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Substrate decomposition and product release by ericoid and ectomycorrhizal fungi grown on protein
Agriculture, E c o s y s t e m s and Envlronment, 2 8 (1989) 285-291 Elsevler Science Publishers B.V., Amsterdam Printed in Czechoslovakia
SUBSTRATE DECOMPOSITION AND PRODUCT RELEASE BY
ERICOID AND ECTOMYCORRNIZAL FUNGI GROWN ON PROTEIN
By A.R. LANGDALg and D.J. READ Department of Plant Sciences,
ABST~CT liquid
The e r i c o i d
of
harvests
as the sole
o f one s e t o f c u l t u r e s
exosenous
Sheffield
and an e c t o m y c o r r h i z a l
medium w i t h p r o t e i n
exception
The U n i v e r s i t y ,
glucose.
Dry
f u n g u s were e a c h grown i n
source
of the ericoid
weight
yields
and t h e p r o d u c t s o f p r o t e i n
of nitrogen endophyte,
were
medimm. No amaonimm was d e t e c t e d
the
of
analyses
Results
o f amino a c i d r e l e a s e
protein
utilisation
~NTROD~CTION
It i s known t h a t e r i c o i d
can be t r a n s f e r r e d
Abuzlnadah
tional
significance
protein
breakdown.
(HysenoscYvhue e r i c a e )
sequential
of amino-acids
and
When E. e r i c a e
was grown i n
and g r o w t h c e a s e d and e c o l o g i c a l
discussed.
and t h a t
to infected
f u n g i can
the nitrogen
host plants.
released (Eajwa e_t_t
& Read 1986 a ) .
Because of their
potential
it
to
the
is
The
necessary
pattern
~nd an e c t n -
of
characterise
protein
before
quantitative
and some e c t o m y c o r r h i z a l
as sole source of nitrogen
from t h e a u b s t r a t e a l . 1985,
are briefly
the
Growth o f b o t h
was c o m p l e t e . The p h y s i o l o g i c a l
of these observations
protein
at
in these cultures
ammonium was r e l e a s e d
complications
utilise
measured
qualitative
are presented.
the absence of exogenous glucose before
of
with
in the presence
to the release
into the culture
growth.
and,
breakdown d e t e r m i n e d .
fungi in the presence of glucose led rapidly
termination
S10 2TN, UK
utilisation
by
(Hebeloma c r u s t u l i n i f o r m e )
nutri-
products an
of
ericold
mycorrhizal
2 86 fungus has now been examined protein
breakdown
and the identities
have been determined
of the major products of
in H. crustullniforme
using HPLC
analysis of sequentially harvested culture filtrates.
MATERIALS
AND METHODS
temperature
Both
on a basal
fungi were grown in liquid culture
medium
(full
strength
MMN,
minus
at room
yeast
extract,
plus lOg glucose litre -1) in which the pure protein bovine serum albumin (BSA)
- M.W.
Three
replicate
tlme
determined
protein.
67,000.
N content
cultures by
the
the sole source of nitrogen.
of each
fungus were harvested
pattern
of
fungal
growth
at set points in
and
utilisation
of
The culture solutions were aseptically filtered by millipore and
the funsal yield was determined c o n c e n t r a t i o n of t h e f i l t r a t e Chemical
16% - was
Company) and
the
derivatisation
w i t h 0PA.
after
protein
residual
by oven drying at 80"C.
Total
protein
was measured u s i n g Coomassie r e a g e n t
(Pierce
amino-acid
content
determined
by HPLC a f t e r
Ammonium was d e t e r m i n e d u s i n g M e s s l e r ' s
had been removed w i t h 10Z TCA.
reagent
The above e x p e r i -
ment was r e p e a t e d w i t h ~. e r i c a e but u s i n g m o d i f i e d HNN w i t h o u t g l u c o s e .
RESULTS
A. H v l e n o m c ~ h u s e r i c a e
The a b i l i t y
of the e r i c o i d
s o u r c e was c o n f i r m e d . over the f i r s t
rate days.
declined
in
of
the
inoculation,
protein
quantities
solution
by
but
protein
this
4,
but
remained, their
rapidly
growth b e i n g a s s o c i a t e d (Fig. i ) .
Growth
breakdown c o n t i n u e d u n t i l ,
of s u b s t r a t a day
as a s o l e N
fungus increased
of a p p r o x i m a t e l y 50Z of t h e p r o t e i n
from 8 days
negligible
detectable
Dry w e i g h t y i e l d
e i g h t days a f t e r
with the u t i l i s a t i o n
e n d o p h y t e to u t i l i s e
by 24
Free amino a c i d s were
concentration
increased
287
markedly as growth slowed from day 12 up to day 24 at which point there was,
for the first time, a decline.
This decline may be attributable to
the fact that protein levels at this stage were no longer sufficient to support growth.
Free ammonium was not detected at any stage during the
development of the cultures.
In medium,
NH4*
the it
absence being
reached
of
first
free
glucose,
detected
after
18 ~g m1-1 by 12 d a y s .
ammonium was 4 days of
At t h i s
incubation.
stage
glucose
to
these
ammonium and a f u r t h e r
B. Mebeloma
(i)
fall
led
to
complete
protein
crustuliniforme f u n g u s were
fall
in p r o t e i n was
utilisation
and
protein
b o t h slow o v e r t h e
A s u r g e of growth
fungus
of
the
free
amino
utilisation
first
40
utillsed.
days.
they
were
in
release
the
by
H.
ectomycorrhisal
24 days f o l l o w i n g i n o c u l a t i o n
(Fig.
d u r i n g which a p p r o x i m a t e l y 70Z of t h e added
This
Thereafter that
being
growth of t h e f u n g u s .
acid
from 24 to 48 days was a s s o c i a t e d w i t h a d r a m a t i c
concentration
s h a r p l y which s u g g e s t s protein
of
Subsequent addition
utiilsation
fall
coincided
with
c o n c e n t r a t i o n of f r e e amino a c i d s in t h e c u l t u r e at
Levels
in p r o t e i n c o n c e n t r a t i o n .
Growth and
2).
peak
the
crustuliniforne
Growth,
protein
cultures
into
growth of the
c e a s e d and o n l y 25Z of t h e p r o t e i n had been u t i l i s e d . of
released
the in
used
quantity
the as
of
a
sharp
solution.which free
amino
a b s e n c e of s i g n i f i c a n t
a substrate
Trace q u a n t i t i e s
increase
to
support
acid
reached a declined
quantities the
in
of
continuing
of ammonium were d e t e c t e d
in the
solution only after 56 days by which time growth of the fungus has ceased.
:~88
H twic~lt
22. -~ 20. -~gO - ®
,
i
,IlO - ..o- i
~
I
1./..
.~o~
1.0.
3G
06 O.;b /,
II
IZ
16
20
Z&
"~
:t
--~ 2.Z. •-~ 110 2,G [ --
~o~
,oo.
.¢S
IJI-
co.
.:zo
EG •
SO.
o~
/,0-
.ZO.~
O6-
30-
-'~ .(
0~-
20-
.lO U
02-
1056
e~,
7'2
'CO
r~,~ Ida,/v, !
Fig. 1
Dry w e i g h t y i e l d , erlcae nitrogen
2rowing source.
protein in
liquid
utilisation culture
and amino a c i d r e l e a s e with
protein
as
sole
by H.
exogenous
289
I
20-
16~ 12J O.~' 0.60.4~
~
~
~o
~
iT
t, 1.2-
.,~
io-
| °"0,6-
3O-
Ok,,-
20=
0.2-
108
16
26
~
40
gb
~
72
80
r,me (OWsl
Fig. 2
Dry weight yield, protein utiiisation and amino acid release by H. crustuliniforme
growing
exogenous nitrogen source.
in liquid
culture
with
protein
as sole
290
(ii)
S p e c t r u m o f amino a c i d s
Growth o f
the
solution,
fourteen
concentration
fungus led of
of lost
to
in culture the
release
which c o u l d
amino a c i d s i n c r e a s e d utilisation
concentration.
the
absent,
Analysis
AA's
over
suggested
and l y s i n e
of
of
the
that
indlvidual
two
aspartlc
after
acids
into
only 8 days.
The
w i t h t i m e , up to
of t h e amlno a c i d s r e d u c e d t h e i r levels
saaples
acid,
were b e i n g s e l e c t i v e l y
aliuo
progressively
proportional
final
o f H. c r u s t u l l n i f o r m e .
be i d e n t i f i e d
a r o u n d 56 d a y s . S u b s e q u e n t l y ,
individual
filtrate
during
glutamic
of
reduction
of
which
protein
was
acid,
arginlne,
slanine
absorbed to support continued growth of
the fungus.
DISCUSSION
In qualitative acid release growth
of
teras
the pattern
by t h e two t y p e s
both
leads
which is associated
to
of aycorrhizal
a decline
In neither
or
breakdown when g l u c o s e
rates
of protein
fungus is
with rather
carbon
present
host
that
plant,
in
the
into
the culture
p r o d u c t o f growth medium.
condition it
aeeus
Both
of azino acid release
the nature
in deteruinlng
Since in the sycorrh~zal by t h e i r
acids
The
a process
than in the ecto aycorrhizal
revealed
t o t h e f u n g u s p l a y s a key r o l e
concentration,
asmoniua a significant is
and o f amino
fungus are comparable.
of free alino
in the ericold
The s t u d y o f ~. e r i c a e
utilisation
protein
breakdown and t h e q u a n t i t i e s
h o w e v e r , Much g r e a t e r
released.
in
with the release
solution. protein
of protein
the are,
fungus.
of the carbon supply
w h e t h e r or n o t a m o n i u n fungi are norsally lost
t h a n ammoniua w i l l be t h e p r o d u c t o f p r o t e i n
likely
that
is
supplied aaino-acid
breakdown i n n a t u r e .
291
It
is evident
assimilate
from t h e s e r e s u l t s
both of the fungi r e l e a s e and
amino acids when grown on a proteinaceous
observation
is potentially
carbon n u t r i t i o n
of t h e
mycorrhizsl
of great
significance
fungus and h o s t ,
n i t r o g e n c y c l i n g in s o i l .
involving
that
substrate.
for the nitrogen
as well as for
the process
and
and of
The s t u d y i s b e i n g e x t e n d e d to o t h e r s p e c i e s of
fungi and to aseptically synthesised mycorrhizal pine
This
birch
so that the
full implication
associations
of this newly
revealed pattern of nitrogen turnover can be ascertained.
REFERENCES
BAJWA. R.. ABUARGHUB. S. and READ. D.J. (1985). The Biology of Mycorrhiza in
the
Ericaceae.
mycorrhiza]
The p r o d u c t i o n
of
proteolytic
endophyte and by m y c o r r h i z a l p l a n t s .
enzymes by
the
New P h y t o l o g i s t .
101, p 469-486.
ABUZINADAH.
R.A. and READ. D.J. (1986).
nitrogen nutrition peptides
of
and p r o t e i n s
The role of proteins
ectomycorrhizal plants. by e c t o m y c o r r h i z a l
fungi.
I.
in the
Utillsation
of
New P h y t o l o g i s t .
103. 481-493.
Langdale, A.R. and Read, D.J., 1989: S u b e t r a t e d e c o m p o s i t i o n and p r o d u c t r e l e a s e by ericoid and e o t o m y c o r r h i z a l fungi g r o w n on protein. Agric., E c o s y s t e m s Environ., 28: 285-291.
SUBSTRATE DECOMPOSITION AND PRODUCT RELEASE BY
ERICOID AND ECTOMYCORRNIZAL FUNGI GROWN ON PROTEIN
By A.R. LANGDALg and D.J. READ Department of Plant Sciences,
ABST~CT liquid
The e r i c o i d
of
harvests
as the sole
o f one s e t o f c u l t u r e s
exosenous
Sheffield
and an e c t o m y c o r r h i z a l
medium w i t h p r o t e i n
exception
The U n i v e r s i t y ,
glucose.
Dry
f u n g u s were e a c h grown i n
source
of the ericoid
weight
yields
and t h e p r o d u c t s o f p r o t e i n
of nitrogen endophyte,
were
medimm. No amaonimm was d e t e c t e d
the
of
analyses
Results
o f amino a c i d r e l e a s e
protein
utilisation
~NTROD~CTION
It i s known t h a t e r i c o i d
can be t r a n s f e r r e d
Abuzlnadah
tional
significance
protein
breakdown.
(HysenoscYvhue e r i c a e )
sequential
of amino-acids
and
When E. e r i c a e
was grown i n
and g r o w t h c e a s e d and e c o l o g i c a l
discussed.
and t h a t
to infected
f u n g i can
the nitrogen
host plants.
released (Eajwa e_t_t
& Read 1986 a ) .
Because of their
potential
it
to
the
is
The
necessary
pattern
~nd an e c t n -
of
characterise
protein
before
quantitative
and some e c t o m y c o r r h i z a l
as sole source of nitrogen
from t h e a u b s t r a t e a l . 1985,
are briefly
the
Growth o f b o t h
was c o m p l e t e . The p h y s i o l o g i c a l
of these observations
protein
at
in these cultures
ammonium was r e l e a s e d
complications
utilise
measured
qualitative
are presented.
the absence of exogenous glucose before
of
with
in the presence
to the release
into the culture
growth.
and,
breakdown d e t e r m i n e d .
fungi in the presence of glucose led rapidly
termination
S10 2TN, UK
utilisation
by
(Hebeloma c r u s t u l i n i f o r m e )
nutri-
products an
of
ericold
mycorrhizal
2 86 fungus has now been examined protein
breakdown
and the identities
have been determined
of the major products of
in H. crustullniforme
using HPLC
analysis of sequentially harvested culture filtrates.
MATERIALS
AND METHODS
temperature
Both
on a basal
fungi were grown in liquid culture
medium
(full
strength
MMN,
minus
at room
yeast
extract,
plus lOg glucose litre -1) in which the pure protein bovine serum albumin (BSA)
- M.W.
Three
replicate
tlme
determined
protein.
67,000.
N content
cultures by
the
the sole source of nitrogen.
of each
fungus were harvested
pattern
of
fungal
growth
at set points in
and
utilisation
of
The culture solutions were aseptically filtered by millipore and
the funsal yield was determined c o n c e n t r a t i o n of t h e f i l t r a t e Chemical
16% - was
Company) and
the
derivatisation
w i t h 0PA.
after
protein
residual
by oven drying at 80"C.
Total
protein
was measured u s i n g Coomassie r e a g e n t
(Pierce
amino-acid
content
determined
by HPLC a f t e r
Ammonium was d e t e r m i n e d u s i n g M e s s l e r ' s
had been removed w i t h 10Z TCA.
reagent
The above e x p e r i -
ment was r e p e a t e d w i t h ~. e r i c a e but u s i n g m o d i f i e d HNN w i t h o u t g l u c o s e .
RESULTS
A. H v l e n o m c ~ h u s e r i c a e
The a b i l i t y
of the e r i c o i d
s o u r c e was c o n f i r m e d . over the f i r s t
rate days.
declined
in
of
the
inoculation,
protein
quantities
solution
by
but
protein
this
4,
but
remained, their
rapidly
growth b e i n g a s s o c i a t e d (Fig. i ) .
Growth
breakdown c o n t i n u e d u n t i l ,
of s u b s t r a t a day
as a s o l e N
fungus increased
of a p p r o x i m a t e l y 50Z of t h e p r o t e i n
from 8 days
negligible
detectable
Dry w e i g h t y i e l d
e i g h t days a f t e r
with the u t i l i s a t i o n
e n d o p h y t e to u t i l i s e
by 24
Free amino a c i d s were
concentration
increased
287
markedly as growth slowed from day 12 up to day 24 at which point there was,
for the first time, a decline.
This decline may be attributable to
the fact that protein levels at this stage were no longer sufficient to support growth.
Free ammonium was not detected at any stage during the
development of the cultures.
In medium,
NH4*
the it
absence being
reached
of
first
free
glucose,
detected
after
18 ~g m1-1 by 12 d a y s .
ammonium was 4 days of
At t h i s
incubation.
stage
glucose
to
these
ammonium and a f u r t h e r
B. Mebeloma
(i)
fall
led
to
complete
protein
crustuliniforme f u n g u s were
fall
in p r o t e i n was
utilisation
and
protein
b o t h slow o v e r t h e
A s u r g e of growth
fungus
of
the
free
amino
utilisation
first
40
utillsed.
days.
they
were
in
release
the
by
H.
ectomycorrhisal
24 days f o l l o w i n g i n o c u l a t i o n
(Fig.
d u r i n g which a p p r o x i m a t e l y 70Z of t h e added
This
Thereafter that
being
growth of t h e f u n g u s .
acid
from 24 to 48 days was a s s o c i a t e d w i t h a d r a m a t i c
concentration
s h a r p l y which s u g g e s t s protein
of
Subsequent addition
utiilsation
fall
coincided
with
c o n c e n t r a t i o n of f r e e amino a c i d s in t h e c u l t u r e at
Levels
in p r o t e i n c o n c e n t r a t i o n .
Growth and
2).
peak
the
crustuliniforne
Growth,
protein
cultures
into
growth of the
c e a s e d and o n l y 25Z of t h e p r o t e i n had been u t i l i s e d . of
released
the in
used
quantity
the as
of
a
sharp
solution.which free
amino
a b s e n c e of s i g n i f i c a n t
a substrate
Trace q u a n t i t i e s
increase
to
support
acid
reached a declined
quantities the
in
of
continuing
of ammonium were d e t e c t e d
in the
solution only after 56 days by which time growth of the fungus has ceased.
:~88
H twic~lt
22. -~ 20. -~gO - ®
,
i
,IlO - ..o- i
~
I
1./..
.~o~
1.0.
3G
06 O.;b /,
II
IZ
16
20
Z&
"~
:t
--~ 2.Z. •-~ 110 2,G [ --
~o~
,oo.
.¢S
IJI-
co.
.:zo
EG •
SO.
o~
/,0-
.ZO.~
O6-
30-
-'~ .(
0~-
20-
.lO U
02-
1056
e~,
7'2
'CO
r~,~ Ida,/v, !
Fig. 1
Dry w e i g h t y i e l d , erlcae nitrogen
2rowing source.
protein in
liquid
utilisation culture
and amino a c i d r e l e a s e with
protein
as
sole
by H.
exogenous
289
I
20-
16~ 12J O.~' 0.60.4~
~
~
~o
~
iT
t, 1.2-
.,~
io-
| °"0,6-
3O-
Ok,,-
20=
0.2-
108
16
26
~
40
gb
~
72
80
r,me (OWsl
Fig. 2
Dry weight yield, protein utiiisation and amino acid release by H. crustuliniforme
growing
exogenous nitrogen source.
in liquid
culture
with
protein
as sole
290
(ii)
S p e c t r u m o f amino a c i d s
Growth o f
the
solution,
fourteen
concentration
fungus led of
of lost
to
in culture the
release
which c o u l d
amino a c i d s i n c r e a s e d utilisation
concentration.
the
absent,
Analysis
AA's
over
suggested
and l y s i n e
of
of
the
that
indlvidual
two
aspartlc
after
acids
into
only 8 days.
The
w i t h t i m e , up to
of t h e amlno a c i d s r e d u c e d t h e i r levels
saaples
acid,
were b e i n g s e l e c t i v e l y
aliuo
progressively
proportional
final
o f H. c r u s t u l l n i f o r m e .
be i d e n t i f i e d
a r o u n d 56 d a y s . S u b s e q u e n t l y ,
individual
filtrate
during
glutamic
of
reduction
of
which
protein
was
acid,
arginlne,
slanine
absorbed to support continued growth of
the fungus.
DISCUSSION
In qualitative acid release growth
of
teras
the pattern
by t h e two t y p e s
both
leads
which is associated
to
of aycorrhizal
a decline
In neither
or
breakdown when g l u c o s e
rates
of protein
fungus is
with rather
carbon
present
host
that
plant,
in
the
into
the culture
p r o d u c t o f growth medium.
condition it
aeeus
Both
of azino acid release
the nature
in deteruinlng
Since in the sycorrh~zal by t h e i r
acids
The
a process
than in the ecto aycorrhizal
revealed
t o t h e f u n g u s p l a y s a key r o l e
concentration,
asmoniua a significant is
and o f amino
fungus are comparable.
of free alino
in the ericold
The s t u d y o f ~. e r i c a e
utilisation
protein
breakdown and t h e q u a n t i t i e s
h o w e v e r , Much g r e a t e r
released.
in
with the release
solution. protein
of protein
the are,
fungus.
of the carbon supply
w h e t h e r or n o t a m o n i u n fungi are norsally lost
t h a n ammoniua w i l l be t h e p r o d u c t o f p r o t e i n
likely
that
is
supplied aaino-acid
breakdown i n n a t u r e .
291
It
is evident
assimilate
from t h e s e r e s u l t s
both of the fungi r e l e a s e and
amino acids when grown on a proteinaceous
observation
is potentially
carbon n u t r i t i o n
of t h e
mycorrhizsl
of great
significance
fungus and h o s t ,
n i t r o g e n c y c l i n g in s o i l .
involving
that
substrate.
for the nitrogen
as well as for
the process
and
and of
The s t u d y i s b e i n g e x t e n d e d to o t h e r s p e c i e s of
fungi and to aseptically synthesised mycorrhizal pine
This
birch
so that the
full implication
associations
of this newly
revealed pattern of nitrogen turnover can be ascertained.
REFERENCES
BAJWA. R.. ABUARGHUB. S. and READ. D.J. (1985). The Biology of Mycorrhiza in
the
Ericaceae.
mycorrhiza]
The p r o d u c t i o n
of
proteolytic
endophyte and by m y c o r r h i z a l p l a n t s .
enzymes by
the
New P h y t o l o g i s t .
101, p 469-486.
ABUZINADAH.
R.A. and READ. D.J. (1986).
nitrogen nutrition peptides
of
and p r o t e i n s
The role of proteins
ectomycorrhizal plants. by e c t o m y c o r r h i z a l
fungi.
I.
in the
Utillsation
of
New P h y t o l o g i s t .
103. 481-493.
Langdale, A.R. and Read, D.J., 1989: S u b e t r a t e d e c o m p o s i t i o n and p r o d u c t r e l e a s e by ericoid and e o t o m y c o r r h i z a l fungi g r o w n on protein. Agric., E c o s y s t e m s Environ., 28: 285-291.