CHEMICAL STUDIES ON BACTERIAL AGGLUTINATION
II. Tae Ipentrry oF Precreitin AND AGGLUTININ*

By MICHAEL HEIDELBERGER, Px.D., anp ELVIN A. KABAT

(From the Laboratories of the Departments of Medicine and Biological Chemisiry,
College of Physicians and Surgeons, Columbia University, and the
Presbyterian Hospital, New York)

(Received for publication, February 5, 1936)

Although the unitarian theory of antibodies has gained general
acceptance since its formulation by Zinsser and others (1), quantita-
tive evidence for the identity of agglutinins and precipitins has been
lacking. Zinsser (2) has attempted to reconcile mathematically the
apparent discrepancy between the serum dilutions in which agglutina-
tion and precipitation occur and Jones (3) has shown that collodion
particles coated with egg albumin are agglutinated by small quantities
of anti-egg albumin serum. Antibody concentrates, purified by
Felton and Bailey (4), have been found to contain precipitins, agglu-
tinins, opsonins, and protective antibody, but quantitative data were
lacking until after the writers’ preliminary report (5).

The development of quantitative micro methods for the estimation
of precipitins (6, 7) and agglutinins (8) has now made it possible to
investigate the quantitative correspondence of precipitin and agglu-
tinin.

Pneumococcus Type I specific polysaccharide (acetyl form) (9),! a Chamber-
land filtrate of an autolyzed 8 day Type I Pneumococcus culture, Pneumococcus

* The work reported in this communication was carried out under the Harkness
Research Fund of the Presbyterian Hospital, New York. Submitted by Mr. El-
vin A. Kabat in partial fulfilment of the requirements for the degree of Doctor
of Philosophy, in the Faculty of Pure Science, Columbia University.

1A preparation of Type I pneumococcus specific polysaccharide in which the
use of heat was avoided (98) precipitated the same amount of antibody from
horse antibody solution B 78 as did the original broth filtrate or material prepared
according to (9a).

137
738 BACTERIAL AGGLUTINATION. II

I S (Dawson M (10)) and R (Dawson §S) strains, and Type I antipneumo-
coccus sera were chosen as the objects of study. Serum H 701, which was a
combined Pneumococcus I, II antiserum, was precipitated with a slight excess of
Type IL polysaccharide in order to leave only the Type I anticarbohydrate (cf. 8).
To make the system approach as nearly as possible that of a single type specific
hapten and its homologous antibody, the other sera were absorbed with C poly-
saccharide and protein derived from Type I R pneumococci. These sera still
contained considerable amounts of group specific antibody (5), but it was found
possible to prepare sclutions containing antibody only to the type specific carbo-
hydrate by repeated absorption with large amounts of Pneumococcus I R sus-
pension.

Before using the Pneumococcus I R strain it was necessary to know whether
it contained residual traces of type specific carbohydrate since it was to be used
both for the determination of anti-R in the sera, and for the removal of the anti-R
by absorption of the sera. That the method used was applicable was shown by a
similar study of a Type III R strain, in which specific polysaccharide was actually
present.

EXPERIMENTAL

The precipitin determinations were carried out by addition of known amounts
of Type I pneumococcus specific polysaccharide to accurately measured quantities
of absorbed serum or antibody solution and determination of the specifically pre-
cipitated nitrogen after 48 hours at 0° on the washed precipitates by the micro
Kjeldahl method (6, 7, 11). Agglutinin determinations were made similarly (8),
using measured volumes of washed pneumococcus suspensions and estimating the
increase in nitrogen content. Heat-killed suspensions were used for all analyses,
but formalinized suspensions were also used in absorbing sera. All determina-
tions were run ‘in duplicate at 0° for 48 hours in order to remove antibody as
completely as possible (11).

I. Absence of Type Specific Polysaccharide in a Pneumoceccus I R Strain
The Pneumococcus I R strain used* (strain I-192 R (12)) had been degraded
from a virulent Type I S strain (strain I-230 S) which was also used in all
agglutinations with S organisms. It was assumed that if the I R suspension
contained type specific substance it should remove all of the antibody from a
type specific antiserum in a series of absorptions. The data in Table II on sera
H 610, H 701, and antibody solution B 76 show that no antibody was taken out
after the initial absorption. Since the limits of error of the quantitative agglu-
tinin method are about -+ 0.02 mg. of nitrogen and it wes also found that 0.01
mg. of specific polysaccharide removed about 0.20 mg. of antibody nitrogen from
antibody solution B 76, 0.02 mg. of antibody nitrogen would thus correspond to
0.001 mg. of specific polysaccharide. The amount of I R (Dawson S) suspen-

2 Kindly supplied by Dr. Martin H. Dawson. The pneumococci used in this
investigation were grown by Mr. C. M. Soo Hoo.
MICHAEL HEIDELBERGER AND ELVIN A. KABAT 739

sion used was 2 ml., containing about 0.44 mg. of bacterial nitrogen or approxi-
mately 44 billion organisms.’ This amount of suspension, therefore, contained
no more than 0.001 mg. of specific polysaccharide. Similarly with a larger
quantity of the same suspension and the stronger serum H 610, 0.66 mg. of
bacteria] nitrogen or approximately 66 billion organisms contained less than
0.001 mg. of type specific substance (Table I).

TABLE I

Absorption of Agglutinins from Horse and Rabbit Antisera with Pneumococcus I R,
III R, and III S Suspensions

 

 

 

 

fom) He) Aa 1.0 ml, R 348, rabbit serum
Abepton Agglutinin N ed b:
°. Agglutinin N sglutinin N removed by
removed by | seuaSted by LH Rt
ITR MIs
mg. mg. meg. mg.
1 0.16 0.14 0.098 0.176
2 0.00 0.08 Aliquot of 1st su-
pernatant 0.07 0.022
3 0.06 Aliquot of 2nd su-
pernatant 0.014
4 0.06
5 0.05 Total agglutinin N} 0.182 0.198
6 0.05
7 0.04
Absorption dis-
continued

 

 

 

 

 

 

In absorptions 2 to 7 on serum H 53300 the entire supernatant from the pre-
ceding absorption was used.

* Centrifuged sediment from 2.0 ml. suspension. Agglutinin N determina-
tions with IIT R and III S suspensions gave 0.56 and 0.54 mg. N per ml., re-
spectively.

In order to remove the group specific antibody, 12 ml. of antibody solution
B 76 were repeatedly absorbed with Pneumococcus I R organisms (about 3.5
mg. N per absorption). The pneumococci were first centrifuged, the super-
natant was poured off, and the antibody solution was added to the bacterial
sediment, taking care to obtain an even suspension. After 24 or 48 hours the

* The number of organisms was determined by comparison with a suspension of
pneumococci standardized by counting. The numerical correspondence of bac-
terial nitrogen and the number of organisms is purely accidental.
740 BACTERIAL AGGLUTINATION. II

agglutinated bacteria were centrifuged off and the supernatant was poured onto
another portion of centrifuged organisms. In this way undue dilution was
avoided. After about 12 absorptions, a determination of the anti-R on 1.0 ml.
samples of the supernatant showed 0.016 mg. N per ml., and since this was within
the limit of error of the determination (8) and equalled only 1.3 per cent of the
type specific anticarbohydrate still present, absorption was discontinued. In the
preparation of a large quantity of serum or of Felton antibody solution (13) free
from group specific antibody it is convenient to divide the material into 12 to 15
ml. portions and absorb repeatedly with I R organisms as described for B 76.

2. Presence of Type Specific Polysaccharide in a Pnewmococcus III R Strain. —
In a similar manner it was found that a III R strain? (M III R (12)) actually
contained a small amount of Type III specific polysaccharide. It will be seen
from Table I that on repeated absorption of a Type III S antiserum, H 53300,
with the suspension, small amounts of antibody nitrogen were continually re-
moved and a limit was not reached. On determining the total agglutinin in a
smaller amount of a weaker serum, R 348,, with both Type III § and R suspen-
sions (Table I), it was found that the same total amount of antibody nitrogen
was ultimately removed by both strains. These results were interpreted on the
basis that the Type ITI R strain contained a small amount of specific polysaccha-
ride and this was confirmed as follows:

To 5.0 ml. of the bacterial suspension in saline 2.6 ml, of normal sodium hy-
droxide were added and the mixture was allowed to stand at 37° for 72 hours.
The solution was neutralized to phenol red with hydrochloric acid, and was made
up to 25.0 ml. and centrifuged free from traces of insoluble material. The salt
concentration was then about 0.9 per cent. 3 ml. of this solution were set up with
1.0 ml. of a calibrated antibody solution (14) and the suspension was found to
contain 0.0154 mg. of type specific polysaccharide per mg. of bacterial nitrogen—
an appreciable amount. .

Two different lots of the Type I S suspension used were found by this method to
contain 0.462 and 0.493 mg. of type specific polysaccharide per mg. of bacterial
nitrogen. The analyses were made as in the case of the Type III suspension ex-
cept that the Type I polysaccharide used in calibrating the serum was treated
with alkali at 37° for 72 hours in the same way as the bacterial suspension of which
the polysaccharide content was to be determined, since Avery and Goebel (9)
have shown that alkali treatment decreases the precipitating power of the poly-
saccharide.

3. Identity of Agglutinin and Precipitin—In Table II are given the precipitin
and agglutinin determinations. As will be noted, total agglutinin and total
precipitin estimations were run, and in other instances a portion of the precipitin
or agglutinin was removed and the agglutinin or precipitin in the supernatant was
determined. In the last column are given the values for total antibody found,
either for total agglutinin or precipitin alone, or for the sum of the analytical
values for agglutinin plus precipitin. Serum H 610 and antibody solution B 76
were the same as those used in the first paper of this series (8), except that
TABLE Il
Quantitative Comparison of Agglutinin and Precipitin in Type I Antipneumococcus Sera and Antibody Solutions

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

Yohume asst Precip- Remain- Volume Asst Remain-
Laboratory “x | Gata N | Strain | itm N | Boay w | Total | Antic |] O80 | Precip, | SSE | serain | bodyN | Total | Anti.
Schacrum. [5aHbody[emoved| sed | Spe | Pen PO |S | bere (tuted | removed | Mampe| wed Loy Pats| "NY | pera
natant 3 suspen-
med pension sion
od, me. mE. me. me. me, mi. me. me. we. mg. mg.
Serum H 610 0.50 | 0.77%; TS {| 0.00 | 0.00 | 0.77 | 1.54 0.50 |0.75¢ | 0.05 |] IR 0.80 |. 1.60
0.50 | 0.32 |} IS | 0.38 | 0.05 | 0.75 | 1.50 |} 0.50 |0.75¢ | 0.02 | IR | 0.00 | 0.77 | 1.54
0.50 | 0.25 | TS | 0.50 | 0.06 | 0.81 | 1.62 0.50 [0.52tf| 0.26 | IS 0.78 | 1.56
0.50 | 0.168; IR | 0,59¢) 0.00 | 0.75 | 1.50 jl 0.50 {0.60 0.22 | IS | 0.01 | 0.82 | 1.64
Serum H 701 | 1.00 | 1.16j{] IS 0.00 | 0.00 | 1.16 | 1.16 1.00 |1.05 0.14 | IS | 0.00 | 1.19 | 1.19
(1:1)** 1.00 | 0.27 | IS | 0.73 | 0.16 | 1.16 | 1.16 1.00 | 1.05 0.13 | IR | 0.00 | 1.18 | 1.18
1.00 } 0.33]|} TR | 0.8it¢| 0.03 | 1.17 | 1.17 1.00 | 0.89 0.31*/ IS 6.00 | 1.20 | 1.20
Antibody B76 | 0.50 | 0.82*/ IS {| 0.00 | 0.00 { 0.82 | 1.64 || 0.50 10.75 0.01 |} IR | 0.00 | 0.76 | 1.52
0.50 | 0.53 | IS | 0.08 } 0.17 | 0.78 | 1.56 |} 0.50 | 0.55 0.244) 1S 0.00 | 0.79 | 1.58
0.50 | 0.09§} IR | 0.61f] 0.07 | 0.77 | 1.54
Antibody B 76} 0.50 | 0.61%} IS | 0.00 | 0.00 | 0.6% | 1.22 0.50 10.52 0.10 | IS 0.00 | 0.62 | 1.24
absorbed 0.50 | 0.16 | IS { 0.32 | 0.12*| 6.60 | 1.20 0.50 |0.54t | 0.06 | IS 0.00 | 0.60 | 1.20
1.00 | 0.02 | IR 0.50 | 0.35 0.25 |} IS 0.01 | 0.61 | 1.22
Antibody B 78 ; 1.00 | 0.691) IS | 0.00 0.69 ] 0.69 || 1.00 | O0.69tt | 0.05 | IS | 0.00 | 0.74 | 0.74
absorbed 1.00 } 0.30 | IS | 0.33 | 0.07 | 0.70 } 0.70 1.00 | 0.63 0.10 | IS 0.00 | 0.73 | 0.73
1.00 | 0.56 0.11) IS 0.02 | 0.69 | 0.60
* Two absorptions. || Three absorptions,
+ Complete removal of anti-S as shown by excess S in supernatant. ** Contained 0,13 mg. anti-C N per ml.
ft 2 hours at 37°. Ice box overnight. {Broth culture filtrate of Pneumococcus

§ A second absorption with Pneumococcus I R removed no more antibody. IS used.

LVGvai “V NIATS INV WADATATACIGH TAVHOIN

TPL
742 BACTERIAL AGGLUTINATION. II

B 76 was somewhat more concentrated. ‘‘B 76 absorbed” and B 78 are the anti-
body solutions from which practically all of the group specific antibody was re-
moved as described above. H 701 was a New York City Department of Health
Type I, IY mixed antipneumococcus serum from which the Type II antibody had-
been removed. ‘The data for antibody solution B 75 have already been presented
in the preliminary note (5) and are therefore not repeated.

The Type I specific polysaccharide used contained a small amount of C sub-
stance (15), so that I R agglutinin values were smaller after removal of precipitin.

In the experiments on the partial removal of agglutinin and precipitin, a known
volume of bacterial suspension (or of polysaccharide solution) was added to a
measured volume of serum or antibody solution, and after removal and analysis of
the precipitate (6-8), an aliquot portion of the supernatant was set up with an-
other measured volume of polysaccharide solution (or bacterial suspension).
Finally, an aliquot of this second supernatant was set up with a known volume of
Pneumococcus I § suspension in order to remove any traces of antibody remaining.
The values in the table are corrected for the aliquots taken.

DISCUSSION

In order to determine whether or not precipitin and agglutinin are
identical it was desirable to limit the investigation as nearly as pos-
sible to a single type specific antigen or hapten and its homologous
antibody. However, pneumococci contain group specific antigens,
and antipneumococcus sera may show varying amounts of group
specific as well as type specific antibodies. It was therefore essential
to have available a strain free from type specific antigen both for the
purpose of estimating quantitatively the group specific antibody in a
serum and for absorption of group specific antibody from such sera.
Owing to the large number of absorptions necessary, the presence of
even small amounts of type specific polysaccharide would result in
removal of much of the antibody it was desired to retain.

The application of the quantitative agglutinin method (8) to estab-
lish the presence or absence of an antigenic component in the R
strains used is illustrated in the section on experiments and sum-
marized in Table I. It may be noted that Dawson (16) found it
possible to cause reversion of the Pneumococcus M III R strain (which
contains specific polysaccharide) to the S variant by 7» vitro as well as
in vivo methods, whereas the ]-192 R strain (which is free from specific
polysaccharide) was exceedingly stable and could only be converted
into the S form by subcutaneous injection with I S vaccine. The
MICHAEL HEIDELBERGER AND ELVIN A. KABAT 743

analytical method given should therefore be of service in indicating
the completeness of dissociation and possibly the stability of variants.

Data regarding the identity of agglutinins and precipitins are
summarized in Table II. In the Type I antipneumococcus horse
sera H 610 and H 701 it will be seen that type specific precipitin plus
the small amount of residual group specific agglutinin equals total
agglutinin, and that total antibody nitrogen remains the same when
only a portion of the type specific antibody (anticarbohydrate) is
first removed either as agglutinin or precipitin and the remainder as
precipitin or agglutinin. Since the value for total antibody nitrogen
in the combined precipitin-aggiutinin estimations is the result of three
independent sets of analyses, each involving several successive deter-
minations, the precision attained is not as great as in the estimation
solely of total agglutinin or total precipitin. The difference between
the extreme values in the various sera ranges from 3.5 to 8.5 per cent
of the total antibody content.

The data for sera H 610 and H 701 indicate the quantitative corre-
spondence of the type specific anticarbohydrate agglutinin and
precipitin within the limits of accuracy of the method. Using the
mean values for total antibody nitrogen, antibody solution B 76, both
unabsorbed and absorbed, yielded about 11.5 per cent more agglutinin
nitrogen than precipitin nitrogen, while solution B 78 showed only a 4
per cent excess of type specific agglutinin. Since serum H 610, from
which solution B 76 was prepared, did not show this effect, it would
appear that a portion of the antibody had been slightly altered in the
process of purification, a possibility already considered by Felton (13).

While the data for total type specific agglutinin and precipitin show
the same quantity of each form of antibody it would still be possible
that different substances, present in equal quantity, were involved.
This possibility is eliminated, however, by the experiments on the
partial removal of precipitin and agglutinin (Table IT), since such a
reduction of the content of precipitin or agglutinin resulted in
an equal reduction of the amount of agglutinin or precipitin,
respectively, remaining in the solution. Evidence is thus given for
the identity of the type specific anticarbohydrate agglutinin and
precipitin in these sera.
744 BACTERIAL AGGLUTINATION. II

SUMMARY

1. The absolute, quantitative agglutinin method has been used for
the determination of the presence or absence of small amounts of
specific polysaccharide in pneumococcus variants.

2. A technique is described for the removal of group specific anti-
body from antipneumococcus horse serum.

3. The type specific anticarbohydrate agglutinin and precipitin
are not only present in identical amounts in Type I antipneumococcus
horse serum, but a reduction in one is also accompanied by a quanti-
tatively identical reduction in the other, providing evidence for their
actual identity. In purified antibody solutions somewhat more agglu-
tinin than precipitin is found, possibly owing to alteration of a portion
of the antibody in the process of purification.

BIBLIOGRAPHY

1. Cf. Wells, H. G., Chemical aspects of immunity, New York, Chemical Catalog
Co., 2nd edition, 1929, Chapter 4, 109. Marrack, J. R., Chemistry of
antigens and antibodies, Great Britain Med. Research Council, Special Rep.
Series, No. 194,1934, 125. A more detailed review will be found in these
references.
. Zinsser, H., J. Immunol., 1930, 18, 483.
. Jones, F.S., J. Exp. Med., 1927, 48, 303.
4, Felton, L. D., and Bailey, G. H., J. Immunol., 1926, 11,197. Felton, L. D.,
Science, 1934, 79, 277.

5. Heidelberger, M., and Kabat, E. A., Proc. Soc. Exp. Biol. and Med., 1934,
31, 595.

6. Heidelberger, M., Sia, R. H. P., and Kendall, F. E., J. Exp. Med., 1930, 52,
477.

7. Heidelberger, M., Kendall, F. E., and Soo Hoo, C. M., J. Exp. Med., 1933,
58, 137.

. Heidelberger, M., and Kabat, E. A., J. Exp. Med., 1934, 60, 643.

. (a) Avery, O. T., and Goebel, W. F., J. Exp. Med., 1933, 68, 731. (6) Hei-
delberger, M., and Kendall, F. E., Proc. Soc. Exp. Biol. and Med., 1935,
33, 445.

10. Dawson, M. H., J. Path. and Bact., 1934, 39, 323.

11. Heidelberger, M., and Kendall, F. E., J. Exp. Med., 1935, 61, 559.

12, Dawson, M. H., J. Exp. Med., 1928, 47, 577.

13. Felton, L. D., J. Immunol., 1931, 21, 341; and earlier papers.

14, Heidelberger, M., and Kendall, F. E., J. Exp. Med., 1932, 65, 555.

15. Tillett, W. S., Goebel, W. F., and Avery, O. T., 7. Exp. Med., 1930, 52, 896.

Heidelberger, M., and Kendall, F. E., J. Exp. Med., 1931, 58, 625.

16. Dawson, M. H., J. Exp. Med., 1930, 51, 99.

& Xe

© Oo