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Immunization against babesiosis: Current studies and future outlook
Preventive Veterinary Medicine, 2 (1984) 401--408
401
Elsevier Science Publishers B.V., Amsterdam -- Printed in The Netherlands
IMMUNIZATION AGAINST BABESIOSIS: CURRENTSTUDIES AND FUTURE OUTLOOK D.F. Mahoney, I.G. Wright and B.V. Goodger CSIRO Division of Tropical Animal Science Long Pocket Laboratories, Private Bag No. 3, P.O. IndooroopiIIy, Queensland 4068, Australia
ABSTRACT
Mahoney, D.F., Wright, I.G. and Goodger, B.V., 1984. Immunization against babesiosis: current studies and future outlook. Prev. Vet. Med., 2: 401-408. Experiments were conducted on the induction of immunity to Babesia bovis in cattle with antigen extracted from erythrocytes infected wit-B--t~-~parasite. Protection after inoculation with crude parasite-erythrocyte stroma mixtures was as strong as that induced by natural infection. B. bovis appears to contain several different protective antigens, and one o f ~ h ~ was p a r t i a l l y purified by immunoabsorption using a monoclonal antibody. It is a protein consisting of a single peptide of low molecular weight and appears to be located in or on the surface of the parasite. INTRODUCTION I t is now over a decade since the f i r s t demonstration that immunity could be induced against Babesia parasites by inoculation of their hosts with crude antigenic material prepared from infected blood (Mahoney 1967a, Phillips 1967). However, notwithstanding these developments in immunological research, vaccination with the l i v i n g organism (Callow 1977) is the only available means of preventing babesiosis, even though a number of serious disadvantages are associated with this form of immunization (Mahoney 1981).
The slow progress has
been caused by the nature of the organism and its close association with the host erythrocyte.
It is d i f f i c u l t to separate either the parasites or their
antigens from red-cell material (Mahoney and Goodger 1981) and this invariably results in the immunization of the host with erythrocyte antigens in addition to those from the parasite.
Unlike many bacterial diseases for which k i l l e d
suspensions of the causal organisms are used for immmunization, the isolation of protective antigens of Babesia spp. is a prerequisite for such development. Until recently, Babesia spp. had not been grown successfully in v i t r o .
A cul-
ture system for B. bovis is now available (Levy and Ristic 1980), but although it
increased the a v a i l a b i l i t y of infected blood, the problem of erythrocytic
contamination of antigen remained. Therefore the purification and characterization of the protective antigen(s) is relevant and the eventual aim is to clone and express such substances in a suitable organism in order to solve the dual problem of production and purification of antigen for vaccination. 0167-5877/84/$03.00
© 1984 Elsevier Science Publishers B.V.
402
EXPERIMENTAL METHODS AND RESULTS The experimental work described in t h i s
paper r e f e r s to B. bovis which is a
p a r a s i t e of c a t t l e and one of major economic s i g n i f i c a n c e throughout the w o r l d . The basic requirement f o r s t u d i e s on the antigens of t h i s species was to o b t a i n a concentrated
source
of
the
organism.
This
s e p a r a t i o n of i n f e c t e d from n o n - i n f e c t e d c e l l s
requirement
was met by the
in blood (Mahoney, 1967b).
The
technique was based on the o b s e r v a t i o n t h a t the i n f e c t e d e r y t h r o c y t e s were less susceptible
to
hypotonic
lysis
than the u n i n f e c t e d
cells.
It
was t h e r e f o r e
possible to select a concentration of salt solution that lysed all uninfected erythrocytes
leaving the infected ones intact to be recovered by d i f f e r e n t i a l
centrifugation.
The method was rapid,
preparative scale.
reproducible
and applicable on a
It was used to produce suspensions of 95-100% infected
erythrocytes from blood with parasitaemia in the range of 5 to 15%. Extracts of crude antigen were prepared from these infected cell suspensions by sonic disintegration for 2-4 minutes at maximum power of the instrument followed by centrifugation at 145,000 g for 60 minutes at 4°C. the
crude soluble antigen
and i t
The supernatant f l u i d was
was fractionated by precipitation with
protamine sulphate and by immunoabsorption (IA) using antibodies from immune cattle and monoclonal antibodies produced by the techniques established by Kohler and Milstein (1975).
A flow diagram for fractionation procedures is
shown in Figure 1.
INFECTED ERYTHROCYTES I Disintegration INFECTED ERYTHROCYTE ANTIGEN I Centrifuge at 145,000g x 60mins I
I CRUDE SOLUBLE $ EXTRACT $
CRUDE INSOLUBLE EXTRACT
I
Affinity Purification
I SUPERNATANT FRACTION (SPE)
I Antibodies
Precipitation with ~1 Protamine Sulphate
I PRECIPITATE FRACTION (FAA) I
in Calves
Antibodies in Calves
I
I
Affinity Purification
I ,
Figure 1. Flow diagram of the fractionation procedure for bovine erythrocytes infected with B. bovis.
403
Tests for the immunogenic a c t i v i t y of antigens consisted of the subcutaneous inoculation of the antigen as a water-in-oil emulsion with Freund's Complete Adjuvant (FCA) into either two-year-old steers or 6-month-old splenectomized calves.
In early work three inoculations, two weeks apart were used but in
later studies the number of inoculations were reduced to two and to one. Two to four weeks after immunization, the two-year-old steers were challenged by I/V inoculation with a different strain of B. bovis from the one used to prepare the antigen.
For splenectomized calves the same strain as that used to
prepare the antigen was used for challenge.
The immune response was then
assessed by comparing daily rectal temperatures, levels of parasitaemia and f a l l s in packed cell volume in vaccinated and control groups. The l a t t e r were sham-immunised with FCA alone. 0 ~(9 -IO.E
~. ~ o20, 0 ~ -30. m o ~ -4o >
~
(a) m" ,,o,O-
/ .. ....
.
~ ,'~-~ ~
~.;''" ! !ii!ie~a~ed
~
~
~ - 5C 0
g ~ -~0
"~'~c~:
#~..,.~-'~
.~
~bl
~ -20' ....
~ -ao
g ~ -40.
g
~ -5~' -~0-
o
i
i
A
g
YO
1"2
1~
i'~
Days
Figure 2. (a) Comparison of the changes in packed cell volume (PCV) in cattle vaccinated with crude B. bovis antigen and in cattle immunised by B. bovis infection, after c h a l ~ g ~ h virulent heterologous B. bovis organlsms. Taken from Mahoneyand Wright (1976). (b) The changes in PCV in cattle vaccinated with soluble and insoluble fractions of crude B. bovis antigen and challenged with an heterologous strain of the organism.
404
Protection by crude antigen. Mahoney and Wright (1976) showed that prepared by disruption heterologous B. bovis -
of
immunization with
infected erythrocytes
protected
crude antigen cattle
against
infection as effectively as immunity associated with
-
active infection (Figure 2a).
T h i s material was a mixture of all particulate
and soluble components contained by infected erythrocytes.
It was fractionated
into soluble and insoluble components by ultracentrifugation and both fractions induced similar protection (Figure 2b), demonstrating that protective antigen was released into solution. Fractionation of the crude soluble antigen. The f i r s t
fractionation procedure was based on studies by Goodger (1971,
1973, 1976) who showed that the antigens extracted from the B. bovis-infected erythrocyte contained several different specificities and he classified them into three groups.
The f i r s t
group was composed of two antigens associated
with the stroma of the erythrocyte.
These were responsible for staining of the
membrane by fluorescein-labe|led antibodies (Ludford,
1967).
One of
the
antigens was located as a dense band in or under the cell membrane and the other had a granular distribution throughout the stroma. Characterization of the stromal antigens showed that they were basically fibrinogen molecules, altered by conjugation with a number of babesial and others of host origin 1980).
peptides,
some of which were of
(Goodger, Wright, Mahoney and McKenna,
Separationof the fibrinogen-associated antigen complexes was achieved
by methods that
specifically precipitated fibrinogen (Goodger, 1976).
second group was composed of antigens located on the parasite.
The
They differed
in specificity from those on the stroma and red-cell membrane, but l i t t l e was known of their physical and chemical properties.
Another antigen was found in
the cytoplasm of the infected erythrocyte and extracted from the haemoglobin solution obtained after lysis of the erythrocytes
in d i s t i l l e d water.
The
fibrinogen-associated antigens were precipitated from the crude soluble extract with protamine sulphate and this step effectively separated those antigens that were associated with the erythrocyte stroma from those located on the parasite and in the erythrocyte cytoplasm. fraction seemed to confirm
The response in calves inoculated with each
this broad separation because antibodies from those
immunized with fibrinogen-associated antigen stained the stroma of infected erythrocytes in the indirect fluorescent antibody (IFA) test and the antibodies from the group immunized with the antigen(s) l e f t in solution after the removal of the precipitate stained only the parasites (Mahoney, Wright and Goodger, 1981).
405 IA
Eluate
of S P E
4~
~
34
m ~.
2,
~ ( 3 / 5 )
.....
6 0 ._~
~'
t
(a) i
IA Eluate
._ ~
6 0 1,
o
~...--
100 ug
m,~ ( )
500ug Survival
~
(515)
--.. . .
(b)
{
FAA
~
Control
3
of
~
;,
~
(,3/5)
~
~
A
9
Days
Figure 3. Parasitaemia and survival in cattle vaccinated with different doses (100 ug, 500 ~g protein) of antigen obtained by immunoabsorption from (a) a soluble extract of B. bovis (SPE) and (b) a fibrinogen-like precipitate from the soluble e x t r a c T S , bovis (FAA), and challenged with a virulent heterologous strain of t h e ~ r ~ s m . Both fractions protected cattle against challenge.
One interpretation of
this result was that an antigenic component, common to both fractions but not distinguishable by IFA test was responsible for protection.
However, there
could be more than one target antigen involved in protection against B. bovis and these could be located on both the infected red cells and the parasites. Mahoney, Kerr,
Goodger and Wright (1979) concluded that
antibodies attacked targets at both sites.
the
protective
The immunoglobulins from the serum
of calves inoculated with each of the above fractions ( i . e . precipitate and supernatant)
were purified and coupled to
immunoabsorption.
CNBr Sepharose 4B columns for
These columns were then used to extract antigen from the
crude soluble material
(Figure 1).
The concentration of
protein
in
the
extracts was approximately 200 pg/ml and contained in addition to B. bovis-
406
specific
material,
components from normal
specific
absorption of such m a t e r i a l
bovine
erythrocytes
owing to
on the Sepharose columns.
non-
Each f r a c t i o n
contained t h r e e a n t i g e n i c components from B. b o v i s , but t h e r e were no r e a c t i o n s of i d e n t i t y tests.
or even p a r t i a l - i d e n t i t y
between the two groups in immunodiffusion
C a t t l e were immunized w i t h each f r a c t i o n
dose l e v e l s ,
100 ~g and 500 ~g of p r o t e i n ,
the supernatant f r a c t i o n (Figure
3a)
isolated
but
the
(SPE), the dose of
higher
dose
was
from crude s o l u b l e m a t e r i a l
the 500 ug dose gave more e f f e c t i v e
by a s i n g l e i n j e c t i o n .
Two
were used. With the antigens from 100 ug of p r o t e i n gave p r o t e c t i o n
less
protective.
With
the
antigens
by a n t i b o d i e s to the p r e c i p i t a t e
(FAA),
p r o t e c t i o n (Figure 3b).
The Use of Monoclonal Antibodies. Antigen
was
obtained
from
the
c r u d e soluble
extract
by
affinity
chromatography using antibodies from calves previously inoculated with the supernatant fraction
(Figure I).
T h i s material was used to immunize BALB/c
mice and their spleen cells were fused with P3-NSI-Ag4-1 mouse myeloma cells. After screening of the hybrid-cell lines for babesial antibody production by radio immuno assay (RIA) and indirect fluorescent antibody (IFA) tests, three clones were f i n a l l y obtained which showed different staining specificities for B. bovis.
Each clone was used to produce ascites f l u i d in BALB/c mice and
gamma-globulin was extracted from the f l u i d and used for immunoabsorption. The specificity of each monoclonal antibody determined by IFA analysis and the preliminary characterization of
the
fractions extracted by
IA from crude
soluble material are show in Table 1 below. TABLE I . Hybridoma Clone No.
2C3 15B1 18A5
S p e c i f i c i t y of Monoclonal Antibodies by IFA S t a i n i n g
No. of Antigens in IA Eluate (Western t r a n s f e r analysis)*
Parasites + Erythrocyte Stroma Parasites only Parasites only. Preference for blunt end
1 I i
M.W. (daltons)
Strain Specificity of Antigen
1.3X10~ 44X10~ 180X103
multiple multiple multiple
IFA = I n d i r e c t f l u o r e s c e n t a n t i b o d y . IA = A f f i n i t y chromatography. M.W. = m o l e c u l a r w e i g h t . Estimates were made on the n a t i v e p r o t e i n s . * These are p r e l i m i n a r y r e s u l t s using the bovine antiserum to each e l u a t e and a peroxidase l a b e l l e d - a n t i b o v i n e y - g l o b u l i n . Analysis of the 15B1 e l u a t e on p o l y a c r y l a m i d e gel e l e c t r o p h o r e s i s showed t h a t i t also contained a number of n o n - a n t i g e n i c contaminating p r o t e i n s , presumably of host o r i g i n . Each e x t r a c t calf
was used to
immunize groups of 4 splenectomized c a l v e s .
was given 2 doses in FCA each c o n t a i n i n g
I00 ~g p r o t e i n ,
Each
4 weeks a p a r t ,
407
and then challenged with the homologous strain of parasites, 2 weeks a f t e r the last i n o c u l a t i o n .
Only the calves immunized with the fraction isolated by 15BI
antibodies showed evidence of protection. days of
infection,
occurred
at
but
3 of
14 days.
the
The control calves died within I0
15BI group survived and the single death
Levels
of
parasitaemia
in
the
group
were
also
s i g n i f i c a n t l y lower than those in the controls from day 5 onwards. DISCUSSION An
effective
d e a d vaccine
characteristics: different
(a)
for
B. bovis
prevention of c l i n i c a l
should
h a v e the
disease;
immunological strains of the parasite;
foliowing
(b) efficacy against
(c) one or two inoculations
should induce protection; (d) protection should be induced for a minimum of 6 months;
(e) no concurrent immunisation against host blood group antigens; ( f )
a v a i l a b i l i t y in large q u a n t i t i e s ; (g) s t a b i l i t y on storage. (b) and (c) above have been f u l f i l l e d duration
of
determined.
protection However, i t
after
The c r i t e r i a
(a),
by the crude antigenic preparations.
immunization
with
antigen
has
The
not
been
has been found that immunity to r e i n f e c t i o n remained
for at least 6 months a f t e r termination of i n fec t io n with chemotherapy (Callow, McGregor, Parker and Dalgliesh, 1974) and a s i m i l a r duration of immunity would be expected to follow antigen inoculation. The p u r i f i c a t i o n of protective antigens w i l l the knowledge accumulated so far.
require some reassessment of
For example, i t
is not yet known whether a
single p u r i f i e d antigen w i l l give protection under a l l circumstances or whether several
antigens
ch a ra c t e r i s t i c s
are
needed to
give
the
artifically-induced
immunity
implied in the essential c r i t e r i a outlined above.
the
A further
complication is the possible i n t e r a c t i o n of a mixture of p u r i f i e d antigens in the host.
Under d i f f e r e n t conditions, one might e i t h e r i n h i b i t or enhance the
effect
another.
of
absorption precipitate least
three
to
(FAA) f r a c t i o n s , babesial
immunodiffusion tests. but
The experiments with
mat er ial,
antibodies from cows immunized with produced
antigens,
that
partially
two preparations, were a l l
purified
crude soluble
by
(SPE) and
each containing at
different
on analysis
with
Both preparations contained impurities of host o r i g i n
nevertheless protected c a t t l e
against
disease in
small
doses.
These
results suggested that B. bovis might contain more than one antigen capable of conferring
protection
on
the
host.
The
three
antigens
detected
by
immunodiffusion in SPE were presumably those isolated by using the monoclonal antibodies 2C3, 15BI and 18A5, but only 15BI was p r o t e c t i v e . induced in
splenectomized calves
by the
The protection
15BI antigen was s i m i l a r
to
that
produced in such animals by crude antigenic extracts of the parasite (Goodger, Wright and Mahoney, 1981).
This suggests therefore that the antigen is a major
408
common protective component of B. bovis parasites.
I t remains to be determined
which of the antigens detected in the FAA fraction are also protective, and i f each can, on its own, provide an effective protection system that w i l l f u l f i l l the
above c r i t e r i a .
If
the
confirmed, there seems l i t t l e available in
protective a c t i v i t y doubt that i t
will
of
the
15B1 protein is
soon be cloned and become
larger quantities suitable for more extensive testing.
This
should also allow work to proceed on the molecular basis of its antigenicity. REFERENCES
Callow L.L., McGregor W., Parker R.J. and Dalgliesh R.J. 1974. The immunity of cattle to Babesia argentina after drug s t e r i l i s a t i o n of infections of varying duration. Aust. Vet. J., 50: 6-11. Callow, L.L., 1977. Vaccination against bovine babesiosis. A d v . Exp. Med. B i o l . , 93, 121-149. Goodger B.V., 1971. Preparation and preliminary assessment of purified antigens in the passive haemagglutination test for bovine babesiosis. Aust. Vet. J., 47: 251-256. Goodger B.V., 1973. Babesiaargentina: intraerythrocytic location of babesial antigen extracted from parasite suspensions. Int. J. Parasitol., 3: 387-391. Goodger B.V., 1976. Babesia argentina: studies on the nature of an antigen associated with infection. Int. J. Parasitol., 6: 213-216. Goodger B.V., Wright I.G., Mahoney D.F. and McKenna R.V., 1980. Babesia bovis (argentina): studies on the composition and location of antigen associated with infected erythrocytes. Int. J. Parasitol., I0: 33-36. Goodger, B.V., Wright, I.G. and Mahoney, D.F., 1981. The use of pathophysiological reactions to assess the efficacy of the immune response to Babesia bovis in cattle. Z. Parasitenkd., 66: 41-48. KoTG.~d Milstein, C., 1975. Continuous cultures of fused cells secreting antibody of predefined specificity. Nature (London), 256: 495-497. Levy M.G. and Ristic M., 1980. Babesia bovis: continuous cultivation in a microaerophilous stationary phase culture. Science, 20/: 1218-1220. Ludford C.G., 1967. Studies on Babesia rodhaini, its morphology, course of infection and immunity in rats; with observations on Babesia affecting cattle. Ph.D. Thesis, University of Queensland. Mahoney D.Fo, 1967a. Bovine babesiosis: the immunization of cattle with k i l l e d Babesia argentina. Exp. Parasitol., 20: 125-129. Mahoney ~ 1 9 6 7 b . B o v i n e babesiosis: preparation and assessment of complement fixing antigens. Exp. Parasitol., 20: 232-241. Mahoney D.F., 1981. Prospects for an antibabesial vaccine. In: M. Ristic and J.P. Kreier (Editors), Babesiosis. Academic Press, New York, pp. 555-562. Mahoney D.F. and Goodger, B.V., 1981. The isolation of Babesia parasites and t h e i r products from the blood. In: M. Ristic and J.P. Kreier (Editors), Babesiosis. Academic Press, New York, pp. 323-335. Mahoney D.F. and Wright I.G., 1976. Babesiaargentina: immunizationof cattle with a k i l l e d antigen against infec ~--Ct-i-6~---with a heterologous strain. Vet. Parasitol., 2: 273-282. Mahoney D.F., K e r r J.D., Goodger B.V. and Wright I.G., 1979. The immune response of cattle to Babesia bovis (syn. B. argentina). Studies on the nature and specificity of protection. Int. J. Parasitol., 9: 297-306. Mahoney D.F., Wright I.G. and Goodger B.V., 1981. Bovine babesiosis: the immunization of cattle with fractions of erythrocytes infected with Babesia bovis (syn. B. argentina). V e t . Immunol. and Immunopathol., 2: 145-156. Ph~s R.S.~--1967. Active immunization of rats against Babesia (Nuttallia) rodhaini using a k i l l e d vaccine. Parasitology, 57: i i p . -
-
401
Elsevier Science Publishers B.V., Amsterdam -- Printed in The Netherlands
IMMUNIZATION AGAINST BABESIOSIS: CURRENTSTUDIES AND FUTURE OUTLOOK D.F. Mahoney, I.G. Wright and B.V. Goodger CSIRO Division of Tropical Animal Science Long Pocket Laboratories, Private Bag No. 3, P.O. IndooroopiIIy, Queensland 4068, Australia
ABSTRACT
Mahoney, D.F., Wright, I.G. and Goodger, B.V., 1984. Immunization against babesiosis: current studies and future outlook. Prev. Vet. Med., 2: 401-408. Experiments were conducted on the induction of immunity to Babesia bovis in cattle with antigen extracted from erythrocytes infected wit-B--t~-~parasite. Protection after inoculation with crude parasite-erythrocyte stroma mixtures was as strong as that induced by natural infection. B. bovis appears to contain several different protective antigens, and one o f ~ h ~ was p a r t i a l l y purified by immunoabsorption using a monoclonal antibody. It is a protein consisting of a single peptide of low molecular weight and appears to be located in or on the surface of the parasite. INTRODUCTION I t is now over a decade since the f i r s t demonstration that immunity could be induced against Babesia parasites by inoculation of their hosts with crude antigenic material prepared from infected blood (Mahoney 1967a, Phillips 1967). However, notwithstanding these developments in immunological research, vaccination with the l i v i n g organism (Callow 1977) is the only available means of preventing babesiosis, even though a number of serious disadvantages are associated with this form of immunization (Mahoney 1981).
The slow progress has
been caused by the nature of the organism and its close association with the host erythrocyte.
It is d i f f i c u l t to separate either the parasites or their
antigens from red-cell material (Mahoney and Goodger 1981) and this invariably results in the immunization of the host with erythrocyte antigens in addition to those from the parasite.
Unlike many bacterial diseases for which k i l l e d
suspensions of the causal organisms are used for immmunization, the isolation of protective antigens of Babesia spp. is a prerequisite for such development. Until recently, Babesia spp. had not been grown successfully in v i t r o .
A cul-
ture system for B. bovis is now available (Levy and Ristic 1980), but although it
increased the a v a i l a b i l i t y of infected blood, the problem of erythrocytic
contamination of antigen remained. Therefore the purification and characterization of the protective antigen(s) is relevant and the eventual aim is to clone and express such substances in a suitable organism in order to solve the dual problem of production and purification of antigen for vaccination. 0167-5877/84/$03.00
© 1984 Elsevier Science Publishers B.V.
402
EXPERIMENTAL METHODS AND RESULTS The experimental work described in t h i s
paper r e f e r s to B. bovis which is a
p a r a s i t e of c a t t l e and one of major economic s i g n i f i c a n c e throughout the w o r l d . The basic requirement f o r s t u d i e s on the antigens of t h i s species was to o b t a i n a concentrated
source
of
the
organism.
This
s e p a r a t i o n of i n f e c t e d from n o n - i n f e c t e d c e l l s
requirement
was met by the
in blood (Mahoney, 1967b).
The
technique was based on the o b s e r v a t i o n t h a t the i n f e c t e d e r y t h r o c y t e s were less susceptible
to
hypotonic
lysis
than the u n i n f e c t e d
cells.
It
was t h e r e f o r e
possible to select a concentration of salt solution that lysed all uninfected erythrocytes
leaving the infected ones intact to be recovered by d i f f e r e n t i a l
centrifugation.
The method was rapid,
preparative scale.
reproducible
and applicable on a
It was used to produce suspensions of 95-100% infected
erythrocytes from blood with parasitaemia in the range of 5 to 15%. Extracts of crude antigen were prepared from these infected cell suspensions by sonic disintegration for 2-4 minutes at maximum power of the instrument followed by centrifugation at 145,000 g for 60 minutes at 4°C. the
crude soluble antigen
and i t
The supernatant f l u i d was
was fractionated by precipitation with
protamine sulphate and by immunoabsorption (IA) using antibodies from immune cattle and monoclonal antibodies produced by the techniques established by Kohler and Milstein (1975).
A flow diagram for fractionation procedures is
shown in Figure 1.
INFECTED ERYTHROCYTES I Disintegration INFECTED ERYTHROCYTE ANTIGEN I Centrifuge at 145,000g x 60mins I
I CRUDE SOLUBLE $ EXTRACT $
CRUDE INSOLUBLE EXTRACT
I
Affinity Purification
I SUPERNATANT FRACTION (SPE)
I Antibodies
Precipitation with ~1 Protamine Sulphate
I PRECIPITATE FRACTION (FAA) I
in Calves
Antibodies in Calves
I
I
Affinity Purification
I ,
Figure 1. Flow diagram of the fractionation procedure for bovine erythrocytes infected with B. bovis.
403
Tests for the immunogenic a c t i v i t y of antigens consisted of the subcutaneous inoculation of the antigen as a water-in-oil emulsion with Freund's Complete Adjuvant (FCA) into either two-year-old steers or 6-month-old splenectomized calves.
In early work three inoculations, two weeks apart were used but in
later studies the number of inoculations were reduced to two and to one. Two to four weeks after immunization, the two-year-old steers were challenged by I/V inoculation with a different strain of B. bovis from the one used to prepare the antigen.
For splenectomized calves the same strain as that used to
prepare the antigen was used for challenge.
The immune response was then
assessed by comparing daily rectal temperatures, levels of parasitaemia and f a l l s in packed cell volume in vaccinated and control groups. The l a t t e r were sham-immunised with FCA alone. 0 ~(9 -IO.E
~. ~ o20, 0 ~ -30. m o ~ -4o >
~
(a) m" ,,o,O-
/ .. ....
.
~ ,'~-~ ~
~.;''" ! !ii!ie~a~ed
~
~
~ - 5C 0
g ~ -~0
"~'~c~:
#~..,.~-'~
.~
~bl
~ -20' ....
~ -ao
g ~ -40.
g
~ -5~' -~0-
o
i
i
A
g
YO
1"2
1~
i'~
Days
Figure 2. (a) Comparison of the changes in packed cell volume (PCV) in cattle vaccinated with crude B. bovis antigen and in cattle immunised by B. bovis infection, after c h a l ~ g ~ h virulent heterologous B. bovis organlsms. Taken from Mahoneyand Wright (1976). (b) The changes in PCV in cattle vaccinated with soluble and insoluble fractions of crude B. bovis antigen and challenged with an heterologous strain of the organism.
404
Protection by crude antigen. Mahoney and Wright (1976) showed that prepared by disruption heterologous B. bovis -
of
immunization with
infected erythrocytes
protected
crude antigen cattle
against
infection as effectively as immunity associated with
-
active infection (Figure 2a).
T h i s material was a mixture of all particulate
and soluble components contained by infected erythrocytes.
It was fractionated
into soluble and insoluble components by ultracentrifugation and both fractions induced similar protection (Figure 2b), demonstrating that protective antigen was released into solution. Fractionation of the crude soluble antigen. The f i r s t
fractionation procedure was based on studies by Goodger (1971,
1973, 1976) who showed that the antigens extracted from the B. bovis-infected erythrocyte contained several different specificities and he classified them into three groups.
The f i r s t
group was composed of two antigens associated
with the stroma of the erythrocyte.
These were responsible for staining of the
membrane by fluorescein-labe|led antibodies (Ludford,
1967).
One of
the
antigens was located as a dense band in or under the cell membrane and the other had a granular distribution throughout the stroma. Characterization of the stromal antigens showed that they were basically fibrinogen molecules, altered by conjugation with a number of babesial and others of host origin 1980).
peptides,
some of which were of
(Goodger, Wright, Mahoney and McKenna,
Separationof the fibrinogen-associated antigen complexes was achieved
by methods that
specifically precipitated fibrinogen (Goodger, 1976).
second group was composed of antigens located on the parasite.
The
They differed
in specificity from those on the stroma and red-cell membrane, but l i t t l e was known of their physical and chemical properties.
Another antigen was found in
the cytoplasm of the infected erythrocyte and extracted from the haemoglobin solution obtained after lysis of the erythrocytes
in d i s t i l l e d water.
The
fibrinogen-associated antigens were precipitated from the crude soluble extract with protamine sulphate and this step effectively separated those antigens that were associated with the erythrocyte stroma from those located on the parasite and in the erythrocyte cytoplasm. fraction seemed to confirm
The response in calves inoculated with each
this broad separation because antibodies from those
immunized with fibrinogen-associated antigen stained the stroma of infected erythrocytes in the indirect fluorescent antibody (IFA) test and the antibodies from the group immunized with the antigen(s) l e f t in solution after the removal of the precipitate stained only the parasites (Mahoney, Wright and Goodger, 1981).
405 IA
Eluate
of S P E
4~
~
34
m ~.
2,
~ ( 3 / 5 )
.....
6 0 ._~
~'
t
(a) i
IA Eluate
._ ~
6 0 1,
o
~...--
100 ug
m,~ ( )
500ug Survival
~
(515)
--.. . .
(b)
{
FAA
~
Control
3
of
~
;,
~
(,3/5)
~
~
A
9
Days
Figure 3. Parasitaemia and survival in cattle vaccinated with different doses (100 ug, 500 ~g protein) of antigen obtained by immunoabsorption from (a) a soluble extract of B. bovis (SPE) and (b) a fibrinogen-like precipitate from the soluble e x t r a c T S , bovis (FAA), and challenged with a virulent heterologous strain of t h e ~ r ~ s m . Both fractions protected cattle against challenge.
One interpretation of
this result was that an antigenic component, common to both fractions but not distinguishable by IFA test was responsible for protection.
However, there
could be more than one target antigen involved in protection against B. bovis and these could be located on both the infected red cells and the parasites. Mahoney, Kerr,
Goodger and Wright (1979) concluded that
antibodies attacked targets at both sites.
the
protective
The immunoglobulins from the serum
of calves inoculated with each of the above fractions ( i . e . precipitate and supernatant)
were purified and coupled to
immunoabsorption.
CNBr Sepharose 4B columns for
These columns were then used to extract antigen from the
crude soluble material
(Figure 1).
The concentration of
protein
in
the
extracts was approximately 200 pg/ml and contained in addition to B. bovis-
406
specific
material,
components from normal
specific
absorption of such m a t e r i a l
bovine
erythrocytes
owing to
on the Sepharose columns.
non-
Each f r a c t i o n
contained t h r e e a n t i g e n i c components from B. b o v i s , but t h e r e were no r e a c t i o n s of i d e n t i t y tests.
or even p a r t i a l - i d e n t i t y
between the two groups in immunodiffusion
C a t t l e were immunized w i t h each f r a c t i o n
dose l e v e l s ,
100 ~g and 500 ~g of p r o t e i n ,
the supernatant f r a c t i o n (Figure
3a)
isolated
but
the
(SPE), the dose of
higher
dose
was
from crude s o l u b l e m a t e r i a l
the 500 ug dose gave more e f f e c t i v e
by a s i n g l e i n j e c t i o n .
Two
were used. With the antigens from 100 ug of p r o t e i n gave p r o t e c t i o n
less
protective.
With
the
antigens
by a n t i b o d i e s to the p r e c i p i t a t e
(FAA),
p r o t e c t i o n (Figure 3b).
The Use of Monoclonal Antibodies. Antigen
was
obtained
from
the
c r u d e soluble
extract
by
affinity
chromatography using antibodies from calves previously inoculated with the supernatant fraction
(Figure I).
T h i s material was used to immunize BALB/c
mice and their spleen cells were fused with P3-NSI-Ag4-1 mouse myeloma cells. After screening of the hybrid-cell lines for babesial antibody production by radio immuno assay (RIA) and indirect fluorescent antibody (IFA) tests, three clones were f i n a l l y obtained which showed different staining specificities for B. bovis.
Each clone was used to produce ascites f l u i d in BALB/c mice and
gamma-globulin was extracted from the f l u i d and used for immunoabsorption. The specificity of each monoclonal antibody determined by IFA analysis and the preliminary characterization of
the
fractions extracted by
IA from crude
soluble material are show in Table 1 below. TABLE I . Hybridoma Clone No.
2C3 15B1 18A5
S p e c i f i c i t y of Monoclonal Antibodies by IFA S t a i n i n g
No. of Antigens in IA Eluate (Western t r a n s f e r analysis)*
Parasites + Erythrocyte Stroma Parasites only Parasites only. Preference for blunt end
1 I i
M.W. (daltons)
Strain Specificity of Antigen
1.3X10~ 44X10~ 180X103
multiple multiple multiple
IFA = I n d i r e c t f l u o r e s c e n t a n t i b o d y . IA = A f f i n i t y chromatography. M.W. = m o l e c u l a r w e i g h t . Estimates were made on the n a t i v e p r o t e i n s . * These are p r e l i m i n a r y r e s u l t s using the bovine antiserum to each e l u a t e and a peroxidase l a b e l l e d - a n t i b o v i n e y - g l o b u l i n . Analysis of the 15B1 e l u a t e on p o l y a c r y l a m i d e gel e l e c t r o p h o r e s i s showed t h a t i t also contained a number of n o n - a n t i g e n i c contaminating p r o t e i n s , presumably of host o r i g i n . Each e x t r a c t calf
was used to
immunize groups of 4 splenectomized c a l v e s .
was given 2 doses in FCA each c o n t a i n i n g
I00 ~g p r o t e i n ,
Each
4 weeks a p a r t ,
407
and then challenged with the homologous strain of parasites, 2 weeks a f t e r the last i n o c u l a t i o n .
Only the calves immunized with the fraction isolated by 15BI
antibodies showed evidence of protection. days of
infection,
occurred
at
but
3 of
14 days.
the
The control calves died within I0
15BI group survived and the single death
Levels
of
parasitaemia
in
the
group
were
also
s i g n i f i c a n t l y lower than those in the controls from day 5 onwards. DISCUSSION An
effective
d e a d vaccine
characteristics: different
(a)
for
B. bovis
prevention of c l i n i c a l
should
h a v e the
disease;
immunological strains of the parasite;
foliowing
(b) efficacy against
(c) one or two inoculations
should induce protection; (d) protection should be induced for a minimum of 6 months;
(e) no concurrent immunisation against host blood group antigens; ( f )
a v a i l a b i l i t y in large q u a n t i t i e s ; (g) s t a b i l i t y on storage. (b) and (c) above have been f u l f i l l e d duration
of
determined.
protection However, i t
after
The c r i t e r i a
(a),
by the crude antigenic preparations.
immunization
with
antigen
has
The
not
been
has been found that immunity to r e i n f e c t i o n remained
for at least 6 months a f t e r termination of i n fec t io n with chemotherapy (Callow, McGregor, Parker and Dalgliesh, 1974) and a s i m i l a r duration of immunity would be expected to follow antigen inoculation. The p u r i f i c a t i o n of protective antigens w i l l the knowledge accumulated so far.
require some reassessment of
For example, i t
is not yet known whether a
single p u r i f i e d antigen w i l l give protection under a l l circumstances or whether several
antigens
ch a ra c t e r i s t i c s
are
needed to
give
the
artifically-induced
immunity
implied in the essential c r i t e r i a outlined above.
the
A further
complication is the possible i n t e r a c t i o n of a mixture of p u r i f i e d antigens in the host.
Under d i f f e r e n t conditions, one might e i t h e r i n h i b i t or enhance the
effect
another.
of
absorption precipitate least
three
to
(FAA) f r a c t i o n s , babesial
immunodiffusion tests. but
The experiments with
mat er ial,
antibodies from cows immunized with produced
antigens,
that
partially
two preparations, were a l l
purified
crude soluble
by
(SPE) and
each containing at
different
on analysis
with
Both preparations contained impurities of host o r i g i n
nevertheless protected c a t t l e
against
disease in
small
doses.
These
results suggested that B. bovis might contain more than one antigen capable of conferring
protection
on
the
host.
The
three
antigens
detected
by
immunodiffusion in SPE were presumably those isolated by using the monoclonal antibodies 2C3, 15BI and 18A5, but only 15BI was p r o t e c t i v e . induced in
splenectomized calves
by the
The protection
15BI antigen was s i m i l a r
to
that
produced in such animals by crude antigenic extracts of the parasite (Goodger, Wright and Mahoney, 1981).
This suggests therefore that the antigen is a major
408
common protective component of B. bovis parasites.
I t remains to be determined
which of the antigens detected in the FAA fraction are also protective, and i f each can, on its own, provide an effective protection system that w i l l f u l f i l l the
above c r i t e r i a .
If
the
confirmed, there seems l i t t l e available in
protective a c t i v i t y doubt that i t
will
of
the
15B1 protein is
soon be cloned and become
larger quantities suitable for more extensive testing.
This
should also allow work to proceed on the molecular basis of its antigenicity. REFERENCES
Callow L.L., McGregor W., Parker R.J. and Dalgliesh R.J. 1974. The immunity of cattle to Babesia argentina after drug s t e r i l i s a t i o n of infections of varying duration. Aust. Vet. J., 50: 6-11. Callow, L.L., 1977. Vaccination against bovine babesiosis. A d v . Exp. Med. B i o l . , 93, 121-149. Goodger B.V., 1971. Preparation and preliminary assessment of purified antigens in the passive haemagglutination test for bovine babesiosis. Aust. Vet. J., 47: 251-256. Goodger B.V., 1973. Babesiaargentina: intraerythrocytic location of babesial antigen extracted from parasite suspensions. Int. J. Parasitol., 3: 387-391. Goodger B.V., 1976. Babesia argentina: studies on the nature of an antigen associated with infection. Int. J. Parasitol., 6: 213-216. Goodger B.V., Wright I.G., Mahoney D.F. and McKenna R.V., 1980. Babesia bovis (argentina): studies on the composition and location of antigen associated with infected erythrocytes. Int. J. Parasitol., I0: 33-36. Goodger, B.V., Wright, I.G. and Mahoney, D.F., 1981. The use of pathophysiological reactions to assess the efficacy of the immune response to Babesia bovis in cattle. Z. Parasitenkd., 66: 41-48. KoTG.~d Milstein, C., 1975. Continuous cultures of fused cells secreting antibody of predefined specificity. Nature (London), 256: 495-497. Levy M.G. and Ristic M., 1980. Babesia bovis: continuous cultivation in a microaerophilous stationary phase culture. Science, 20/: 1218-1220. Ludford C.G., 1967. Studies on Babesia rodhaini, its morphology, course of infection and immunity in rats; with observations on Babesia affecting cattle. Ph.D. Thesis, University of Queensland. Mahoney D.Fo, 1967a. Bovine babesiosis: the immunization of cattle with k i l l e d Babesia argentina. Exp. Parasitol., 20: 125-129. Mahoney ~ 1 9 6 7 b . B o v i n e babesiosis: preparation and assessment of complement fixing antigens. Exp. Parasitol., 20: 232-241. Mahoney D.F., 1981. Prospects for an antibabesial vaccine. In: M. Ristic and J.P. Kreier (Editors), Babesiosis. Academic Press, New York, pp. 555-562. Mahoney D.F. and Goodger, B.V., 1981. The isolation of Babesia parasites and t h e i r products from the blood. In: M. Ristic and J.P. Kreier (Editors), Babesiosis. Academic Press, New York, pp. 323-335. Mahoney D.F. and Wright I.G., 1976. Babesiaargentina: immunizationof cattle with a k i l l e d antigen against infec ~--Ct-i-6~---with a heterologous strain. Vet. Parasitol., 2: 273-282. Mahoney D.F., K e r r J.D., Goodger B.V. and Wright I.G., 1979. The immune response of cattle to Babesia bovis (syn. B. argentina). Studies on the nature and specificity of protection. Int. J. Parasitol., 9: 297-306. Mahoney D.F., Wright I.G. and Goodger B.V., 1981. Bovine babesiosis: the immunization of cattle with fractions of erythrocytes infected with Babesia bovis (syn. B. argentina). V e t . Immunol. and Immunopathol., 2: 145-156. Ph~s R.S.~--1967. Active immunization of rats against Babesia (Nuttallia) rodhaini using a k i l l e d vaccine. Parasitology, 57: i i p . -
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