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Role of cell surface mobility on bacteriophage infection: Translocation of salmonella phages to membrane adhesions
Vol.
73, No,
BIOCHEMICAL
3,1976
ROLE
OF
CELL
SURFACE
TRANSLOCATION
Toshio The
Institute
Received
OF
MOBILITY
Shintaro
ON
PHAGES
The
RESEARCH
COMMUNICATIONS
BACTERIOPHAGE
IWASHITA,
Science,
October
BIOPHYSICAL
SALMONELLA
TOMITA, of Medical
AND
TO
and
University
INFECTION:
MEMBRANE
Shiro
ADHESIONS
KANEGASAKI
of Tokyo,
P.O.Takanawa,
Tokyo
108
5,1976
SUMWRY: Ph age 615 adsorbed at a low temperature (or by short-time incubation) to the outer surface of Salmonella anatum gathers on further incubation at a high temperature to a certain region where the inner and outer membranes may join. This was demonstrated by separating the inner and outer membranes of the cells in sucrose gradient after addition of 3%-labeled 615 to the cells. Radioactivity adsorbed at 4” was first recovered mainly with the dense outer membrane but disappeared by further incubation at 35” within 5 min. Instead, the radioactivity was recovered with the membrane fraction which had intermediate density. S UC h p h age traslocation was not observed when phage 815 was added to a m mutant of S.anatum to which the phage can adsorb but fail to infect. A host range mutant phage which can infect the a mutant migrated to the intermediate dense region,
The
smooth
antigen, of the
specific
the outer
peripheral surface
of a single
species
polysaccharide the
release
bacterial which
specific
DNA
the
Salmonella and
how
sites,
the
phage
these
limited
randomly
to reach
al I over than
the
to the
the
adhesions
of binding outer
negative acid,
adhesion
reside
0 1976 by Academic Press, Inc. of reproduction in any form reserved.
early
stages
yet
kind
sites.
sites.
The and
the
subsequently
phage
adsorption,
penetrate
into
especially
the those
of DNA
including
adhesion
If the
is that
the
receptors
adsorbed
tothe
adhesion
rhe
are
the
place
be considered over
directly
sites
smooth
between sites
can
is that
the
sites
adhesion
phages
phages
0 antigen
completion
the
to the 807
the
consists
understood.
possibility
and other
and
of possibilities
One
host
After may
to 0
constituent phages
of infection,
the
bacteria. two
the
particles
over
P22 adsorb
of these
acid
clearly phage
preferentially
membrane
migrate
nucleic
located
of Gram
plate
(3,7).
the
various
preferentially
receptors
numbers
(8) that
base
to its receptor not
and
is an important
adsorption
and
are
9341
or deacetylates
phage
of phage
its nucleic
The
in these
however,
membranes
~34, which
cleaves
for
involved
by Bayer
penetrates
which
be triggered
attachment
phages
inner
phage
may
cytoplasm,
as e15,
organisms.
is responsible
Events
demonstrated
the phages
Copyright All rights
protein
between
It was
other
of enzyme
of phage
such
of Iipopalysaccharide, negative
and
into
phages
of Gram
cytoplasm.
transfer
where
portion
(l-6)
occur
outer
Salmonella
the
for
adhesion
recognize are receptor
during
distributed at the incubation.
sites
Vol.
73, No.
3,1976
In this adhesion
BIOCHEMICAL
communication sites.
MATERIALS
we show
The
AND
step
seems
AND
the
BIOPHYSICAL
migration
RESEARCH
of phage
to be essential
for
the
~‘5
from
COMMUNICATIONS
the
attachment
accomplishment
to
of phage
infection.
METHODS:
Most of the methods and materials used in this experiment were the same as those described previously (9). Bacteria and phases: Salmonella anatum A 1, S. gnatum SK59 (a m mutant) (9) and phages oT5vir, eT5hp32 (a host range mutant phage which infects the-bacterium) (9) and ~341 were used. 35S-Labeled phages: 35S-labeled phages eT5 vir, eT5hp32 and ~341 were prepared and purified according to the method described previously (9). Adsorption of radioactive ohaae to bacteria: Bacteria grown in L broth (5 x 108 cells/ml) and the radiactive phage (approximately 100,000 cpm/250 ml) (see figure legends) were mixed at 0’ or 35” and incubated at 0’ or 350. After the incubation, the mixtures were quickly chilled and phagewdsorbed cells were recovered by cenfrifugation. Membrane This was done according to a modified method (10) of the Schnaitman procedure (11). The position of the inner and outer membrane were usually defined by protein profile (12), distribution of cytochrome bT (13), and contents of rhamnose (14). Thedensity of the resultant peaks is comparable to that observed by Smit et al. (IO). The densest peak is outer membrane since it containes the majority of rhamnose. The middle band is unseparated inner and outer membrane as indicated by an intermediate amount of rhamnose and cytochrome bT . The lightest bands are inner membrane as indicated by the lack of rhamnose and high absorbance of cytochrome bl .
RESULTS
:
Salmonella for
anatum
30 min.
cell.
The
The
cells
region
the
membrane
the
radioactive the
region
phage were
decreased of incubation,
indicate
that
are
can
the
to the
further
that
in the
phage
the
receptor
site
intermediate
outer other
than and
previously
reported
bacterial
fail
to lyse
(9).
to its receptor
One
the
gathers
such
The
region
mutants mutant
808
(Fig.
the
outer
the
membrane designated (SK59)
sucrose
fig.
cells
and
When
the
ICI.
(Fig.
and
Id).
The
results
that outer
the
phage
membranes
adhesions. as pep were
to which mixed
cells
After
which
suggest
inner
with
membrane
lipopolysaccharide also
pressure
recovered
lb).
increased
results
ceils
were
when
membrane
where
to the
phage
in the
outer
at 4’
was associated
15 set
region
incubated
a discontinuous
obtained
radioactivity
with
.
onto
of radioactivity were
dense
membrane
migrates
but
the
and
in a French
of the
at 35O for
at 35O,
attaches
applied
rest
results
was found
initially
over
the
incubated
subsequently have
adsorb
and
no radioactivity
randomly
fused, We
incubated
and
mixed
disrupted
of radioactivity
Similar
density.
were
and were
60%
membrane
mixed
e15vir
by centrifugotion
almost
outer
were
while
5 min
adsorbed
la,
of intermediate
phage
distributes
dense
phage
by centrifugation
in Fig.
of the
35 S-labeled
collected
collected
As shown
in the
and
were
membranes
gradient.
and
cells
with
phage the
e15
BIOCHEMICAL
Vol. 73, No. 3,1976
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
1 10
20 Fraction
Fig.
1.
Translocation
of 35S-labeled
phase
e15 vir
from
the
primary
adsorption
sites
(the
outer membrane) to the membrane with intermediate density. Al cells (5.5 x 108/ml) in 150 ml of chilfed L-broth were mixed with 35S-labeled el%ir (89,000 cpm:MOI+l. 15) in a ice bath. After 30 min for adsorption, the mixture was di vided into three 50 ml portions (a,c and d) and two portions were further incubated at 35” for 1 (c) or 5 min(d). In another experiment, the L-broth culture of Al cells (5.5 x 108cells/ml) in 50 ml was mixed with 3%labeled cT5vir (88,000 cpm:MOI=O. 15) and incubated for 15 set at 35” (b). After incubation, the mixtures were poured into 200 ml (o,c and d) or 150 ml (b) of precooled L-broth containing carrier cells(l, 1 x 10” or 8 x lOTo cells, respectively). The cells washed twice with ice-cold N-2-hydroxyethylpiperazine-N’-2’ethanesulfonic acid (HEPES) buffer, pH 7.4 (10 mM) were suspended in 25 ml of the same buffer, and after addition of 0.5 mg each of deoxyribonuclease and ribonuclease, disrupted in a French pressure cell at 1,200 kg/cm2. Membranes were collected by centrifugation in a Spinco type 60Ti rotor for 3 hrs at 40,000 rpm, suspended into 1 ml of the HEPES buffer and applied to a discontinuous sucrose density gradient (1,5 ml of 2.02 M, 5.5 ml of 1.44 M and 4 ml of 0.77 M sucrose in the buffer). The gradients were centrifuged in a Spinco SW 41 Ti rotor for 15 hrs at 20,500 rpm. The fractions were At iquots of the fractions were spotted on collected by puncturing the bottom of the tubes. 25 mm filter discs (Whatman GF83) and radioactivity was measured (+). The protein profile was also shown (-0 l - - ). 0 and I indicate the positions of the outer and inner membrane, respectively.
radioactive
phage
eT5vir
above
ond
as described to the pels this Lack
m
bacteria
mutant of migration
were lacks
and
incubated
the resultswere recovered
an anchoring
of the
phage-receptor
at 35” shown
with
the
for
5 min.
The
2.
Almost
in Fig. outer
mechanism
membrane.
of phage
complex
809
in the
particles mutant
membranes all The
were
radioactivity results
at the is less
adsorbed
suggest membrane
likely
separated
(see
that adhesions. below).
Vol.
73, No.
3, 1976
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
20
10 Fraction
Fig. 2. Association of 35S-labeled e’5vir with the outer membrane of m mutant celis. SK 59 cells (5.5 x 108/mi) in 250 ml of L-broth were mixed with J% -labeled e15vir (107,000 cpm, MOkO. 04) and incubated for 5 min at 35”. For disruption of the cells and separation of membranes, the similar conditions as described in the legend of Fig. 1 were employed. Radioactivity(+) and protein profile@me0) were shown. 0 and l indicate the positions of the outer and inner membrane, respectively.
20 3 z 0 u
0 ‘0 x
2 1.0 10
-
2 .> .-
1.0
;: ;
0.5
03
0: 3
c .P,
2:
cl cc
1 0
0 20
10 Fraction
Fig.
3.
Miaration
of a host
range
mutant
phage,
c’5h032.
on the
cell
surface
of
--@-e-.(5.5 x 1 /ml) SK 59 cells in 50 ml of L-broth were infected with 35S-labeled c15hp32 (28,000 cpm:MOlrO. 005) and incubated for 15 set (a) or 5 min (b) at 35’. The conditions for disrupting the cells and separating membranes were similar as those described in the legend of Fig. 1. Radioactivity (+) and protein profile (- - l - .) were shown. 0 and I indicate the positions of the outer and inner membrane, respectively.
810
vol.
73, No.
BIOCHEMICAL
3,1976
As previously come
by
reported,
a host
the m
range
bacteria,
o significant
the
with
fraction
with
migration
similar
outer
accomplishment
were
density.
mutants
mutant
phage,
mutant
bocterio, results
in m
As shown
range
pep
to the
such
performed.
These
membrane
Using
host
of the
infection
(9).
of the
membrane
outer
of the
eT5
experiments
the intermediote the
of phage
of phage
of radioactivity
the
from
inhibition
mutation
portion
associated
the
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
intermediate
dense
was originally
into
suggest
the
that
and
30 and b,
which
migrated
be over-
e 15hp32
in Fig.
phage
strongly
can
membrane
the
phage
mambrane
is essential
for
the
is surrounded
by a rigid
layer
infection.
DISCUSSION: The the
cytoplasmic
membrane
peptideglycan
proteins
and
and
is a limited
(8).
These
saccharide
number
are
translocated
to the
membrane
with
to be
(or at least
penetrates
initially
the
wild
adhesion
sites
wos fast
and
the
of fixation The
mechanism
unclear
bacteria
phage
of the
ot the
has otready
can
(9).
These
phages
not
present.
The
demonstrated
microscope,
the
of migration
of phage-receptor
direction
the by
lateral
diffusion complexes
and
phage
adhesion
( or the
play
diffusion et al.
of the are
at 35O. blocks
by a host
range
more
efficiently
traslocation
infection.
of
In the m although
phage-receptor
on essential
and newly
reverse.
811
The
which
of 2.~
molecules
of the
(17)
membrane.
mutant
sites,
is considered
5 min
the
the
migrated
outer
that
the
the
mutant, mechanism
unknown.
receptor
may
that
region
within
suggest phage
ot the
of the
surface
inner
mutants
accomplishing
MChlradt
of the
pep
which
membrane of this
cells
lipopoly-
through
wos overcome
strongly
is still
and
in a bacterial
the
results
of the
mobility cell
Although
infect
adhesions
of traslocotion
the
but thisdifficulty
for
outer
membrone
observed
to be trapped
ot the
on the
complexes.
mutant
The
of the
we demonstrated
was accomplished
was not stage
dense
between
migration
is essential seems
lipopolysocchoride) of the
early
phage
adhesions
type
in the
the
type
to the
receptor
membranes,
synthesized (16)
paper,
outer
plasmolysis
newly
membrone
In this
and
after
where
of
of lipopolysacchorides,
(inner)
visible
sites
cytoplasm.
include)
ot the
are
to the outer
phage
consists
cytoplasmic
to be the
to the
of the
latter
which
density.
This
wild
the
intermediate
cT5infection phage.
bacteria The
sites
into
adsorbed
translocation
phoges the
acid
of migration
the
of adhesion
molecules
eT5
than
Between
considered
phoge
mutant
(15).
are
nucleic
phage
membrane.
adhesions
phage
The
outer
phospholipids
there
rate
the
of Gram-negative
( in this role
newly
Bayer formed
complex)
for
case,
the
under
the
lateral
synthesized (18)
is also
movement
lipopolysaccharides the
electron
lipopolysaccharides
In addition,
neither
and cteovageof
that
Vol.
73, No.
0 antigen plate
polysaccharide
of the
smooth since
phws, or phage
Felix
saccharide gathered
The
enzymatic
especially
specific
0,
the
and
action
phages
the
the mechanism
intermediate
dense
region
formed
treatment
can
release
( unpublished of the
phage
of the
traslocation
of the
membrane
number
observation
). Further
ACKNOWLEDGEMENTS:
acid
into
We
to have
of phage
the
thank
cytoplasm
Dr.
We also thank Dr. Masanosuke Yoshikawa work was supported in part by a grant-in-aid of Education, Science and Culture, Japan.
Yoshito for
most
with
takes
the
of the
polysaccharide
smooth
phages
specific
(l-6)
allow
(5)
of the
lipopolyphages,
(unpublished
which
base
movement
portion
incubation
of the
its DNA,
are
of the
observation). may
correct
be required orientation
DNA. is,
particles
lateral
R-core
from
phages,
ejected
action
0 antigen
specific
their
experiments
the
cleave
after
smooth
fraction
enzymatic
to be the
of the
to eject
seemed
not
different
of the
surface
a significant
nucleic
plate
the explain
region
movement
cell
even
is known
dense
perpendicular
above
does
is quite
intermediate
the
after
of which
base
nor
sufficiently
which
morphology
of the
e15
may
(c341),
receptor
whose
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
by phage
phages
9341
to the
for
Whatever
shown
phage
(19)
also
of the
BIOCHEMICAL
3, 1976
radioactive
since
EDTA-Triton associated
needed place
Kaziro
his support for scientific
with
few
plaques
X100.
This
the
to clarify through
for
phage
outer
whether the
in the were,
treatment membrane the
penetration
region.
his interest
and encouragement. research from
and the
criticism. This Ministry
REFERENCES: S. (1973) Biachem. Biophys. Res. Comn., a, 4031. Iwashita, S., and Kanegasaki, 409. 2. Kanegasaki, S., and Wright, A. (1973) Virology, 2, 160-173. 3. Iwashita, S., and Kanegasaki, S. (1975) Virology, &, 27-34. 4. Iwashita, S., and Kanegasaki, S. (1976) Eur. J. Biochem., 45, 87-94. 5. Iwashita, S., and Kanegasaki, S. (1976) J. Biol. Chem. , in press. S. (1975) Abstr., 3rd Int. Cong. Viol., 6. Takeda, K., Uetake, H., and Toyama, hAcldrid, p.213. 7. Israel, J. V., Anderson, T.F., and Levine, M, (1967) Proc. Natl. Acad. Sci. U.S., z, 284-291. 8. Bayer, M. E. (1974) Ann. N.Y. Acad. Sci., 235, 6-28. 9. Kanegasaki, S., and Tomita, T. (1976) J. Bacterial., m, 7-13. 10. Smit, J., Kamio, Y., and Nikaido, H. (1975) J. Bacterial., 124, 942-958. 11. Schnaitman, C. A. (1970) J. Bacterial., 104, 890-901. 12. Lowry, 0. H., Rosebrough, N. J., Farr, A. L., and Randall, R. J . (1951) J. Biol . Chem ., 193, 265-275. 13. Osborn, M. J., Gander, J. E., Parisi, E., and Carson, J. (1972) J. Biol. Chem., 247, 3962-3972. 14. Bray, D., and Robbins, P.W. (1967) J Mol. Biol., 30, 457-475.
812
Vol. 73, No. 3, 1976
15. 16. 17. 18. 19.
Wright, Mijhlradt,
A.,
and P. F.,
BIOCHEMICAL
Kanegosaki, Menzel,
S. J.,
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
(1971) Golecki,
J.
physiol. Rev., 51, 748-784. R., and Speth, V. (1973)
Biochem., 35, 471-481. Miihlradt, P. F., Menzel, J., Golecki, J. R., and Speth, Biochem., &3, 533-539. Bayer, M. E. (1975) In Proceedings of the 1st Intersectional Vol. 2, pp. 43-49, Univ. of Tokyo Press. Lindberg, A. A. (1967) J. Gen. Microbial., 48, 225-233.
813
V.
(1974)
Congress
Eur.
J.
Eur.
J.
of the
I.A.M.S.
73, No,
BIOCHEMICAL
3,1976
ROLE
OF
CELL
SURFACE
TRANSLOCATION
Toshio The
Institute
Received
OF
MOBILITY
Shintaro
ON
PHAGES
The
RESEARCH
COMMUNICATIONS
BACTERIOPHAGE
IWASHITA,
Science,
October
BIOPHYSICAL
SALMONELLA
TOMITA, of Medical
AND
TO
and
University
INFECTION:
MEMBRANE
Shiro
ADHESIONS
KANEGASAKI
of Tokyo,
P.O.Takanawa,
Tokyo
108
5,1976
SUMWRY: Ph age 615 adsorbed at a low temperature (or by short-time incubation) to the outer surface of Salmonella anatum gathers on further incubation at a high temperature to a certain region where the inner and outer membranes may join. This was demonstrated by separating the inner and outer membranes of the cells in sucrose gradient after addition of 3%-labeled 615 to the cells. Radioactivity adsorbed at 4” was first recovered mainly with the dense outer membrane but disappeared by further incubation at 35” within 5 min. Instead, the radioactivity was recovered with the membrane fraction which had intermediate density. S UC h p h age traslocation was not observed when phage 815 was added to a m mutant of S.anatum to which the phage can adsorb but fail to infect. A host range mutant phage which can infect the a mutant migrated to the intermediate dense region,
The
smooth
antigen, of the
specific
the outer
peripheral surface
of a single
species
polysaccharide the
release
bacterial which
specific
DNA
the
Salmonella and
how
sites,
the
phage
these
limited
randomly
to reach
al I over than
the
to the
the
adhesions
of binding outer
negative acid,
adhesion
reside
0 1976 by Academic Press, Inc. of reproduction in any form reserved.
early
stages
yet
kind
sites.
sites.
The and
the
subsequently
phage
adsorption,
penetrate
into
especially
the those
of DNA
including
adhesion
If the
is that
the
receptors
adsorbed
tothe
adhesion
rhe
are
the
place
be considered over
directly
sites
smooth
between sites
can
is that
the
sites
adhesion
phages
phages
0 antigen
completion
the
to the 807
the
consists
understood.
possibility
and other
and
of possibilities
One
host
After may
to 0
constituent phages
of infection,
the
bacteria. two
the
particles
over
P22 adsorb
of these
acid
clearly phage
preferentially
membrane
migrate
nucleic
located
of Gram
plate
(3,7).
the
various
preferentially
receptors
numbers
(8) that
base
to its receptor not
and
is an important
adsorption
and
are
9341
or deacetylates
phage
of phage
its nucleic
The
in these
however,
membranes
~34, which
cleaves
for
involved
by Bayer
penetrates
which
be triggered
attachment
phages
inner
phage
may
cytoplasm,
as e15,
organisms.
is responsible
Events
demonstrated
the phages
Copyright All rights
protein
between
It was
other
of enzyme
of phage
such
of Iipopalysaccharide, negative
and
into
phages
of Gram
cytoplasm.
transfer
where
portion
(l-6)
occur
outer
Salmonella
the
for
adhesion
recognize are receptor
during
distributed at the incubation.
sites
Vol.
73, No.
3,1976
In this adhesion
BIOCHEMICAL
communication sites.
MATERIALS
we show
The
AND
step
seems
AND
the
BIOPHYSICAL
migration
RESEARCH
of phage
to be essential
for
the
~‘5
from
COMMUNICATIONS
the
attachment
accomplishment
to
of phage
infection.
METHODS:
Most of the methods and materials used in this experiment were the same as those described previously (9). Bacteria and phases: Salmonella anatum A 1, S. gnatum SK59 (a m mutant) (9) and phages oT5vir, eT5hp32 (a host range mutant phage which infects the-bacterium) (9) and ~341 were used. 35S-Labeled phages: 35S-labeled phages eT5 vir, eT5hp32 and ~341 were prepared and purified according to the method described previously (9). Adsorption of radioactive ohaae to bacteria: Bacteria grown in L broth (5 x 108 cells/ml) and the radiactive phage (approximately 100,000 cpm/250 ml) (see figure legends) were mixed at 0’ or 35” and incubated at 0’ or 350. After the incubation, the mixtures were quickly chilled and phagewdsorbed cells were recovered by cenfrifugation. Membrane This was done according to a modified method (10) of the Schnaitman procedure (11). The position of the inner and outer membrane were usually defined by protein profile (12), distribution of cytochrome bT (13), and contents of rhamnose (14). Thedensity of the resultant peaks is comparable to that observed by Smit et al. (IO). The densest peak is outer membrane since it containes the majority of rhamnose. The middle band is unseparated inner and outer membrane as indicated by an intermediate amount of rhamnose and cytochrome bT . The lightest bands are inner membrane as indicated by the lack of rhamnose and high absorbance of cytochrome bl .
RESULTS
:
Salmonella for
anatum
30 min.
cell.
The
The
cells
region
the
membrane
the
radioactive the
region
phage were
decreased of incubation,
indicate
that
are
can
the
to the
further
that
in the
phage
the
receptor
site
intermediate
outer other
than and
previously
reported
bacterial
fail
to lyse
(9).
to its receptor
One
the
gathers
such
The
region
mutants mutant
808
(Fig.
the
outer
the
membrane designated (SK59)
sucrose
fig.
cells
and
When
the
ICI.
(Fig.
and
Id).
The
results
that outer
the
phage
membranes
adhesions. as pep were
to which mixed
cells
After
which
suggest
inner
with
membrane
lipopolysaccharide also
pressure
recovered
lb).
increased
results
ceils
were
when
membrane
where
to the
phage
in the
outer
at 4’
was associated
15 set
region
incubated
a discontinuous
obtained
radioactivity
with
.
onto
of radioactivity were
dense
membrane
migrates
but
the
and
in a French
of the
at 35O for
at 35O,
attaches
applied
rest
results
was found
initially
over
the
incubated
subsequently have
adsorb
and
no radioactivity
randomly
fused, We
incubated
and
mixed
disrupted
of radioactivity
Similar
density.
were
and were
60%
membrane
mixed
e15vir
by centrifugotion
almost
outer
were
while
5 min
adsorbed
la,
of intermediate
phage
distributes
dense
phage
by centrifugation
in Fig.
of the
35 S-labeled
collected
collected
As shown
in the
and
were
membranes
gradient.
and
cells
with
phage the
e15
BIOCHEMICAL
Vol. 73, No. 3,1976
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
1 10
20 Fraction
Fig.
1.
Translocation
of 35S-labeled
phase
e15 vir
from
the
primary
adsorption
sites
(the
outer membrane) to the membrane with intermediate density. Al cells (5.5 x 108/ml) in 150 ml of chilfed L-broth were mixed with 35S-labeled el%ir (89,000 cpm:MOI+l. 15) in a ice bath. After 30 min for adsorption, the mixture was di vided into three 50 ml portions (a,c and d) and two portions were further incubated at 35” for 1 (c) or 5 min(d). In another experiment, the L-broth culture of Al cells (5.5 x 108cells/ml) in 50 ml was mixed with 3%labeled cT5vir (88,000 cpm:MOI=O. 15) and incubated for 15 set at 35” (b). After incubation, the mixtures were poured into 200 ml (o,c and d) or 150 ml (b) of precooled L-broth containing carrier cells(l, 1 x 10” or 8 x lOTo cells, respectively). The cells washed twice with ice-cold N-2-hydroxyethylpiperazine-N’-2’ethanesulfonic acid (HEPES) buffer, pH 7.4 (10 mM) were suspended in 25 ml of the same buffer, and after addition of 0.5 mg each of deoxyribonuclease and ribonuclease, disrupted in a French pressure cell at 1,200 kg/cm2. Membranes were collected by centrifugation in a Spinco type 60Ti rotor for 3 hrs at 40,000 rpm, suspended into 1 ml of the HEPES buffer and applied to a discontinuous sucrose density gradient (1,5 ml of 2.02 M, 5.5 ml of 1.44 M and 4 ml of 0.77 M sucrose in the buffer). The gradients were centrifuged in a Spinco SW 41 Ti rotor for 15 hrs at 20,500 rpm. The fractions were At iquots of the fractions were spotted on collected by puncturing the bottom of the tubes. 25 mm filter discs (Whatman GF83) and radioactivity was measured (+). The protein profile was also shown (-0 l - - ). 0 and I indicate the positions of the outer and inner membrane, respectively.
radioactive
phage
eT5vir
above
ond
as described to the pels this Lack
m
bacteria
mutant of migration
were lacks
and
incubated
the resultswere recovered
an anchoring
of the
phage-receptor
at 35” shown
with
the
for
5 min.
The
2.
Almost
in Fig. outer
mechanism
membrane.
of phage
complex
809
in the
particles mutant
membranes all The
were
radioactivity results
at the is less
adsorbed
suggest membrane
likely
separated
(see
that adhesions. below).
Vol.
73, No.
3, 1976
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
20
10 Fraction
Fig. 2. Association of 35S-labeled e’5vir with the outer membrane of m mutant celis. SK 59 cells (5.5 x 108/mi) in 250 ml of L-broth were mixed with J% -labeled e15vir (107,000 cpm, MOkO. 04) and incubated for 5 min at 35”. For disruption of the cells and separation of membranes, the similar conditions as described in the legend of Fig. 1 were employed. Radioactivity(+) and protein profile@me0) were shown. 0 and l indicate the positions of the outer and inner membrane, respectively.
20 3 z 0 u
0 ‘0 x
2 1.0 10
-
2 .> .-
1.0
;: ;
0.5
03
0: 3
c .P,
2:
cl cc
1 0
0 20
10 Fraction
Fig.
3.
Miaration
of a host
range
mutant
phage,
c’5h032.
on the
cell
surface
of
--@-e-.(5.5 x 1 /ml) SK 59 cells in 50 ml of L-broth were infected with 35S-labeled c15hp32 (28,000 cpm:MOlrO. 005) and incubated for 15 set (a) or 5 min (b) at 35’. The conditions for disrupting the cells and separating membranes were similar as those described in the legend of Fig. 1. Radioactivity (+) and protein profile (- - l - .) were shown. 0 and I indicate the positions of the outer and inner membrane, respectively.
810
vol.
73, No.
BIOCHEMICAL
3,1976
As previously come
by
reported,
a host
the m
range
bacteria,
o significant
the
with
fraction
with
migration
similar
outer
accomplishment
were
density.
mutants
mutant
phage,
mutant
bocterio, results
in m
As shown
range
pep
to the
such
performed.
These
membrane
Using
host
of the
infection
(9).
of the
membrane
outer
of the
eT5
experiments
the intermediote the
of phage
of phage
of radioactivity
the
from
inhibition
mutation
portion
associated
the
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
intermediate
dense
was originally
into
suggest
the
that
and
30 and b,
which
migrated
be over-
e 15hp32
in Fig.
phage
strongly
can
membrane
the
phage
mambrane
is essential
for
the
is surrounded
by a rigid
layer
infection.
DISCUSSION: The the
cytoplasmic
membrane
peptideglycan
proteins
and
and
is a limited
(8).
These
saccharide
number
are
translocated
to the
membrane
with
to be
(or at least
penetrates
initially
the
wild
adhesion
sites
wos fast
and
the
of fixation The
mechanism
unclear
bacteria
phage
of the
ot the
has otready
can
(9).
These
phages
not
present.
The
demonstrated
microscope,
the
of migration
of phage-receptor
direction
the by
lateral
diffusion complexes
and
phage
adhesion
( or the
play
diffusion et al.
of the are
at 35O. blocks
by a host
range
more
efficiently
traslocation
infection.
of
In the m although
phage-receptor
on essential
and newly
reverse.
811
The
which
of 2.~
molecules
of the
(17)
membrane.
mutant
sites,
is considered
5 min
the
the
migrated
outer
that
the
the
mutant, mechanism
unknown.
receptor
may
that
region
within
suggest phage
ot the
of the
surface
inner
mutants
accomplishing
MChlradt
of the
pep
which
membrane of this
cells
lipopoly-
through
wos overcome
strongly
is still
and
in a bacterial
the
results
of the
mobility cell
Although
infect
adhesions
of traslocotion
the
but thisdifficulty
for
outer
membrone
observed
to be trapped
ot the
on the
complexes.
mutant
The
of the
we demonstrated
was accomplished
was not stage
dense
between
migration
is essential seems
lipopolysocchoride) of the
early
phage
adhesions
type
in the
the
type
to the
receptor
membranes,
synthesized (16)
paper,
outer
plasmolysis
newly
membrone
In this
and
after
where
of
of lipopolysacchorides,
(inner)
visible
sites
cytoplasm.
include)
ot the
are
to the outer
phage
consists
cytoplasmic
to be the
to the
of the
latter
which
density.
This
wild
the
intermediate
cT5infection phage.
bacteria The
sites
into
adsorbed
translocation
phoges the
acid
of migration
the
of adhesion
molecules
eT5
than
Between
considered
phoge
mutant
(15).
are
nucleic
phage
membrane.
adhesions
phage
The
outer
phospholipids
there
rate
the
of Gram-negative
( in this role
newly
Bayer formed
complex)
for
case,
the
under
the
lateral
synthesized (18)
is also
movement
lipopolysaccharides the
electron
lipopolysaccharides
In addition,
neither
and cteovageof
that
Vol.
73, No.
0 antigen plate
polysaccharide
of the
smooth since
phws, or phage
Felix
saccharide gathered
The
enzymatic
especially
specific
0,
the
and
action
phages
the
the mechanism
intermediate
dense
region
formed
treatment
can
release
( unpublished of the
phage
of the
traslocation
of the
membrane
number
observation
). Further
ACKNOWLEDGEMENTS:
acid
into
We
to have
of phage
the
thank
cytoplasm
Dr.
We also thank Dr. Masanosuke Yoshikawa work was supported in part by a grant-in-aid of Education, Science and Culture, Japan.
Yoshito for
most
with
takes
the
of the
polysaccharide
smooth
phages
specific
(l-6)
allow
(5)
of the
lipopolyphages,
(unpublished
which
base
movement
portion
incubation
of the
its DNA,
are
of the
observation). may
correct
be required orientation
DNA. is,
particles
lateral
R-core
from
phages,
ejected
action
0 antigen
specific
their
experiments
the
cleave
after
smooth
fraction
enzymatic
to be the
of the
to eject
seemed
not
different
of the
surface
a significant
nucleic
plate
the explain
region
movement
cell
even
is known
dense
perpendicular
above
does
is quite
intermediate
the
after
of which
base
nor
sufficiently
which
morphology
of the
e15
may
(c341),
receptor
whose
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
by phage
phages
9341
to the
for
Whatever
shown
phage
(19)
also
of the
BIOCHEMICAL
3, 1976
radioactive
since
EDTA-Triton associated
needed place
Kaziro
his support for scientific
with
few
plaques
X100.
This
the
to clarify through
for
phage
outer
whether the
in the were,
treatment membrane the
penetration
region.
his interest
and encouragement. research from
and the
criticism. This Ministry
REFERENCES: S. (1973) Biachem. Biophys. Res. Comn., a, 4031. Iwashita, S., and Kanegasaki, 409. 2. Kanegasaki, S., and Wright, A. (1973) Virology, 2, 160-173. 3. Iwashita, S., and Kanegasaki, S. (1975) Virology, &, 27-34. 4. Iwashita, S., and Kanegasaki, S. (1976) Eur. J. Biochem., 45, 87-94. 5. Iwashita, S., and Kanegasaki, S. (1976) J. Biol. Chem. , in press. S. (1975) Abstr., 3rd Int. Cong. Viol., 6. Takeda, K., Uetake, H., and Toyama, hAcldrid, p.213. 7. Israel, J. V., Anderson, T.F., and Levine, M, (1967) Proc. Natl. Acad. Sci. U.S., z, 284-291. 8. Bayer, M. E. (1974) Ann. N.Y. Acad. Sci., 235, 6-28. 9. Kanegasaki, S., and Tomita, T. (1976) J. Bacterial., m, 7-13. 10. Smit, J., Kamio, Y., and Nikaido, H. (1975) J. Bacterial., 124, 942-958. 11. Schnaitman, C. A. (1970) J. Bacterial., 104, 890-901. 12. Lowry, 0. H., Rosebrough, N. J., Farr, A. L., and Randall, R. J . (1951) J. Biol . Chem ., 193, 265-275. 13. Osborn, M. J., Gander, J. E., Parisi, E., and Carson, J. (1972) J. Biol. Chem., 247, 3962-3972. 14. Bray, D., and Robbins, P.W. (1967) J Mol. Biol., 30, 457-475.
812
Vol. 73, No. 3, 1976
15. 16. 17. 18. 19.
Wright, Mijhlradt,
A.,
and P. F.,
BIOCHEMICAL
Kanegosaki, Menzel,
S. J.,
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
(1971) Golecki,
J.
physiol. Rev., 51, 748-784. R., and Speth, V. (1973)
Biochem., 35, 471-481. Miihlradt, P. F., Menzel, J., Golecki, J. R., and Speth, Biochem., &3, 533-539. Bayer, M. E. (1975) In Proceedings of the 1st Intersectional Vol. 2, pp. 43-49, Univ. of Tokyo Press. Lindberg, A. A. (1967) J. Gen. Microbial., 48, 225-233.
813
V.
(1974)
Congress
Eur.
J.
Eur.
J.
of the
I.A.M.S.