BioMed CentralBMC Oral Health
BMC Oral Health 2002, 2Research article
Elevated antibody to D-alanyl lipoteichoic acid indicates caries 
experience associated with fluoride and gingival health
Martin Levine*1, Robert L Brumley1,4, Kevin T Avery2, Willis L Owen3 and 
Donald E Parker3

Address: 1Department of Biochemistry and Molecular Biology, University of Oklahoma Health Sciences Center, P.O. Box 26901, Oklahoma City 
OK 73190 USA, 2Department of Community Dentistry, University of Oklahoma Health Sciences Center, P.O. Box 26901, Oklahoma City OK 
73190 USA, 3Department of Biostatistics and Epidemiology, University of Oklahoma Health Sciences Center, P.O. Box 26901, Oklahoma City OK 
73190 USA and 4GenSys Technologies Inc., 9155 Little Farm Dr White Lake, MI 48386

E-mail: Martin Levine* - martin-levine@ouhsc.edu; Robert L Brumley - jaluckey@aol.com; Kevin T Avery - kevin-avery@ouhsc.edu; 
Willis L Owen - willis-owen@ouhsc.edu; Donald E Parker - don-parker@ouhsc.edu

*Corresponding author

Background: Acidogenic, acid-tolerant bacteria induce dental caries and require D-alanyl glycerol
lipoteichoic acid (D-alanyl LTA) on their cell surface. Because fluoride inhibits acid-mediated
enamel demineralization, an elevated antibody response to D-alanyl LTA may indicate subjects with
more acidogenic bacteria and, therefore, an association of DMFT with fluoride exposure and
gingival health not apparent in low responders.

Methods: Cluster analysis was used to identify low antibody content. Within low and high
responders (control and test subjects), the number of teeth that were decayed missing and filled
(DMFT), or decayed only (DT) were regressed against fluoride exposure in the water supply and
from dentrifice use. The latter was determined from gingival health: prevalences of plaque (PL) and
bleeding on probing (BOP), and mean pocket depth (PD). Age was measured as a possible
confounding cofactor.

Results: In 35 high responders, DMFT associated with length of exposure to fluoridated water (F
score), PL and BOP (R2 = 0.51, p < 0.001), whereas in 67 low D-ala-IgG responders, DMFT
associated with PL, age, and PD (R2 = 0.26, p < 0.001). BOP correlated strongly with number of 7
7 decayed teeth (DT) in 54 high responders (R2 = 0.57, p < 0.001), but poorly in 97 low responders
(R2 = 0.12, p < 0.001). The strength of the PD association with DMFT, or of BOP with DT, in high
responders significantly differed from that in low responders (p < 0.05).

Conclusion: Caries associates with gingival health and fluoridated water exposure in high D-alanyl
LTA antibody responders.

Background
Over the last 50 years, the widespread usage of fluoridated
water and fluoridated dentrifices have been cited as major

reasons for a decline in caries since the early 1970s [1],
and for the appearance of a significant association be-
tween oral hygiene and caries experience [2–4]. An inverse

Published: 12 February 2002

BMC Oral Health 2002, 2:2

Received: 12 October 2001
Accepted: 12 February 2002

This article is available from: http://www.biomedcentral.com/1472-6831/2/2

© 2002 Levine et al; licensee BioMed Central Ltd. Verbatim copying and redistribution of this article are permitted in any medium for any purpose, 
provided this notice is preserved along with the article's original URL.
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relationship exists between salivary fluoride concentra-
tion and caries experience in the deciduous and perma-
nent dentition [5], but fluoride concentration is excluded
from most caries prediction models [6,7]. Acids in bacte-
rial plaques cause caries in pits, fissures and interdental re-
gions of teeth, but they also enhance the inhibitory effect
of fluoride on demineralization, confounding the ability
to predict caries from the salivary fluoride concentration
[8,9].

The greater the consumption of dietary sucrose, the great-
er the fall in pH and fraction of acidogenic, acid tolerant
bacteria in tooth adherent plaques [10,11]. The number
of these bacteria (mostly mutans streptococci and lactoba-
cilli), and the fluoride content, discriminate between se-
vere and mild caries in 12–15 year-old children [12,13].
Acid-tolerant bacteria require D-alanyl glycerol lipotei-
choic acid (D-alanyl LTA) in their membranes and cell
surfaces [14]. D-alanyl LTA is made by esterifying car-
boxyl-activated D-alanine to glycerol in membrane LTA
by means of a D-alanyl-carrier enzyme, DCP [15]. Strains
of Streptococcus mutans in which DCP is inactive do not in-
itiate growth at below pH 6.5 and make glycerol LTA with-
out D-alanine [14]. In the DCP active strains, soluble D-
Alanyl LTA is extruded into culture fluid in vitro[16,17] or
plaque in vivo[18]. The D-alanyl esters are stable at pH 6.0
at 37°C, but hydrolyze to free D-alanine and LTA with a
half-life of 3.9 h at pH 8.0 [19]. Healthy gingival sulci
have a pH of 6.5 – 7.5 and inflamed sulci a pH of 7.5–8.5
[20].

About 30% of young adults have serum IgG antibodies
that precipitate with D-alanyl LTA, but not with D-
alanine-free LTA [17,21]. It is likely that plaques induce
these IgG antibodies from gingival sulci that contain more
acid-tolerant bacteria. An elevated IgG antibody response
to D-alanyl LTA may therefore indicate the subjects in
whom an inhibitory effect of fluoride on caries is en-
hanced. The fluoride concentrations of plaque and saliva
are related to whether the drinking water is fluoridated
[13] and to oral hygiene, which nearly always involves us-
ing a fluoridated dentrifice. The aim of this study was
therefore to determine whether elevated antibody re-
sponders to D-alanyl LTA show a association of DMFT
with fluoride exposure and gingival health not apparent
in low responders.

Methods
Subjects
Antibody was obtained from blood from four sources: 1)
105 dental students, 2) 147 patients seeking dental treat-
ment, 3) 145 volunteer blood donors (volunteers), and 4)
37 siblings aged 5 through 25 from six Amish families.
The dental students and patients were attending the Uni-
versity of Oklahoma Health Sciences Center between

1985 and 1988. The volunteers and Amish family mem-
bers were attending centers elsewhere in the US at the
same time. All subjects consented to provide blood for an-
tibody analysis according to local Institutional Review
Board procedures (see Acknowledgements). The student,
patient and volunteer populations (397 subjects) were
used to determine what IgG concentration constituted an
elevated antibody response to D-alanyl LTA, to ensure
that these antibodies were not unique to dental or Okla-
homa populations and to examine whether the antibody
concentration was sex or age-associated. The Amish family
siblings were selected to determine the frequency of high
antibody concentration in children and young adults.
Each sibling had at least one parent high responder to in-
crease the likelihood of exposure to an antibody-associat-
ed oral microbiota from birth.

The clinical study participants consisted of 87 dental stu-
dents (88.4% male) and 64 patients (31.3% male) who
were medically healthy. All had 18 or more natural teeth
and were aged >22 and <38 years. Of these participants,
67 dental students and 35 patients provided information
that permitted an estimate of exposure to fluoridated wa-
ter: residence(s) from birth through age 14 in the 1980
Fluoridation Census. Subjects not using the public water
supply, or resident outside of the US for more than 18
months, were excluded. Exposure to water fluoridation
scored 1 for each of five 3-year age cohorts: 0–2, 3–5, 6–
8, 9–11 and 12–14 to give a fluoride exposure score (F
Score) of 0 (no exposure) to 5 (complete exposure) de-
scribed previously [22].

Most dental students had mild caries and gingivitis and
most patients had moderate to severe caries and gingivitis.
Exceptionally healthy or exceptionally diseased subjects
were therefore increased compared to a similar number of
subjects obtained as a random sample. This wide distribu-
tion of clinical measurements provided more stable esti-
mates (narrower confidence intervals) of regression
coefficients (β) than would be obtained from a similar
number from a random survey of the general population.
Regression lines are more robust when a greater range of
measurements is used [23].

Clinical measurements
Dental caries experience was the number of Decayed,
Missing and Filled Teeth (DMFT), excluding third molars
and teeth reported missing for other reasons. Decayed
teeth (DT) were also enumerated separately from missing
and filled teeth (MFT). DT indicates a combination of de-
lay in seeking therapy and faster development of new cav-
ities. Fluoridated dentrifice use is related to oral hygiene
but not toothbrushing frequency in adults aged as in the
present clinical study [3] and young enough to have likely
used fluoridated dentrifices from early childhood. Sensi-
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tive staining for plaque accumulation [24] was therefore
used with measures of gingivitis and pocket depth at the
mesio-buccal, buccal, disto-lingual and lingual surfaces of
the six teeth employed for the simplified oral hygiene in-
dex [25], substituting adjacent teeth as necessary (24 sites
sampled).

Gingivitis was determined by whether a site bled within
30 sec of gentle probing, BOP [26,27] and pocket depth
by measuring the distance (mm) from the free gingival
margin to the base of the sulcus or pocket. Finally, each
subject was asked to suck an erythrosin tablet for 30 sec
and the sites examined for stained plaque [24]. For each
subject, the mean prevalences of plaque (PL) and bleed-
ing on probing (BOP), and the mean pocket depth (PD),
were calculated across all sampled sites. The clinical meas-
urements were made by two experienced clinicians who
were calibrated for this study. The clinicians agreed
strongly with respect to all measurements (correlation co-
efficients, r > 0.85; p < 0.001) except gingival bleeding in-
dex, for which a weaker correlation was noted (r = 0.60, p
< 0.001). The data reported are the mean measurements
from the clinical examiners.

Antigen purification
D-alanyl LTA, but not D-alanine-free LTA, is present in
culture filtrates of Streptococcus mutans GS5 [17]. Bacteria
were grown at 37°C in trypticase soy broth to late station-
ary phase (96 h), when the maximal amount of antigen is
extruded into the culture fluid [18]. After centrifugation to
remove the bacteria, culture fluid (10 1) was concentrated
20-fold over a YM10 Diaflo Membrane filter (Amicon
Corp., Beverley, MA). D-Alanyl LTA in the concentrate was
detected by immunoelectrophoresis, using a standard hu-
man serum identified previously [16]. D-Alanine-free LTA
does not react with this serum IgG [17,18,21]. The D-ala-
nyl LTA was purified by passing the concentrated culture
fluid over a 90 × 2.5 cm Sephacryl column in 0.4 M NaCl
buffered with 0.05 M sodium acetate pH 5. Antigen in the
fractions was collected. After equilibrating with 5 mM so-
dium acetate buffer pH 5.0, it bound to a short Sephacryl
S-200 and eluted by adding 14 mM NaCl as described pre-
viously [16].

Measuring antibody content and determining high and low 
responders
IgG antibody content was measured by enzyme-immu-
noassay employing a Fast Assay Screening Test System at
room temperature [28]. Pegs protruding from a lid were
placed over a 96-well plate or trough containing 14 ml of
10 µg/ml D-alanyl LTA in acetate buffer pH 5 for 2 h (Bec-
ton Dickinson, Lincoln Park, NJ). The pegs were blocked
with 14 ml of phosphate buffered saline (PBS) pH 7.0 in
1.0% Tween-20 and immersed in wells containing 0.1 ml
serum. After overnight incubation, excess IgG antibody

from the serum was washed away by thrice transferring
the pegs to troughs containing 14 ml of PBS containing
0.05 % Tween 20 (PBS-Tween) for 5 min each time. The
pegs were then immersed for 2 h in a trough containing
14 ml of anti-human IgG F(ab'2) fragment conjugated to
alkaline phosphatase in PBS-Tween and developed with
nitrophenyl phosphate (Sigma Chemical Co. St Louis,
MO).

The concentration of antigen-specific IgG in standard se-
rum was obtained by measuring the optimal amount of
protein immunoprecipitated [16], and a standard curve of
absorbance against concentration was obtained (Fig. 1).
The greatest range of absorbance occurred when sera were
measured at a dilution of 1:200 [28]. Replicate antibody
assays were performed on each serum and the concentra-
tions read off the standard curve. The antibody concentra-
tions are shown ranked in Fig. 2.

Data analyses
The amount of IgG antibody to D-alanyl LTA varies with
no obvious cutoff (Fig. 2). However, the sera containing
precipitating antibody should tend to have high IgG anti-
body contents. The IgG antibody measurements were al-
ternatively divided into clusters, using the unweighted
pair group method with arithmetic averages [29] and NT-
SYS, a package of multivariate statistical computer pro-
grams [30]. A low response supremum was obtained by
taking the antilog of the mean IgG content of the non-pre-
cipitating sera plus one standard deviation, or the antilog
of the highest IgG content of the cluster grouping contain-
ing the least antibody.

Figure 1
Graph of absorbance at 410 nm against log ng/ml of antibody
to D-alanyl LTA. Vertical lines indicate the standard deviation
of the measurements.
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The effect of age was determined after splitting the sub-
jects into decile cohorts (Table 1) and comparing the frac-
tion of high antibody responders in each cohort. The
youngest cohort was composed of Amish family siblings
who were younger than any dental students, patients or
volunteers.

A multiple linear regression procedure was utilized to ex-
amine the relationship of caries (DMFT) with age, F score,
and measures of gingival health obtained in this study: PL,
BOP, and PD. The regression on DMFT was used: 1) to es-
timate the partial regression coefficients (β coefficients)
within the high and low antibody response group; 2) to
test each β coefficient for significance after accounting for
the effects of the other four variables; and 3) to examine
for significant differences in β coefficients between the an-
tibody response groups. A β coefficient is interpreted as
the change in disease response (DMFT) per unit change in
one of the independent variables after adjusting for all the
other independent variables in the model. Within each
antibody response group, the multiple regression coeffi-
cient (R2) provided an estimate of the proportion of vari-
ance in DMFT explained by the combination of variables
tested. Stepwise regression then identified the best esti-
mate of the variance in DMFT that was explained by mul-
tiple variables in the separate and combined high and low
responder groups. These multiple regression analyses
were repeated using gingivitis (BOP) as the dependent
variable and OHPI, PD, DT and MFT and age as independ-
ent variables. All of the clinically examined subjects were
included because F score was not an independent variable
for BOP.

To ensure that obtained relationships were robust, influ-
ential points (outliers) were identified using a statistic
(DFFITS) which measured the change in coefficients
caused by removing the data for each subject. If this
change exceeded 2√(p/n), where p was the number of in-
dependent variables and n the number of samples [31],
the point was influential. Repeating the regressions with
all the influential points removed determined the degree
to which these points had affected the results.

Results
Definition of high antibody response
IgG antibodies were initially detected in sera irrespective
of whether D-alanyl LTA was immunoprecipitated. Ex-
cluding the Amish family group, there were 288 subjects
whose sera failed to immunoprecipitate antigen (detected
by immunoelectrophoresis). The mean IgG antibody con-
centration (log ng/ml) was 3.19 (0.64 standard deviation,
s.d.) compared with 4.25 (0.57 s.d.) for 109 subjects
whose sera did precipitate antigen ('t' test p <10-6). High
responders therefore had a log antibody content (ng/ml)
that exceeded the mean plus standard deviation of non-
precipitating serum (log ng IgG /ml >3.83). However, low
IgG concentrations formed a cluster whose supremum
(log ng IgG antibody/ml) was 3.861, which corresponds
to 7.26 µg/ml (left side of Fig. 2). Subjects were therefore
classified as low responders if their log IgG antibody con-
tent exceeded 3.86 rather than 3.83. The odds ratio for a
serum from a high antibody responder immunoprecipi-
tating D-alanyl LTA was 14 times greater than for a low re-
sponder.

Figure 2
Graph of ranked antibody contents. The cut-off points sepa-
rates high from low responders (see Methods).

Table 1: Age decile cohorts for determining changes in fraction of 
high antibody responders

Cohort No. Decile aNumber in Cohort High Responders

1 5–15 b19 c21.05%
2 15–25 b97 35.05%
3 25–35 176 36.36%
4 35–45 76 40.79%
5 45–55 31 38.71%
6 55–65 13 c23.08%
7 65–72 6 c16.67%

a381 subjects after excluding all Amish family members and 16 of the 
397 dental student, patient and volunteer subjects whose age was not 
recorded. bThe Amish family siblings <15 years comprised Cohort 1 
and those >15 years were included within Cohort 2. cComparison of 
cohorts 1, 6 and 7 with the remainder: X2 = 3.21, p = 0.073 (not sig-
nificant).
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High antibody response, age and gender
Of the 397 students, patients and volunteers, 16 did not
have their age recorded. High responders had a mean age
of 32.7 years ± 9.4 s.d. (136 subjects) and low responders
a mean age of 33.0 years ± 10.7 s.d. (245 subjects). Table
1 shows the fraction of high responders in different age
cohorts. There was a high responder frequency of 35–40%
from age 15 through 54. The reduced frequencies of high
response in childhood and old age were not significant.
However, within the Amish family offspring high IgG re-
sponders were significantly older. Table 2 shows that the
high responder offspring had a mean age of 17.1 years
compared with 13.3 years for low responders. This signif-
icant difference ('t' statistic = 2.42, degrees of freedom, d.f.
= 35; p < 0.03) was due to few high responder children
and young teenagers and a slightly greater fraction of sib-
lings aged 15–25 years who were high responders (50%)
compared with the general population.

High antibody responders accounted for a similar fraction
of subjects irrespective of whether they were in the clinical
study, or dental students, or patients (Table 3). Men were
49.1% of the 395 students patients and volunteers whose
sex was recorded. Men had also a greater frequency of high
response 40.21% vs 31.34% and a greater mean log ng/ml
IgG antibody content, 3.52 ± 0.76 standard deviation
(s.d.) vs 3.44 ± 0.80 s.d. Neither of these differences were
significant (X2 = 3.00, p = 0.09; 't' statistic = 0.34, p =
0.73). In serum samples from 18 subjects aged between
22 and 38, the IgG antibody concentrations were essen-
tially the same after 6 months as originally estimated
(squared correlation coefficient, R2 >0.95, p < 0.01). The
results indicate that, for subjects aged 15 – 55, age and sex
had little effect on the frequency of high D-alanyl LTA an-
tibody response.

Association of DMFT with gingival health and fluoride in 
high and low responders
Table 4 lists the variables tested for association with DMFT
and the observed β coefficients in high and low antibody
responders. It was immediately apparent that the β coeffi-
cients from PL were similar in both groups, whereas those
from BOP and F score were only significant in high re-
sponders and those from PD were only significant in low
responders. Comparison of the differences in β coeffi-
cients between high and low responders, column 4 (col-
umn 2 – column 3), indicated relationships of DMFT to
pocket depth that were significantly different and relation-
ships of DMFT to F score that were almost significantly
different, p = 0.062 (Table 4, column 4).

Stepwise regression confirmed the similar associations of
DMFT with plaque prevalence in both high and low IgG
antibody responders, but significant associations with
only F score and BOP prevalence in high responders and

Table 2: Age of siblings from 6 families with at least one high re-
sponder parent

High responders Low responders
Familya Ages Ages

F+M- 17 16,14.13,12,10,8
F+M+ 20,13 21,18,16,8,5
F+M+ 22,20,18 25,16,14
F?M+ None 12,11,10,9,8
F+M- 22,20,13,11 17
F+M' 17,16,13 20,18,10,7
bMean age (s.d)c 17.08(3.68) 13.25(5.00)

aF, Father; M, Mother; +, high responder; -, low responder, ? Not 
known. bMean age of the high and low responders cs.d., standard devi-
ation.

Table 3: Fraction of high antibody responders in or not in the clin-
ical study.

Subject group Number % high
responders

Dental students in clinical studya 87 37.9
Patients in clinical studya 64 32.8
Same-age subjects not in clinical study 129 31.8
Other subjects not in clinical studyc 117 39.7
All subjects 397 33.8

aSee first section of Materials & Methods. bSame-age subjects not in 
the clinical study were 12.4% dental students, 17.1% patients and 
70.5% volunteers. cOther subjects were a mixture of patients and vol-
unteers: 70.9% older (ages >38 and <72 years), 15.4% younger (ages 
>15 and <22 years), and the remainder age unknown.

Table 4: Changes in the equality of the partial β coefficients for as-
sociation of tested variables withcaries severity in high and/or low 
respondersa.

Variablea High responders 
bn = 35

Low responders 
n = 67

Difference 
(Hi – Low)

F score c-0.847 0.006 d-0.853
PL d0.259 d0.234 0.025
BOP c0.447 0.167 0.280
PD -1.903 c4.249 c-6.152
Age 0.099 d0.261 -0.162

aVariable names are defined under "Clinical Measurements" in the 
Methods bn = number of subjects cp <0.05 for value of constant or 
variable (β) or for all values in indicated model. dp > 0.05 & < 0.15. If 
no subscript, p > 0.15 eHLS: high response = 1, low response = 0.
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with only PD and age in low responders. In high respond-
ers, DMFT increased as plaque and BOP prevalences in-
creased and fell as fluoride exposure increased. The
equation obtained was: DMFT = 4.60 + 0.28 PL +
0.39BOP - 0.88FScore (R2 = 0.51, F statistic = 10.75, p <
0.0001). By contrast, in low responders, DMFT increased
with plaque prevalence, pocket depth and age. The equa-
tion was: DMFT = -13.37 + 4.58 PD + 0.27 Age + 0.30 PL
(R2 = 0.26, F statistic = 7.41, p < 0.0003). Within each
equation, the constant and the respective β coefficients
were significant (p < 0.05), except for the β coefficient of
age in low responders (p = 0.062). High responders re-
ceiving fluoridated drinking water for all 14 years of child-

hood (F score = 5), had a significantly lower DMFT than
those never receiving fluoridated water (F score = O):
DMFT = 7.50 ± 4.52 (s.d.) vs 11.60 ± 4.06 (s.d.); 't' test p
< 0.04. This was not true of low responders in whom the
difference between F score 5 and F score 0 was not signif-
icant (DMFT = 9.33 ± 5.72 vs 12.07 ± 5.85; 't' test p =
0.14).

When antibody was ignored in stepwise regression (con-
trol), DMFT increased with age, PL and BOP, and de-
creased with F score: DMFT = -2.11 + 0.17 Age + 0.25 PL +
0.27 BOP - 0.39 FScore (R2 = 0.29, F statistic = 6.62, p <
0.0001). PL and BOP were individually significant. F
Score and age were borderline, p = 0.09 and 0.14 respec-
tively, and PD was not significant, being entirely replaced
with age. Despite the subjects increasing to 102 (from 35
or 67) the strength of association was similar to that of
low responders only.

Association of DT with gingivitis in high and low responders
Because caries experience associated with fluoride and
gingival health in high responders, poor gingival health
should increase the number of decayed teeth (DT) more
than in low responders. When BOP was regressed against
the variables in Table 5, only DT (column 4) differed sig-
nificantly between the high and low responders. Although
DT alone significantly correlated with BOP in both re-
sponse groups (p < 0.01), it associated with BOP much
more strongly in high responders (R2 = 0.57) than in low
responders (R2 = 0.12). Fig. 3 shows the respective corre-
lations, and also the patient data (filled circles) skewed by
few healthy subjects and the student data (unfilled circles)
skewed by few moderate and no severely diseased sub-
jects. Clearly, combining students and patients strength-
ened the respective associations (β coefficients). Stepwise
regression indicated that, excluding DT, BOP associated
with PL and PD similarly (BOP = -14.02 + 0.42 PL + 4.8
PD in high responders and BOP = -11.07 + 0.34 PL + 4.10
PD in low responders; R2 = 0.40 and 0.41 respectively; p
< 0.001). However, DT explained more variance (BOP = -
1.46 + 0.24 PL + 0.95 DT, R2 = 0.62, p < 0.001) in high
responders, and less variance (BOP = -3.25 + 0.41 PL +
0.33 DT, R2 = 0.31, p < 0.001) in low responders.

Influential points (outliers), whose presence might have
affected the strength and significance of these complex re-
gression analyses, were identified in five low responders
and two high responders. When these subjects were omit-
ted, the respective regression coefficients or their signifi-
cance were little changed, indicating that the different,
partial, linear regression coefficients in high or low re-
sponders were not artifacts of influential or outlying
points.

Figure 3
Graph of number of decayed teeth against gingival bleeding
index. Results are provided separately for the dental students
(o) and patients (•). Data from more than one subject are
superimposed. Regression line equation, high responders
(upper graph): DT = 0.123 BOP - 3.65 Regression line equa-
tion, low responders (lower graph): DT = 0.053 BOP - 15.11
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Discussion
This study has demonstrated that IgG antibodies to D-ala-
nyl LTA are widespread in US adults. The fraction of high
responders was essentially constant from early adulthood
through middle age, but reduced in children (<15 years)
and old age (>55 years). Within the adults (ages 15–55
years) a change from low to high response or vice versa was
found unlikely from repeated measurements over 2–6
months. A similar lack of change in this IgG antibody con-
centration was reported 2–3 months after an additional
26 similarly aged patients had received oral hygiene ther-
apy in another study [32]. Finally, the family studies es-
tablished that a high antibody response was probably
induced during the mid-teenage years. In order to apply
the results of this study to children and young teenagers,
longitudinal studies of the antibody response in relation
to age and the clinical measurements in this study may
need to be undertaken.

Despite few investigations of caries risk in 22–38 year old
subjects compared with a younger or older group [7], the
association of DMFT with PL in this study agrees with that
obtained from 35 year old Norwegians [3]. Plaque (sim-
plified oral hygiene index measurement) accounted for
15% of the variance in number of decayed/filled teeth sur-
faces in that study, and for 19% of the DMFT variance
within all 151 clinically examined subjects in this study
(ignoring age, antibody and all other variables). Other
studies have shown that the amount of fluoride applied
from dentrifices is measured better from oral hygiene or
plaque accumulation, as in this study, and not from the
reported frequency of dentrifice use [2,3]. Finally, because
subjects aged more than 38 are unlikely to have used
fluoridated toothpastes until later in life, they were omit-
ted to avoid confounding the results.

The rationale behind this study was that acidic plaque en-
vironments increase the amount of D-alanyl LTA and pro-
mote its immunogenicity. Accordingly, caries-protection
by fluoride in the water supply and dentrifices was strong
in high IgG antibody responders, accounting for just over
50% of the variance in DMFT. In addition, gingivitis (BOP
prevalence) associated strongly and significantly with the
number of decayed (untreated) teeth, suggesting that pre-
venting gingivitis increased fluoride exposure from dentri-
fices and reduced the number of decayed teeth. Increased
exposure to fluoridated water, and dentrifices associated
with good gingival health, may result in fluoride inhibit-
ing enamel remineralization at the acidic plaque pH likely
present in high responders.

In low responders, the fewer antibodies to D-alanyl LTA
suggest less colonization by acid-tolerant bacteria and a
weaker cariogenic attack. DMFT associated with age, as re-
ported for other subjects whose sera did not precipitate D-
alanyl LTA [22], and also with pocket depth. An increase
in pocket depth is caused by periodontopathic bacteria
that associate with an alkaline environment in the sulci
over many years [20] and a microbiota that is neither acid-
ic nor acid-tolerant [10]. The coefficient of DMFT associa-
tion with PD in low responders therefore differed
significantly from high responders within whom F score
and gingival health were stronger covariates.

Conclusions
An increased mutans streptococcal challenge accompany-
ing low plaque pH (high antibody response to D-alanyl
LTA) allows much of the variation in caries experience to
be controlled by water fluoridation and by the use of
fluoridated dentrifices associated with maintaining oral
health. High IgG antibody responders are therefore better
protected from caries in an optimally fluoridated environ-
ment. The concept that fluoride protects better from caries
in a low pH environment [12] was recently used to ex-
plain why there is a poor association between caries expe-
rience and pH fall after a 10% sucrose rinse [33]. In low
responders, increased fluoride exposure from dentriflce
use to maintain oral health, or from water fluoridation,
associate relatively poorly with caries experience. Al-
though this study has indicated that the IgG antibodies to
D-alanyl LTA do not become elevated until after age 17,
when much caries may have already developed, they may
be elevated to a lower level in children who eventually be-
come high responders. The D-alanyl LTA antibody re-
sponse is not detectable in saliva (unpublished studies),
but it can be measured from only a thumb-prick of blood.
Longitudinal studies of the D-alanyl LTA response in chil-
dren could improve current efforts to predict caries sus-
ceptibility by relating it to fluoride or the fluoride ion
product for fluoroapatite in saliva and the pH change after
a sucrose rinse [5,12,13,33].

Table 5: Changes in the equality of the partial β coefficients for as-
sociation of tested variables withgingivitis (BOP) in high and/or 
low responders.

Variablea High responders 
n = 54

Low responders 
n = 97

Difference 
(Hi – Low)

PL d0.182 c0.321 -0.140
PD c2.529 c3.588 -1.059
DT c0.906 0.202 c0.703
MFT 0.154 0.054 0.099
Age 0.022 -0.053 0.074

aVariable names are defined under "Clinical Measurements" in the 
Methods bn = number of subjects. cp < 0.05 for value of constant or 
variable (β). dp > 0.05 & <0.15. If no subscript, p > 0.15.
Page 7 of 8
(page number not for citation purposes)



BMC Oral Health 2002, 2 http://www.biomedcentral.com/1472-6831/2/2
Competing interests
None declared

Acknowledgements
This investigation was largely supported by USPHS Research Grant 1R01 
DE-06740 from the National Institute of Dental Research, National Insti-
tutes of Health, Bethesda. We sincerely thank Dr. W. Bias, Immunogenetics 
Laboratory, Johns Hopkins University, Baltimore and Dr. F. Bach, Immuno-
biology Research Center, University of Minnesota Medical School, Minne-
apolis for donations of human serum from their patients; E. Carter and D. 
LeFlore for technical assistance; S. Pitts, J. Chowning and Dr. A. Cucchiara, 
Computing Center, University of Oklahoma Health Sciences Center, for 
computing assistance; Drs. R. Reynolds, M. Martin and L. Coggins Dept. of 
Oral Diagnosis for clinical assistance.

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	Elevated antibody to D-alanyl lipoteichoic acid indicates caries experience associated with fluor...
	Background
	Methods
	Results
	Discussion
	Conclusions
	Competing interests
	Acknowledgements
	References