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Journal of Virology, January 2001, p. 759-771, Vol. 75, No. 2
0022-538X/01/$04.00+0 DOI: 10.1128/JVI.75.2.759-771.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
Organization of Immature Human Immunodeficiency Virus Type
1
Thomas
Wilk,1,2
Ingolf
Gross,3
Brent E.
Gowen,1,2
Twan
Rutten,1
Felix
de
Haas,1
Reinhold
Welker,3
Hans-Georg
Kräusslich,3,4
Pierre
Boulanger,5 and
Stephen D.
Fuller1,2,*
The Structural Biology Programme, European Molecular
Biology Laboratory, D69012 Heidelberg,1
Heinrich-Pette-Institut, Stiftung des Privaten Rechts, D-20251
Hamburg,3 and Abteilung Virologie,
Universität Heidelberg, 69120 Heidelberg,4
Federal Republic of Germany; Division of Structural
Biology, The Wellcome Trust Centre for Human Genetics, Headington,
Oxford OX3 7BN, England2; and
Laboratoire de Virologie et Pathogenése Virale, CNRS UMR
5537, Faculté de Médecine RTH Laennec, Lyon 693732 Cedex 08, France5
Received 23 May 2000/Accepted 4 October 2000
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ABSTRACT |
Immature retrovirus particles contain radially arranged Gag
polyproteins in which the N termini lie at the membrane and the C
termini extend toward the particle's center. We related image features
to the polyprotein domain structure by combining mutagenesis with
cryoelectron microscopy and image analysis. The matrix (MA) domain
appears as a thin layer tightly associated with the inner face of the
viral membrane, separated from the capsid (CA) layer by a low-density
region corresponding to its C terminus. Deletion of the entire p6
domain has no effect on the width or spacing of the density layers,
suggesting that p6 is not ordered in immature human immunodeficiency
virus type 1 (HIV-1). In vitro assembly of a recombinant Gag
polyprotein containing only capsid (CA) and nucleocapsid (NC) domains
results in the formation of nonenveloped spherical particles which
display two layers with density matching that of the CA-NC portion of
immature HIV-1 Gag particles. Authentic, immature HIV-1 displays
additional surface features and an increased density between the lipid
bilayers which reflect the presence of gp41. The other internal
features match those of virus-like particles.
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INTRODUCTION |
The genome of the human
immunodeficiency virus (HIV) contains three open reading frames common
to all retroviruses (28, 45): gag
the
group-specific antigen frame which encodes the precursor (Gag) of the
major structural proteins of the virus interior (matrix [MA], capsid
[CA], nucleocapsid [NC] domains and protein p6 in HIV),
polwhich encodes the enzymatic activities of the virus
(protease, reverse transcriptase, RNase H, and the integrase), and the
env framewhich encodes the precursor (gp160) of the viral
envelope proteins (gp41 [TM] and gp120 [SU]). HIV is a
complex retrovirus (5) and hence encodes a further six regulatory proteins which enhance and control the replication of the
virus (6, 7). The pol open reading frame
overlaps that of gag and is expressed via a frame-shifting
event that produces a Gag-Pol protein (45).
Virus assembly begins at the cell surface with the clustering of
roughly 2,000 Gag proteins, 200 Gag-Pol proteins, and the two strands
of genomic RNA. Gag and Gag-Pol proteins are bound to the inner surface
of the membrane by covalently linked myristate at their N termini and a
charged surface region. The budding particle includes envelope protein
complexes (TM-SU) if they are present. After budding, the protease
cleaves the Gag and Gag-Pol proteins to produce the proteins of the
mature, infectious virion (43). This maturation process
changes the arrangement of the structural components inside the virion:
the radially arranged Gag molecules are dismantled, and a conical core
structure is assembled in the center of the particle (45).
Mutagenesis and expression studies have shown the remarkable robustness
of particle assembly. Expression of the Gag protein alone in mammalian
and insect cells leads to budding of virus-like particles (VLPs) or Gag
particles which are very similar in morphology to immature HIV
(9, 20, 39-41). Mutated Gag proteins from which large
regions have been deleted remain capable of directing budding (e.g.,
see reference 11).
Early work on HIV and other retroviruses was based on the assumption of
icosahedral symmetry for the interpretation of images (17-19,
23, 26, 31, 32, 34). Indeed, surface views and glancing sections
were interpreted as consistent with a triangulation number
(T = 7 laevo) for HIV (18). Recent work
using cryoelectron microscopy (cEM) has demonstrated that the
retrovirus particle is neither icosahedral nor consistent in size and
shape (13, 47, 48, 51). This absence of regularity
cripples the traditional methods of structural analysis which have been
so successful in more regular systems (3). Components
display local order but are assembled in various ways to produce the
plethora of sizes and shapes which characterizes the assembled particle
(13). Approaching retrovirus structure requires setting
aside the familiar tools of structural analysis and focusing on the
characterization of the regular elements of the structure within the
variation that is the hallmark of the complete particle. The result of
such an analysis will be parameters of the local organization that can
be combined with other information, such as that provided by X-ray
crystallography, to generate testable models of the interactions which
drive particle formation. It will not produce a single, unique
three-dimensional structure for the virion, since a single structure
cannot represent the array of structures observed in preparations.
While this approach is more difficult (47) and may be
unsatisfactory to some (33), it is the only one that accurately reflects observations.
The simplest level of organization in the retrovirus particle is a
radial one. The Gag protein in the immature particle appears to be
arranged with its amino terminus (MA domain) at the viral envelope and
the carboxy terminus (NC domain) within the center of the particle
where it interacts with the genomic RNA. This organization is seen in
the VLPs which bud from insect cells upon expression of the Gag
protein. A well-established radial organization can serve as a
framework for addressing specific questions. For example, we were able
to use fine immunocytochemical mapping to demonstrate that actin
interacts specifically with the NC domain of the immature HIV particle
(48) rather than the MA domain (35) as
suggested by occasional images. This paper describes the use of cEM in
combination with profile analysis and mutagenesis to explore the radial
organization of immature HIV-1. The mutagenesis and cEM approaches
complement each other. cEM provides a faithful representation of the
density in the particle when corrected for the imaging effects of
defocus phase contrast. Fortunately, the phase-contrast transfer
function (CTF) is well understood (10), and its correction
has become routine (8, 29, 30) so that quantitative
evaluation of the particle density is possible. Mutagenesis is a
particularly powerful tool of analysis for the HIV system because such
a large array of mutants have been characterized and assembly of VLPs
is surprisingly tolerant to significant modifications of the Gag protein.
Here we probe the radial organization of the immature particle by
examining VLPs formed by deleted versions of Gag, particles assembled
in vitro without membranes, and the authentic immature HIV particle.
Our results resolve the MA domain underneath the membrane, provide
evidence for the TM density within the bilayer, and demonstrate that p6
is arranged irregularly in the Gag particle and the virion.
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MATERIALS AND METHODS |
Preparation of Gag particles.
Gag particles were produced by
expression of HIV-1 Gag (pNL4-3) (2) with the recombinant
baculoviruses AcNPVgag12myr (for expression of wild-type Gag, see
reference 39), AcNPVgag13myr (for HIV-1 Gag
p6
expression, see Gagamb438 in reference 4), and
AcNPVgag dl41-143myr (for HIV-1 GagMA expression, see reference 16) in BTI-TN-5B1-4 cells (known as High 5 cells).
Immature HIV-1 particles (pNL4-3) (2) were produced from
infected MT-4 cells treated with an inhibitor of the viral protease
(0.05 µg/ml) (48). VLPs and immature HIV-1 were purified
(49) and prepared for cEM (13) as described previously.
In vitro assembly.
Recombinant HIV-1GagMAp6 protein
was purified from Escherichia coli (24) and
stored in 500 mM NaCl and 50 mM Tris (pH 8.0) at a final concentration
of 1 mg/ml. The assembly reaction was initiated by the addition of 15 µM 73-mer DNA oligonucleotide, and it was performed with a dialysis
bag dialyzing for 60 min at 4°C against 100 mM NaCl and 50 mM Tris
(pH 8.0). Assembled particles were collected by centrifugation for 10 min at 4°C in an Eppendorf centrifuge and were resuspended in 100 mM
NaCl and 50 mM Tris (pH 8.0).
Microscopy and image analysis.
cEM was performed as
described previously using a Philips CM200FEG electron microscope
operated at 200 kV (13). The radial density distribution
in the virus particles was calculated by using the Fourier-Bessel
expansion method that was described previously (13). The
profiles from individual particles were averaged by aligning the
density corresponding to the two leaflets of the membrane of the
bilayer. Profiles of HIV-1 GagMA were aligned using the position of
the two peaks corresponding to the CA protein layer, and the radial
density profiles were derived from measurements of well-ordered areas.
The program for performing the radial density measurements
(13) is written in FORTRAN using standard subroutines (37) and is available upon request. Each averaged profile
combines up to 3,600 (360° × 10 samples) measurements. The defocus
was determined from the positions of the local minima in a radially averaged power spectrum of the individual particles. Contrast transfer
function (CTF) correction was performed by division of the transform of
the image with the appropriate CTF as described previously
(8). The radial density distribution of CTF-corrected images is an average of 50 measurements at different positions of the
particle. The individual profiles were aligned by placing the paired
leaflets of the lipid bilayers into coincidence.
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RESULTS |
Wild-type HIV-1 Gag particles visualized by cEM.
We have
previously proposed a model for the arrangement of Gag polyproteins in
immature HIV-1 particles (13). Here we provide experimental evidence for the proposed arrangement and present further
details of the structural organization of immature HIV particles.
Wild-type VLPs were expressed in H5 cells after infection with
recombinant baculovirus. Particles in the cell culture supernatants were harvested 20 to 24 h after infection, concentrated by
centrifugation through a cushion of sucrose, and gently resuspended in
buffer. Analysis of stained sodium dodecyl sulfate-polyacrylamide gels and Western blots showed that the Gag protein was the single most abundant protein in the preparation (data not shown). cEM demonstrated that a large number of particles had been released from
baculovirus-infected cells (data not shown). The most abundant
particles found in the cell culture supernatant were the spherical
HIV-1 Gag particles. The Gag particles' size and shape were very
heterogeneous as reported previously (13, 16), ranging in
diameter from 120 to 250 nm (Fig.
1E) and often showing a
distorted profile rather than a spherical one. The Gag particles were
easily distinguished from the elongated baculovirus particles that
remained intact under our gentle conditions of purification.
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FIG. 1.
Wild-type HIV-1 Gag and Gag deletion mutants. Constructs
A through C were expressed in H5 cells by infection with recombinant
baculovirus. Construct D was expressed in E. coli and
assembled in vitro in the presence of oligonucleotides. (E) The
histograms show the effect of the deletions on the particle size. The
x axis indicates the particle diameter in nanometers, and
the y axis indicates the frequency of occurrence in the
population as a percentage.
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Observation of individual Gag particles at high magnification revealed
further details (Fig.
2A). No consistent
external features
were seen on the surface of the viral membrane,
reflecting the
absence of viral glycoproteins. A regular, azimuthal
variation
of contrast was visible between the two leaflets of the
membrane,
matching the periodic density variation of the underlying
protein
layer. The bulk of the internal density was separated from the
membrane by a 40-Å-wide, low-density space. Thin tethers run through
this region below the membrane and connect the internal structural
proteins with the inner leaflet of the membrane (Fig.
2A). The
spacing
between neighboring connections was 33 ± 5 Å (
n = 75)
and did not vary between particles. The internal density was
subdivided
into two major densities separated by a 15-Å-wide
low-density
region (Fig.
2A). The outer domain typically displayed a
rod-like
shape. This appearance was not maintained throughout the
entire
circumference of the particle. In some regions, the straight tip
of the rod appeared more globular and the distance and angle between
neighboring rods increased accordingly. This variation in appearance
could reflect conformational variation between regions. The inner
Gag
domains always appeared to be tightly packed.
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FIG. 2.
Wild-type HIV-1 Gag particles in cEM. (A) cEM of
wild-type Gag particles shows thin tethers (arrows, left panel)
spanning the low density submembrane space. The density at the lower
radius is subdivided into two major bands (arrows, right panel).
Arrowheads mark the CA rods. Areas of white correspond to higher
density and hence mass in all of the images presented. Scale bar, 50 nm. (B) The average of 10 radial density distributions of wild-type
HIV-1 Gag particles aligned to the position of the membrane reflects
the presence of radially arranged Gag domains. The inset shows the
assignment of individual peaks of density to the domains of the HIV-1
Gag polyprotein. The plot shows density (y axis) as a
function of distance from the particle center in angstroms
(x axis). (C) CTF-corrected images of two typical regions of
a VLP membrane and the corresponding average radial density
distribution from 50 regions of the membranes of five Gag particles.
The internal density is masked (gray area) in this image. The
interpretation of the CTF-corrected density of the particle (left) is
shown by the arrows matching its features with the corresponding radial
density profile and a schematic of the arrangement of the proteins. The
peaks corresponding to the MA domain and the inner leaflet of the
membrane were not resolved in the uncorrected image (B) and are
represented by a single, broad peak of density in the same radial
position (C).
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We employed image processing to analyze the radial organization of the
particles in greater detail. cEM images of particles
were digitized,
and their radial density distribution was calculated
(Fig.
2B). Simple
averaging of the projected radial density of
particles of different
diameters would result in a blurring of
features. A Fourier-Bessel
method (
13) was used to overcome
this problem by averaging
the three-dimensional radial density
distributions from different radii
of the particles after aligning
them on the position of the membrane.
The average particle profile
is shown in Fig.
2B. The result confirms
our previously reported
observation of separately folded domains in a
radially arranged
Gag polyprotein. The viral membrane itself shows up
as two closely
juxtaposed density peaks separated by a distance of
~50 Å. The
density peak at the inner leaflet of the membrane is
broader than
that of the outer, reflecting the presence of additional
mass,
presumably contributed by the MA domain of the Gag polyprotein.
The remainder of the Gag polyprotein is located further inside
and is
separated from the viral membrane by a ~40 Å-wide (70-Å
peak-to-peak distance) region of low density. The adjacent density
is
formed by the broad protein layer, composed of rod-like subunits
(see
Fig.
2A). The profile reveals two peaks of density in this
position.
These paired peaks are characteristic of the CA protein,
which contains
two subdomains. The peaks are separated by 39 ±
4 Å (
n = 10) and contribute to a CA-derived protein layer
of 85
± 6 Å (
n = 10) width. Another density peak
at a lower radial position
indicates the location of the innermost
protein layer, presumably
created by the NC and p6 domains and the p6
domain. This most-intense
density peak is separated from the
neighboring density by a distance
of 66 ± 4 Å (
n = 10, peak-to-peak spacing), leaving a gap of 15
Å.
cEM revealed thin tethers crossing from the inner face of the particle
membrane to the internal layers of density. This suggested
that a
portion of the viral polyprotein was anchored to the lipid
bilayer of
the particle; however, the nature of the arrangement
near the membrane
was not apparent from the original, uncorrected
images. The contrast in
a cEM image arises primarily from defocus
phase contrast. This contrast
allows the visualization of features
in images of unstained material;
however, it does so by distorting
the relative densities of features in
the particle. A complete
interpretation of the density in the particle
requires that the
defocus and hence the CTF (
10) be
determined so that the densities
can be corrected computationally
(
8). Naturally, this correction
cannot restore the
information at the nodes of the CTF, and so
multiple defocuses must be
examined to avoid
misinterpretation.
Figure
2C shows a characteristic view of the wild-type VLP membrane
after CTF correction of the image and the radial density
distribution
across the membrane. The presence of three individual
layers of density
is now clearly discernible. We assigned the
two external layers to the
outer and inner leaflets of the particle
membrane and speculated that
the submembrane density may be contributed
by the globular portion of
the MA domain of Gag. Careful examination
of a large number of images
showed that the same arrangement was
retained over most of the VLP
membrane. It was noted that a thin
space of low density is present
between the individual layers
of density. Hence, the measurement of the
corrected radial density
distribution reveals three separate peaks of
density in the position
of the membrane (Fig.
2C). The peaks of the
bilayer leaflets were
~26 Å apart. The inner density layer is ~22
Å below the peak of
the inner
leaflet.
A deletion in the MA domain affects the VLP membrane and the
submembrane space.
We assigned the density immediately apposed to
the inner surface of the membrane to the MA domain and assigned the
peaks at lower radius to CA and the NC-p6 domain. Previously we
suggested that this 40-Å-wide region of low density below the membrane
represents the C-terminal residues of MA (47, 48). We
tested this hypothesis by expressing the deletion mutant HIV-1GagMA,
which lacks the carboxy-terminal two-thirds of the MA domain and the 11 amino-terminal residues of CA. We chose this construct because it is
known to lead to efficient particle release (16). Many
other constructs affect particle release or stability or result in
redirecting budding to inappropriate domains (11).
Infection of H5 cells with the corresponding recombinant baculovirus
resulted in efficient release of HIV-1 Gag
MA particles
into the cell
culture supernatant. Particles were harvested 20
to 24 h after
infection, concentrated by centrifugation through
a cushion of sucrose,
and gently resuspended in buffer. The HIV-1
Gag
MA particles migrated
to a density of 1.166 g/cm
3 on a sucrose density gradient,
similar to the density of authentic
retrovirus particles. Analysis of
stained sodium dodecyl sulfate-polyacrylamide
gels and Western blots
showed that the Gag polyprotein was the
single most abundant protein in
the preparation (data not shown).
Examination of the pelleted material
by cEM revealed the presence
of enveloped VLPs in the cell culture
supernatant. Many of the
VLPs were disrupted, indicating that the
deletion in MA reduced
particle stability (data not shown). In
contrast, most baculovirus
particles remained intact and undistorted by
the preparation for
cEM. Wild-type Gag particles and HIV-1Gag
MA
particle diameters
were measured and plotted in a histogram (Fig.
1E).
The diameters
of wild-type and mutant VLPs ranged from ~100 nm to
more than
250 nm (Fig.
1E), with an average particle diameter of
169 ± 29
nm (wild-type HIV-1 Gag,
n = 97) and
170 ± 33 nm (HIV-1Gag
MA,
n = 107),
respectively. HIV-1Gag
MA particles showed a size heterogeneity
similar to that of wild-type Gag particles. Sixty-six percent
of
wild-type HIV-1 Gag VLPs and 72% of HIV-1Gag
MA VLPs deviated
from
the average diameter by more than 10 nm (Fig.
1E).
The HIV-1Gag
MA particles displayed an uneven mass distribution (Fig.
3A) in which the bulk of the mutant Gag
polyproteins
were found in one hemisphere of the particle. This
hemisphere
contained regular arrays of Gag polyproteins, similar to
those
observed in wild-type particles (Fig.
3A). Particles always
showed
areas of unstructured density with an apparent size which
depended
on the orientation of the particle in the water layer. Careful
examination of structured areas within mutant VLPs demonstrated
that
the lipid bilayer and the space below were clearly affected
by the
deletion in the MA domain. The regular internal-density
variation
detected between the two leaflets of wild-type membranes
was not
observed in HIV-1Gag
MA particles; instead, the membranes
were smooth
and featureless. The inner leaflet of the HIV-1Gag
MA
VLPs also
appeared thinner than that of the wild type, probably
reflecting the
removal of the MA domain from the inner face of
the lipid bilayer.
Further, the 40-Å gap beneath the wild-type
VLP membrane was much
narrower in the HIV-1Gag
MA mutant so that
the internal density
was brought closer to the lipid bilayer.
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FIG. 3.
HIV-1 GagMA particles visualized by cEM. (A) A cEM of
an HIV Gag particle with a deletion of residues 41 to 143. The deletion
of MA sequences results in the thinning of the submembrane space and a
reduced inner leaflet thickness and affects the regular variation in
density within the membrane. Frequently the internal organization is
disrupted, and the regular array of Gag molecules is only preserved in
limited regions of the circumference. The arc within the membrane
(right) shows the presence of a vacant region of the particle. The
arrowheads (left) mark CA-derived rods of Gag density while the arrows
(right) mark radial CA and NC density. Size bar, 50 nm. (B) The radial
density distribution of HIV-1 GagMA demonstrates the effect of the
matrix deletion. The mutation results in an approximation of regular
internal density and the particle membrane. The superimposition with
the profile of wild-type Gag particles illustrates the effect of the
deletion. The plot shows density (y axis) as a function of
distance from the particle center in angstroms (x axis). (C)
CTF-corrected image of the membrane region of an HIV-1 GagMA
particle and the corresponding region of the average of the
radial density distribution from 50 particles with the central
region (gray) masked.
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These changes in the membrane region and the region beneath the
membrane were also reflected in the radial density profiles
of
HIV-1Gag
MA particles (Fig.
3B). Measurements were taken from
clearly
structured portions of the particle, since inclusion of
unstructured
regions blurred the average profile. The deletion
had no significant
effect on the general structural features of
the internal protein
layers in HIV-1Gag
MA particles so that individual
profiles could
be aligned. The comparison of wild-type and HIV-1Gag
MA
radial
density profiles revealed the dramatic effect of the deletion
on the
membrane-associated regions. A gap of ~15 Å (rather than
the 40 Å seen in wild-type VLPs) separates the inner leaflet from
the first
internal protein layer. This spacing varied somewhat
between individual
HIV-1Gag
MA particles, suggesting that an intact
matrix protein fixes
the position of the Gag polyprotein more
precisely relative to the
inner face of the viral
membrane.
The analysis of the wild-type VLP membrane had shown that CTF
correction of the images revealed a layer beneath the membrane
(Fig.
2C). We hypothesized that this density was created by the
globular head
of the MA protein and should therefore be affected
by the deletion in
HIV-1Gag
MA particles. This hypothesis was
confirmed by the
CTF-corrected images of the mutant VLP membrane,
which contained two,
rather than three, density layers (Fig.
3C).
The remaining radial
density peaks in the profile superimpose
well. The outer and inner
leaflets of the bilayer retain the same
spacing of ~26 Å as in the
wild-type VLP membrane (Fig.
3C).
Deletion of the p6 domain has no apparent effect on VLP
structure.
Images and radial density measurements of wild-type
particles displayed two prominent internal layers in wild-type VLPs. We assigned the innermost layer to the NC and p6 domains; however, the relative contributions of the NC and p6 domain to the density were unclear. We expressed the Gag deletion mutant HIV-1Gagp6 that
lacks the entire p6 domain (Fig. 1) to address this question. Infection
of H5 cells with the recombinant baculovirus resulted in the efficient
release of mutant Gag particles into the cell culture supernatant as
revealed by Western blot and cEM analysis of particle preparations
(data not shown). The mutant VLPs were clearly less heterogeneous than
wild-type particles, having a much narrower distribution of particle
diameters (Fig. 1E). Only 25% of HIV-1Gagp6 particles deviated by
more than 10 nm from their average value (140 ± 23 nm;
n = 111), whereas more than 66% of wild-type Gag
particles fell outside this range. The better-defined particle diameter
may indicate a better control of size during assembly of HIV-1Gagp6
polyproteins. Most HIV-1 Gagp6 particles appeared truly spherical
(Fig. 4). Fewer of the mutant particles were distorted or disrupted than in wild-type VLPs.
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FIG. 4.
HIV-1 Gagp6 particles in cEM. (A) cEM of HIV-1
Gagp6 particles shows no effect of the p6 deletion on the internal
layers of density. Mutant particles display the same details as
wild-type Gag particles. The arrows (left) mark the tethers. The arrows
(right) indicate a region of typical rod density for comparison with a
region of altered rod density marked by arrowheads. Bar, 50 nm. (B)
Radial density distribution of HIV Gagp6 particles. The
superimposition with the radial density distribution of wild-type VLPs
demonstrates that the C-terminal p6 domain does not contribute to the
averaged innermost density of the Gag protein layer. The plot shows
density (y axis) as a function of distance from the particle
center in angstroms (x axis). Positive and negative density
values correspond to areas of black/white in panel A, respectively.
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The structural details in HIV-1 Gag
p6 particles match those of
wild-type VLPs (Fig.
4A). A regular variation of density was
noticed
between the two leaflets of the membrane that matched
the periodic
density variation of the underlying protein layer
seen in the wild
type. The deletion of the C-terminal p6 domain
had no apparent effect
on the overall organization of the mutant
particles, nor did it alter
the spacing of protein layers inside
the particle. Thin connections
were visible crossing the space
below the membrane and establishing
linkages between the inner
leaflet of the membrane and the CA-derived
protein layer further
inside (Fig.
4A, left). Neighboring connections
were separated
by 33 ± 5 Å (
n = 54), which
exactly matches the spacing seen in
wild-type VLPs (33 ± 5 Å,
n = 75).
Intriguingly, the similarity of the wild-type and mutant particles
extended to the innermost density layer, which we originally
ascribed
to the NC-p6 domain. This indicates that the p6 domain
of the Gag
polyprotein does not contribute ordered density to
the wild-type Gag
particle. This observation is confirmed by the
comparison of the
average radial density profiles of wild-type
and HIV-1 Gag
p6
particles. Figure
4B demonstrates that the deletion
of the entire p6
domain had no significant effect on the organization
of internal
layers, the spacing between protein layers, or the
width of the Gag
domains in the Gag particles. The fact that the
innermost portion of
the average density layer was not altered
demonstrates that it only
reflects contributions from the NC domain
of the Gag
polyprotein.
Organization of immature HIV-1 particles in the absence of a
membrane.
We examined particles assembled in vitro from
recombinant Gag polyproteins and nucleic acids to determine the
role of the membrane in organizing the internal Gag domains. We have
recently demonstrated that HIV-1 GagMAp6 protein (Fig. 1)
forms spherical particles under in vitro assembly conditions
(24). The in vitro-assembled particles were concentrated
by brief centrifugation and studied by cEM. A large number of spherical
particles were present in the sample, reflecting efficient assembly of
recombinant Gag polyprotein. The resultant particles are shown in
Fig. 5 and display a well-defined diameter of 111.7 ± 7.3 nm (n = 67). Although
nonenveloped, the in vitro-assembled particles shared features with the
enveloped immature particles produced by the expression of Gag
polyproteins in insect cells (Fig. 2A). In particular, in
vitro-assembled particles displayed two layers that were similar to the
two internal layers of Gag particles that we had attributed to CA and
NC. The outer layer was formed by rod-like subunits indistinguishable
in size and shape from the CA rods of wild-type VLPs. This layer was
separated from an internal layer by a 15-Å-thin low-density gap
corresponding to that between the CA and NC protein layers in the VLPs.
The average radial density profile for the in vitro-assembled
particles (Fig. 5B) matches that of the HIV-1 Gag wt particles with the exception of the outer layers, which represent the membrane; the protein layers are arranged in a very similar manner.
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FIG. 5.
cEM of in vitro-assembled HIV GagMAp6. (A) cEM of
in vitro-assembled particles. Recombinant Gag polyprotein lacking the
entire p6 domain and most of the MA domain (including the N-terminal
myristic acid) can be assembled into spherical particles. The two major
layers of density are marked by arrows (right). Note the rod-like shape
of the outer protein layer (left, arrowheads), reminiscent of the CA
protein layer in Gag particles. A second protein layer is located
further inside and is similar in appearance to the innermost protein
layer of Gag particles released from cells. Bar, 50 nm. (B) Radial
density profile of HIV-1 GagMAp6 particles. The two main peaks of
density corresponding to the CA and NC protein layers can easily be
aligned with the radial density profiles of enveloped HIV-1 Gag
particles. The plot shows density (y axis) as a function of
distance from the particle center in angstroms (x axis).
|
|
Immature HIV-1 particles: are VLPs like the virus?
The results
obtained with the wild-type and mutant Gag VLPs lead to a better
understanding of the multilayered immature state of HIV-1, allowing the
assignment of Gag domains to the protein layers. Several lines of
evidence suggest that the VLPs produced in insect cells are a good
model for the study of immature HIV-1. Nevertheless, the HIV-1 Gag
particle lacks several potentially important structural components,
including the Gag-Pol precursor, the virus glycoproteins, and the
authentic viral RNA. Their presence might modify the arrangement of the
Gag polyprotein and result in a changed organization of the immature virion.
We explored the role of additional virus proteins on the organization
of immature HIV-1 by analyzing virions harvested from
infected T cells
after treatment of cells with an inhibitor of
the viral protease (Fig.
6A). The majority of the
particles had
the radial arrangement typical of immature virions. Less
than
1% of particles showed the internal cone produced by the
maturation
cleavage.
View larger version (439K):
[in this window]
[in a new window]
|
FIG. 6.
cEM of immature HIV-1. (A) Overview of immature HIV-1
released from infected T cells. The image shows a typical
low-magnification view of particles that have been released from T
cells after treatment of the cells with an inhibitor of the viral
protease (bar = 100 nm). Note the presence of spikes on the
surface of the particles and the heterogeneity of diameters within the
population. The asterisk marks a rare particle in the preparation
(<1%) which shows a mature phenotype. (B) The details of the
structure of the immature HIV-1 particle are seen in the views of
individual particles. The two major layers of density are marked by
arrows (upper right). Note the rod-like shape of the outer protein
layer (arrowheads, lower left), reminiscent of the CA protein layer in
Gag particles (bar = 100 nm). Small arrows mark the tethers in the
upper-right panel and the glycoproteins in the lower-right panel. (C)
The comparison of the radial density profiles of the immature virion
and the wild-type VLP shows that the internal features are conserved.
The plot shows density (y axis) as a function of distance
from the particle center in angstroms (x axis). The two
particles differ in the depth of the features in the membrane region
and the presence of a weak average external density corresponding to
that of the envelope proteins. (D) The CTF-corrected image of a portion
of an immature particle reveals the extra density in the membrane
region. The correspondence between the CTF-corrected image and the
average radial density profile from 50 particles is indicated by the
arrows matching their corresponding features with a schematic of the
arrangement of the proteins. The internal density is masked (grey
region).
|
|
The immature virions were clearly not uniform in diameter; however,
they appeared significantly less heterogeneous than wild-type
VLPs. The
size distribution of authentic immature virions peaked
around their
average diameter (133 ± 17 nm;
n = 118), with
less
than 30% of the particles deviating by more than 10 nm from this
value (Fig.
1E).
cEM of authentic immature HIV at high magnification revealed an overall
organization reminiscent of that of the VLPs (Fig.
6B). In particular,
internal radial arrangements in the immature
virion and in the VLP were
very similar. The internal protein
layers were separated from the
membrane by a prominent gap, as
in the VLPs. Similar thin tethers were
observed crossing the gap
and connecting the internal densities to the
virus membrane (Fig.
6B). One clear difference between immature virions
and the VLP
structure was seen at the position of the virus membrane,
which
contained regularly spaced viral spike proteins (Fig.
6). These
protruded ~120 Å from the center of the membrane and were visible
on
all of the particles in the preparation, forming an additional
layer of
density on the outside of the immature virion (Fig.
6A
and
B).
The radial density measurement of immature HIV-1 particles confirmed
the visual impression of the internal organization of
the virion (Fig.
6C). It shows a radial density distribution which
superimposes well
with that of the wild-type VLPs, thereby demonstrating
that the layers
of density observed in the authentic immature
virion are exclusively
created by the Gag polyprotein. The virus
glycoproteins which are
easily discernible in the images (Fig.
6A and B) show up only weakly in
the radial density profile because
they are a less consistent feature
than the radially arranged
internal structural
proteins.
We corrected the images for the effect of the CTF (Fig.
6D) to obtain a
more accurate view of the membrane organization. CTF-corrected
images
show that the membrane of authentic immature HIV-1 is composed
of three
layers of density. Careful examination of a large number
of images
revealed several interesting features. The leaflets
of the bilayer
retained the same spacing as in the VLPs: however,
the separation of
layers was less obvious because the space between
them appeared filled.
Frequently, density appeared to connect
the MA-derived layer with the
lipid bilayer and the inner to the
outer leaflet of the membrane (Fig.
6D). This contrasts with the
VLP images, which showed the membrane
layers of Gag particles
clearly
separated.
We cannot completely interpret the more complex organization of the
membrane of the immature virion, however; the virus glycoprotein
adds a
considerable amount of mass to the virus membrane and could
easily
account for the observed features. On the outside of the
particles,
regularly spaced protrusions were observed, reflecting
the presence of
the surface portion of the HIV-1 glycoprotein.
Measurements show that
the glycoprotein protrudes ~120 Å from
the center of the membrane.
The radial density measurement (Fig.
6D) confirms these observations.
The three peaks of density superimpose
well with the radial density
distribution in the Gag particle,
indicating the same spacing of the
bilayer leaflets and the MA
domain-derived layer. The shallower density
trough between these
layers in immature HIV-1 indicates the presence of
additional
mass in this region (Fig.
6D). The additional density found
outside
the membrane reflects the presence of glycoprotein on the
surface.
The HIV-1 TM protein contains a cytoplasmic subdomain of ~17
kDa.
Several lines of evidence suggest that this portion of the TM
protein is located near the viral membrane; however, the radial
density
profile did not resolve it as a separate
feature.
| |
DISCUSSION |
Gag determines the radial organization of immature HIV.
The
radial organization of the immature HIV particle is revealed by cEM.
Our previous work showed that VLPs contain a radially arranged Gag
polyprotein with the N terminus (MA domain) located at the membrane and
the C terminus (NC and p6 domains) toward the center of the particle
(47, 48). The domains of the Gag polyprotein fold
separately and create individual protein layers in the particle
(13). Here, we use an analysis of Gag deletion mutants to
confirm this arrangement in the VLP.
The ability to compare the radial density profiles of the immature
virion and the in vitro-assembled particle with the VLP
allowed us to
look for a role of the specific RNA and of the membrane
in the
organization of the particle. Our analysis of the immature
virion
showed that the radial profile of its internal structure
matches that
of the VLP. Hence, the additional components present
in the authentic
particle do not have a perceptible effect on
its internal organization.
Interestingly, the inner portions of
this region are also unchanged in
the in vitro-assembled particle
without a membrane, showing that the
membrane plays a limited
role in the organization. HIV-1 resembles
D-type retroviruses
(
45) in this respect. Hence, the Gag
polyprotein itself plays
the dominant role in defining the internal
organization of the
immature
particle.
The bipartite organization of MA is retained during
maturation.
We previously suggested that the matrix domain is
tightly associated with the inner face of the viral membrane and is
separated from the underlying capsid derived protein layer by a space
of approximately 40-Å thickness (13). Here, we visualize
a discrete protein layer at the inside of the lipid bilayer. Further,
thin tethers are seen crossing the underlying 40-Å low-density space. We tested the assignment of these feature to the MA domain by comparing
wild-type Gag particles to Gag particles lacking residues 41 to 143. Deleting most of the MA domain and 11 N-terminal residues of CA removed
the protein layer next to the membrane and reduced the space
underneath. This result confirms that both of these distinct structural
elements are formed by the MA domain of the Gag polyprotein.
A bipartite organization of the MA domain is consistent with other
structural data. The precise sequence that spans the 40-Å
space must
be defined by smaller deletions; however, the appearance
of extended
thin tethers is consistent with the presence of
-helices.
X-ray
crystallographic studies have shown that the C terminus
of the mature
MA domain forms a 25-amino-acid-long
-helix that
is distinct from
the rest of the molecule (
25). This helix (helix
5) points
away from the globular head of the MA domain and hence
should extend
toward the center of the virion. Its 37-Å length
would span most of
the 40-Å space observed. Although evidence
suggests that the structure
of the MA domain in the uncleaved
(i.e., immature) state of Gag may
differ from the cleaved (mature)
state, particularly in the
neighborhood of the CA domain (
24),
a helix in this
position would certainly be consistent with our
observations. This
arrangement of helix 5 would position the globular
head of the MA
molecule next to the inner leaflet of the lipid
bilayer. The detection
of a distinct MA domain-derived protein
layer just below the inner
leaflet of the immature particle lends
strong support to the idea that
the bipartite organization seen
in crystals of the cleaved protein also
corresponds to the immature
state and is retained after
maturation.
A model for the arrangement of the MA protein layer in mature
lentiviruses has been proposed from its arrangement in the simian
immunodeficiency virus (
38) and HIV (
25) MA
domain crystal
structures. The observed ~25-Å width of the membrane
proximal
matrix layer is consistent with the arrangement of the
globular
head structure in these models. The arrangement of the MA
domain
as a network of six membered rings linked by two MA trimers
(
38)
results in a center-to-center spacing of neighboring
MA trimers
(~66 Å) and would yield a ~33-Å spacing in projection
along the
membrane. The tethers which cross the low-density region in
the
VLPs display a 33 ± 5 Å separation (Fig.
2B). This spacing
would
be consistent with the hexamer network (
25,
38), if
the tethers
represent bundles of MA domain carboxy-terminal
extensions. The
analysis of the repeating unit in the VLP
(
13) supported a similar
local
arrangement.
The data presented here reveals the striking arrangement of the MA
domain in immature HIV-1. It reveals a thin MA domain protein
layer
next to the membrane, resting on thin stalks which connect
it to CA.
The role of this construction is unclear. The MA layer
may support the
viral membrane from the inside. The fact that
a deletion in MA
significantly affects particle stability provides
some evidence for
this suggestion. We think it is likely that
some space in proximity to
the domain boundaries is helpful during
viral maturation because it
will significantly increase the accessibility
of the protease cleavage
sites. This speculation is supported
by the presence of a similar,
albeit thinner, space between the
CA and NC protein layers. This
stretch of amino acids is bordered
by two viral protease cleavage sites
and has been identified as
the spacer peptide, sp1 (
36).
sp1 has been shown to be an important
conformational determinant with
profound influence on the symmetry
of assembly of Gag particles in
vitro (
1,
16,
24). Although
no direct structural
information is available, molecular modeling
suggests that the residues
between CA and NC form a continuous
-helix (
1).
TM contributes density to the bilayer region.
The internal
regions of the immature virion and the VLP were indistinguishable;
however, subtle differences were seen in the region of the membrane.
The membrane organization of authentic immature HIV-1 appeared more
complex than that in Gag particles. The layers of the membrane were
clearly separated in the VLPs by spaces which were filled with density
in the virion. This difference may explain the fact that VLP membranes
are sensitive to nonionic detergents under conditions which leave the
membrane of authentic immature virions intact (T. Wilk, unpublished
observation, and reference 48). We believe that the
additional density is contributed by the viral glycoprotein complex of
HIV-1 which was observed to cover the entire surface of the immature
virions. The abundance of surface projections was surprising, since the
SU portion is known to be bound weakly to the virion (45).
Further work is needed to show whether this projecting density reflects
the entire glycoprotein (SU-TM) complex or only the stable,
membrane-anchored TM protein. The projections are indeed shorter than
those seen in the distantly related spumavirus retrovirus, in which the
SU domain is retained (46).
All lentivirus TM proteins contain long cytoplasmic tails
(
45). The HIV-1 tail contributes a mass of ~17 kDa,
equivalent
to the mass of the MA domain. It has been suggested
(
13) that
the 40-Å space below the membrane could harbor
the large C-terminal
tail of TM. Our analysis of cEM images and radial
density measurements
provides no support for this suggestion, since no
additional density
was detected at this position in immature virions or
further within
the particle. Interestingly, MA mutations that prevent
glycoprotein
incorporation largely map to the membrane-exposed surface
of the
MA trimer model (
38). This suggests a placement of
the C-terminal
domain between the inner leaflet of the membrane and the
MA domain-derived
protein layer. Indeed, multiple palmitoylation events
(
50) and
the presence of amphipathic helices
(
44) suggest a rather intimate
association of the TM C
terminus with the lipid bilayer, as proposed
previously
(
50). The observation of additional density within
the
membrane of immature HIV-1 supports such an arrangement; however,
only
the analysis of a virus mutant lacking the cytoplasmic domain
would
address this issue
directly.
The CA and NC domains, but not p6, form regular inner-density
layers.
The capsid domain of the Gag polyprotein is visible as a
pair of peaks spaced ~45 Å apart, reflecting the division of the CA
protein into separately folding N- and C-terminal subdomains. This
spacing matches that seen in tubes formed by the CA protein in vitro
(22) and the outer two rings seen in tubes assembled from
recombinant CA-NC protein and nucleic acid (T. Wilk, unpublished data),
confirming that these regions represent CA.
The NC domain contributes the innermost radial density to the immature
particle. We originally assigned this layer in immature
particles to
the NC-p6 domain (
13); however, the contribution
of the
C-terminal p6 domain was unclear. The deletion of the entire
p6 domain
did not affect the width or the substructure of the
innermost protein
layer in mutant HIV-1 Gag
p6 VLPs or in vitro-assembled
particles.
Hence, p6 does not contribute to this density. Since
p6 is roughly the
same size as the NC domain, its deletion should
have a marked effect on
the density unless it is disordered or
unstructured. This latter
possibility is consistent with structural
studies of the isolated
protein (
42).
The function of p6 during or after assembly and budding remains unclear
(reviewed in reference
12). When Gag is expressed
alone, the p6 domain can be deleted without causing a defect in
assembly (
39). In contrast, p6 deletions from the
full-length
viral genome result in the arrest of budding particles at
the
plasma membrane (
21), a phenotype which has been shown
to depend
on the virus protease (
27). It has been
suggested recently that
p6 is a major determinant of particle size and
that p6 deletion
results in the generation of large particles
(
14,
15). Nevertheless,
analysis of p6 mutants (
16,
21,
26,
39) by conventional
electron microscopy revealed no
effect on the particle diameter.
cEM of wild-type and mutant subviral
Gag particles allows visualization
of unstained particles and reveals
the entire particle in projection,
providing a more reliable measure.
The cEM results show that deletion
of p6 results in the generation of
particles with a diameter of
140 ± 23 nm. The similar diameter of
authentic immature virions
(133 ± 17 nm) and p6-deleted VLPs
demonstrates that the control
of Gag assembly is not affected by the
absence of a functional
p6 domain. In fact, the absence of the p6
domain was advantageous
in the expression system, since the mutant
particles were more
regular in size and shape than wild-type
VLPs.
Conclusions.
The analysis presented here complements the
ability of cEM to provide quantitative density distributions with
mutational analysis. Our analysis validates the radial model
of domain arrangement (13, 47, 48) and extends it to
reveal the details of the interaction between MA and the membrane in
the uncleaved Gag protein. It also defines differences between the VLPs
and the immature virion in the organization of the membrane region
while showing that the membrane is not necessary for the organization
of the internal Gag domains.
| |
ACKNOWLEDGMENTS |
We are pleased to acknowledge the discussions and help of our
colleagues at the European Molecular Biology Laboratory and the
Heinrich-Pette-Institut who made the work presented both easier and
more enjoyable.
This work was supported by a DFG grant (Fu354/1-1) to H.-G.K. and
S.D.F., a Wellcome Trust Programme Grant to S.D.F., and a grant from
the Agence National de Recherche sur la SIDA (ANRS-1998) to P.B.
S.D.F. is a Wellcome Trust Principal Research Fellow.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Division of
Structural Biology, The Wellcome Trust Centre for Human Genetics,
Roosevelt Dr., Headington, Oxford OX3 7BN, England. Phone:
44-1865-287546. Fax: 44-1865-287547. E-mail:
stephen.fuller{at}strubi.ox.ac.uk.
| |
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Journal of Virology, January 2001, p. 759-771, Vol. 75, No. 2
0022-538X/01/$04.00+0 DOI: 10.1128/JVI.75.2.759-771.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
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Abstract
Introduction
