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Ter mutation and susceptibility to φx174 phage in E. coli K12
Vol. 91, No. 3, 1979 December
BKICHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
14, 1979
Pages
Ter Mutation
and Susceptibility
to @X174 Phage
Tsutomu Department
Received
of Biochemistry, Kanazawa,
October
23,
in E. coli
1051-l
056
K12
Ohkawa
School of Medicine, Ishikawa, Japan
Kanazawa 920
University,
1979
SUMMARY :
The Ter-15 mutant derived from E. coli K12 W2252-lluRCStr (wild type I) is found to be sensitive to $x174 phage infection. Lipopolysaccharide extracted from this mutant inactivates the phage, and has core oligosaccharides identical in amounts to those in the lipopolysaccharide from wild type cells. In contrast, the Ter-21 mutant derived from E. coli K12 W2252-lluRCrel (wild type II) is not sensitive to this phage infection, and its lipopolysaccharide does not inactivate the phage. Its lipopolysaccharide sugars are found to be D-glucose and D-ribose, thus differing from the lipopolysaccharide sugars of the wild type cells. @x174 phage
contains
a single
nucleotides
(1)
in an icosa
From the
reports
of Lindberg
able
to
infect
strains.
the
is
primarily
specific
receptor
binding,
it
releases
the
ved from
sensitive
(7,8).
identified Lindberg
is
strain,
DNA (6).
the
and Kornberg is
of E. coti
be represented
in the
structure
(4),
the
the
on the cell
cells.
wall
purified
of
found
inactivates
the
cell
phage
or semirough
to
4x174
phage
regard
phage
can bind to
to
41x174 phage
(LPS)
deri-
to
for
the
be
$x174
outer
core
Abbreviations used : LPS, lipopolysaccharide ; circular deoxyribonucleic acid ; dTDPG, thymidine KW, 2-keto-3-deoxymannulosoctonic acid.
phage
receptors chain
activity the
the
is
lipopolysaccharides
and showed in the
$x174
(2).
and
receptor that
5375
(5)
the polysaccharide
for
LPS of
With
of
12 particles
smooth
or not
and S. typhinmriwn,
by the
infect
are demonstrated
important
et al
upon whether
the
structure
at the
strain
(4) demonstrated
found
spikes
coli
sites
Further,
cannot
DNA (SS-DNA)
Escherichia
isolated
strains
Also,
but
of the
the
with
(3) and Jazwinski
attachment found
circular
coat
dependent
as crucially
S13 receptor strains
hedral
The susceptibility
infection
phage
rough
strand
in the
LPS is
(3).
Jazwinski,
and the
related
membrane this
this
of
phage
sensitive
binding
and backbone SS-DNA, single 5'-diphosphate
phage
of
site the
to
LPS.
strand glucose
;
0006-291X/79/231051-06$01.00/0 1051
Copyright All rights
@ 1979 by Academic Press, Inc. of reproduction in anyform reserved.
Vol. 91, No. 3, 1979
We are
interested
in resistant dine
coli
in the
and sensitive
5'-diphosphate
precursor
for
synthesis
(wild
mutant type
their
E. cozi
In this
paper,
by the
LPS from
is
cell's
in 9x174
sensitive
type the
nor
its
were
but
its
K12 W2252-llu-
Ter-21
mutant
in the the
as a
phage,
cozi
from
thymi-
Escherichia
9x174
discrepancy
contents
of cells
membrane.
Escherichia I)
infection
in growing
to
extracted
sugar
phage
concentration
formed outer
Neither to
RESEARCH COMMUNICATIONS
decreased
is not
and their
strains
Ter-mutation
wild
types
analyzed
and
in detail
chromatography.
we describe these
the
LPS were
and gas-liquid
occurs
which
To resolve
the
strains,
that
sensitive.
phage.
K12 strains,
Ter mutant
I)
strain
to $x174
by thin-layer
tion
(9) becomes
II)(non-isogenic
sensitive
from
(dTDPG)
type
BIOPHYSICAL
through
of LPS of (wild
AND
change
strains
glucose
K12 W2252-llU-
Ter-15
is
BIOCHEMICAL
the
E. coli
phaqe cells,
sensitivity, and the
the sugar
phaqe
inactiva-
components
of
the
LPS. Materials and Methods Bacteria : Escherichia coli K12 W2252-llU(thy-,ura-,met-) RCStr (wild type I) and its dTDPG pyrophosphorylase deficient mutant is named Ter-15 (9). Escherichia cozi K12 W2252-llu(thy-,ura-,met-) RCrel (wild type II) and its dTDPG pyrophosphorylase deficient mutant is named Ter-21 (9). Escherichia cozi C strain is used as an indicator for 4x174 phage infection. Phaqe
:
@X174 phaqe,
wild
type.
Chemicals : Uracil (Ura) and thymine (Thy) were purchased mica1 Company, LTD. Casamino acid was from Difco laboratories, U.S.A. Methionine, hexose and pentose and other chemicals Pure Chemical Company, LTD, Japan. Adsorption of $X174 by E. cozi The kinetics of attachment starvation buffer, as detailed
from
PL-BiocheDetroit, were from Wako
K12 and to its Ter-mutant strains to whole bacteria were determined by newbold and Sinsheimer (10).
Inactivation of 41x174 phaqe by LPS from E. coli strains : Bacteria were grown in the synthetic 37OC. The LPS in the outer membrane of E. COli E. coli C (as a control) strains were extracted al (11) and of Westphal et al (12). The 50% inactivation doses (ID50 ; see 13) the residual infectivity after incubation (1 hr amounts of homogenized LPS with 5 X lo4 PFU per of Simmon's medium containing magnesium ion.
: in a
K12 and from its Ter-mutant medium (9) with aeration K12, its Ter-mutant and by the methods of Galanos were estimated at 37OC) of ml starvation
at et
by titrating increasing buffer, or
Isolation and analysis of LPS core oliqosaccharides : The LPS samples were degraded by heating (2 hr at 1OO'C) in 1% aqueous acetic acid, the insoluble and the core oliqosaccharides were lipid A was removed by centrifuqation, chromatoqraphed through Bioqel P2 (14).
1052
Vol. 91, No. 3, 1979
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
The aldose analysis of the core oligosaccharides was carried out on the methyl-sugar derivatives formed after methanolysis with 1 N HCl-methanol for 6 - 8 hr at 1OO'C by gas-liquid chromatography (Shimadsu Gas Chromatograph, model GC 6 AM, column 2 m, 2.6 nunID, OV-17, 2%, chromosorb W, 80 - 100 mesh, chromacarrier gas N2, 60 ml/min, 2 Kg/cm2, Temp. 150°C) and by thin-layer E. Merck AG) with solvent ; chlotography (Silica Gel 60 F254, TLC plates, roform : methanol ( 3 : 1, v/v ). 2-keto-3-deoxymannulosoctonic acid (KDO) was determined by the thiobarbituric acid method of Weissbach and Hurwitz (15), as modified by Osborn
(16)
.
Heptose was determined by the (16). The phosphorous determinations (17).
cysteine-H2SOq
reaction
as modified
by
Osborn al
were
Results The susceptibility 4x174 are
phage
type
coli
to
I)
becomes
K12 (wild
that
the
type
cells.
cell
type
the
the
type
Therefore,
structures tions
have
of cozi
membrane
extracted
the
the
LPS from
and measured
the
inactivity
Table
the
LPS from
LPS from
the
inactivate the
the
mutant
phage.
It
but is
could type)
the
et
the
from
Ter-21
surmised from
a rough
should
wild
derived
cells
the
core
strains
E.
from
from
these
that
of
results
the
wild
or semirough
or "deep-rough"
under
K12
coli
mutant
show altered
type
to
types)
are a smooth
to
cells
Ter mutants (wild
differ
cells
may mutate
of
to Lowry
cell
chenosurface
identical
condi-
growth. reported
that
receptor E.
coli
of
$x174
the
for
and its
K12 (wild phage
Ter-15
E.
type)
related and its
by these
mutant
and parent
The LPS from
$x174
component
LPS.
inactivates
cells
(wild
cozi
C cells
phages.
We 1
Ter-mutant
cells,
The results the
type
of LPS of the
show in
phage, but the
I and II)
as a control
cannot inactivates
phage. Further,
oligosaccharide cells.
Ter-21
insensitive. Ter-mutant
(4) have is
mutant
phage,
those
and its
K12 W2252-llU-
The Ter--15
Ter-mutant
cell
et al
coli
K12 (wild
according
Discussion
to the
cells
with
of exponential
1 that
the
the
compared
cell
is
Ter-mutant
Jazwinski outer
II)
E.
chenotype,
phage.
out
K12 W2252-llU-
1. E.
sensitive
surface If
(18).
4x174
and
coli
shown in Table
non-sensitive
(wild E.
is
of E.
carried
Table
we determined of the
the
LPS from
2 shows that
sugar
nature E.
cozi
residues
1053
of the
sugars
K12 (wild of
the
present
types) core
in the
and the
oligosaccharide
core
Ter-mutant in the
Vol. 91, No. 3, 1979
Table
1.
BIOCHEMICAL
Susceptibility
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
to @X174 phage and inactivation
of 9X174 by LPS.
Bacterial
Lipopoly*Whole cells
Strains E. coli
IU2 (wild
type I)
Ter-15 E. cozi
**saccharides
K12 (wild
+
+
+
+
type II)
Ter-21 E. coli 'i
from
;
the
(+)
Ter-15
E. coli
in the
The LPS from core
( R (rfb)
were
2.
type
same amounts sugar
mutant
termed
residues are different
Ter-15 E. coli K12 (wild type II)
heptose sugars
from
oligo-
those
in
of
lipid
of the
E. coli
in the
and KDO from
the
core,
A
K12
common occurrence
of these
oligosaccharides cells
show that
in the
LPS from
galactose,
glucose,
fractions
from the LPS
Glucose
Ribose
Heptose
1.0
2.2
-
2.2
1.4
1.9
1.0
2.0
-
1.9
1.5
1.9
1.0
2.1
-
2.2
1.3
2.0
2.2
1.0
0.004
0.5
2.6
2.3
-
1.03
1.8
1.7
1.0
LPS
sugar
(21 - 24).
of core
Ter-mutant
Ter-21 C
core
They consist
may be complete
Molar ratios of the components of core of E. coti K12 and its Ter-mutants.
E. cozi K12 (wild type I)
in the
of the
R antigens.
Because
(19,20).
Galactose
as those
II).
which
basal
and its
the
Ter-21
K12 are
of analysis
Bacterial Strains
E. coli
but
galactose,
termed
types)
Table
(wild
) cells
glucose,
The results K12 (wild
the
Kl2
in the
I),
oligosaccharide,
glucosamine, components
type
6. cozi
mutants
( - ) : non-sensitive ( - ) is not inactivated
occur
LPS from
E. coti
LPS from
and the
mutant
K12 (wild
saccharide the
: sensitive, : inactivated,
(+I
l *
LPS from
c
1054
RDO Phosphorus
E. COzi
Vol. 91, No. 3, 1979
heptose II)
and KW are present
and the
ribose
Ter-15
core
from
the
Ter-21
However,
cells,
from
core
of E. of,
tial
complement
which
core
To study
presence
30% of the the
heptose-deficient
mutant
membrane
"heptose-less"
amounts thesis
of the
major
apparently
membrane altered the
of these
cells
filament
From these
membrane
formation
(31,21),
galactosamine,
in other
residue
is
and the galactose
also
the
the
linkage
The structure
phage shown to
may be
in strain
E.
contains
proteins,
of
Ter-21
reduction
in the
of
The 020 antigen
10%
and a substancozi
E.
GR 467,
of the
cell
envelope,
coli
(28).
The outer
the
(29).
reduced
mutation into cells protein
in LPS biosynthe
outer
should
have
fraction,
in contrast
W-irradiation O-antigens
(27).
is not
mutant
is made up of
( 25 -
CR 34,
W-irradiation,
after
upon the
LPS core
of proteins
the
susceptibi-
galactose
drastically
as the
incorporation
after
core
to C21, whereas
from
the
to be important
in its
isolated
of the
C21, depend
of
were
and ribose.
cells,
is
cells.
membrane
05 antigen
mutant
type
outer
found
(14).
mutant
in the
strains
the
Ter-15
was found
present
form
because
Ter-15
in why
the
amount
susceptible
reports,
because
explains
adsorption
type)
specific
galactose
mutants
the
the
glucose,
investigation.
relative
membrane
show an elliptical
D-ribose strains
outer
inhibits
(28,18). outer
cells
wild
heptose
heptose
alterations
from
core
the
sugars
the phage of
I and
can be found
infection,
K12 (wild
the
little is
core
type
cells
heptose
phage
C21 has been
of
has
of heptose,
has only
to
in,
which
from
other
mutants
nor
for
core
now under
with
or a reduction
CR34 (28),
in the
is
the
B. coti
mutant
of these
4x174
of the
from
in the
rough
in addition, coti
core
experiment
COli
to
K12 (wild
Ter-21
is necessary
and glucose that
in the
RESEARCH COMMUNICATIONS
coli
E.
The absence
content
oligosaccharide
From the
27);
core
from
galactose
non-sensitive
as in the
different
but
mutant.
galactose
galactose
core
Neither
in the
as the
between
absence
is
residue
same amount
lity
Ter-21
mutant
galactose
E.
mutant
the
AND BIOPHYSICAL
in the
and KDC are present.
the
the
BIOCHEMICAL
as
to the
(30). 05 and 020 of
E.
3-amino-3,6-dideoxyglucose, also
is
made up of
an
cozi
Vol. 91, No. 3, 1979
galactose
and
glucose,
ribose
mutant poration
differs
ribose,
BIOCHEMICAL
but
the
R-antigen
and KDO. The content from
of D-ribose
that into
AND BIOPHYSICAL
of
Ter-21
mutant
in the
LPS of the
of ribose
in O-antigens the
the
of E.
LPS of E.
COzi
RESEARCH COMMUNICATIONS
coli
and the
are now under
contains Ter-21
mechanism
of
incor-
investigation.
References 1.
2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12.
13. 14. 15. 16. 17. 18. 19. 20. 21. 22. 23. 24. 25. 26. 27. 28. 29. 30. 31.
Sanger,F., Air,G.M., Barrell,B.G., Brown,N.L., Coulson,A.R., Fiddes,J.C., Hutchison III, C.A., Slocombe,P.M. and Smith,M. (1977) Nature 265, 687 - 695. Sinsheimer,R.L. (1968) Progr. Nucl. Acid Res. 8, 115 - 169. Lindbera,A.A. (1973) Annu. Rev. Microbial. 27, 205 - 241. Jazwinski,S.M., Lindberg,A.A. and Kornberg,A. (1975) Virology, 66, 268 - 282. Fujimura,R. and Kaseberg,P. (1962) Biophys. J. 2, 433 - 449. Brown,D.T., Mackenzie,J.M. and Bayer,M E. (1971) J. Virol. 7, 836 - 846. Jazwinski,S.M. and Marco,R (1973) Fed. Proc. 32, 491. Incardona,N.L. and Selvide,L. '1973) J. Virol. 11. 775 - 782. Ohkawa,T. (1976) Europ. J. Biochem. 61, 81 - 91. Newbold J.E. and Sinsheimer.S.L. (1970) J. Virol. '55, 427 - 431. Galanos, C., Liideritz,O. and Westphal,O. (1969) Europ. J. Biochem. 2, 245 - 249. Westphal,O,, Liideritz,O. and Bister,F. (1952) 2. Naturforsch. 76, 148 - 155. Benmer,J. and Dirkx,J. (1960) Ann. Ins. Pasteur (Parie) 98, 910 - 914. Feige,U. and Stirm,S. (1976) Biochem. Biophys. Res. Comm. 71, 566 - 573. Weissbach,A. and Hurwitz,J. (1959) J. Biol. Chem. 234, 7Or709. Osborn,M.J. (1963) Proc. Nat. Acad. Sci. U.S.A. =,x9 - 560. Lowry,O.H., Roberts,N.R., Leiner,K.Y., Wu,M.L. and Farr,A.L. (1954) J. Biol. Chem. 207, 1 - 17. Smit,J., Kamio,Y. and Nikaido,H. (1975) J. Bacterial. 124, 942 - 958. Schmidt,G. (1973) J. Gen. Microbial. E, 151 - 160. Schmidt,G., Jann,B. and Jann,K. (1969) Europ. J. Biochem. lo, 501 - 510. Orskov,I., Orskov,F., Jann,B. and Jann,K. (1977) Bacterial. Rev. 41, 667 - 710. Liideritz,O., Jann,K. and Wheat,R. (1968) Compr. Biochem. z, 105 - 228. Ltideritz,O. Westphal,O., Staub,A.M. and Nikaido,H. (1971) ~145 - 233, In Weinbaum,G., Kadis,S. and Aj1,S.S. ted), Microbial Toxins, Vol. IV. Academic Press Inc., London. Liideritz,O., Galanos,C., Lehmann,V., Nurminen,M., Rietscgel,E., Rosenfelder,G., Simon,M. and Westphal,O. (1973) J. Infec. Dis. 128, (suppl), 9 - 21. Kalcker,H.M., Laursen,P. and Rapin,A.M.C. (1966) Proc. Nat. Acad. Sci. U.S.A. 56, 1852 - 1858. Rapin,A.M.C., Kalcker,H.M. and Alberico,L. (1968) Arch. Biochem. Bio95 - 105. @vs. 128, Schmidt,G., Jann,B. and Jann,K. (1970) Europ. J. Biochem. 16, 382 - 392. Koplow,J. and Goldfine,H. (1974) J. Bacterial. 117, 527 - 543. Rooney,S.A., Goldfine,H. and Sweeley,C.C. (1972) Biochim. Biophys. Acta 289 - 295. 270, Ohkawa,T. (1977) Biochim. Biophys. Acta 476, 190 - 202. Vasilieu,N.N. and Zakharova,I.Y. (1976) Bioorg. Chem. 2, 199 - 206.
1056
BKICHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
14, 1979
Pages
Ter Mutation
and Susceptibility
to @X174 Phage
Tsutomu Department
Received
of Biochemistry, Kanazawa,
October
23,
in E. coli
1051-l
056
K12
Ohkawa
School of Medicine, Ishikawa, Japan
Kanazawa 920
University,
1979
SUMMARY :
The Ter-15 mutant derived from E. coli K12 W2252-lluRCStr (wild type I) is found to be sensitive to $x174 phage infection. Lipopolysaccharide extracted from this mutant inactivates the phage, and has core oligosaccharides identical in amounts to those in the lipopolysaccharide from wild type cells. In contrast, the Ter-21 mutant derived from E. coli K12 W2252-lluRCrel (wild type II) is not sensitive to this phage infection, and its lipopolysaccharide does not inactivate the phage. Its lipopolysaccharide sugars are found to be D-glucose and D-ribose, thus differing from the lipopolysaccharide sugars of the wild type cells. @x174 phage
contains
a single
nucleotides
(1)
in an icosa
From the
reports
of Lindberg
able
to
infect
strains.
the
is
primarily
specific
receptor
binding,
it
releases
the
ved from
sensitive
(7,8).
identified Lindberg
is
strain,
DNA (6).
the
and Kornberg is
of E. coti
be represented
in the
structure
(4),
the
the
on the cell
cells.
wall
purified
of
found
inactivates
the
cell
phage
or semirough
to
4x174
phage
regard
phage
can bind to
to
41x174 phage
(LPS)
deri-
to
for
the
be
$x174
outer
core
Abbreviations used : LPS, lipopolysaccharide ; circular deoxyribonucleic acid ; dTDPG, thymidine KW, 2-keto-3-deoxymannulosoctonic acid.
phage
receptors chain
activity the
the
is
lipopolysaccharides
and showed in the
$x174
(2).
and
receptor that
5375
(5)
the polysaccharide
for
LPS of
With
of
12 particles
smooth
or not
and S. typhinmriwn,
by the
infect
are demonstrated
important
et al
upon whether
the
structure
at the
strain
(4) demonstrated
found
spikes
coli
sites
Further,
cannot
DNA (SS-DNA)
Escherichia
isolated
strains
Also,
but
of the
the
with
(3) and Jazwinski
attachment found
circular
coat
dependent
as crucially
S13 receptor strains
hedral
The susceptibility
infection
phage
rough
strand
in the
LPS is
(3).
Jazwinski,
and the
related
membrane this
this
of
phage
sensitive
binding
and backbone SS-DNA, single 5'-diphosphate
phage
of
site the
to
LPS.
strand glucose
;
0006-291X/79/231051-06$01.00/0 1051
Copyright All rights
@ 1979 by Academic Press, Inc. of reproduction in anyform reserved.
Vol. 91, No. 3, 1979
We are
interested
in resistant dine
coli
in the
and sensitive
5'-diphosphate
precursor
for
synthesis
(wild
mutant type
their
E. cozi
In this
paper,
by the
LPS from
is
cell's
in 9x174
sensitive
type the
nor
its
were
but
its
K12 W2252-llu-
Ter-21
mutant
in the the
as a
phage,
cozi
from
thymi-
Escherichia
9x174
discrepancy
contents
of cells
membrane.
Escherichia I)
infection
in growing
to
extracted
sugar
phage
concentration
formed outer
Neither to
RESEARCH COMMUNICATIONS
decreased
is not
and their
strains
Ter-mutation
wild
types
analyzed
and
in detail
chromatography.
we describe these
the
LPS were
and gas-liquid
occurs
which
To resolve
the
strains,
that
sensitive.
phage.
K12 strains,
Ter mutant
I)
strain
to $x174
by thin-layer
tion
(9) becomes
II)(non-isogenic
sensitive
from
(dTDPG)
type
BIOPHYSICAL
through
of LPS of (wild
AND
change
strains
glucose
K12 W2252-llU-
Ter-15
is
BIOCHEMICAL
the
E. coli
phaqe cells,
sensitivity, and the
the sugar
phaqe
inactiva-
components
of
the
LPS. Materials and Methods Bacteria : Escherichia coli K12 W2252-llU(thy-,ura-,met-) RCStr (wild type I) and its dTDPG pyrophosphorylase deficient mutant is named Ter-15 (9). Escherichia cozi K12 W2252-llu(thy-,ura-,met-) RCrel (wild type II) and its dTDPG pyrophosphorylase deficient mutant is named Ter-21 (9). Escherichia cozi C strain is used as an indicator for 4x174 phage infection. Phaqe
:
@X174 phaqe,
wild
type.
Chemicals : Uracil (Ura) and thymine (Thy) were purchased mica1 Company, LTD. Casamino acid was from Difco laboratories, U.S.A. Methionine, hexose and pentose and other chemicals Pure Chemical Company, LTD, Japan. Adsorption of $X174 by E. cozi The kinetics of attachment starvation buffer, as detailed
from
PL-BiocheDetroit, were from Wako
K12 and to its Ter-mutant strains to whole bacteria were determined by newbold and Sinsheimer (10).
Inactivation of 41x174 phaqe by LPS from E. coli strains : Bacteria were grown in the synthetic 37OC. The LPS in the outer membrane of E. COli E. coli C (as a control) strains were extracted al (11) and of Westphal et al (12). The 50% inactivation doses (ID50 ; see 13) the residual infectivity after incubation (1 hr amounts of homogenized LPS with 5 X lo4 PFU per of Simmon's medium containing magnesium ion.
: in a
K12 and from its Ter-mutant medium (9) with aeration K12, its Ter-mutant and by the methods of Galanos were estimated at 37OC) of ml starvation
at et
by titrating increasing buffer, or
Isolation and analysis of LPS core oliqosaccharides : The LPS samples were degraded by heating (2 hr at 1OO'C) in 1% aqueous acetic acid, the insoluble and the core oliqosaccharides were lipid A was removed by centrifuqation, chromatoqraphed through Bioqel P2 (14).
1052
Vol. 91, No. 3, 1979
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
The aldose analysis of the core oligosaccharides was carried out on the methyl-sugar derivatives formed after methanolysis with 1 N HCl-methanol for 6 - 8 hr at 1OO'C by gas-liquid chromatography (Shimadsu Gas Chromatograph, model GC 6 AM, column 2 m, 2.6 nunID, OV-17, 2%, chromosorb W, 80 - 100 mesh, chromacarrier gas N2, 60 ml/min, 2 Kg/cm2, Temp. 150°C) and by thin-layer E. Merck AG) with solvent ; chlotography (Silica Gel 60 F254, TLC plates, roform : methanol ( 3 : 1, v/v ). 2-keto-3-deoxymannulosoctonic acid (KDO) was determined by the thiobarbituric acid method of Weissbach and Hurwitz (15), as modified by Osborn
(16)
.
Heptose was determined by the (16). The phosphorous determinations (17).
cysteine-H2SOq
reaction
as modified
by
Osborn al
were
Results The susceptibility 4x174 are
phage
type
coli
to
I)
becomes
K12 (wild
that
the
type
cells.
cell
type
the
the
type
Therefore,
structures tions
have
of cozi
membrane
extracted
the
the
LPS from
and measured
the
inactivity
Table
the
LPS from
LPS from
the
inactivate the
the
mutant
phage.
It
but is
could type)
the
et
the
from
Ter-21
surmised from
a rough
should
wild
derived
cells
the
core
strains
E.
from
from
these
that
of
results
the
wild
or semirough
or "deep-rough"
under
K12
coli
mutant
show altered
type
to
types)
are a smooth
to
cells
Ter mutants (wild
differ
cells
may mutate
of
to Lowry
cell
chenosurface
identical
condi-
growth. reported
that
receptor E.
coli
of
$x174
the
for
and its
K12 (wild phage
Ter-15
E.
type)
related and its
by these
mutant
and parent
The LPS from
$x174
component
LPS.
inactivates
cells
(wild
cozi
C cells
phages.
We 1
Ter-mutant
cells,
The results the
type
of LPS of the
show in
phage, but the
I and II)
as a control
cannot inactivates
phage. Further,
oligosaccharide cells.
Ter-21
insensitive. Ter-mutant
(4) have is
mutant
phage,
those
and its
K12 W2252-llU-
The Ter--15
Ter-mutant
cell
et al
coli
K12 (wild
according
Discussion
to the
cells
with
of exponential
1 that
the
the
compared
cell
is
Ter-mutant
Jazwinski outer
II)
E.
chenotype,
phage.
out
K12 W2252-llU-
1. E.
sensitive
surface If
(18).
4x174
and
coli
shown in Table
non-sensitive
(wild E.
is
of E.
carried
Table
we determined of the
the
LPS from
2 shows that
sugar
nature E.
cozi
residues
1053
of the
sugars
K12 (wild of
the
present
types) core
in the
and the
oligosaccharide
core
Ter-mutant in the
Vol. 91, No. 3, 1979
Table
1.
BIOCHEMICAL
Susceptibility
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
to @X174 phage and inactivation
of 9X174 by LPS.
Bacterial
Lipopoly*Whole cells
Strains E. coli
IU2 (wild
type I)
Ter-15 E. cozi
**saccharides
K12 (wild
+
+
+
+
type II)
Ter-21 E. coli 'i
from
;
the
(+)
Ter-15
E. coli
in the
The LPS from core
( R (rfb)
were
2.
type
same amounts sugar
mutant
termed
residues are different
Ter-15 E. coli K12 (wild type II)
heptose sugars
from
oligo-
those
in
of
lipid
of the
E. coli
in the
and KDO from
the
core,
A
K12
common occurrence
of these
oligosaccharides cells
show that
in the
LPS from
galactose,
glucose,
fractions
from the LPS
Glucose
Ribose
Heptose
1.0
2.2
-
2.2
1.4
1.9
1.0
2.0
-
1.9
1.5
1.9
1.0
2.1
-
2.2
1.3
2.0
2.2
1.0
0.004
0.5
2.6
2.3
-
1.03
1.8
1.7
1.0
LPS
sugar
(21 - 24).
of core
Ter-mutant
Ter-21 C
core
They consist
may be complete
Molar ratios of the components of core of E. coti K12 and its Ter-mutants.
E. cozi K12 (wild type I)
in the
of the
R antigens.
Because
(19,20).
Galactose
as those
II).
which
basal
and its
the
Ter-21
K12 are
of analysis
Bacterial Strains
E. coli
but
galactose,
termed
types)
Table
(wild
) cells
glucose,
The results K12 (wild
the
Kl2
in the
I),
oligosaccharide,
glucosamine, components
type
6. cozi
mutants
( - ) : non-sensitive ( - ) is not inactivated
occur
LPS from
E. coti
LPS from
and the
mutant
K12 (wild
saccharide the
: sensitive, : inactivated,
(+I
l *
LPS from
c
1054
RDO Phosphorus
E. COzi
Vol. 91, No. 3, 1979
heptose II)
and KW are present
and the
ribose
Ter-15
core
from
the
Ter-21
However,
cells,
from
core
of E. of,
tial
complement
which
core
To study
presence
30% of the the
heptose-deficient
mutant
membrane
"heptose-less"
amounts thesis
of the
major
apparently
membrane altered the
of these
cells
filament
From these
membrane
formation
(31,21),
galactosamine,
in other
residue
is
and the galactose
also
the
the
linkage
The structure
phage shown to
may be
in strain
E.
contains
proteins,
of
Ter-21
reduction
in the
of
The 020 antigen
10%
and a substancozi
E.
GR 467,
of the
cell
envelope,
coli
(28).
The outer
the
(29).
reduced
mutation into cells protein
in LPS biosynthe
outer
should
have
fraction,
in contrast
W-irradiation O-antigens
(27).
is not
mutant
is made up of
( 25 -
CR 34,
W-irradiation,
after
upon the
LPS core
of proteins
the
susceptibi-
galactose
drastically
as the
incorporation
after
core
to C21, whereas
from
the
to be important
in its
isolated
of the
C21, depend
of
were
and ribose.
cells,
is
cells.
membrane
05 antigen
mutant
type
outer
found
(14).
mutant
in the
strains
the
Ter-15
was found
present
form
because
Ter-15
in why
the
amount
susceptible
reports,
because
explains
adsorption
type)
specific
galactose
mutants
the
the
glucose,
investigation.
relative
membrane
show an elliptical
D-ribose strains
outer
inhibits
(28,18). outer
cells
wild
heptose
heptose
alterations
from
core
the
sugars
the phage of
I and
can be found
infection,
K12 (wild
the
little is
core
type
cells
heptose
phage
C21 has been
of
has
of heptose,
has only
to
in,
which
from
other
mutants
nor
for
core
now under
with
or a reduction
CR34 (28),
in the
is
the
B. coti
mutant
of these
4x174
of the
from
in the
rough
in addition, coti
core
experiment
COli
to
K12 (wild
Ter-21
is necessary
and glucose that
in the
RESEARCH COMMUNICATIONS
coli
E.
The absence
content
oligosaccharide
From the
27);
core
from
galactose
non-sensitive
as in the
different
but
mutant.
galactose
galactose
core
Neither
in the
as the
between
absence
is
residue
same amount
lity
Ter-21
mutant
galactose
E.
mutant
the
AND BIOPHYSICAL
in the
and KDC are present.
the
the
BIOCHEMICAL
as
to the
(30). 05 and 020 of
E.
3-amino-3,6-dideoxyglucose, also
is
made up of
an
cozi
Vol. 91, No. 3, 1979
galactose
and
glucose,
ribose
mutant poration
differs
ribose,
BIOCHEMICAL
but
the
R-antigen
and KDO. The content from
of D-ribose
that into
AND BIOPHYSICAL
of
Ter-21
mutant
in the
LPS of the
of ribose
in O-antigens the
the
of E.
LPS of E.
COzi
RESEARCH COMMUNICATIONS
coli
and the
are now under
contains Ter-21
mechanism
of
incor-
investigation.
References 1.
2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12.
13. 14. 15. 16. 17. 18. 19. 20. 21. 22. 23. 24. 25. 26. 27. 28. 29. 30. 31.
Sanger,F., Air,G.M., Barrell,B.G., Brown,N.L., Coulson,A.R., Fiddes,J.C., Hutchison III, C.A., Slocombe,P.M. and Smith,M. (1977) Nature 265, 687 - 695. Sinsheimer,R.L. (1968) Progr. Nucl. Acid Res. 8, 115 - 169. Lindbera,A.A. (1973) Annu. Rev. Microbial. 27, 205 - 241. Jazwinski,S.M., Lindberg,A.A. and Kornberg,A. (1975) Virology, 66, 268 - 282. Fujimura,R. and Kaseberg,P. (1962) Biophys. J. 2, 433 - 449. Brown,D.T., Mackenzie,J.M. and Bayer,M E. (1971) J. Virol. 7, 836 - 846. Jazwinski,S.M. and Marco,R (1973) Fed. Proc. 32, 491. Incardona,N.L. and Selvide,L. '1973) J. Virol. 11. 775 - 782. Ohkawa,T. (1976) Europ. J. Biochem. 61, 81 - 91. Newbold J.E. and Sinsheimer.S.L. (1970) J. Virol. '55, 427 - 431. Galanos, C., Liideritz,O. and Westphal,O. (1969) Europ. J. Biochem. 2, 245 - 249. Westphal,O,, Liideritz,O. and Bister,F. (1952) 2. Naturforsch. 76, 148 - 155. Benmer,J. and Dirkx,J. (1960) Ann. Ins. Pasteur (Parie) 98, 910 - 914. Feige,U. and Stirm,S. (1976) Biochem. Biophys. Res. Comm. 71, 566 - 573. Weissbach,A. and Hurwitz,J. (1959) J. Biol. Chem. 234, 7Or709. Osborn,M.J. (1963) Proc. Nat. Acad. Sci. U.S.A. =,x9 - 560. Lowry,O.H., Roberts,N.R., Leiner,K.Y., Wu,M.L. and Farr,A.L. (1954) J. Biol. Chem. 207, 1 - 17. Smit,J., Kamio,Y. and Nikaido,H. (1975) J. Bacterial. 124, 942 - 958. Schmidt,G. (1973) J. Gen. Microbial. E, 151 - 160. Schmidt,G., Jann,B. and Jann,K. (1969) Europ. J. Biochem. lo, 501 - 510. Orskov,I., Orskov,F., Jann,B. and Jann,K. (1977) Bacterial. Rev. 41, 667 - 710. Liideritz,O., Jann,K. and Wheat,R. (1968) Compr. Biochem. z, 105 - 228. Ltideritz,O. Westphal,O., Staub,A.M. and Nikaido,H. (1971) ~145 - 233, In Weinbaum,G., Kadis,S. and Aj1,S.S. ted), Microbial Toxins, Vol. IV. Academic Press Inc., London. Liideritz,O., Galanos,C., Lehmann,V., Nurminen,M., Rietscgel,E., Rosenfelder,G., Simon,M. and Westphal,O. (1973) J. Infec. Dis. 128, (suppl), 9 - 21. Kalcker,H.M., Laursen,P. and Rapin,A.M.C. (1966) Proc. Nat. Acad. Sci. U.S.A. 56, 1852 - 1858. Rapin,A.M.C., Kalcker,H.M. and Alberico,L. (1968) Arch. Biochem. Bio95 - 105. @vs. 128, Schmidt,G., Jann,B. and Jann,K. (1970) Europ. J. Biochem. 16, 382 - 392. Koplow,J. and Goldfine,H. (1974) J. Bacterial. 117, 527 - 543. Rooney,S.A., Goldfine,H. and Sweeley,C.C. (1972) Biochim. Biophys. Acta 289 - 295. 270, Ohkawa,T. (1977) Biochim. Biophys. Acta 476, 190 - 202. Vasilieu,N.N. and Zakharova,I.Y. (1976) Bioorg. Chem. 2, 199 - 206.
1056