as being from serogroups 1 and 3 by the schema of
Lior (15). Antigen was used at 0.5 mg/ml. Sera were diluted
1:100 in phosphate-buffered saline containing Tween 20 and 5 mg of
bovine serum albumin per ml and were tested in duplicate. A goat
anti-human IgG peroxidase conjugate (Nordic Immunological Laboratories,
Tilburg, The Netherlands) diluted 1:5,000 was used. The substrate,
2,2'-azino-di-(3-ethylbenzthiazolinsulfonate) (Boehringer Mannheim,
Mannheim, Germany), was used at 220 mg/ml with 0.1%
H2O2. Coloration was measured in a
spectrophotometer at 405 nm. Optical densities above 0.400 were
considered positive, and values between 0.350 and 0.400 were considered
to be in the grey zone.
All sera considered to be positive or in the grey zone were then tested
by a modification of an immunoblotting technique which has been
previously described (4). For the immunoblotting, the
antigen used was a whole-cell preparation of the same two strains used
earlier for the ELISA. Antigen bands and a mixture of protein standards
(Protein Molecular Weight Standards; range, 14,300 to 200,000; Bethesda
Research Laboratories) were first separated by sodium dodecyl
sulfate-polyacrylamide gel electrophoresis and were then
electrotransferred to nitrocellulose paper (Bio-Rad, Ivry Sur Seine,
France) by using a Biolyon electrotransfer apparatus. Electrotransfer
was carried out under semidry conditions in Trisma base (25 mM)-glycine
(192 mM) containing methanol for 10 min at 12 V and for 1 h at 24 V. Proteins on nitrocellulose were immunoblotted in a Multiscreen
device (Bio-Rad). After a blocking step of 1 h with 3% skim milk
in Tris-buffered saline (TBS) with Tween 20 (0.05%), the immunoblots
were washed three times for 5 min each time with TBS-Tween 20 and were
then placed in contact with sera diluted 1:50 in TBS-Tween 20 with 1%
skim milk for 2 h. After washing, goat anti-human IgG peroxidase
conjugate diluted 1:500 was applied for 1 h. Blots were rewashed
before adding the substrate. The substrate solution consisted of 1.6 mg
of 4-chloro-1-naphthol per ml, 5 ml of cold methanol, and 15 µl of
30% H2O2 in 25 ml of TBS. Coloration of the
substrate was carried out at room temperature in the dark for 30 min
and was then stopped by washing with distilled H2O.
Finally, the protein standards were restained with Poinceau S (Sigma,
St. Quentin, Fallavier, France).
Among the 13 bands which can be present, 6 commonly noted bands which
were considered to be major bands were studied. These particular bands
were chosen because they are usually clear and unequivocal and can be
measured with a certain degree of confidence. The additional bands
potentially present can be more difficult to interpret. The molecular
masses of the bands chosen were approximately 115,000, 93,000, 90,000, 58,000, 45,000, and 20,000 kDa. Their presence or absence was noted for
207 of the serum specimens tested.
Study of the similarities among profiles.
The distance
between the different profiles (combinations of bands) was measured by
calculating the Dice coefficient [(2 × the number of pairs of
characteristics in common)/total number of characteristics in the two
profiles](8). In this calculation only positive
characteristics are taken into consideration.
The Dice coefficient was used in the UPGMA formula to assign levels of
hierarchy in the similarity of profiles. The distance (d)
between two clusters was measured as a function of the number of
individuals in the cluster (M).
In this model, i is a given individual (profile or
cluster of profiles) and jk is the cluster to which i
is being compared, j being the last member added to the
cluster and k being the initial or previous component
(profile or cluster of profiles). By using the levels of hierarchy
assigned by this model, a dendrogram was constructed to illustrate the
relationship between the profiles.
| |
RESULTS |
By using six bands, 34 profiles were found. The relationship
between the different profiles is illustrated in Fig.
1. From 1 to 43 serum specimens were
classified in each of these 34 profiles. The profile with the most
serum specimens (43 serum specimens) was composed of five bands at
115,000, 93,000, 90,000, 58,000, and 45,000 kDa. The next most common
profile contained 19 serum specimens and was composed of four bands
at 115,000, 93,000, 90,000, and 58,000 kDa. Figure
2 illustrates the number of serum
specimens in each profile. At a level of 72% similarity, 115 of the
serum specimens studied fell into eight profiles. At a level of 48% similarity, 186 of the serum specimens studied fell into 22 profiles.
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|
FIG. 1.
Dendrogram of 34 different profiles (combinations of six
bands) revealed by immunoblotting of 207 serum specimens which had
tested positive for H. pylori antibodies by ELISA.
|
|
Thirteen of the 34 profiles contained at least four of the bands
studied. These 13 profiles grouped 130 serum specimens. Of these 130 serum specimens, 3 (2%) had ELISA results considered to be in the grey
zone (optical densities of between 0.350 and 0.400). Of the remaining
77 serum specimens whose profiles contained three or fewer of the bands
studied, 8 (10%) had ELISA results in the grey zone. Therefore, a
total of 11 of the 207 serum specimens studied had ELISA results in the
grey zone.
The profile (profile 1) with all six bands contained 13 serum
specimens. Five profiles (profiles 2 to 5 and 34) contained five bands.
As a group, they contained 59 serum specimens. The seven different
profiles (profiles 6 to 12) with four bands grouped a total of 59 serum
specimens. The 13 profiles with three bands were profiles 13 to 22 and
31 to 33. They grouped 46 serum specimens. Profiles with two bands
(profiles 23 to 28) grouped 25 serum specimens. Two profiles had only
one band, and these two (profiles 29 and 30) contained six serum
specimens.
| |
DISCUSSION |
It is interesting that 17 of the 34 profiles found lacked a band
at 115 kDa. These 17 profiles together contained 65 serum specimens
(31%). Although in some cases differences in the molecular masses of
the protein bands reported in the literature can be due to differences
in the extraction procedures and gel electrophoresis techniques used,
in the case of the 115-kDa band studied here, the differences observed
by Faulde et al. (12) (130-kDa protein), Reiff et al.
(19) (120-kDa protein), and von Wulffen (22) (110-kDa protein) are due to the structure of the gene coding for this
protein (6). This gene has been found to contain sequences which can be repeated a variable number of times, affecting the length
of the protein product. The results of this study are in agreement with
those of previous studies (7, 12), which found that the
prevalence of this antigen was 60 to 70% in patients with nonulcer
dyspepsia. This antigen is of special importance because it is a marker
for the cag pathogenicity island (5) which is
more frequently found in strains isolated from patients with severe
diseases (7, 23). In considering the frequency of antibody
response to this protein, one must bear in mind that the sera for this
study came from the general population and not a population of patients
with gastric diseases.
Exactly where to place the cutoff point when interpreting ELISA data is
a perennial problem. Some investigators even suggest that it should
change as a function of the population studied (11).
Immunoblotting can be used to verify questionable ELISA results, but it
is not required to verify results after a certain level of positivity
has been reached.
Human serum contains antibodies that react with a number of different
H. pylori antigens (2). Several bands are
detected by immunoblotting significantly more frequently with sera from H. pylori-positive patients than healthy controls. The total
number of bands detected by individual sera is higher for H. pylori-positive patients than for healthy controls. The problem
with immunoblotting, however, is that tertiary and quaternary protein
structure can be affected by denaturation by sodium dodecyl sulfate and
reduction of disulfide bonds during electrophoresis (21).
This could lead to a loss of or a decrease in the antigenicity of the
epitopes presented to the antibody.
In this study, the profiles obtained by immunoblotting were compared.
The technique used to compare these profiles has been proposed for
bacterial taxonomy. Although arbitrary, the results allow for a
systematic comparison of the homology found between different profiles.
The significance of the heterogeneity found is not addressed. For the
immunoblotting analysis, all serum specimens were tested against the
same strain and not the homologous strain (the strain isolated from the
same patient). The differences in the profiles obtained by
immunoblotting could be due to heterogeneity in the host immune
response or to infection with strains with different antigens. Despite
the genetic heterogeneity of H. pylori strains
(17), most antigens are conserved. Although not proven, the
diversity in immunoblotting profiles noted in this study was most
likely due to the immune response of the host.
We used a collection of sera obtained from a well-designed
epidemiological study in the general population in order to achieve insight into the extent of heterogeneity of the immune response. This
provides the background and paves the way for the study of different
groups of patients. The diversity of the immune responses observed with
sera from asymptomatic H. pylori-infected subjects indicates
that sera from patients with different clinical entities should also be
studied in an attempt to find a specific profile which could be useful
for diagnostic purposes.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Laboratoire de
Bactériologie, Hôpital Pellegrin, Place Amélie
Raba-Léon, 33076 Bordeaux cedex, France. Phone: (33) 5 56 79 59 10. Fax: (33) 5 56 79 60 18. E-mail address:
Francis.Megraud{at}labhel.u-bordeaux2.fr.
| |
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Clinical and Diagnostic Laboratory Immunology, January 1998, p. 70-73, Vol. 5, No. 1
1071-412X/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.
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Abstract
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