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Use of immunosorbent electron microscopy for detection of rota- and hepatitis a virus in sucrose solutions
Journal of Virological Methods, 12 (1985) 161-167
161
Elsevier JVM 00446
USE OF IMMUNOSORBENT
ELECTRON
OF ROTA- AND HEPATITIS
ELISABETH
KJELDSBERG
MICROSCOPY
A VIRUS IN SUCROSE
and JENS CHRISTIAN
FOR DETECTION
SOLUTIONS
SIEBKE
Virological Department, National Institute of Public Healih, Geitmyrsveien 75, 0462 Oslo 4, Norway (Accepted
30 July
1985)
Immunosorbent concentrations achieved
electron
microscopy
was used to demonstrate
after 18,42 and 66 h of incubation.
after 18 h incubation
and nearly
rotavirus
in solutions
About 50% of adsorption
of varying
of virus particles
100% after 42 h when compared
to trapping
sucrose
to the grid was
of virus from sucrose
free solutions. Hepatitis
A virus
immunosorbent
was purified
electron
dioimmunoassay.
The sensitivities
essentially
and considerably
electron
similar
in a lo-30%
microscopy,
direct
sucrose
electron
of immunosorbent greater
than
gradient
microscopy, electron
and each fraction immune
microscopy
direct electron
electron
was examined microscopy
and radioimmunoassay
microscopy
by
and ra-
and conventional
were immune
microscopy.
immunosorbent
electron
microscopy
rotavirus
hepatitis
A virus
sucrose
solutions
INTRODUCTION
Direct
electron
microscopy
(EM) and conventional
(IEM) have been used commonly (Feinstone
electron
microscopy
in sucrose or salt gradients
et al., 1974; Bradley et al., 1975; Flewett and Boxall, 1976). The presence of
low molecular it difficult
immune
for locating virus particles
material
to obtain
such as sucrose or salt in high concentrations,
good results by the negative
staining
technique.
however, makes Procedures
used
earlier for removing the sucrose prior to electron microscopy such as dialysis, pelleting and resuspension of material or evaporation and washing of the specimen on the grid are cumbersome, unreliable and of low sensitivity. Immunosorbent
electron
microscopy
(ISEM)
is widely used for detection
of virus
particles in clinical specimens and cell culture material as reviewed by Katz and Kohn (1984). It is a highly sensitive technique which allows thorough washing of the specimen and thereby removal of contaminating material without loss of virus particles. Plant viruses have been demonstrated in diluted or undiluted samples taken from sucrose gradients by this technique using specific antibody coating of virus particles adsorbed to the grid (Milne and Luisoni, 1975) or by coating of the grid with specific antibody prior to virus adsorption (Lesemann et al., 1980). In this report we describe 0166-0934/85/$03.30
0 1985 Elsevier
Science Publishers
B.V. (Biomedical
Division)
162
the application
of a protein
high concentrations
A - antibody
of sucrose
and radioimmunoassay
coating ISEM for rotavirus
and a comparison
(RIA) for detection
of ISEM,
of hepatitis
suspensions
EM, conventional
with IEM
A virus in sucrose gradient
fractions. MATERIALS
AND
Virus Human
METHODS
rotavirus
was extracted
from faeces as described
earlier (Kjeldsberg,
1977)
in Hanks’ salt solution supplemented with bovine serum albumin and antibiotics. Sucrose in 0.1 M phosphate buffer, pH 7, was added to the virus suspension to final concentrations of 10, 20 and 40%. Hepatitis A virus (HAV) was propagated in fetal rhesus monkey kidney cells (Frhk-4R). The cells were detached from the Roux bottle with glass beads, washed by centrifugation and lysed by freeze-thawing two times in the presence of 2% Triton X-100 in phosphate buffered saline. Cellular debris was removed by low speed centrifugation. The supernatant was layered on a lo-30% semi-linear gradient of sucrose in phosphate buffered saline containing 0.5% carrier bovine serum albumin and centrifuged for 3 h at 27,000 rpm in a Beckman SW 50.1 rotor. The collected fractions were stored at 4°C. Antisera Rabbit
anti-(human)
rotavirus
serum was prepared
as described
previously
(Kjelds-
berg and Mortensson-Egnund, 1982). The serum had a titre of 10,240 in fluorescent antibody test (FAT). As antiserum to hepatitis A virus, a human convalescent serum with hepatitis
A antibody
All serum dilutions
titre of 2,000 when tested by radioimmunoassay
were made in 0.1 M phosphate
buffer,
was used.
pH 7, with 0.02% sodium
azide added. Direct electron microscopy A 10 ul sample was placed on formvar carbon-coated copper grid and allowed to evaporate until nearly dry. The grid was dipped into distilled water twice, and in 2% potassium phosphotungstate (KPT), pH 6.5, once. Excess water was removed with filter paper and the grid was examined
in a JEM
1OOB electron
microscope.
Immune electron microscopy Conventional IEM was performed by mixing equal amounts (50 ~1) of virus suspension and antiserum diluted 1 : 50, incubation overnight at 4”C, the mixture was diluted three times with 0.1 M phosphate buffer and centrifuged for 1 h at 17,000 rpm in Sorvall centrifuge, SS-34 rotor. The pellet was suspended in 2% KPT, pH 6.5, and examined in the electron microscope.
163
Immunosorbent ISEM
electron
was performed
1982). Antiserum dilution dilutions
microscopy as described
against
human
earlier
rotavirus
(Kjeldsberg
and Mortensson-Egnund,
was used at a dilution
1: 2,500. Optimal
of the antiserum against hepatitis A virus was established by testing serial of the serum. The grid was pretreated with protein A, 10 pg/ml (Pharmacia),
washed with 0.1 M phosphate buffer, pH 7, coated with antiserum, washed with buffer and incubated with virus suspension. After adsorption of the virus particles the grid was washed with distilled water, negatively stained with 2% KPT and examined in the electron microscope. Radioimmunoassay Wells of Costar 2595 vinyl assay plates were coated with rabbit
IgG against human
IgM and subsequently with a 1 : 4,000 dilution of a serum from a patient with acute hepatitis A virus infection. Fractions to be tested were diluted 1 : 10 in buffered saline/carrier albumin. 50 ul samples were incubated in the wells overnight at ambient temperature. After washing, 50 ul of 1251-labelled anti-HAV (obtained from an Abbott HAVAB-M test kit) was added to each well and incubated for 4 h at 37°C. After final washing, wells were cut with a pair of scissors and counted. RESULTS
Suspensions examined
of human
rotaviruses
by immunosorbent
in 0, 10, 20 and 40% sucrose
electron
microscopy
and reaction
solutions
were
times of 18,42 and 66
h were used for adsorption of the virus particles to the grids. The results are summarized in Table 1. In the absence of sucrose, maximum adsorption of virus was achieved after reaction for 18 h and remained constant at further incubation. With sucrose in increasing concentrations, the number of trapped virus particles was reduced to about
TABLE
1
Adsorption
of rotavirus
concentration
on protein
and incubation
% Sucrose
A and antibody
electron
microscopy
grids at varying
No. of particle? 18 hb
42 hb
66 hb 104
0
95
72
10
52
85
70
20
52
91
72
40
45
74
99
a Mean count b Reaction
coated
time
on five 60 X 90 mm micrographs
time for binding
of virus.
taken
at a magnification
of X 10,000.
sucrose
164
50% at 18 h incubation. 66 h resulted electron
Prolongation
in almost
microscopy
maximum
of the reaction
adsorption
optima1 conditions
grids were coated with serial dilutions
Fig. 1. Rotavirus direct
trapped
EM. Negatively
TABLE
also. Direct
particles or none
la,b).
In order to establish prepared
of virus to 42 or
from the sucrose solutions
of the same samples showed only a few rotavirus
at all on the grids (Fig.
cell cultures
time for binding
as described
on erectron
stained
for the demonstration
of antiserum
to HAV. Hepatitis
above was used as antigen
microscopy
with 2% potassium
of HAV by ISEM,
grids in the presence phosphotungstate,
A virus from
in the test (Table
2).
of 15% sucrose by (a) ISEM and (b) pH 6.5. Bars represent
200 nm.
2
Adsorption
of hepatitis
Serum dilution
A virus on protein
1:
200
179
1:
400
257
1:
800
375
1:
1,600
374
1: 3,200
379
1: 6,400
275
1: 12,ROO
119
a Reaction
coated
grids at varying
antiserum
No. of particlesh Positive
1: 25,600
A and antibody
serum
Negative
serum
48 time for binding
b Mean count
of virus was 18 h.
on two 60 X 90 mm micrographs
taken at a magnification
of X 25,000.
dilution’
165
Dilutions
of 1: 800 to 1: 3,200 gave maximum
1: 2,000 serum dilution No virus particles Purification lo-30%
adsorption
was chosen for the examination
were seen on the grids coated
of hepatitis
sucrose gradient.
A virus propagated Each fraction
of virus
particles
of sucrose gradient
with negative in cell cultures
was examined
human
and
fractions.
serum.
was performed
in a
by RIA, ISEM, direct EM and
conventional IEM and the results are presented in Table 3. Virus particles were demonstrated in all fourteen fractions by RIA and ISEM. Conventional IEM revealed the presence of HAV in fractions 3,5,7,8 and 10, while virus was demonstrated only in fraction 8 by direct electron microscopy. Figure 2 illustrates the amount of virus antigen and virus particles in the fractions as measured by RIA and ISEM, respectively. In spite of minor deviations the shape of the graphs are almost identical and the top fractions are easily selected.
=o
:
i
2
150.
2
4:
:
2
2 3
.E ?lOO-
.3 5 zi (D
P k
x
2
-2 0
: 50. .o .L >
z”
c: -1
z
12345676
9
Fraction
Fig. 2. Demonstration 18 h). Number magnification
TABLE
of hepatitis
of virions
10
11
12
13
I
14
nr.
A virus in a lo-40%
trapped
sucrose gradient
on the grid was counted
by RIA and ISEM (incubation
on 60 X 90 mm micrographs
taken
time at a
of X 25,000.
3
Comparison microscopy
of radioimmunoassay
(RIA), immunosorbent
(IEM) and direct electron
microscopy
electron
(EM) for detecting
microscopy hepatitis
(ISEM), immune electron A virus in a lo-30%sucrose
gradient Method
Fraction
no.
1
2
3
4
5
6
7
RIA
+
+
+
+
ISEM IEM
+ _
+ -
+ +
+ -
EM
-
-
-
-
8
9
+
+
+ +
+ -
-
-
10
11
12
13
14
+
+
+
+
+
+
+
+
+ +
+ +
+ -
+ +
+ -
+ -
+ -
+ -
-
+
-
-
-
-
-
-
166
DISCUSSION
Previously gradient
used electron
fractions
EM to remove
microscopy
methods
have been unsatisfactory. sucrose
or dialysis
for detection
Extensive
washing
and centrifugation
of viruses
in sucrose
procedures
by direct
procedures
for IEM cause
dramatic loss of material and thereby a low sensitivity. Coating of grids with antibody prior to adsorption of virus would overcome this problem as the virus particles are firmly trapped on the grid by antibody without loss of virus.
and thorough
washing
may be performed
The time required for maximum adsorption of virus particles from sucrose solutions was determined as increasing viscosity of the solution has a restraining effect on diffusion
of the particles
and thereby prolongs
the reaction
time for maximum
binding
of virus. To achieve maximum adsorption of virus from solutions of high sucrose concentration 42 h incubation was necessary. If, however, the sensitivity is not critical the reaction time may be reduced to 18 h or even less. Testing serial dilutions of human convalescent antiserum against hepatitis A virus by ISEM showed the well known prozone effect with low binding of virus at low dilutions of serum, maximum binding at dilutions 1: 800 to 1 : 3,200 and decreasing virus trapping at increasing serum dilutions. A comparison of the four methods applied to detect hepatitis A virus in sucrose gradient
fractions
showed that ISEM and RIA were essentially
equal in sensitivity
and
superior to both direct EM and conventional IEM. The amount of virus particles demonstrated by ISEM and virus antigen determined by RIA in the gradient fractions are on the whole in good accordance. The low values measured for hepatitis A antigen by RIA in fractions 5 and 6 are difficult to explain, Possibly the particles in these fractions reacted poorly with specific IgM. Conventional IEM is less sensitive than ISEM and RIA and less reliable. Fractions which contain a high number of virus particles as shown by ISEM, as for example fraction
9, are negative
demonstrated
by ISEM,
by IEM, while fraction is positive
3 in which only a few virus particles
by IEM. This makes it difficult
fractions. Direct EM has a very low sensitivity.
Only the top fraction,
and RIA, is positive by this method. Immunosorbent electron microscopy
is a simple method,
to locate the top
as determined neither
are
by ISEM
dialysis nor cen-
trifugation steps are necessary. Only small samples are needed, about 10 ul, which is essential as usually small amounts of material are available when working with gradient fractions. The test may be performed within a reasonable period of time. We find adsorption overnight at 4°C convenient but previous work has shown that 3-4 h incubation at 33°C resulted in the same number of particles trapped on the grid (Kjeldsberg and Mortensson-Egnund, 1982). If an electron microscope is available ISEM thus seems to be a suitable method for demonstration of virus particles in sucrose
solutions.
167
ACKNOWLEDGEMENTS
We thank supplying
Professor
M. DegrC for reviewing
the hepatitis
A virus-infected
the manuscript
and Dr. E. Tj&ta
for
cell cultures.
REFERENCES
Bradley,
D.W., C.L. Hornbeck,
Feinstone, Flewett, Katz,
C.R. Gravelle,
S.M., A.Z. Kapikian, T.H. and E. Boxall,
D. and
Maramorosch
A. Kohn,
J.L. Germ
E.H. Cook and J.E. Maynard, and R.H. Purcell,
1976, Clin. Gastroenterol.
1984, in: Advances
(Academic
Press, U.S.A.)
Kjeldsberg,
E., 1977, Acta Pathol.
Kjeldsberg,
E. and K. Mortensson-Egnund,
Lesemann,
D.E., R.F. Bozarth
Milne, R.G. and E. Luisoni,
in Virus Stand.
Research,
4, 45.
1980, J. Cert. Virol. 48, 257.
68, 270.
13, 1412.
Vol. 29, eds. M.A.
Sect. B. 85, 351.
1982, J. Virol. Methods
and R. Koenig,
1975, J. Infect. Dis. 13 1,304.
5, 359.
p. 169.
Microbial.
1975, Virology
1974, J. Virol.
Lauffer
and K.
161
Elsevier JVM 00446
USE OF IMMUNOSORBENT
ELECTRON
OF ROTA- AND HEPATITIS
ELISABETH
KJELDSBERG
MICROSCOPY
A VIRUS IN SUCROSE
and JENS CHRISTIAN
FOR DETECTION
SOLUTIONS
SIEBKE
Virological Department, National Institute of Public Healih, Geitmyrsveien 75, 0462 Oslo 4, Norway (Accepted
30 July
1985)
Immunosorbent concentrations achieved
electron
microscopy
was used to demonstrate
after 18,42 and 66 h of incubation.
after 18 h incubation
and nearly
rotavirus
in solutions
About 50% of adsorption
of varying
of virus particles
100% after 42 h when compared
to trapping
sucrose
to the grid was
of virus from sucrose
free solutions. Hepatitis
A virus
immunosorbent
was purified
electron
dioimmunoassay.
The sensitivities
essentially
and considerably
electron
similar
in a lo-30%
microscopy,
direct
sucrose
electron
of immunosorbent greater
than
gradient
microscopy, electron
and each fraction immune
microscopy
direct electron
electron
was examined microscopy
and radioimmunoassay
microscopy
by
and ra-
and conventional
were immune
microscopy.
immunosorbent
electron
microscopy
rotavirus
hepatitis
A virus
sucrose
solutions
INTRODUCTION
Direct
electron
microscopy
(EM) and conventional
(IEM) have been used commonly (Feinstone
electron
microscopy
in sucrose or salt gradients
et al., 1974; Bradley et al., 1975; Flewett and Boxall, 1976). The presence of
low molecular it difficult
immune
for locating virus particles
material
to obtain
such as sucrose or salt in high concentrations,
good results by the negative
staining
technique.
however, makes Procedures
used
earlier for removing the sucrose prior to electron microscopy such as dialysis, pelleting and resuspension of material or evaporation and washing of the specimen on the grid are cumbersome, unreliable and of low sensitivity. Immunosorbent
electron
microscopy
(ISEM)
is widely used for detection
of virus
particles in clinical specimens and cell culture material as reviewed by Katz and Kohn (1984). It is a highly sensitive technique which allows thorough washing of the specimen and thereby removal of contaminating material without loss of virus particles. Plant viruses have been demonstrated in diluted or undiluted samples taken from sucrose gradients by this technique using specific antibody coating of virus particles adsorbed to the grid (Milne and Luisoni, 1975) or by coating of the grid with specific antibody prior to virus adsorption (Lesemann et al., 1980). In this report we describe 0166-0934/85/$03.30
0 1985 Elsevier
Science Publishers
B.V. (Biomedical
Division)
162
the application
of a protein
high concentrations
A - antibody
of sucrose
and radioimmunoassay
coating ISEM for rotavirus
and a comparison
(RIA) for detection
of ISEM,
of hepatitis
suspensions
EM, conventional
with IEM
A virus in sucrose gradient
fractions. MATERIALS
AND
Virus Human
METHODS
rotavirus
was extracted
from faeces as described
earlier (Kjeldsberg,
1977)
in Hanks’ salt solution supplemented with bovine serum albumin and antibiotics. Sucrose in 0.1 M phosphate buffer, pH 7, was added to the virus suspension to final concentrations of 10, 20 and 40%. Hepatitis A virus (HAV) was propagated in fetal rhesus monkey kidney cells (Frhk-4R). The cells were detached from the Roux bottle with glass beads, washed by centrifugation and lysed by freeze-thawing two times in the presence of 2% Triton X-100 in phosphate buffered saline. Cellular debris was removed by low speed centrifugation. The supernatant was layered on a lo-30% semi-linear gradient of sucrose in phosphate buffered saline containing 0.5% carrier bovine serum albumin and centrifuged for 3 h at 27,000 rpm in a Beckman SW 50.1 rotor. The collected fractions were stored at 4°C. Antisera Rabbit
anti-(human)
rotavirus
serum was prepared
as described
previously
(Kjelds-
berg and Mortensson-Egnund, 1982). The serum had a titre of 10,240 in fluorescent antibody test (FAT). As antiserum to hepatitis A virus, a human convalescent serum with hepatitis
A antibody
All serum dilutions
titre of 2,000 when tested by radioimmunoassay
were made in 0.1 M phosphate
buffer,
was used.
pH 7, with 0.02% sodium
azide added. Direct electron microscopy A 10 ul sample was placed on formvar carbon-coated copper grid and allowed to evaporate until nearly dry. The grid was dipped into distilled water twice, and in 2% potassium phosphotungstate (KPT), pH 6.5, once. Excess water was removed with filter paper and the grid was examined
in a JEM
1OOB electron
microscope.
Immune electron microscopy Conventional IEM was performed by mixing equal amounts (50 ~1) of virus suspension and antiserum diluted 1 : 50, incubation overnight at 4”C, the mixture was diluted three times with 0.1 M phosphate buffer and centrifuged for 1 h at 17,000 rpm in Sorvall centrifuge, SS-34 rotor. The pellet was suspended in 2% KPT, pH 6.5, and examined in the electron microscope.
163
Immunosorbent ISEM
electron
was performed
1982). Antiserum dilution dilutions
microscopy as described
against
human
earlier
rotavirus
(Kjeldsberg
and Mortensson-Egnund,
was used at a dilution
1: 2,500. Optimal
of the antiserum against hepatitis A virus was established by testing serial of the serum. The grid was pretreated with protein A, 10 pg/ml (Pharmacia),
washed with 0.1 M phosphate buffer, pH 7, coated with antiserum, washed with buffer and incubated with virus suspension. After adsorption of the virus particles the grid was washed with distilled water, negatively stained with 2% KPT and examined in the electron microscope. Radioimmunoassay Wells of Costar 2595 vinyl assay plates were coated with rabbit
IgG against human
IgM and subsequently with a 1 : 4,000 dilution of a serum from a patient with acute hepatitis A virus infection. Fractions to be tested were diluted 1 : 10 in buffered saline/carrier albumin. 50 ul samples were incubated in the wells overnight at ambient temperature. After washing, 50 ul of 1251-labelled anti-HAV (obtained from an Abbott HAVAB-M test kit) was added to each well and incubated for 4 h at 37°C. After final washing, wells were cut with a pair of scissors and counted. RESULTS
Suspensions examined
of human
rotaviruses
by immunosorbent
in 0, 10, 20 and 40% sucrose
electron
microscopy
and reaction
solutions
were
times of 18,42 and 66
h were used for adsorption of the virus particles to the grids. The results are summarized in Table 1. In the absence of sucrose, maximum adsorption of virus was achieved after reaction for 18 h and remained constant at further incubation. With sucrose in increasing concentrations, the number of trapped virus particles was reduced to about
TABLE
1
Adsorption
of rotavirus
concentration
on protein
and incubation
% Sucrose
A and antibody
electron
microscopy
grids at varying
No. of particle? 18 hb
42 hb
66 hb 104
0
95
72
10
52
85
70
20
52
91
72
40
45
74
99
a Mean count b Reaction
coated
time
on five 60 X 90 mm micrographs
time for binding
of virus.
taken
at a magnification
of X 10,000.
sucrose
164
50% at 18 h incubation. 66 h resulted electron
Prolongation
in almost
microscopy
maximum
of the reaction
adsorption
optima1 conditions
grids were coated with serial dilutions
Fig. 1. Rotavirus direct
trapped
EM. Negatively
TABLE
also. Direct
particles or none
la,b).
In order to establish prepared
of virus to 42 or
from the sucrose solutions
of the same samples showed only a few rotavirus
at all on the grids (Fig.
cell cultures
time for binding
as described
on erectron
stained
for the demonstration
of antiserum
to HAV. Hepatitis
above was used as antigen
microscopy
with 2% potassium
of HAV by ISEM,
grids in the presence phosphotungstate,
A virus from
in the test (Table
2).
of 15% sucrose by (a) ISEM and (b) pH 6.5. Bars represent
200 nm.
2
Adsorption
of hepatitis
Serum dilution
A virus on protein
1:
200
179
1:
400
257
1:
800
375
1:
1,600
374
1: 3,200
379
1: 6,400
275
1: 12,ROO
119
a Reaction
coated
grids at varying
antiserum
No. of particlesh Positive
1: 25,600
A and antibody
serum
Negative
serum
48 time for binding
b Mean count
of virus was 18 h.
on two 60 X 90 mm micrographs
taken at a magnification
of X 25,000.
dilution’
165
Dilutions
of 1: 800 to 1: 3,200 gave maximum
1: 2,000 serum dilution No virus particles Purification lo-30%
adsorption
was chosen for the examination
were seen on the grids coated
of hepatitis
sucrose gradient.
A virus propagated Each fraction
of virus
particles
of sucrose gradient
with negative in cell cultures
was examined
human
and
fractions.
serum.
was performed
in a
by RIA, ISEM, direct EM and
conventional IEM and the results are presented in Table 3. Virus particles were demonstrated in all fourteen fractions by RIA and ISEM. Conventional IEM revealed the presence of HAV in fractions 3,5,7,8 and 10, while virus was demonstrated only in fraction 8 by direct electron microscopy. Figure 2 illustrates the amount of virus antigen and virus particles in the fractions as measured by RIA and ISEM, respectively. In spite of minor deviations the shape of the graphs are almost identical and the top fractions are easily selected.
=o
:
i
2
150.
2
4:
:
2
2 3
.E ?lOO-
.3 5 zi (D
P k
x
2
-2 0
: 50. .o .L >
z”
c: -1
z
12345676
9
Fraction
Fig. 2. Demonstration 18 h). Number magnification
TABLE
of hepatitis
of virions
10
11
12
13
I
14
nr.
A virus in a lo-40%
trapped
sucrose gradient
on the grid was counted
by RIA and ISEM (incubation
on 60 X 90 mm micrographs
taken
time at a
of X 25,000.
3
Comparison microscopy
of radioimmunoassay
(RIA), immunosorbent
(IEM) and direct electron
microscopy
electron
(EM) for detecting
microscopy hepatitis
(ISEM), immune electron A virus in a lo-30%sucrose
gradient Method
Fraction
no.
1
2
3
4
5
6
7
RIA
+
+
+
+
ISEM IEM
+ _
+ -
+ +
+ -
EM
-
-
-
-
8
9
+
+
+ +
+ -
-
-
10
11
12
13
14
+
+
+
+
+
+
+
+
+ +
+ +
+ -
+ +
+ -
+ -
+ -
+ -
-
+
-
-
-
-
-
-
166
DISCUSSION
Previously gradient
used electron
fractions
EM to remove
microscopy
methods
have been unsatisfactory. sucrose
or dialysis
for detection
Extensive
washing
and centrifugation
of viruses
in sucrose
procedures
by direct
procedures
for IEM cause
dramatic loss of material and thereby a low sensitivity. Coating of grids with antibody prior to adsorption of virus would overcome this problem as the virus particles are firmly trapped on the grid by antibody without loss of virus.
and thorough
washing
may be performed
The time required for maximum adsorption of virus particles from sucrose solutions was determined as increasing viscosity of the solution has a restraining effect on diffusion
of the particles
and thereby prolongs
the reaction
time for maximum
binding
of virus. To achieve maximum adsorption of virus from solutions of high sucrose concentration 42 h incubation was necessary. If, however, the sensitivity is not critical the reaction time may be reduced to 18 h or even less. Testing serial dilutions of human convalescent antiserum against hepatitis A virus by ISEM showed the well known prozone effect with low binding of virus at low dilutions of serum, maximum binding at dilutions 1: 800 to 1 : 3,200 and decreasing virus trapping at increasing serum dilutions. A comparison of the four methods applied to detect hepatitis A virus in sucrose gradient
fractions
showed that ISEM and RIA were essentially
equal in sensitivity
and
superior to both direct EM and conventional IEM. The amount of virus particles demonstrated by ISEM and virus antigen determined by RIA in the gradient fractions are on the whole in good accordance. The low values measured for hepatitis A antigen by RIA in fractions 5 and 6 are difficult to explain, Possibly the particles in these fractions reacted poorly with specific IgM. Conventional IEM is less sensitive than ISEM and RIA and less reliable. Fractions which contain a high number of virus particles as shown by ISEM, as for example fraction
9, are negative
demonstrated
by ISEM,
by IEM, while fraction is positive
3 in which only a few virus particles
by IEM. This makes it difficult
fractions. Direct EM has a very low sensitivity.
Only the top fraction,
and RIA, is positive by this method. Immunosorbent electron microscopy
is a simple method,
to locate the top
as determined neither
are
by ISEM
dialysis nor cen-
trifugation steps are necessary. Only small samples are needed, about 10 ul, which is essential as usually small amounts of material are available when working with gradient fractions. The test may be performed within a reasonable period of time. We find adsorption overnight at 4°C convenient but previous work has shown that 3-4 h incubation at 33°C resulted in the same number of particles trapped on the grid (Kjeldsberg and Mortensson-Egnund, 1982). If an electron microscope is available ISEM thus seems to be a suitable method for demonstration of virus particles in sucrose
solutions.
167
ACKNOWLEDGEMENTS
We thank supplying
Professor
M. DegrC for reviewing
the hepatitis
A virus-infected
the manuscript
and Dr. E. Tj&ta
for
cell cultures.
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