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Fractionation of nucleic acids from dormant and germinated Azotobacter cysts
Vol. 35, No. 5, 1969
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
FRACTIONATION
OF NUCLEIC ACIDS FROM DORMANT AZOTOBACTER CYSTS* Karl
Department
Received
E.
of at
Olson
and
Microbiology, Austin, Austin,
Orville
AND GERMINATED
Wyss
The University Texas 78712
of
Texas
May 5, 1969
Summary. Chromatography of nucleic acid extracts of Azotobacter vinelandii cysts and of phased germinated cysts was performed using methylated albumin-kieselguhr(MAK) columns. After 4 hours germination, DNA and ribosomal RNA peaks are seen to elute at higher NaCl concentrations than those of dormant cysts. The elution profile of transfer RNA did not change during cyst germination. Kvidence is presented which suggests that shifts in elution profiles are due to changes in nucleic acid configuration during the process of germination. This evidence may indicate an additional mechanism for cyst survival in a deleterious environment. The
normal
encapsulated homogeneous (1961),
through over
termed
a cyst.
in
The
the
The
vegetative physical
Parker
and
Socolofsky
(1966)
central
Wyss,
body
investigation nation process. differences
Lin
the
and
nucleic
was
to
have of
1968),
monitor the
of the
is
the
*This investigation was supported grant ~1-02830-10 and training Institutes of Health.
acids
acids which of
713
results
been
are
Wyss,
well 1962). of
several 1967;
Olson
documented
purpose during
indicates
by Public Health grant GM 00600-09
a
properties
no
dormant
of
medium.
Wyss,
there is
cyst
have
various
The
by
the
and
and
there cyst.
replica
a growth
cysts
(Olson
nucleic
presented
nucleic
in
Although
cysts
transcell
surrounded of
on
cyst. of
is
resting
Socolofsky
reported
the
Sadoff,
cell
is
of
1961;
Socolofsky
spherical
8 hours
properties
acids
Evidence between
6 to
Wyss,
composition
19681 on
which
thick
a fairly
and
a spherical
Germination
after
resistant and
concerning
research
body,
and
Neumann
a compact,
structure.
long,
wall
vegetative
into
central
(Socolofsky
isolated
reports
and
the
5 days of
cell
a rather
cell
by Wyss,
consists
coat
is
a thin
process
4 to
cyst
cell
with
described
stage of
cell,
documented
and
a four
double-layered
a normal
the
As
a period
vegetative
dense
vegetative rod
cytoplasm.
formed the
Azotobacter gram-negative
of the
the cyst
present germi-
qualitative
and
germinating
Service from the
research National
cysts
Vol. 35, No. 5, 1969
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
METHODS Organism.
A.
studies
for
were
grown
1952)
at
obtained as
the
the
in
Burk's
nitrogen-free
33 C with
0.5%
by
at
growth
carbon
ATCC 12837, of vegetative
vinelandii, production
cells
Cysts
Germination.
Phased
pensions
was
using
methods
reported
by
obtained
broth
33 C for
placed
15 minutes.
on a rotary
intervals
was
filter. viable
diluent
as
of
24
per
9 to
10 days3
dormant
of
temperature
the
ml
1 C for
was
then
added
At
and
were
at
zero
cyst and in
the
and
were Smith
dilution
growth
followed
at
and
optical
with
no.42
Wyss
(1969),
with
Burk's
and
Burk's
was
half-hour
removed
method
on
sterile
culture
calorimeter of
Wyss
50 minutes and
susshift
Lin
placed
time
culture
the
hours
with
(1965)
report
by
Cysts were 0,2$ n-butanol
washed
held
the
the
made
after
of
a Klett-Summerson
with were
after
Knight,
18 hours.
33 C.
at
with
counts
harvested
cysts
and
samples
accordance
cell
broth
shaker
recorded
In
medium
Vedehina
Sucrose
thereafter,
density
107
sucrose
and
source.
agar
germination
1 x
without
(Wilson
carbon
a modification and
organism used in these and cysts. Cells
broth
the
at
Zaitseva
Approximately
(1965). Burk's
were
collected
Phased
by
as
33 C on Burk's
were
the cells
salts
sucrose
source.
vegetative
was
with
agar
0.576
sucrose. Nucleic
Acid
7.5 hours
and
4,6,
Isolation.
nucleic
acid
nation,
suspensions
collected
Total from
by
suspended
at were
coat central 0.15M
two
final were the
plus
shaking was
tion with dissolved
of
and
washed
buffer
(pH
frozen
Burk's
ensure
25mM
The
pellet
of
maximum the
and bodies Tris
15 minutes, by
washed were
tris(hydroxy-
1 mg per lysis
After
mild of
and
then carried
of of
the
sodium
lauryl
shaking,
lyoozyme. the
central
sulfate the
EDTA + in 40 ml
nucleic
body to
a
acids
equal
volumes
Gierer
and
Schramm
(1.956).
After
of 95% ethyl 5OmM sodium phosphate
alcohol, buffer
the
final
precipitate
was
(pH
6.3),
containing
O.lM
714
liquefied
ml of
cyst
released
twice in O.lM then suspended
with of
germi-
was
pellet
0,2, stop
medium,
rupture
complete
addition
2.0%.
salts
acid(EDTA)
to
0.2M
during
4 C in
7.4).
at To
cultures.
intervals
at
extracted
with
3 volumes in
cyst time
centrifugation,
4 ml
for
obtained
concentration method
over
was then resuspended pH 8.0. The central
buffer
extracted
germinating
cycles
Following
bodies NaCl at
suspension
were
5mM ethylenediaminetetraacetic freeze-thaw
mild
acids
various
poured
(Tris)
structure.
EDTA-NaCl After
the
centrifugation
in
through
phased
synthesis
methyl)aminomethane
nucleic
phenol according to the third precipita-
Vol. 35, No. 5, 1969
NaCl. of
In
25
MAK
all
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
experiments
optical
density
were
eluted
from 0.3 to 1.2M Twelve fractions tration man
units
columns(Sueoka
acids
approximately
and
at
and
Cheng,
under
mild
NaCl in of 3 ml
1 mg nucleic
255mp) 1962)
air
was at
applied
room
pressure
absorption
in
was
to
(a
2.0
manner
buffer each
measured
at
7.5
cm
Nucleic
a stepwise for
total
by
temperature.
50mM sodium phosphate each were collected
ultraviolet
acid
with
(pH 6.3). saline concen-
255rnr-I
in
a Beck-
DU spectrophotometer. RESULTS In
with iments The
order
to
regard
to
were
of
are by
an
viable
after
addition
viable sky
obtain
in
of
counts the
cell
counts. with
carbon
the The
observed in
microscope
earlier
to
a cyst
of
cells
at
cell
of
counts
6 and
9 hours
made
with
with
were
Wyss,
culture. as deter-
correlation
observations
observations
of
double
close
events exper-
described
number
Direct
were
cellular
germination,
previously
total
source.
chamber Phase
the
was
random cyst
germination
utilizing 1.
than
during
phased
Fig.
counting
rather
synthesis
experiment
cell
Petroff-Hauser agreement
to
presented
mined
sequential acid
designed
results
method
obtain
nucleic
in
Neumann
a
the
close
and
Socolof-
(1961).
J 5 s;
8.5
CELLS-o0.0.
6.0
i
r
o
Fig. were then Viable cell
-*-
2
4
6
8
IO HOURS
12
14
16
24
1. Phased germination of Azotobacter cysts. Cyst cultures phased by the temperature shift method: 1 C for 50 minutes 33 C for 15 minutes, followed by the addition of sucrose. and direct cell c.>unts reveale, a two-fold increase in numbers at 6 and 9 hours. Extracts
illustrated elution
in patterns
of
dormant
cysts
Fig. 2. (Midgley
Other and
had
a nucleic
bacterial McCarthy, 715
acid
r- ,stems 1962).
elution exhibit Peaks
pattern I,
similar III and
a IV
A 0.0
_
I DORMANT
//
CYSTS
1.0
/
2
g N
0.0
0.6
f 3
0.6
;
0.4
I
I
1
I
20
40
60
00
I
0.2
1
100
FRACTION
GERMINATED 4.0
CYSTS
HOURS
20
40
60
00
100
FRACTION C o.O
_
DOAMAN 1
CYSTS
--c
4 HAS. GERMINATION 2
0.6
---
/
.A
/
z
0
I 20
I 40
/ ”
I
-
pq
1
1.0
-0.0
z
’
I 00
I 100
0.2
FRA&ON Fig. 2. Elution patterns (from MAK columns) of nucleic acids extracted from dormant cysts (A) and 4 hour germinated cysts (B) Nucleic acids were determined by absorbance at 255 rnp. In these patterns, peak I represents sRNA; peak II, DNA; peak III, 16~ rRNAJ peak IV, 23s rRNA; and peak V, unidentified RNAJ 0, sodium chloride gradient. Peaks II, III and IV exhibited a shift in elution pattern after 4 hours germination as seen in graph C which is a composite of graphs A and B.
716
Vol. 35, No. 5, 1969
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
contained
RRA and
minations
by
the
minations
by
either
1956)
(Keck, other
16s
Similar
elution
hour
intervals
each
interval
separate
the
and
This while
method
were
extracted
and
the
When it
was
peaks
concentration
is II,
and
results that than
III than
peaks the
in
Fig.
and IV elute the analogous
II,
III
analogous Peak
at found
least be
culture
elutes
at
in and
IV
1962). at
acids
to
and IV peaks I
shown III
extracted Nucleic
a 4 hour
2.
been
Cheng,
at approximately peak from dormant
A _
and
reaction
peaks
samples
were
from
DNA deter-
has
chromatographed
did
illustrated
It
germination.
acids
noticed
for
obtained
nucleic
concentrations finding
of
RNA deter-
Ceriotti
RNA and
(Sueoka
obtained
start
the
(1968). transfer
respectively
by
1957) and of
Burton
were the
revealed
modification
contains
RNA,
after
DNA as (Schneider,
of I
patterns
times
tographed,
Keck
peak
23s
reproducible, saline
contained method
the
that
contain
II
orcinol
or
systems
peak
2 from
three closely were
chroma-
eluted at higher 0 and 2 hours. at
0.6M
saline
O.lM higher saline cysts, Nucleic
B PEAK I
2b
40
8OC-25
MIN
20
4.0
0.8
FRACTION
Ic 0.6 -1
0 PEAK
m
n
SOC-
25MIN
_
E" z 0.4 N 2 p 0.2
0.8 0 z"
0
0
,0.6 80
100
80
100
FRACTION
Fig. 3. Co-chromatography (from MAK columns) of pooled fractions from analogous peaks of dormant cyst and 7.5 hour germinated cyst nucleic acid extracts, Peak I eluted at 0.6M NaCl before and after heating (A,B). Peak IV eluted as two distinct peaks prior to heating (C), but only one peak was detected after heating the pooled fractions (D).
717
Vol. 35, No. 5, 1969
acid
extracts
log-phase
from in
significant Fig.
2,
at
tative
cell
no
fifth
profiles
were
lowing
experiments
analogous arations
are
heated
at
these
a single and
80
C for was
this
in
and
peak
I
as
from
and
folthe
results
prep-
of
of
two
fractions As
results in
elution
a
distinct
differences
pooled
cysts
peak. in
cyst
Detection
chromatographed.
illustrated
vegethere
this
germinated
configurational
Identical
in
the
The
were
rewere
seen
then
in
obtained
germinated
in
first
containing
hour
Similar
25 minutes detected.
of
configuration,
3.
Fig.
that
seen
and
changes
fractions
no
RNA but
character that
When were
was
contain
chromatographed.
presented
manner,
IV, hours
7.5
and
patterns.
although
in
peak
7.5
to
and
As
after
in The
cysts
contention
elution
peak III,
behave
the
there
6 and and
differences
again
profiles.
hypothesis
performed.
and
experiment in
of
dormant
pooled
supported
sulted
II
from
were
typical
result
elution profiles.
found
nature
a working
were
peaks
at
V was
the
with
the
eluted
cultures
employed,
elution
appeared
concerning
conjunction
were
various
Peak
cyst
similar
which
also
preparations.
information In
the
peak, and
germinated
procedure in
4 hours
hour
exhibited
extraction
a small
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
7.5
cells
the
differences
detected
peaks
6 and
4,
vegetative
variations
is
BIOCHEMICAL
cysts
3,
Fig. for
peaks
did
not
3.
Fig.
DISCUSSION The in
an
Azotobacter
Parker
and
The
cyst.
the
nucleic
of
the
central
period,
yet
of
nation various
cyst
can
coat
to
of
structure
is
properties
communication adapt
survive
studies
resistance
this
also
than
the
undergoes it
of
suggests
the
that
conditions
in
the
of
elute
4S
a
were
detected.
elution
a one from
does pooled After 718
not
6 to
dormant change and heating
cysts in
and
re-chromatographed, the
been cysts
DNA and
saline
elution
pooled
germi-
and
the
higher
form-
have
cysts
4 hours, step
The
this
8 hour
profiles dormant
nuclear
formation.
during
the
After at
peaks
RNA peak
during
the
cyst
compaction
from
germination. to
peaks were
MAR column extracte-d
analogous
The
size
(1961),
during
from in
acids seen
Socolofsky
compaction
increases
during
and
decreases
Changes
analogous peaks
Neumann
body
nucleic
times
cysts.
Wyss,
cell
RNA are
tration
distinct
the
from
ribosomal
When
by
process.
detected
nated
may
the
and
in
which The
environment. observed
material
at
that
survival
cyst
cell
growth.
indicate
the
the
resting
normal
presented
of
As
ative
for
for
evidence
acids
deleterious
a unique
(1966)
responsible
the
is
unsuitable
Socolofsky
primarily
size
cyst
environment
concen-
2 hour
germi-
pattern. two fractions,
Vol. 35, No. 5, 1969
only
BIOCHEMICAL
one peak was apparent.
time under
mild
acid
conditions
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Heating
the nucleic
acids
has been observed
for
a short
by Bock (1967)
rupture a small number of the hydrogen bonds. It is suggested our findings that rupture of hydrogen bonds unique to the cyst
to from DNA
and ribosomal RNA occurs, which results in a configuration similar to those of vegetative cells and late germinated cysts. These results suggest that during the encystment process and subsequent compaction of the central body and nuclear material, the configuration of the DNA and ribosomal RNA is modified. Such a change in configuration protecting the nucleic terious environment.
could contribute a survival advantage by acids from possible denaturation in a deleThe transfer RNA did not exhibit this effect
suggesting
somewhat smaIler
that
these
molecules
are not modified
during the encystment process. Change in elution profiles in other bacterial systems have also been attributed to changes in configuration, quite possibly in the secondary and/or tertiary structure of the polynucleotide chains (Kaji and Tanaka, 1967; Stern, Zutra and Littauer, 1969). Stafford and Donnellan (1968) have reported photochemical evidence for differences spore and vegetative cell DNA. eluting
in the configuration
The detection, after 4 hours germination, after the 23s RNA peak is of interest.
of
of a small peak This peak is an RNA
peak and may represent messenger RNA. Doi and Igarashi (1964) studied spore messenger RNA fractions and these were found to elute after the 23s RNA. Failure to detect this peak prior to 4 hours germination may indicate low messenger RNA content in the dormant cyst and during early germination. The results of our investigation indicate that in addition to the survival advantage conferred by the protective cyst coat structure, other advantageous events may occur during cyst formation. Changes in nucleic acid configuration in conjunction with central body compaction may also represent an additional survival mechanism. Such changes in the intracellular environment may enhance the ability of the cyst to survive in a deleterious external environment. Quantitative changes in the nucleic acida during the germination process will be reported in a future communication.
REFERENCES Bock, R.M. 1967. In Methods in Enzymology, 218, Academic Press, Inc., New York. 719
Vol.
XII,
Part
A,
Vol. 35, No. 5, 1969
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
In Methods in Enzymology, Vol. XII, Part B, Press, Inc., New York. Doi, R.H. and Igarashi, R.T. 1964. Proc. Nat. Acad. Sci. 52,755. 177,702. Gierer, A. and Schramm, G. 1956. .Nature H. and Tanaka, Y. 1967. Biochim. Biophys. Acta =,642. Kaji, Keck, K. 1956. Arch. Biochem. Biophys. 6~~446. Lin, L. and Wyss, 0. 1965. Tex. Rep. Biol. Med. 2J,474. Lin, L. and Sadoff, H.L. 1968. J. Bacterial. %,2336. Midgley, J,E,M, and McCarthy, B-J, 1962. Biochim. Biophys. Acta Burton,
K. 1968. 163 > Academic
61,696. Olson, K-E. and Wyss, 0, 1967. Tex. J. Science 1 ,433. Olson, K.E. and Wyss, 0. 1968. Bacterial. Proc. -38,22. Parker, L.T. and Socolofsky, M.D. 1966. J. Bacterial. $0,297. Schneider, W.C. 1957. In Methods in Enzymology, Vol. III, 680. Academic Press, Inc., New York. Smith, D-D, and Wyss, 0. 1969. Antonie van Leeuwenhoek ,84. Socolofsky, M.D. and Wyss, 0. 1961. 3. Bacterial. f&94 F . Socolofsky, M.D. and Wyss, 0. 1962. J. Bacterial. 84,119. Stafford, R.S. and Donnellan, J.E. 1968. Proc. Nat. Acad. Sci.
2,822.
R., Zutra, L.E. and Littauer, U.2, 1969. Biochem. 8,313. N. and Cheng, T,Y+ 1962. J. Mol. Biol. 4,161. P.W. and Knight, S.G. 1952. Experiments in Bacterial Physioloa. Burgess Publishing Co., Minneapolis. Wyss, O., Neumann, M.G. and Socolofsky, M.D. 1961. J. Biophys. Biochem. Cytol. 2,555. G.N. and Vedenina, I.Ya. 1965. Microbiol.(DSSR) 2,945. Zaitseva, (English translation). Stern, Sueoka, Wilson,
720
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
FRACTIONATION
OF NUCLEIC ACIDS FROM DORMANT AZOTOBACTER CYSTS* Karl
Department
Received
E.
of at
Olson
and
Microbiology, Austin, Austin,
Orville
AND GERMINATED
Wyss
The University Texas 78712
of
Texas
May 5, 1969
Summary. Chromatography of nucleic acid extracts of Azotobacter vinelandii cysts and of phased germinated cysts was performed using methylated albumin-kieselguhr(MAK) columns. After 4 hours germination, DNA and ribosomal RNA peaks are seen to elute at higher NaCl concentrations than those of dormant cysts. The elution profile of transfer RNA did not change during cyst germination. Kvidence is presented which suggests that shifts in elution profiles are due to changes in nucleic acid configuration during the process of germination. This evidence may indicate an additional mechanism for cyst survival in a deleterious environment. The
normal
encapsulated homogeneous (1961),
through over
termed
a cyst.
in
The
the
The
vegetative physical
Parker
and
Socolofsky
(1966)
central
Wyss,
body
investigation nation process. differences
Lin
the
and
nucleic
was
to
have of
1968),
monitor the
of the
is
the
*This investigation was supported grant ~1-02830-10 and training Institutes of Health.
acids
acids which of
713
results
been
are
Wyss,
well 1962). of
several 1967;
Olson
documented
purpose during
indicates
by Public Health grant GM 00600-09
a
properties
no
dormant
of
medium.
Wyss,
there is
cyst
have
various
The
by
the
and
and
there cyst.
replica
a growth
cysts
(Olson
nucleic
presented
nucleic
in
Although
cysts
transcell
surrounded of
on
cyst. of
is
resting
Socolofsky
reported
the
Sadoff,
cell
is
of
1961;
Socolofsky
spherical
8 hours
properties
acids
Evidence between
6 to
Wyss,
composition
19681 on
which
thick
a fairly
and
a spherical
Germination
after
resistant and
concerning
research
body,
and
Neumann
a compact,
structure.
long,
wall
vegetative
into
central
(Socolofsky
isolated
reports
and
the
5 days of
cell
a rather
cell
by Wyss,
consists
coat
is
a thin
process
4 to
cyst
cell
with
described
stage of
cell,
documented
and
a four
double-layered
a normal
the
As
a period
vegetative
dense
vegetative rod
cytoplasm.
formed the
Azotobacter gram-negative
of the
the cyst
present germi-
qualitative
and
germinating
Service from the
research National
cysts
Vol. 35, No. 5, 1969
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
METHODS Organism.
A.
studies
for
were
grown
1952)
at
obtained as
the
the
in
Burk's
nitrogen-free
33 C with
0.5%
by
at
growth
carbon
ATCC 12837, of vegetative
vinelandii, production
cells
Cysts
Germination.
Phased
pensions
was
using
methods
reported
by
obtained
broth
33 C for
placed
15 minutes.
on a rotary
intervals
was
filter. viable
diluent
as
of
24
per
9 to
10 days3
dormant
of
temperature
the
ml
1 C for
was
then
added
At
and
were
at
zero
cyst and in
the
and
were Smith
dilution
growth
followed
at
and
optical
with
no.42
Wyss
(1969),
with
Burk's
and
Burk's
was
half-hour
removed
method
on
sterile
culture
calorimeter of
Wyss
50 minutes and
susshift
Lin
placed
time
culture
the
hours
with
(1965)
report
by
Cysts were 0,2$ n-butanol
washed
held
the
the
made
after
of
a Klett-Summerson
with were
after
Knight,
18 hours.
33 C.
at
with
counts
harvested
cysts
and
samples
accordance
cell
broth
shaker
recorded
In
medium
Vedehina
Sucrose
thereafter,
density
107
sucrose
and
source.
agar
germination
1 x
without
(Wilson
carbon
a modification and
organism used in these and cysts. Cells
broth
the
at
Zaitseva
Approximately
(1965). Burk's
were
collected
Phased
by
as
33 C on Burk's
were
the cells
salts
sucrose
source.
vegetative
was
with
agar
0.576
sucrose. Nucleic
Acid
7.5 hours
and
4,6,
Isolation.
nucleic
acid
nation,
suspensions
collected
Total from
by
suspended
at were
coat central 0.15M
two
final were the
plus
shaking was
tion with dissolved
of
and
washed
buffer
(pH
frozen
Burk's
ensure
25mM
The
pellet
of
maximum the
and bodies Tris
15 minutes, by
washed were
tris(hydroxy-
1 mg per lysis
After
mild of
and
then carried
of of
the
sodium
lauryl
shaking,
lyoozyme. the
central
sulfate the
EDTA + in 40 ml
nucleic
body to
a
acids
equal
volumes
Gierer
and
Schramm
(1.956).
After
of 95% ethyl 5OmM sodium phosphate
alcohol, buffer
the
final
precipitate
was
(pH
6.3),
containing
O.lM
714
liquefied
ml of
cyst
released
twice in O.lM then suspended
with of
germi-
was
pellet
0,2, stop
medium,
rupture
complete
addition
2.0%.
salts
acid(EDTA)
to
0.2M
during
4 C in
7.4).
at To
cultures.
intervals
at
extracted
with
3 volumes in
cyst time
centrifugation,
4 ml
for
obtained
concentration method
over
was then resuspended pH 8.0. The central
buffer
extracted
germinating
cycles
Following
bodies NaCl at
suspension
were
5mM ethylenediaminetetraacetic freeze-thaw
mild
acids
various
poured
(Tris)
structure.
EDTA-NaCl After
the
centrifugation
in
through
phased
synthesis
methyl)aminomethane
nucleic
phenol according to the third precipita-
Vol. 35, No. 5, 1969
NaCl. of
In
25
MAK
all
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
experiments
optical
density
were
eluted
from 0.3 to 1.2M Twelve fractions tration man
units
columns(Sueoka
acids
approximately
and
at
and
Cheng,
under
mild
NaCl in of 3 ml
1 mg nucleic
255mp) 1962)
air
was at
applied
room
pressure
absorption
in
was
to
(a
2.0
manner
buffer each
measured
at
7.5
cm
Nucleic
a stepwise for
total
by
temperature.
50mM sodium phosphate each were collected
ultraviolet
acid
with
(pH 6.3). saline concen-
255rnr-I
in
a Beck-
DU spectrophotometer. RESULTS In
with iments The
order
to
regard
to
were
of
are by
an
viable
after
addition
viable sky
obtain
in
of
counts the
cell
counts. with
carbon
the The
observed in
microscope
earlier
to
a cyst
of
cells
at
cell
of
counts
6 and
9 hours
made
with
with
were
Wyss,
culture. as deter-
correlation
observations
observations
of
double
close
events exper-
described
number
Direct
were
cellular
germination,
previously
total
source.
chamber Phase
the
was
random cyst
germination
utilizing 1.
than
during
phased
Fig.
counting
rather
synthesis
experiment
cell
Petroff-Hauser agreement
to
presented
mined
sequential acid
designed
results
method
obtain
nucleic
in
Neumann
a
the
close
and
Socolof-
(1961).
J 5 s;
8.5
CELLS-o0.0.
6.0
i
r
o
Fig. were then Viable cell
-*-
2
4
6
8
IO HOURS
12
14
16
24
1. Phased germination of Azotobacter cysts. Cyst cultures phased by the temperature shift method: 1 C for 50 minutes 33 C for 15 minutes, followed by the addition of sucrose. and direct cell c.>unts reveale, a two-fold increase in numbers at 6 and 9 hours. Extracts
illustrated elution
in patterns
of
dormant
cysts
Fig. 2. (Midgley
Other and
had
a nucleic
bacterial McCarthy, 715
acid
r- ,stems 1962).
elution exhibit Peaks
pattern I,
similar III and
a IV
A 0.0
_
I DORMANT
//
CYSTS
1.0
/
2
g N
0.0
0.6
f 3
0.6
;
0.4
I
I
1
I
20
40
60
00
I
0.2
1
100
FRACTION
GERMINATED 4.0
CYSTS
HOURS
20
40
60
00
100
FRACTION C o.O
_
DOAMAN 1
CYSTS
--c
4 HAS. GERMINATION 2
0.6
---
/
.A
/
z
0
I 20
I 40
/ ”
I
-
pq
1
1.0
-0.0
z
’
I 00
I 100
0.2
FRA&ON Fig. 2. Elution patterns (from MAK columns) of nucleic acids extracted from dormant cysts (A) and 4 hour germinated cysts (B) Nucleic acids were determined by absorbance at 255 rnp. In these patterns, peak I represents sRNA; peak II, DNA; peak III, 16~ rRNAJ peak IV, 23s rRNA; and peak V, unidentified RNAJ 0, sodium chloride gradient. Peaks II, III and IV exhibited a shift in elution pattern after 4 hours germination as seen in graph C which is a composite of graphs A and B.
716
Vol. 35, No. 5, 1969
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
contained
RRA and
minations
by
the
minations
by
either
1956)
(Keck, other
16s
Similar
elution
hour
intervals
each
interval
separate
the
and
This while
method
were
extracted
and
the
When it
was
peaks
concentration
is II,
and
results that than
III than
peaks the
in
Fig.
and IV elute the analogous
II,
III
analogous Peak
at found
least be
culture
elutes
at
in and
IV
1962). at
acids
to
and IV peaks I
shown III
extracted Nucleic
a 4 hour
2.
been
Cheng,
at approximately peak from dormant
A _
and
reaction
peaks
samples
were
from
DNA deter-
has
chromatographed
did
illustrated
It
germination.
acids
noticed
for
obtained
nucleic
concentrations finding
of
RNA deter-
Ceriotti
RNA and
(Sueoka
obtained
start
the
(1968). transfer
respectively
by
1957) and of
Burton
were the
revealed
modification
contains
RNA,
after
DNA as (Schneider,
of I
patterns
times
tographed,
Keck
peak
23s
reproducible, saline
contained method
the
that
contain
II
orcinol
or
systems
peak
2 from
three closely were
chroma-
eluted at higher 0 and 2 hours. at
0.6M
saline
O.lM higher saline cysts, Nucleic
B PEAK I
2b
40
8OC-25
MIN
20
4.0
0.8
FRACTION
Ic 0.6 -1
0 PEAK
m
n
SOC-
25MIN
_
E" z 0.4 N 2 p 0.2
0.8 0 z"
0
0
,0.6 80
100
80
100
FRACTION
Fig. 3. Co-chromatography (from MAK columns) of pooled fractions from analogous peaks of dormant cyst and 7.5 hour germinated cyst nucleic acid extracts, Peak I eluted at 0.6M NaCl before and after heating (A,B). Peak IV eluted as two distinct peaks prior to heating (C), but only one peak was detected after heating the pooled fractions (D).
717
Vol. 35, No. 5, 1969
acid
extracts
log-phase
from in
significant Fig.
2,
at
tative
cell
no
fifth
profiles
were
lowing
experiments
analogous arations
are
heated
at
these
a single and
80
C for was
this
in
and
peak
I
as
from
and
folthe
results
prep-
of
of
two
fractions As
results in
elution
a
distinct
differences
pooled
cysts
peak. in
cyst
Detection
chromatographed.
illustrated
vegethere
this
germinated
configurational
Identical
in
the
The
were
rewere
seen
then
in
obtained
germinated
in
first
containing
hour
Similar
25 minutes detected.
of
configuration,
3.
Fig.
that
seen
and
changes
fractions
no
RNA but
character that
When were
was
contain
chromatographed.
presented
manner,
IV, hours
7.5
and
patterns.
although
in
peak
7.5
to
and
As
after
in The
cysts
contention
elution
peak III,
behave
the
there
6 and and
differences
again
profiles.
hypothesis
performed.
and
experiment in
of
dormant
pooled
supported
sulted
II
from
were
typical
result
elution profiles.
found
nature
a working
were
peaks
at
V was
the
with
the
eluted
cultures
employed,
elution
appeared
concerning
conjunction
were
various
Peak
cyst
similar
which
also
preparations.
information In
the
peak, and
germinated
procedure in
4 hours
hour
exhibited
extraction
a small
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
7.5
cells
the
differences
detected
peaks
6 and
4,
vegetative
variations
is
BIOCHEMICAL
cysts
3,
Fig. for
peaks
did
not
3.
Fig.
DISCUSSION The in
an
Azotobacter
Parker
and
The
cyst.
the
nucleic
of
the
central
period,
yet
of
nation various
cyst
can
coat
to
of
structure
is
properties
communication adapt
survive
studies
resistance
this
also
than
the
undergoes it
of
suggests
the
that
conditions
in
the
of
elute
4S
a
were
detected.
elution
a one from
does pooled After 718
not
6 to
dormant change and heating
cysts in
and
re-chromatographed, the
been cysts
DNA and
saline
elution
pooled
germi-
and
the
higher
form-
have
cysts
4 hours, step
The
this
8 hour
profiles dormant
nuclear
formation.
during
the
After at
peaks
RNA peak
during
the
cyst
compaction
from
germination. to
peaks were
MAR column extracte-d
analogous
The
size
(1961),
during
from in
acids seen
Socolofsky
compaction
increases
during
and
decreases
Changes
analogous peaks
Neumann
body
nucleic
times
cysts.
Wyss,
cell
RNA are
tration
distinct
the
from
ribosomal
When
by
process.
detected
nated
may
the
and
in
which The
environment. observed
material
at
that
survival
cyst
cell
growth.
indicate
the
the
resting
normal
presented
of
As
ative
for
for
evidence
acids
deleterious
a unique
(1966)
responsible
the
is
unsuitable
Socolofsky
primarily
size
cyst
environment
concen-
2 hour
germi-
pattern. two fractions,
Vol. 35, No. 5, 1969
only
BIOCHEMICAL
one peak was apparent.
time under
mild
acid
conditions
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Heating
the nucleic
acids
has been observed
for
a short
by Bock (1967)
rupture a small number of the hydrogen bonds. It is suggested our findings that rupture of hydrogen bonds unique to the cyst
to from DNA
and ribosomal RNA occurs, which results in a configuration similar to those of vegetative cells and late germinated cysts. These results suggest that during the encystment process and subsequent compaction of the central body and nuclear material, the configuration of the DNA and ribosomal RNA is modified. Such a change in configuration protecting the nucleic terious environment.
could contribute a survival advantage by acids from possible denaturation in a deleThe transfer RNA did not exhibit this effect
suggesting
somewhat smaIler
that
these
molecules
are not modified
during the encystment process. Change in elution profiles in other bacterial systems have also been attributed to changes in configuration, quite possibly in the secondary and/or tertiary structure of the polynucleotide chains (Kaji and Tanaka, 1967; Stern, Zutra and Littauer, 1969). Stafford and Donnellan (1968) have reported photochemical evidence for differences spore and vegetative cell DNA. eluting
in the configuration
The detection, after 4 hours germination, after the 23s RNA peak is of interest.
of
of a small peak This peak is an RNA
peak and may represent messenger RNA. Doi and Igarashi (1964) studied spore messenger RNA fractions and these were found to elute after the 23s RNA. Failure to detect this peak prior to 4 hours germination may indicate low messenger RNA content in the dormant cyst and during early germination. The results of our investigation indicate that in addition to the survival advantage conferred by the protective cyst coat structure, other advantageous events may occur during cyst formation. Changes in nucleic acid configuration in conjunction with central body compaction may also represent an additional survival mechanism. Such changes in the intracellular environment may enhance the ability of the cyst to survive in a deleterious external environment. Quantitative changes in the nucleic acida during the germination process will be reported in a future communication.
REFERENCES Bock, R.M. 1967. In Methods in Enzymology, 218, Academic Press, Inc., New York. 719
Vol.
XII,
Part
A,
Vol. 35, No. 5, 1969
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
In Methods in Enzymology, Vol. XII, Part B, Press, Inc., New York. Doi, R.H. and Igarashi, R.T. 1964. Proc. Nat. Acad. Sci. 52,755. 177,702. Gierer, A. and Schramm, G. 1956. .Nature H. and Tanaka, Y. 1967. Biochim. Biophys. Acta =,642. Kaji, Keck, K. 1956. Arch. Biochem. Biophys. 6~~446. Lin, L. and Wyss, 0. 1965. Tex. Rep. Biol. Med. 2J,474. Lin, L. and Sadoff, H.L. 1968. J. Bacterial. %,2336. Midgley, J,E,M, and McCarthy, B-J, 1962. Biochim. Biophys. Acta Burton,
K. 1968. 163 > Academic
61,696. Olson, K-E. and Wyss, 0, 1967. Tex. J. Science 1 ,433. Olson, K.E. and Wyss, 0. 1968. Bacterial. Proc. -38,22. Parker, L.T. and Socolofsky, M.D. 1966. J. Bacterial. $0,297. Schneider, W.C. 1957. In Methods in Enzymology, Vol. III, 680. Academic Press, Inc., New York. Smith, D-D, and Wyss, 0. 1969. Antonie van Leeuwenhoek ,84. Socolofsky, M.D. and Wyss, 0. 1961. 3. Bacterial. f&94 F . Socolofsky, M.D. and Wyss, 0. 1962. J. Bacterial. 84,119. Stafford, R.S. and Donnellan, J.E. 1968. Proc. Nat. Acad. Sci.
2,822.
R., Zutra, L.E. and Littauer, U.2, 1969. Biochem. 8,313. N. and Cheng, T,Y+ 1962. J. Mol. Biol. 4,161. P.W. and Knight, S.G. 1952. Experiments in Bacterial Physioloa. Burgess Publishing Co., Minneapolis. Wyss, O., Neumann, M.G. and Socolofsky, M.D. 1961. J. Biophys. Biochem. Cytol. 2,555. G.N. and Vedenina, I.Ya. 1965. Microbiol.(DSSR) 2,945. Zaitseva, (English translation). Stern, Sueoka, Wilson,
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