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The preparation and biochemical characterization of intact capsids of equine infectious anemia virus
Vol. 160, No. 2, 1989
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS Pages
April 28, 1989
486-494
THE PREPARATION AND BIOCHEMICAL CHARACTERIZATION OF INTACT CAPSIDS OF EQUINE INFECTIOUS ANEMIA VIRUS MICHAEL M. ROBERTS AND STEPHEN OROSZLAN LABORATORY OF MOLECULAR VIROLOGY AND CARCINOGENESIS, BRI-BASIC RESEARCH PROGRAM, NCI-FREDERICK CANCER RESEARCH FACILITY, P. 0. BOX B, FREDERICK, MARYLAND 21701 Received
March
8,
1989
Capsids of equine infectious anemia virus have been isolated as coneshaped particles 60x120 nm in size. Detergent treatment of whole virus followed by two cycles of rate-zonal centrifugation in Ficoll produces these capsids in a yield of approximately 10%. The major protein components are the gag-encoded pll nucleocapsid protein and p26 capsid protein, which are present in eauimolar amounts. Substantial cleavaae of $1 to p and p4 can be observed under conditions where the viral p&ease packaged in the capsid is enzymatically active. 0 1989 Academic Press. Inc.
anemia Ew ne infectious sub-classified as a lentivirus (4-6)
to human
elongated
Cores partially
no lentivirus
core
cores
have
myeloblastosis
(14). electron
virus
microscopy
positively
identified
micrograph
(15).
isolated,
by the
visualized
with
nonionic
(AMV)
been
studied
and their
protein
spherical
of the
core
leukemia
and shown
to be similar
shell
virus
(MuLV)
most
of To date,
retrovirus
detergent. the
Those
of
extensively
AMV cores and the seen
an
bilayer
(3,12,13).
composition,
of murine
lipid
Other
by treatment
contain
by EM studies
detergent
the
related
Lentiviruses
characterized.
have
has been
seen
by
p27 was
in the
electron
and AMV were
in morphology
and
(16).
investigated
Abbreviations: immunodeficiency leukemia virus; microscopy. 0006-291x/89
chemically
that
to be genetically
surrounded
by nonionic
as a component Cores
a retrovirus (7-9).
was made between
(EM)
characterized
In this been
has been
correlation
composition
(HIV)
structure
disrupted
been prepared
Direct
virus
core
is
and found
of EIAV and HIV have been
virus
avian
(EIAV)
(l-3)
immunodeficiency
electron-dense
(l,lO,ll). whole
virus
study
the
conditions
for
the
as a means to locate
the
preparation viral
of EIAV capsids
RNA, structural
have
protein
EIAV, equine infectious anemia virus; HIV, human virus; AMV, avian myeloblastosis virus; MuLV, murine NC, nucleocapsid protein; CA, capsid protein; EM, electron
$1.50
Copyright 8 1989 by Academic Press, Inc. All rights of reproduction in any form reserved.
486
BIOCHEMICAL
Vol. 160, No. 2, 1989
components
and replication
can be well-defined core
by physical
preparation
developed
enzymes
and using
for
MuLV (17),
a homogenous
preparation.
and ~'26 (CA)
(for
the
EIAV cores.
purified
capsids.
Since
the
gag-encoded
HIV,
and both
capsids
is
the
AND BIOPHYBICAL RESEARCH COMMUNICATIONS
within
a macromolecular
and chemical
methods.
Ficoll
we have
gradient
succeeded
nomenclature
see ref.
18)
Therefore
these
extensive
sequence
homology
structural
proteins
viruses
a model
have study
for
similar
purification
that cores
the
in a 1:l
molar
pll ratio
can be appropriately
has been
demonstrated enzymes
this
AMV
EIAV capsids
proteins
and the pal-encoded morphology,
the
method
structural
exist
that
By modifying
in purifying
We determined
assembly
investigation
to (NC) in
named between of
EIAV and of EIAV
HIV. MATERIALS
AND METHODS
EIAV-producing Cf2Th cells (Wyoming strain) were grown as Virus: monolayers (19) at 37'C in Dulbecco's modified Eagle medium supplemented with 10% fetal bovine serum containing L-glutamine (4 pmoles/ml), penicillin (100 units/ml), and streptomycin (100 pg/ml) in a humidified 5% CO, atmosphere. Confluency was attained after four days. Cell debris was removed from the medium by centrifugation on a Sorvall centrifuge with an SS-34 rotor for 10 min at 12,000 x g. Whole virus was harvested from the clarified medium by pelleting through a layer of 5% Ficoll 400 (Sigma Chemical Co., St. Louis, MO) for three hours at 100,000 x g using a Beckman L3-50 ultracentrifuge with a SW27.1 rotor. Densitv uradient centrifuoation: Gradients of 40-60% w/w sucrose or 5-30X w/v Ficoll 400 in 10 I# TriseHCl, 1 mM EDTA (TE buffer pH 7.6 or pH 9) were prepared in 12 ml centrifuge tubes at room temperature then equilibrated at 4°C for 1 hour. Centrifugation of detergent treated or untreated virus was carried out on a Beckman L3-50 ultracentrifuge at 100,000 x g for five hours on Ficoll gradients (rate-zonal) and 200,000 x g for 64 hours on sucrose gradients (equilibrium density determination) using a SW41 rotor. Equal fractions of 0.5-l ml were collected by side puncture just clear of any pelleted material at the bottom of the tube. These were diluted to 12 ml with TE buffer and centrifuged at 100,000 x g for four hours on a L3-50 Beckman ultracentrifuge using a type 65 rotor. The pellets containing cores were drained, then resuspended in 0.5 ml of TE buffer to be rebanded through a second Ficoll gradient, followed by another pelleting through TE buffer. After resuspension in TE buffer, fractions from the first and second banding were ready for analysis. Sodium dodecvl sulfate oolvacrvlamide qel electroohoresis (SDS-PAGE): This was performed on 10 to 20% gradient gels by the method of Laemmli (20). Samples were boiled 15 mins in disruption buffer (2% SDS/2% P-mercaptoethanol/2D% glycerol/100 mM Tris HCl pH 6.8/20 bg of bromophenol blue per ml). Gels were stained with Coomassie brilliant blue R-250 (Bio-Rad Laboratories, Richmond, CA). Protein determination: The total protein content of viral preparations were determined by calorimetry using the Bio-Rad dye reagent (21). acid compositions of purified proteins were determined with a Durrum amino acid analyzer (ninhydrin detection) after hydrolysis in vacua HCl containing 0.1% liquid phenol for 24 hrs. Relative proportions proteins were also estimated by densitometry of stained bands after PAGE. 487
Amino D500 with 6N of SDS-
Vol. 160, No. 2, 1989
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
Determination of NC:CA ratio: Both pll (NC) and p26 (CA) were purified by reverse-phase high pressure liquid chromatography (RP-HPLC) (6) from a capsid preparation. These were loaded onto a gel in a 1:1 molar ratio. After electrophoresis, stained gel bands were scanned using a Zeineh Soft Laser scanning densitometer to determine their relative integrated intensities. These were compared to the densitometric values obtained for the same protein bands after electrophoresis of capsid preparations. Electron buffer, electron
microscopv (EM): Samples were submitted for and evaluated by conventional negative staining microscopy with 2% phosphotungstic acid (22).
EM studies in TE transmission
RESULTS The nonionic used
to prepare
that
of Sterox
(14-16). pelleted
SL,
used
from yield.
through
Ficoll
revealed
1 liter
the
(see
probe
Materials
(see
below).
This
contained
Viral
for
corresponding
to the that
through
after
the
pictures
ratio
upper
part
lc).
a 32P-labeled
(see
Fig.
in the
when
the
bar-shaped
DNA
2)
bar-shaped
gradient. cores
were
particles
of the
was
cone-
gradient
The bar-shaped
g/cm3.
collected
and the
density
of the
cone-shaped
(Fig.
The density
by equilibrium
middle
observed
of cone-to by EM.
to be 1.27
capsids
which
resulted
banding at the
there from
were shown
reveal fat
appear
90-180’,
rebanded
in further
are
of EIAV capsids
varies
the
gradient
in the
cores
experiments,
counting
shaped
second
capsid
In initial
of the
particles
were
further.
60 nm in width of the
bands
banded
of fractions
regions
capsids
then
the
RNA using
in two peak
in
of the
appeared
of viral
scattering
RNA.
sucrose
characterized
centrifugation
that
viral
in
The cone
bar-shaped
cone-shaped
was determined
centrifugation not
light the
by particle
capsids
band
mainly presence
30% sucrose,
to be -3:l
shaped
two
both
package
pelleted found
the
below
location
A broader
RNA was located
This
particles
band just
50 1.c1 of
detergent
10 min on ice
to the
to
of AMV
capsids
Illumination
blue
to correspond
similar
(w/v)
producing
for
was
5 mg of protein
A 0.5%
for
TX)
by adding
containing
medium.
optimum
scattering
Houston,
substructures virion
lb and d) and SDS-PAGE analysis
tested
suggests
viral the
and Methods).
light
gradient
(23).
culture
Co.,
has a composition
from
was incubated
band was shown
were
Oil
to prepare
as the
The mixture
gradient.
Fractions
45-12T
was removed
of tissue
by EM (Fig
of the
(Shell
to 1 ml of an EIAV suspension
a distinct This
capsids
previously
was determined
maximal
45-12T
Neodol
bilayer
45-12T
concentration
tube.
Neodol
EIAV capsids.
The lipid
10% Neodol
from
detergent
end,
in a second purification.
in Fig.
particles
le.
approximately
and 25 nm at the
to be three depending
vertices
on the 488
Negative narrow sharply
orientation
cycle
of rate-zonal
Particles stained
recovered EM
120 nm in length, end. defined of the
At the
fat
end
by an angle particle
on
Vol.
160,
No.
BIOCHEMICALAND
2, 1989
BIOPHYSICALRESEARCH
COMMUNICATIONS
Figure 1. Negative-stained electron micrographs (~150,000) of (a) intact EIAV (b) cone-shaped capsid pelleted through 30% sucrose (c) bar-shaped core from which capsids were separated, and (d) capsids obtained after first and (e) second banding through Ficoll. Some changes in surface geometry are evident after the second banding, including a cleaner background.
the with
little
the
capsids
that
grid.
microscope
variation have
show more
The capsid in
shape
a more angular
surface
detail.
preparation or dimensions. appearance There
are 489
appears After against
to the
be homogeneous, second
a cleaner
some suggestions
banding,
background of faces,
edges
Vol. 160, No. 2, 1989
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
Capsids
1
2
3
CAPSID Preparation
02
4
5
6
7
6
9
10
11
Virus
M
12
*9,adlB*
EQWO
..
Control
Figure 2. Dot-blot test for viral RNA on nitrocellulose paper with 32Plabeled complementary DNA probe (23). The fractions were taken from the first 5-3D% Ficoll gradient banding at pH 7.6, run at 1O’C for 5 hours at 100,000 x g. Capsid fraction 5 and control fraction 10 were not tested (NT). SDS-PAGE analysis of the purified capsids prepared at pH 9, ws own a ongside starting whole virus and molecular weight markers (M).
and vertices the acid
caPsid
( see Fig to be pll
analysis
*
le). and p26
of the
M
la
SDS-PAGE (see
2a
the
3).
This
Fig.
RP-HPLC purified
lb
showed proteins
B
2b
92 -
major
was confirmed (see
M
Materials
la
and Methods).
2a
2b
-
p66 p51
45 -
45 -
- p32 - p26
30 -
-
21.5 -
6-
lb
by amino
66 -
- p66 - p61
-
components
92 -
66-
14.4
protein
-
e!sm
30 0
P22
21.5
--
-
-
14.4
--ppi
ab* r,
6-
+
w Ib
-‘_ -
-
-
P32 ~26
-
P22
-
P15
z
g’
Figure 4. SDS-PAGE to illustrate the effect of proteolytic cleavage in EIAV capsids. Samples were prepared and incubated at pH 7.6 at 4'C in the absence (lanes a) and presence (lanes b) of pepstatin (0.5 mg/ml). Samples were electrophoresed before (frame A) and after (frame 8) incubation overnight at 37-C in TE buffer at pH 7.6. Lanes M, molecular weight standards; lanes 1, whole EIAV before banding (-35 Ag loaded); lanes 2, capsid band of second gradient (-25 c(g (a) and 16 Ag (b) loaded). The cleavage of pll to p6 and p4 is inhibited by the presence of pepstatin (lane 2b). 490
of
BIOCHEMICAL
Vol. 160, No. 2, 1989
Other
proteins
after
the
minor
protein
including
second
66K bands
the
banding
(see
Fig.
We have
RT assay
intact
which
have been
(manuscript
to p26 in the The
percentage approximately
capsids
of capsids were
as the
a short
time,
incubation
capsids partial
period were
known (25)
Fig.
to pll
exposed the
used
active
in the in the
densitometry the
of pll
virus
indicated This
of
RP-HPLC
to p26 in the
(Table
the
1) which
Fig.
protease
with
TABLE 1.
almost
is
was
the
cleaved arrested
Fig.
has been
It
capsids
have
(manuscript
Yield of viral coomassie-stained
Protein content ofa ~26 band (rra)
Western
definitely
also
the
protease confirmed
blotting
in preparation).
inhibitor.
proteases
The pll
of cleavage
of
Total p26 content in oreoaration (Iral
0.005
158.4
Capsids
0.86
0.060
14.3
491
a
Cleavage
0.77
p26 standards.
pll
presence
association
Whole virus
on precalibrated
with
by pepstatin,
capsids determined from densitometry p26 band from gel in Figure 3 Fraction of total loaded on se1
from
retroviral the
pH 7.6)
when the
derived
was inhibited
including
by PMSF, a serine
substrates
3).
(at
shown to be due to the
capsid.
even for
In an extended
completely
p6 is
preparation
unchanged.
was completely
at pH 9 (see that
the
remained
at room temperature,
pll
proteinases,
4) but not synthetic
to pH 7.6
to p6 occurred.
in the
of aspartic
Provided
components
of pll
cleavage
packaged
with
'Based
as
intensities
used to determine
and pH 9.
protein
The cleavage
and kept
(6)
inhibitor (see
were
4).
prepared
protease
studies
the
cleavage
not-shown).
of viral
Using
ratio
from whole
at pH 7.6
times,
at 37'C,
to p6 and p4 (see
(data
molar
normally
200 pg of viral
to be 1:3 as for
a 1:l
in TE buffer
incubation
integrated
p26 band was also
obtained
prepared
at 4°C at all
antiserum
implies of the
(24).
10%.
As soon
capsids
relative
and
known.
itself
salts
about
preparation.
the
51K,
not
enzymatically
Usually
capsid
32K,
EIAV capsids
by EM after
was determined
This
The capsids was kept
each
and Methods
intensity
yield
visualized
other
gag-p07
(RT)
or other
RT is
in preparation). from
standards.
capsids.
the
are
are
gag and/or
intact
the detergent be that
22K,
of these
of the in
removed
There
transcriptase
activity
could
3.
capsids:
of each
products
without
It
in Materials
purified
viral
but
was recovered
described pll
Mg+',
buffer.
buffer
protein
cleavage
RT endogenous
capsids,
assay
The nature
completely
in Fig.
in the
The 66K may be reverse
detected
almost
as shown
remained
3 and 4).
(6).
at pH 7.6 with in
Ficoll,
which
They may be intermediate polyproteins
p9 and p15 were
in
components
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Vol. 160, No. 2, 1989
which
occurs
in the
components remains
capsid
has not packaged
incubated
pll,
BIOCHEMICAL
been
observed
pll
in the
Capsids does
to those
prepared
sequence
is
take in
that
subviral
the
protease
at 4°C and subsequently permitting
place,
Fig.
now being
and other
implying
and pH 7.6,
not
shown
RESEARCH COMMUNICATIONS
envelope
virus,
or at 37'C
cleavage
similar
from
in whole
form.
temperature
or at pH 9 where
morphologically cleaved
when separated
in latent
at room
AND BIOPHYSICAL
cleavage
of
appeared
le.
The peptide
bond
investigated.
DISCUSSION We have established component whole is
of the
EIAV
likely
(6)
suggested
virion. is
that
that
(26).
viral
The p26 of
nucleocapsid important
enzymes.
The role
of the
noted
that
is
now under
in the
capsid cycle
RT, are
The isolated
capsids
both
CA coat
functional
to affect
the
the
is
and as
within
an
passage
of
of these
protease
step
integration
in the
that in the
of viral
the
and pepstatin
conceivable
in a critical
on
and other
function
by viral
It
investigation.
around
protease,
allows
lost
by nucleases
(RT substrates)
structure
involved
p27 is
protease,
that
it
as
layer
(RT),
in
(10,ll).
CA protein,
demonstrated the
including
(CA)
results
exterior,
to digestion
transcriptase
pll + p6 cleavage
is
replication
From our
a protective
as deoxynucleotides the
(NC) and p26
on the
as the
form
the
the
stable
on EM and immunolocalization
Apparently
of
features
we have
suggest,
a structurally
capsids.
susceptible
RNA, reverse
into
is
of pll
ratio
therefore
However,
such
inhibitor)
packaged
based
EIAV would
molecules
cycle
models
structure.
(protease life
geometrical
more
experiments
smaller
the
has been
protein,
capsid
of EIAV
recovered
RNA becomes
enzymes.
preliminary intact
in the
p26 forms
In the case of AMV it the
capsid
The equimolar
retained
by structural
banding,
the
the
protease
early
DNA into
viral phases
the
host
cell.
important from
viral
other
capsids
enzymes
viral
contaminants.
crystals
procedures
described
the
in their
can be obtained
investigate would
should
make it capsid,
example. formidable Focusing
here
which
has already
obstacle on capsid
to the
potential
of HIV envelope development
components
proteins
as targets
objective. 492
HIV capsids.
could
drug
aid
binding
HIV p24 (27), is
of a therapy
be possible
to
The preparative
to prepare the
of
of these
should
diffraction.
for
assays interference
yields it
antiviral
proposed
for
without
high
by X-ray
be adapted been
system
environment preparation,
material
could
a good
sufficiently
a purified
to locate
The variability
natural If
in of the
possible
now provide
for
currently AIDS
in achieving
This sites
on
for posing
a
(8,28,29). such
an
BIOCHEMICAL
Vol. 160, No. 2, 1989
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
ACKNOWLEDGMENTS We thank Kalmar
Sally for
Lockhart
help
in tissue
HPLC, and Robert grateful
for
Our appreciation
for
Nagashima finally
Research-sponsored
with
dot-blot
Shawver
Cancer
for
and Akos with
viral the
RNA.
the
RP-
We are
electron
typing
Institute,
Research,
Cassell
assistance for
Gonda for
to Carol
National
for
test
and Matthew
Bionetics
Beth
Ray Sowder
the
goes
by the
NO. NOl-CO-74101
assistance,
culture,
Stephens
to Kunio
technical
also
microscopy.
the
manuscript.
DHHS, under
contract
Inc.
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April 28, 1989
486-494
THE PREPARATION AND BIOCHEMICAL CHARACTERIZATION OF INTACT CAPSIDS OF EQUINE INFECTIOUS ANEMIA VIRUS MICHAEL M. ROBERTS AND STEPHEN OROSZLAN LABORATORY OF MOLECULAR VIROLOGY AND CARCINOGENESIS, BRI-BASIC RESEARCH PROGRAM, NCI-FREDERICK CANCER RESEARCH FACILITY, P. 0. BOX B, FREDERICK, MARYLAND 21701 Received
March
8,
1989
Capsids of equine infectious anemia virus have been isolated as coneshaped particles 60x120 nm in size. Detergent treatment of whole virus followed by two cycles of rate-zonal centrifugation in Ficoll produces these capsids in a yield of approximately 10%. The major protein components are the gag-encoded pll nucleocapsid protein and p26 capsid protein, which are present in eauimolar amounts. Substantial cleavaae of $1 to p and p4 can be observed under conditions where the viral p&ease packaged in the capsid is enzymatically active. 0 1989 Academic Press. Inc.
anemia Ew ne infectious sub-classified as a lentivirus (4-6)
to human
elongated
Cores partially
no lentivirus
core
cores
have
myeloblastosis
(14). electron
virus
microscopy
positively
identified
micrograph
(15).
isolated,
by the
visualized
with
nonionic
(AMV)
been
studied
and their
protein
spherical
of the
core
leukemia
and shown
to be similar
shell
virus
(MuLV)
most
of To date,
retrovirus
detergent. the
Those
of
extensively
AMV cores and the seen
an
bilayer
(3,12,13).
composition,
of murine
lipid
Other
by treatment
contain
by EM studies
detergent
the
related
Lentiviruses
characterized.
have
has been
seen
by
p27 was
in the
electron
and AMV were
in morphology
and
(16).
investigated
Abbreviations: immunodeficiency leukemia virus; microscopy. 0006-291x/89
chemically
that
to be genetically
surrounded
by nonionic
as a component Cores
a retrovirus (7-9).
was made between
(EM)
characterized
In this been
has been
correlation
composition
(HIV)
structure
disrupted
been prepared
Direct
virus
core
is
and found
of EIAV and HIV have been
virus
avian
(EIAV)
(l-3)
immunodeficiency
electron-dense
(l,lO,ll). whole
virus
study
the
conditions
for
the
as a means to locate
the
preparation viral
of EIAV capsids
RNA, structural
have
protein
EIAV, equine infectious anemia virus; HIV, human virus; AMV, avian myeloblastosis virus; MuLV, murine NC, nucleocapsid protein; CA, capsid protein; EM, electron
$1.50
Copyright 8 1989 by Academic Press, Inc. All rights of reproduction in any form reserved.
486
BIOCHEMICAL
Vol. 160, No. 2, 1989
components
and replication
can be well-defined core
by physical
preparation
developed
enzymes
and using
for
MuLV (17),
a homogenous
preparation.
and ~'26 (CA)
(for
the
EIAV cores.
purified
capsids.
Since
the
gag-encoded
HIV,
and both
capsids
is
the
AND BIOPHYBICAL RESEARCH COMMUNICATIONS
within
a macromolecular
and chemical
methods.
Ficoll
we have
gradient
succeeded
nomenclature
see ref.
18)
Therefore
these
extensive
sequence
homology
structural
proteins
viruses
a model
have study
for
similar
purification
that cores
the
in a 1:l
molar
pll ratio
can be appropriately
has been
demonstrated enzymes
this
AMV
EIAV capsids
proteins
and the pal-encoded morphology,
the
method
structural
exist
that
By modifying
in purifying
We determined
assembly
investigation
to (NC) in
named between of
EIAV and of EIAV
HIV. MATERIALS
AND METHODS
EIAV-producing Cf2Th cells (Wyoming strain) were grown as Virus: monolayers (19) at 37'C in Dulbecco's modified Eagle medium supplemented with 10% fetal bovine serum containing L-glutamine (4 pmoles/ml), penicillin (100 units/ml), and streptomycin (100 pg/ml) in a humidified 5% CO, atmosphere. Confluency was attained after four days. Cell debris was removed from the medium by centrifugation on a Sorvall centrifuge with an SS-34 rotor for 10 min at 12,000 x g. Whole virus was harvested from the clarified medium by pelleting through a layer of 5% Ficoll 400 (Sigma Chemical Co., St. Louis, MO) for three hours at 100,000 x g using a Beckman L3-50 ultracentrifuge with a SW27.1 rotor. Densitv uradient centrifuoation: Gradients of 40-60% w/w sucrose or 5-30X w/v Ficoll 400 in 10 I# TriseHCl, 1 mM EDTA (TE buffer pH 7.6 or pH 9) were prepared in 12 ml centrifuge tubes at room temperature then equilibrated at 4°C for 1 hour. Centrifugation of detergent treated or untreated virus was carried out on a Beckman L3-50 ultracentrifuge at 100,000 x g for five hours on Ficoll gradients (rate-zonal) and 200,000 x g for 64 hours on sucrose gradients (equilibrium density determination) using a SW41 rotor. Equal fractions of 0.5-l ml were collected by side puncture just clear of any pelleted material at the bottom of the tube. These were diluted to 12 ml with TE buffer and centrifuged at 100,000 x g for four hours on a L3-50 Beckman ultracentrifuge using a type 65 rotor. The pellets containing cores were drained, then resuspended in 0.5 ml of TE buffer to be rebanded through a second Ficoll gradient, followed by another pelleting through TE buffer. After resuspension in TE buffer, fractions from the first and second banding were ready for analysis. Sodium dodecvl sulfate oolvacrvlamide qel electroohoresis (SDS-PAGE): This was performed on 10 to 20% gradient gels by the method of Laemmli (20). Samples were boiled 15 mins in disruption buffer (2% SDS/2% P-mercaptoethanol/2D% glycerol/100 mM Tris HCl pH 6.8/20 bg of bromophenol blue per ml). Gels were stained with Coomassie brilliant blue R-250 (Bio-Rad Laboratories, Richmond, CA). Protein determination: The total protein content of viral preparations were determined by calorimetry using the Bio-Rad dye reagent (21). acid compositions of purified proteins were determined with a Durrum amino acid analyzer (ninhydrin detection) after hydrolysis in vacua HCl containing 0.1% liquid phenol for 24 hrs. Relative proportions proteins were also estimated by densitometry of stained bands after PAGE. 487
Amino D500 with 6N of SDS-
Vol. 160, No. 2, 1989
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
Determination of NC:CA ratio: Both pll (NC) and p26 (CA) were purified by reverse-phase high pressure liquid chromatography (RP-HPLC) (6) from a capsid preparation. These were loaded onto a gel in a 1:1 molar ratio. After electrophoresis, stained gel bands were scanned using a Zeineh Soft Laser scanning densitometer to determine their relative integrated intensities. These were compared to the densitometric values obtained for the same protein bands after electrophoresis of capsid preparations. Electron buffer, electron
microscopv (EM): Samples were submitted for and evaluated by conventional negative staining microscopy with 2% phosphotungstic acid (22).
EM studies in TE transmission
RESULTS The nonionic used
to prepare
that
of Sterox
(14-16). pelleted
SL,
used
from yield.
through
Ficoll
revealed
1 liter
the
(see
probe
Materials
(see
below).
This
contained
Viral
for
corresponding
to the that
through
after
the
pictures
ratio
upper
part
lc).
a 32P-labeled
(see
Fig.
in the
when
the
bar-shaped
DNA
2)
bar-shaped
gradient. cores
were
particles
of the
was
cone-
gradient
The bar-shaped
g/cm3.
collected
and the
density
of the
cone-shaped
(Fig.
The density
by equilibrium
middle
observed
of cone-to by EM.
to be 1.27
capsids
which
resulted
banding at the
there from
were shown
reveal fat
appear
90-180’,
rebanded
in further
are
of EIAV capsids
varies
the
gradient
in the
cores
experiments,
counting
shaped
second
capsid
In initial
of the
particles
were
further.
60 nm in width of the
bands
banded
of fractions
regions
capsids
then
the
RNA using
in two peak
in
of the
appeared
of viral
scattering
RNA.
sucrose
characterized
centrifugation
that
viral
in
The cone
bar-shaped
cone-shaped
was determined
centrifugation not
light the
by particle
capsids
band
mainly presence
30% sucrose,
to be -3:l
shaped
two
both
package
pelleted found
the
below
location
A broader
RNA was located
This
particles
band just
50 1.c1 of
detergent
10 min on ice
to the
to
of AMV
capsids
Illumination
blue
to correspond
similar
(w/v)
producing
for
was
5 mg of protein
A 0.5%
for
TX)
by adding
containing
medium.
optimum
scattering
Houston,
substructures virion
lb and d) and SDS-PAGE analysis
tested
suggests
viral the
and Methods).
light
gradient
(23).
culture
Co.,
has a composition
from
was incubated
band was shown
were
Oil
to prepare
as the
The mixture
gradient.
Fractions
45-12T
was removed
of tissue
by EM (Fig
of the
(Shell
to 1 ml of an EIAV suspension
a distinct This
capsids
previously
was determined
maximal
45-12T
Neodol
bilayer
45-12T
concentration
tube.
Neodol
EIAV capsids.
The lipid
10% Neodol
from
detergent
end,
in a second purification.
in Fig.
particles
le.
approximately
and 25 nm at the
to be three depending
vertices
on the 488
Negative narrow sharply
orientation
cycle
of rate-zonal
Particles stained
recovered EM
120 nm in length, end. defined of the
At the
fat
end
by an angle particle
on
Vol.
160,
No.
BIOCHEMICALAND
2, 1989
BIOPHYSICALRESEARCH
COMMUNICATIONS
Figure 1. Negative-stained electron micrographs (~150,000) of (a) intact EIAV (b) cone-shaped capsid pelleted through 30% sucrose (c) bar-shaped core from which capsids were separated, and (d) capsids obtained after first and (e) second banding through Ficoll. Some changes in surface geometry are evident after the second banding, including a cleaner background.
the with
little
the
capsids
that
grid.
microscope
variation have
show more
The capsid in
shape
a more angular
surface
detail.
preparation or dimensions. appearance There
are 489
appears After against
to the
be homogeneous, second
a cleaner
some suggestions
banding,
background of faces,
edges
Vol. 160, No. 2, 1989
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
Capsids
1
2
3
CAPSID Preparation
02
4
5
6
7
6
9
10
11
Virus
M
12
*9,adlB*
EQWO
..
Control
Figure 2. Dot-blot test for viral RNA on nitrocellulose paper with 32Plabeled complementary DNA probe (23). The fractions were taken from the first 5-3D% Ficoll gradient banding at pH 7.6, run at 1O’C for 5 hours at 100,000 x g. Capsid fraction 5 and control fraction 10 were not tested (NT). SDS-PAGE analysis of the purified capsids prepared at pH 9, ws own a ongside starting whole virus and molecular weight markers (M).
and vertices the acid
caPsid
( see Fig to be pll
analysis
*
le). and p26
of the
M
la
SDS-PAGE (see
2a
the
3).
This
Fig.
RP-HPLC purified
lb
showed proteins
B
2b
92 -
major
was confirmed (see
M
Materials
la
and Methods).
2a
2b
-
p66 p51
45 -
45 -
- p32 - p26
30 -
-
21.5 -
6-
lb
by amino
66 -
- p66 - p61
-
components
92 -
66-
14.4
protein
-
e!sm
30 0
P22
21.5
--
-
-
14.4
--ppi
ab* r,
6-
+
w Ib
-‘_ -
-
-
P32 ~26
-
P22
-
P15
z
g’
Figure 4. SDS-PAGE to illustrate the effect of proteolytic cleavage in EIAV capsids. Samples were prepared and incubated at pH 7.6 at 4'C in the absence (lanes a) and presence (lanes b) of pepstatin (0.5 mg/ml). Samples were electrophoresed before (frame A) and after (frame 8) incubation overnight at 37-C in TE buffer at pH 7.6. Lanes M, molecular weight standards; lanes 1, whole EIAV before banding (-35 Ag loaded); lanes 2, capsid band of second gradient (-25 c(g (a) and 16 Ag (b) loaded). The cleavage of pll to p6 and p4 is inhibited by the presence of pepstatin (lane 2b). 490
of
BIOCHEMICAL
Vol. 160, No. 2, 1989
Other
proteins
after
the
minor
protein
including
second
66K bands
the
banding
(see
Fig.
We have
RT assay
intact
which
have been
(manuscript
to p26 in the The
percentage approximately
capsids
of capsids were
as the
a short
time,
incubation
capsids partial
period were
known (25)
Fig.
to pll
exposed the
used
active
in the in the
densitometry the
of pll
virus
indicated This
of
RP-HPLC
to p26 in the
(Table
the
1) which
Fig.
protease
with
TABLE 1.
almost
is
was
the
cleaved arrested
Fig.
has been
It
capsids
have
(manuscript
Yield of viral coomassie-stained
Protein content ofa ~26 band (rra)
Western
definitely
also
the
protease confirmed
blotting
in preparation).
inhibitor.
proteases
The pll
of cleavage
of
Total p26 content in oreoaration (Iral
0.005
158.4
Capsids
0.86
0.060
14.3
491
a
Cleavage
0.77
p26 standards.
pll
presence
association
Whole virus
on precalibrated
with
by pepstatin,
capsids determined from densitometry p26 band from gel in Figure 3 Fraction of total loaded on se1
from
retroviral the
pH 7.6)
when the
derived
was inhibited
including
by PMSF, a serine
substrates
3).
(at
shown to be due to the
capsid.
even for
In an extended
completely
p6 is
preparation
unchanged.
was completely
at pH 9 (see that
the
remained
at room temperature,
pll
proteinases,
4) but not synthetic
to pH 7.6
to p6 occurred.
in the
of aspartic
Provided
components
of pll
cleavage
packaged
with
'Based
as
intensities
used to determine
and pH 9.
protein
The cleavage
and kept
(6)
inhibitor (see
were
4).
prepared
protease
studies
the
cleavage
not-shown).
of viral
Using
ratio
from whole
at pH 7.6
times,
at 37'C,
to p6 and p4 (see
(data
molar
normally
200 pg of viral
to be 1:3 as for
a 1:l
in TE buffer
incubation
integrated
p26 band was also
obtained
prepared
at 4°C at all
antiserum
implies of the
(24).
10%.
As soon
capsids
relative
and
known.
itself
salts
about
preparation.
the
51K,
not
enzymatically
Usually
capsid
32K,
EIAV capsids
by EM after
was determined
This
The capsids was kept
each
and Methods
intensity
yield
visualized
other
gag-p07
(RT)
or other
RT is
in preparation). from
standards.
capsids.
the
are
are
gag and/or
intact
the detergent be that
22K,
of these
of the in
removed
There
transcriptase
activity
could
3.
capsids:
of each
products
without
It
in Materials
purified
viral
but
was recovered
described pll
Mg+',
buffer.
buffer
protein
cleavage
RT endogenous
capsids,
assay
The nature
completely
in Fig.
in the
The 66K may be reverse
detected
almost
as shown
remained
3 and 4).
(6).
at pH 7.6 with in
Ficoll,
which
They may be intermediate polyproteins
p9 and p15 were
in
components
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Vol. 160, No. 2, 1989
which
occurs
in the
components remains
capsid
has not packaged
incubated
pll,
BIOCHEMICAL
been
observed
pll
in the
Capsids does
to those
prepared
sequence
is
take in
that
subviral
the
protease
at 4°C and subsequently permitting
place,
Fig.
now being
and other
implying
and pH 7.6,
not
shown
RESEARCH COMMUNICATIONS
envelope
virus,
or at 37'C
cleavage
similar
from
in whole
form.
temperature
or at pH 9 where
morphologically cleaved
when separated
in latent
at room
AND BIOPHYSICAL
cleavage
of
appeared
le.
The peptide
bond
investigated.
DISCUSSION We have established component whole is
of the
EIAV
likely
(6)
suggested
virion. is
that
that
(26).
viral
The p26 of
nucleocapsid important
enzymes.
The role
of the
noted
that
is
now under
in the
capsid cycle
RT, are
The isolated
capsids
both
CA coat
functional
to affect
the
the
is
and as
within
an
passage
of
of these
protease
step
integration
in the
that in the
of viral
the
and pepstatin
conceivable
in a critical
on
and other
function
by viral
It
investigation.
around
protease,
allows
lost
by nucleases
(RT substrates)
structure
involved
p27 is
protease,
that
it
as
layer
(RT),
in
(10,ll).
CA protein,
demonstrated the
including
(CA)
results
exterior,
to digestion
transcriptase
pll + p6 cleavage
is
replication
From our
a protective
as deoxynucleotides the
(NC) and p26
on the
as the
form
the
the
stable
on EM and immunolocalization
Apparently
of
features
we have
suggest,
a structurally
capsids.
susceptible
RNA, reverse
into
is
of pll
ratio
therefore
However,
such
inhibitor)
packaged
based
EIAV would
molecules
cycle
models
structure.
(protease life
geometrical
more
experiments
smaller
the
has been
protein,
capsid
of EIAV
recovered
RNA becomes
enzymes.
preliminary intact
in the
p26 forms
In the case of AMV it the
capsid
The equimolar
retained
by structural
banding,
the
the
protease
early
DNA into
viral phases
the
host
cell.
important from
viral
other
capsids
enzymes
viral
contaminants.
crystals
procedures
described
the
in their
can be obtained
investigate would
should
make it capsid,
example. formidable Focusing
here
which
has already
obstacle on capsid
to the
potential
of HIV envelope development
components
proteins
as targets
objective. 492
HIV capsids.
could
drug
aid
binding
HIV p24 (27), is
of a therapy
be possible
to
The preparative
to prepare the
of
of these
should
diffraction.
for
assays interference
yields it
antiviral
proposed
for
without
high
by X-ray
be adapted been
system
environment preparation,
material
could
a good
sufficiently
a purified
to locate
The variability
natural If
in of the
possible
now provide
for
currently AIDS
in achieving
This sites
on
for posing
a
(8,28,29). such
an
BIOCHEMICAL
Vol. 160, No. 2, 1989
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
ACKNOWLEDGMENTS We thank Kalmar
Sally for
Lockhart
help
in tissue
HPLC, and Robert grateful
for
Our appreciation
for
Nagashima finally
Research-sponsored
with
dot-blot
Shawver
Cancer
for
and Akos with
viral the
RNA.
the
RP-
We are
electron
typing
Institute,
Research,
Cassell
assistance for
Gonda for
to Carol
National
for
test
and Matthew
Bionetics
Beth
Ray Sowder
the
goes
by the
NO. NOl-CO-74101
assistance,
culture,
Stephens
to Kunio
technical
also
microscopy.
the
manuscript.
DHHS, under
contract
Inc.
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494