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Genetical analysis of the efficiency of VA mycorrhiza with spring wheat
Agriculture, Ecosystems and Environment¢ 29 (1989) 273-280 Elsevier Science Publishers B.V., Amste~dam Printed in Czechoslovakia
Genetical
Analysis
of
the
Efficiency
o f V& N y c o r r h i z a
with
SpringWheat G. G.B. HANSKE
Institute for Tropical and Subtropical Crop Science and ~'unal ~Nime at the University of ~ t t i n ~ , Grisebachstr. 6, D-3400 ~ttingen Abstract
The e f f i c i e n c y of VAH depends not only upon the ~nvironmental c o n d i t i o n s but a l s o on the genotype of the host p l a n t . In a pot experiment with a s t e r i l i z e d , P d e f i c i e n t , P - f i x i n g s o i l 22 High f i e l d i n g V a r i e t i e s ~RYVs) and 22 Landraces and wild forms (LHs) of wheat ( T r i t i c u m s s p . ) were i n o c u l a t e d with the m y c o r r b i z a l fungus ~lomus maniboti$ and compared with non-ino,:ulated c o n t r o l plants.Two different P-fertilizer forms were t e s t e d : s o l u b l e m~nocalcium phosphate (MCP) and iron phosphate (FePO4).VAN showed a higher e f f i c i e n c y under P d e f i c i e n c y (FePO~) with most of the Las than with HYVs. The e f f i c i e n t wild v a r i e t y Triticum aestivum rotundatum and the African HYV 'Huanca' were crossed r e c i p r o c a l l y . Chromosomal h e r e d i t y of the YAH e f f i c i e n c y could be okserved. With N C P - f e r t i l i zation d i f f e r e n c e s between the r e c i p r o c a l F~ i n d i c a t e d a l s o p l a s m a t i c e f f e c t s . Introduction nesearch on the g e n e t i c c o n t r o l
of root-microorganism i n t e r a c t i o n s ,
with m y c o r r b i z a l fungi,
r a r e (Krishna et al. 1985, Jensen 1985, Krishna
is still
especially
and Williams 1987).But the VA m y c o r r h i z a l (VAM) mycelium can form the m a j o r i t y of the s o i l m i c r o b i a l biomass ( a ~ a n p a r t i c u l a r l y well i n f e c t e d in f i e l d l i z e r and p e s t i c i d e
a~plioation
from h a r d l y s o l u b l e , relevant fixati~,
for
plant
soil-borne production
1978) and r o o t s of c u l t i v a t e d p l a n t s are s o i l s ,it~, e i t h e r no or low mineral f e r t i -
( S t e f f a n 1985).
VAN can improve the P uptake
or applied P compounds. This i s p a r t i c u l a r l y on d i f f i c u l t
soils
with
a high
such as the acid l a t : , s o l s with high A1 and Fe contents
the humid t r o p i c s and the l l k a l i n e ,
P fertilizer p r e v a l e n t in
calcareous s o i l s of the s u b t r o p i c s
(~oawad
1979). VAN e f f i c i e n c y seems :o depend r o t only upon environmental c o n d i t i o n s an~ e f f i c i e n c y of the VAM fungus but a l s o on the genotype of the host p l a n t a l . 1979,
Sieverdina
cultivars
with
little
1980). need
This i s of
important
fertilizer.
In
for the
the
breeding
of
work d e s c r i b e d
(Gra, et low-input here
the
i n h e r i t a n c e of VA mycorrhizal e f f i c i e n c y in spring wheat has-been i n v e s t i g a t e d .
274
N a t e r i a l s and Netbods Wheat plants were grown in plastic pots containing 2 kg of soil in a greeruhouso under natural sunlight. 1he soil was o:eposed of a P-deficient and P-fixinq, sandy forest soil, with high contents of M, l~t and Fe, mixed with quartz sand in the proportion of 1:1, and limed with CaCO~to 1~ 5.5 . This IM has proved best for the Vl ~corrhizal bingos used, ~Z~vs run.otis, whLch is a very e f f i c i ~ t strain. Before application of the P f o r ~ the soil substrate m sterilized by heat. Two sources of phosphorus with different solubilities were tested, hardly soluble i r ~ phesphate (Fel~) and easily soluble nmocalcium phosphate (IRP), 30 mg P kg-s dry soil. Basic nutrients, s~ficient to eli~nate all nutrient deficiencies except P, were applied in soluti~ after germination. Nycorrhizal inorulum consisted of strorqly infected root pieces of D~torium o~ratum, a tropical, obligatorily e ~ c o t ~ c herb, which were placed wrier the geminating wheat seed. 7he plants were harvested at ~ilk-ripe stage of the grains. Root length was measured by the gridline intersect math0d (Neeman 1966). The roots were stained (PhiliDs and Havman 1970) and placed on a Petri dish under a binocular:The infection rate was ansessed according to the subjective estimation method used in breedL'q prngrans" for mildew resistance in wheat. This is the only possible w~ to investigate VA nvcerrhizal infection in roots of a large number of plants with such an extensive root s ~ t m . The infection rate represents the proportion of root length infected by Vl m~orrhizal fungus. The total infected root length was calculated by multiplying infection rate with root length. Re~esentative sas~les of pmdered straw and ear material lere ashed in ~SO4-Se (~ch and 14bavad 19"~?). P contents ~ r e measured i~tometrically by the vanedate-yellow method (l(umies 1955). P uptake mars P concentration x dry weight.lhe screening ~ t . m conducted in m r 1985 and the ~..~rison of the P and F, generations in m r 1986. TWnt~-t,o High Yielding Varieties and 22 Landraces or wild form were investigated. Results
The $creenina All
44
wheat
varieties
manibotiB. The e f f e c t fertility
conditions
of
were i n f e c t e d
by
the
the symbiosis v a r i e d
(NCP).
The N C P - f e r t i l i z e d
higher dry weights than F e P O 4 - f e r t i l i z e d p l a n t s .
Vk s y c o r r h i z a l under low plants
fungus
Glomu$
(FePO~) and high P
yielded
3 to
5 times
The high l e v e l of a v a i l a b l e P
in the NCP treatments r a i s e d a l s o P c o n c e n t r a t i o n and P uptake ( T a b . l ) . P D e f i c i e n t Conditions (FeP04) Ear and shoot dry weight were increased by ~. manihotis under P - d e f i c i e n t conditions
(FePO4). The uninproved
varieties
(LRs) showed a higher VA mycorrhizal
e f f i c i e n c y (N/NN in ~). The m a j o r i t y of the LRs ranged in t h e i r VA mycorrhizal e f f i c i e n c y of ear dry weight above 130~o 20-30~ more than the mean of the HYVs ( F i g . l ) . But the very high N/NN r a t i o of some LRs was in many cases c o r r e l a t e d with an extremely poor plant growth without VAn, i n d i c a t i n g a high mycorrhizal dependency. The symbiosis
increased
the ear
m~re than
the
shoot
dry w e i g h t
( F i g . l ) , and s i g n i f i c a n t i n c r e a s e s of the shoot dry weights by YAM could only be
2?5
found i n LRs. The e a r p r o p o r t i o n of the HYVs was h i g h e r than of the LRs, but with VAM the LRs could reach t h e l e v e l of HYVs ( T a b . l ) . HYVs were s h o r t e r than LRs, which produced g r e a t e r r o o t l e n g t h than HYVs on average. HYVs showed l e s s v a r i a t i o n i n r o o t l e n g t h and p l a n t h e i g h t than LRs. There were no d i f f e r e n c e s in t h e i n f e c t i o n r a t e of G. maniboti$ between HYVs and LRs on t h e a v e r a g e , but some p r i m i t i v e wheats were more s t r o n g l y i n f e c t e d (above 70q). B~cause of t h e i r g r e a t e r r o o t l e n g t h s t h e LRs showed g r e a t e r i n f e c t e d root l e n g t h . There was no
c o r r e l a t i o n s between VA m y c o r r h i z a l e f f i c i e n c y in terms of
shoot d r y weight and e i t h e r
infection rate
or t o t a l
infected root
l e n g t h . VA~
i n c r e a s e d the P c o n c e n t r a t i o n and P uptake in e a r s and shoot~ in gYVs as well as in LRs. Because of
the g r e a t e r
yield increase
in LRs t h e i r
ear
and shoot P
uptake exceeded t h a t of the HYVs ( T a b . l ) . High P F e r t i l i t y
C o n d i t i o n s (NCP)
The VAM fungus Glomu$ maniboti$ i n f e c t e d wheat r o o t s well fed with P due to NCP f e r t i l i z a t i o n , especially
p o o r l y , when p l a n t s were
and VAN showed p a r a s i t i c
effects,
( T a b . l ) . Eighteen HYVs and s i x LRs showed s i g n i f i c a n t p a r a s i t i s m in
r e s p e c t of shoot dry weight by YAM. I n h e r i t a n c e of
the VA M v c o r r h i z a l E f f i c i e n c y i n a R e c i n r o c a l Cross between an
E f f i c i e n t and N o n - E f f i c i e n t V a r i e t y ~ r l t i c u m aestivum rotUndatum (ro)
(a V A ~ - e f f i c i e n t v a r i e t y }
and 'Huanca'
(Hu)
( n o n - e f f i c i e n t ) were r e c i p r o c a l l y c r o s s e d to o b t a i n seeds f o r the comparison of the P and F: g e n e r a t i o n s . In t h i s and shoot d r y m a t t e r s latter
c a s e in c o n t r a s t
both p a r e n t a l v a r i e t i e s
experiment ~lomus manihotis i n c r e a s e d the e a r
with FePO4 f e r t i l i z a t i o n
as
w e l l as with HCP, in the
t o 1985 where the same fungus a c t e d p a r a s i t i c a l l y
in
(Fig.2).
The w i l d form T. as. rotundatum (ro) y i e l d e d i e s s without YAM than t h e A f r i c a n HYV 'Huanca'(Hu) and both F t s . But ro showed a ~trong p o s i t i v e y i e l d r e s p o n s e to the
symbiosis,
resulting
in
the
highest
~!AM e f f i c i e n c y
for
all
factor
c o m b i n a t i o n s . In the FePO4-treatment the m y c o r r h i z a l e f f i c i e n c y , e s p e c i a l l y f o r
2?6
ear dry weight, was much greater with ro than with Hu and could be transf~rr~:]
by r e c i p r o c a l crossing ~o the n o n - e f f i c i e n t HYV. The e f f i c i e n c y of the F~ rang,.4 between t h a t of the p a r e n t s ,
but the a b s o l u t e dry weight values s u r p a s s e d those
of both parents (Fig.2-Fe?O4) The effect of the inoculation .as different in the MCP treatments. Here only in the case of Hu x ro the M/~M in ~ values of ear and shoot dry weight lay between the low efficiency of Hu and the high of ro (Fig.2-MCP). The non-inoculated ro x Hu - plants
grew very
well,
with
the consequence
that
increase by VAN was low. The better shoot growth of r o x
the
relative
yield
Hu corresponded .it~
the better root growth and higher P-uptake of this hybrid in the uninoculated FePO4
treatment. The significant
differences
in VAM efficiency
indicate that
both chromosomal and pl&smatic genes are involved in the inheritance of the VAM efficiency in .heat (Tab.l).
Differences betveen 22 High Yielding Varieties (IWVs) and 23 landraces (l/bs) of spring wheat in several parmeters, ~ u ~ l a t e d ~ and inocolated ~) ~ t h the Vk s ~ r b i z a l f~gus ~/cms mm~ot~s and fertilized ~th FePO~ or m0oocalcium pb~phate (NCP). * si~LfJJmnt differe~es bergen ]m and Mfor LSD 5~ Ear dr~ weight (mg/pot) FePOq MCP ~m M ax x HYVs LRs LSD 5q LSD 5~
Shoot dry weight (eg/pot) FePO4 NCP NM M NM M
384 ~31 2040* 1307 348 504* 1769 1561 95
205
n
1026
1064
1257" 3533* 3063
3431. 2324
FePO4 KCP M NM M
37 34
377
132
40 60* 56 40* 50 52
3,4
5 4
295
Shoot P - c o n c e n t r a t i o n (mg P/g dry weight) FePO4 MOP NH
LSD 5~ LSD 5~1
(~)
1017
159
HYVs LRs
Ear proportion
3,3 3,3
M
NH
H
4,4" 8,0 "8,0 4,9" 7,8 8,3 0,5
n.s. 0,7
Shoot P uptake (mg P/ pot) FePO4 MCP NM
M
3,4 3,4
NH
M
4,7" 26,8* 18,a 6,2" 26,9 24,9
1,0
3,0 2,0
Z??
~/NM in X
300
e
a
r
s
300,
250i
250
200
200
150
150,
1 O0 .
100!
s
h
o
o
t
50
50
L.ondroces --
~.VA
High Ykddln 9 Vor;4tles
myoorrhizal efficiency in (~r and shoot yield (H/I~ in %) of 22 lligh Yielding Varieties 22 la~raees or Wild ferns of s l r ~ ~heat, ~ a ~ - ~ a t e d (~) or inoculated (14) ~ I ~ ~o~us ~ t ~ s and f e r t i l i z e d w i t h F e ~ . - - - : ~00 % no e f f e c t by V ~
•
(g/pot) O.S]
FePO.
0.2
ILS0 5Z I ~
[300
<
o.
_
m
Y.
5j
:<
= =o ,.
x
p<
(~)
300
150 100
2
100
0
-= o
lehoets
I LSO 5= I
200
50
-
MCP
:1.,\/I
200
•
O-
(g/poilu,=
"~ "~ isheots v,J
ears
150 50
.
'
-
r~ NM
b< I<
~< ~<
n.
-Z..~
~.~
. n . M/NM In IIi
F i g . 2 . Yield and Vk ~ r r h i z a l
e f f i c i e n c y (M/I~ in %) f o r e a r s and shoots of the P and FI genera-
tions of a ~eciprocal cross betwen the African High Yield£ng wheat Variety 'Euanca' (I~) and the v i l d formTriticum aesti~n rotuMatum (re), non-inoculated or inootlate(1 with the t/1 ~eorrtizal fungus Gl~u& ~ o t i $ arid fertilized with Fed~ or NCP. - - - : 100 % no e f f e c t by V ~
Z?8
Tab.2. Effect of ~xx:ulati~ with Glomus manihotis ot~ pa~'~tal and Fs geaerations of reciprocal "cx~ses l ~ t ~ . n the /~rican High Yielding wheat Variety 'Huanca'(HU) and the wild form Tt'iticum ae~tima n~tundatum f ~ t i l i ~ d with I~P, I~ = n~-hx:~'~ated, H = :inoculated with ¢J_~.,= m m ~ t i s * = significant d i f f ~ between NH and H f~r laD ~k o = significant d i f f e r , races betwe~l the reciprocal ¥, for laD St Dry w e i g h t Straw
Ear
H/NH M
'Ruanca'
1471
2705*
184
976
HU x r o r o x HU
962 1610
2418" 2531"
251 157
755 *1158
801
2838*
357
741
LSD 5 q , s e p e r a t e f o r NH and H LSD 5q
508
Shoot
H/NH
NM
r, ae.rotundatum
(mglpot)
in ~
I~
M
Hl(
M
212
2447
4772*
195
1519". 201 1439 124
1716 s2768
3937* 3970
229 143
1542
4157"
270
682
n.s
2067*
1993'
216
n.s. 663
H/~
in ~
269
495 361
Shoot P concentration (ug.Plg) NM )[
983 Shoot P uptake
NM
M
Root length (u/pot) Nil N
'Huan¢~'
2,33
2,51
5,73
11,86"
31
82*
HU x r o r o x HU
1,99 1,96
1,72 1,74
3,48 5,28
6,65* 6,84
26 e37
91" 84*
T.ae.rotundatum
2,01
1,67
3,09
6,86*
32
99*
n.s.
0,3~ 0.41
1,61
bSD 5~,seperate f o r I~H and H LSD 5~
1,72 1,58
n.8.n.8
21
in
279 Discussion The e x t e r n a l hyphae can absorb n u t r i e n t s ,
e s p e c i a l l y with low m o b i l i t y in s o i l
s o l u t i o n l i k e P, Zn and Cu, from a much l a r g e r s o i l volume than the absorbing zone
surrounding
monocotylellous
a
non-mycorrhizal
wheat
with
a
fine
root
{Howeler
branched,
et
extensive
~1.
root
1987).
system
The
has
an
e x c e l l e n t c a p a c i t y for n u t r i e n t uptake from the s o i l and is l e s s dependent upon v e s i c u l a r a r b u s c u l a r mycorrhiza (VAN) than many o t h e r p l a n t s and Khan 1977,
Jacobsen and Nielsen
1983).
Yet t h i s
(Nc Key 1966, Sail
study shows
that
wheat
y i e l d s can be c o n s i d e r a b l y increased by VA mycorrhizal i n f e c t i o n . The FePO4 treatment
used here r e p r e s e n t s
an extreme P d e f i c i e n c y so that
wheat p l a n t s remained small and did not t i l l e r .
the
Although VA mycorrhiza i s most
e f f e c t i v e and a c c e l e r a t e s plant growth, when the P supply in the s o i l is limited as i t
is
here.
Tillering
mycorrhizal e f f i c i e n c y
is
is
an important
estimated
y i e l d component in
by i t s
effect
wheat
and the
on the y i e l d of
the host
p l a n t . Therefore more s c r e e n i n g s under moderate P d e f i c i e n c y are neces~aryo Some wild wheats e v i d e n t l y posses high VA mycorrhizal e f f i c i e n c i e s with b e t t e r grain y i e l d s of the i n o c u l a t e d p l a n t s , and t h i s p r o p e r t y can be t r a n s f e r r e d to a n o n - e f f i c i e n t HYV. But the conclusion about the i n h e r i t a n c e of the VAN must be handled c a r e f u l l y , of
fungus,
plant
fertilization
because t h e r e and
are strong i n t e r a c t i o n s between the genotypes
environmental
conditions.
For
example
with
HCP
G. manihoti$ acted p a r a s i t i c a l l y in the year 1985, but enhanced
growth of both p a r e n t a l v a r i e t i e s
in 1976 with the s u e
experimental design but
d i f f e r e n t weather c o n d i t i o n s . The wide v a r i a t i o n
GZomu$ manibotis. influenced
by
in But
infection the
environment
rate
indicated
susceptibility and
fungus
used
s y c o r r h i z a l e f f i c i e n c i e s of some v a r i e t i e s tested
over s e v e r a l years
to measure
of
a varied
a variety (Nosse
susceptibility
seems to
1975).
for
be s t r o n g l y
Therefore
the
VA
, and P and Fs g e n e r a t i o n s is being
the g e n e t i c a l
v a r i a n c e s . The r e s u l t s are not yet published.
and environment-dependent
280
References GTaw D, Moawad A and Rehn S 1979 Host specifity and the effectiveness of VA nrfx~rhiza. Zeitschrift f~r Icker- und Pflanzenban~ 85-98. Halq~ann D S 1978 Interactions between n~-parasitic soil microorganL~s and plants. E~do~rrhizae. Eds. Y R ~ s and S V Krupa. pp 401-442.Elsevier, Amsterdam.
/~
Howeler R H Sieverding E and Saif S 1987 Practical aspects of .~mrrhizal tecImolcgy in scee tropical crops and pastures.Plant and Soil 100, 249-283. Jakobsan J and Nielsen N E 1983 Vesicular - arbescular )f~corrhiza in f i e l d ~ crops. 1. rhiza infection in cereals and peas at various times .and soil-depths, l~w Phytol. 93, 401-413. Jetsam A 1985 Evaluation of V~ - ~ r r h i z a as a parameter in b r e e d ~ field - pees. Rapist for erhvervsforkenxldannelse. ~" 102 under &TV. Koch R and Noawad A 1977 ~tineralstoffauall~e in Pflanze~aterial und ~,korrhizainfekticmpr~ung in ~trzeln. Institut f~r Trepischen und Subtrepischan Pflanzenbau, GStting~.FRG. Krishua K R, Sherry K 0, Dart P J and Andrew D J 1985 Ganotype dependent variation in u~orrhizal colcnization and response to inoculation of pearl millet. Plant and Soil ~ 113-125. Krishna K R and Villims
H 1987 Vesicular-arbescular myonrrhiza and gonotlq)e efEect on peanut
syehiosin and growth. 2b Proceeding of the ?th North American Conference on Mycorrhizae, Hay 3-8, 1987, Gainesville Florida, USA. K~n~ies B 1955 Colormtrisohe Besti~em~ kleinster F,e~an Phcepborsiure mit .Vanadatmoll~lat. Phos~s~ure ~ 64-72. Mc Key J 1966 The wheat plant as a model in adepti~n to high productivity m~ler differe~t anv~.~.~,~s. ~ ~ljeprivredna 1_,4 3?-48. Noaead M 1979 ~opl~siolo0y of vesicular-arbuscular ~rorrhiza in the tropics. In The Soil-soot Interface. Eds. J L Harley and Scott Ruasel R. pp 197 209. Acsdmic Press, I~lon, ~reat Britain,. Mosse B 1973 Mvances in the s t u ~ of vesicular-arbescalar , ~ r h i z a .
Ann. Rev. Iq~pathol. I1, 171.
Hosse B 1975 b'pecifit~ in VAIt n, ~kn~,orrhizas. ~ k F E Sanders. pp 469-484. Acadenic Press, London, G~at Britain. Ne~an E I 1966 A method oE estimating the total length of root in a sample. J. AI~I. Ecol. 3, 139 Phillips J M a ~ Hal~m D ~ 1970 ~ procedures for clearing roots and staining parasitic and V~ ~ o r r h i z a l f u j i for rapid assesmmt of infection. Trans. B. M~col. SOc. 55, 158-180.
~ i f S R and ~ m A G 1975 The influence of season and stage of develolm~t of plant on ~b~0ne e~corrhiza of field-groom ,heat. Canadian~ of ~icrihiolo~ 21, 1020-1024. $ieverding E 1980 Einflu~ der Rxlanfeuchte aof die E~fektivit&t der VA - I ~ T h i Z a .
Diss.
~ttin~, ~. 8teffan H 1985 Enteicklur~ der ) ~ , - h i z a
in l~ltorpflanzen bei Einfl~6 untarschiedlicher ~irtschafts~.isan. i f o a m, Zeitschrift f~r ~kologische Landeirtschaft 5_,3 6-8.
Yc~g J L, Davis E A and Rose S L 1985 End~q,~Thlzal fungi in breeder .heats and triticale cultivars field-grown on fertile soil. Agronc~ Journal ?7, 219-224.
Manske, G.G.B., 1989: Genetical VA mycorrhlza with spring E n v i r o n . , 29: 2 7 3 - 2 8 0 .
analysis wheat.
of the efficiency of ~grlc. Ecosystems
Genetical
Analysis
of
the
Efficiency
o f V& N y c o r r h i z a
with
SpringWheat G. G.B. HANSKE
Institute for Tropical and Subtropical Crop Science and ~'unal ~Nime at the University of ~ t t i n ~ , Grisebachstr. 6, D-3400 ~ttingen Abstract
The e f f i c i e n c y of VAH depends not only upon the ~nvironmental c o n d i t i o n s but a l s o on the genotype of the host p l a n t . In a pot experiment with a s t e r i l i z e d , P d e f i c i e n t , P - f i x i n g s o i l 22 High f i e l d i n g V a r i e t i e s ~RYVs) and 22 Landraces and wild forms (LHs) of wheat ( T r i t i c u m s s p . ) were i n o c u l a t e d with the m y c o r r b i z a l fungus ~lomus maniboti$ and compared with non-ino,:ulated c o n t r o l plants.Two different P-fertilizer forms were t e s t e d : s o l u b l e m~nocalcium phosphate (MCP) and iron phosphate (FePO4).VAN showed a higher e f f i c i e n c y under P d e f i c i e n c y (FePO~) with most of the Las than with HYVs. The e f f i c i e n t wild v a r i e t y Triticum aestivum rotundatum and the African HYV 'Huanca' were crossed r e c i p r o c a l l y . Chromosomal h e r e d i t y of the YAH e f f i c i e n c y could be okserved. With N C P - f e r t i l i zation d i f f e r e n c e s between the r e c i p r o c a l F~ i n d i c a t e d a l s o p l a s m a t i c e f f e c t s . Introduction nesearch on the g e n e t i c c o n t r o l
of root-microorganism i n t e r a c t i o n s ,
with m y c o r r b i z a l fungi,
r a r e (Krishna et al. 1985, Jensen 1985, Krishna
is still
especially
and Williams 1987).But the VA m y c o r r h i z a l (VAM) mycelium can form the m a j o r i t y of the s o i l m i c r o b i a l biomass ( a ~ a n p a r t i c u l a r l y well i n f e c t e d in f i e l d l i z e r and p e s t i c i d e
a~plioation
from h a r d l y s o l u b l e , relevant fixati~,
for
plant
soil-borne production
1978) and r o o t s of c u l t i v a t e d p l a n t s are s o i l s ,it~, e i t h e r no or low mineral f e r t i -
( S t e f f a n 1985).
VAN can improve the P uptake
or applied P compounds. This i s p a r t i c u l a r l y on d i f f i c u l t
soils
with
a high
such as the acid l a t : , s o l s with high A1 and Fe contents
the humid t r o p i c s and the l l k a l i n e ,
P fertilizer p r e v a l e n t in
calcareous s o i l s of the s u b t r o p i c s
(~oawad
1979). VAN e f f i c i e n c y seems :o depend r o t only upon environmental c o n d i t i o n s an~ e f f i c i e n c y of the VAM fungus but a l s o on the genotype of the host p l a n t a l . 1979,
Sieverdina
cultivars
with
little
1980). need
This i s of
important
fertilizer.
In
for the
the
breeding
of
work d e s c r i b e d
(Gra, et low-input here
the
i n h e r i t a n c e of VA mycorrhizal e f f i c i e n c y in spring wheat has-been i n v e s t i g a t e d .
274
N a t e r i a l s and Netbods Wheat plants were grown in plastic pots containing 2 kg of soil in a greeruhouso under natural sunlight. 1he soil was o:eposed of a P-deficient and P-fixinq, sandy forest soil, with high contents of M, l~t and Fe, mixed with quartz sand in the proportion of 1:1, and limed with CaCO~to 1~ 5.5 . This IM has proved best for the Vl ~corrhizal bingos used, ~Z~vs run.otis, whLch is a very e f f i c i ~ t strain. Before application of the P f o r ~ the soil substrate m sterilized by heat. Two sources of phosphorus with different solubilities were tested, hardly soluble i r ~ phesphate (Fel~) and easily soluble nmocalcium phosphate (IRP), 30 mg P kg-s dry soil. Basic nutrients, s~ficient to eli~nate all nutrient deficiencies except P, were applied in soluti~ after germination. Nycorrhizal inorulum consisted of strorqly infected root pieces of D~torium o~ratum, a tropical, obligatorily e ~ c o t ~ c herb, which were placed wrier the geminating wheat seed. 7he plants were harvested at ~ilk-ripe stage of the grains. Root length was measured by the gridline intersect math0d (Neeman 1966). The roots were stained (PhiliDs and Havman 1970) and placed on a Petri dish under a binocular:The infection rate was ansessed according to the subjective estimation method used in breedL'q prngrans" for mildew resistance in wheat. This is the only possible w~ to investigate VA nvcerrhizal infection in roots of a large number of plants with such an extensive root s ~ t m . The infection rate represents the proportion of root length infected by Vl m~orrhizal fungus. The total infected root length was calculated by multiplying infection rate with root length. Re~esentative sas~les of pmdered straw and ear material lere ashed in ~SO4-Se (~ch and 14bavad 19"~?). P contents ~ r e measured i~tometrically by the vanedate-yellow method (l(umies 1955). P uptake mars P concentration x dry weight.lhe screening ~ t . m conducted in m r 1985 and the ~..~rison of the P and F, generations in m r 1986. TWnt~-t,o High Yielding Varieties and 22 Landraces or wild form were investigated. Results
The $creenina All
44
wheat
varieties
manibotiB. The e f f e c t fertility
conditions
of
were i n f e c t e d
by
the
the symbiosis v a r i e d
(NCP).
The N C P - f e r t i l i z e d
higher dry weights than F e P O 4 - f e r t i l i z e d p l a n t s .
Vk s y c o r r h i z a l under low plants
fungus
Glomu$
(FePO~) and high P
yielded
3 to
5 times
The high l e v e l of a v a i l a b l e P
in the NCP treatments r a i s e d a l s o P c o n c e n t r a t i o n and P uptake ( T a b . l ) . P D e f i c i e n t Conditions (FeP04) Ear and shoot dry weight were increased by ~. manihotis under P - d e f i c i e n t conditions
(FePO4). The uninproved
varieties
(LRs) showed a higher VA mycorrhizal
e f f i c i e n c y (N/NN in ~). The m a j o r i t y of the LRs ranged in t h e i r VA mycorrhizal e f f i c i e n c y of ear dry weight above 130~o 20-30~ more than the mean of the HYVs ( F i g . l ) . But the very high N/NN r a t i o of some LRs was in many cases c o r r e l a t e d with an extremely poor plant growth without VAn, i n d i c a t i n g a high mycorrhizal dependency. The symbiosis
increased
the ear
m~re than
the
shoot
dry w e i g h t
( F i g . l ) , and s i g n i f i c a n t i n c r e a s e s of the shoot dry weights by YAM could only be
2?5
found i n LRs. The e a r p r o p o r t i o n of the HYVs was h i g h e r than of the LRs, but with VAM the LRs could reach t h e l e v e l of HYVs ( T a b . l ) . HYVs were s h o r t e r than LRs, which produced g r e a t e r r o o t l e n g t h than HYVs on average. HYVs showed l e s s v a r i a t i o n i n r o o t l e n g t h and p l a n t h e i g h t than LRs. There were no d i f f e r e n c e s in t h e i n f e c t i o n r a t e of G. maniboti$ between HYVs and LRs on t h e a v e r a g e , but some p r i m i t i v e wheats were more s t r o n g l y i n f e c t e d (above 70q). B~cause of t h e i r g r e a t e r r o o t l e n g t h s t h e LRs showed g r e a t e r i n f e c t e d root l e n g t h . There was no
c o r r e l a t i o n s between VA m y c o r r h i z a l e f f i c i e n c y in terms of
shoot d r y weight and e i t h e r
infection rate
or t o t a l
infected root
l e n g t h . VA~
i n c r e a s e d the P c o n c e n t r a t i o n and P uptake in e a r s and shoot~ in gYVs as well as in LRs. Because of
the g r e a t e r
yield increase
in LRs t h e i r
ear
and shoot P
uptake exceeded t h a t of the HYVs ( T a b . l ) . High P F e r t i l i t y
C o n d i t i o n s (NCP)
The VAM fungus Glomu$ maniboti$ i n f e c t e d wheat r o o t s well fed with P due to NCP f e r t i l i z a t i o n , especially
p o o r l y , when p l a n t s were
and VAN showed p a r a s i t i c
effects,
( T a b . l ) . Eighteen HYVs and s i x LRs showed s i g n i f i c a n t p a r a s i t i s m in
r e s p e c t of shoot dry weight by YAM. I n h e r i t a n c e of
the VA M v c o r r h i z a l E f f i c i e n c y i n a R e c i n r o c a l Cross between an
E f f i c i e n t and N o n - E f f i c i e n t V a r i e t y ~ r l t i c u m aestivum rotUndatum (ro)
(a V A ~ - e f f i c i e n t v a r i e t y }
and 'Huanca'
(Hu)
( n o n - e f f i c i e n t ) were r e c i p r o c a l l y c r o s s e d to o b t a i n seeds f o r the comparison of the P and F: g e n e r a t i o n s . In t h i s and shoot d r y m a t t e r s latter
c a s e in c o n t r a s t
both p a r e n t a l v a r i e t i e s
experiment ~lomus manihotis i n c r e a s e d the e a r
with FePO4 f e r t i l i z a t i o n
as
w e l l as with HCP, in the
t o 1985 where the same fungus a c t e d p a r a s i t i c a l l y
in
(Fig.2).
The w i l d form T. as. rotundatum (ro) y i e l d e d i e s s without YAM than t h e A f r i c a n HYV 'Huanca'(Hu) and both F t s . But ro showed a ~trong p o s i t i v e y i e l d r e s p o n s e to the
symbiosis,
resulting
in
the
highest
~!AM e f f i c i e n c y
for
all
factor
c o m b i n a t i o n s . In the FePO4-treatment the m y c o r r h i z a l e f f i c i e n c y , e s p e c i a l l y f o r
2?6
ear dry weight, was much greater with ro than with Hu and could be transf~rr~:]
by r e c i p r o c a l crossing ~o the n o n - e f f i c i e n t HYV. The e f f i c i e n c y of the F~ rang,.4 between t h a t of the p a r e n t s ,
but the a b s o l u t e dry weight values s u r p a s s e d those
of both parents (Fig.2-Fe?O4) The effect of the inoculation .as different in the MCP treatments. Here only in the case of Hu x ro the M/~M in ~ values of ear and shoot dry weight lay between the low efficiency of Hu and the high of ro (Fig.2-MCP). The non-inoculated ro x Hu - plants
grew very
well,
with
the consequence
that
increase by VAN was low. The better shoot growth of r o x
the
relative
yield
Hu corresponded .it~
the better root growth and higher P-uptake of this hybrid in the uninoculated FePO4
treatment. The significant
differences
in VAM efficiency
indicate that
both chromosomal and pl&smatic genes are involved in the inheritance of the VAM efficiency in .heat (Tab.l).
Differences betveen 22 High Yielding Varieties (IWVs) and 23 landraces (l/bs) of spring wheat in several parmeters, ~ u ~ l a t e d ~ and inocolated ~) ~ t h the Vk s ~ r b i z a l f~gus ~/cms mm~ot~s and fertilized ~th FePO~ or m0oocalcium pb~phate (NCP). * si~LfJJmnt differe~es bergen ]m and Mfor LSD 5~ Ear dr~ weight (mg/pot) FePOq MCP ~m M ax x HYVs LRs LSD 5q LSD 5~
Shoot dry weight (eg/pot) FePO4 NCP NM M NM M
384 ~31 2040* 1307 348 504* 1769 1561 95
205
n
1026
1064
1257" 3533* 3063
3431. 2324
FePO4 KCP M NM M
37 34
377
132
40 60* 56 40* 50 52
3,4
5 4
295
Shoot P - c o n c e n t r a t i o n (mg P/g dry weight) FePO4 MOP NH
LSD 5~ LSD 5~1
(~)
1017
159
HYVs LRs
Ear proportion
3,3 3,3
M
NH
H
4,4" 8,0 "8,0 4,9" 7,8 8,3 0,5
n.s. 0,7
Shoot P uptake (mg P/ pot) FePO4 MCP NM
M
3,4 3,4
NH
M
4,7" 26,8* 18,a 6,2" 26,9 24,9
1,0
3,0 2,0
Z??
~/NM in X
300
e
a
r
s
300,
250i
250
200
200
150
150,
1 O0 .
100!
s
h
o
o
t
50
50
L.ondroces --
~.VA
High Ykddln 9 Vor;4tles
myoorrhizal efficiency in (~r and shoot yield (H/I~ in %) of 22 lligh Yielding Varieties 22 la~raees or Wild ferns of s l r ~ ~heat, ~ a ~ - ~ a t e d (~) or inoculated (14) ~ I ~ ~o~us ~ t ~ s and f e r t i l i z e d w i t h F e ~ . - - - : ~00 % no e f f e c t by V ~
•
(g/pot) O.S]
FePO.
0.2
ILS0 5Z I ~
[300
<
o.
_
m
Y.
5j
:<
= =o ,.
x
p<
(~)
300
150 100
2
100
0
-= o
lehoets
I LSO 5= I
200
50
-
MCP
:1.,\/I
200
•
O-
(g/poilu,=
"~ "~ isheots v,J
ears
150 50
.
'
-
r~ NM
b< I<
~< ~<
n.
-Z..~
~.~
. n . M/NM In IIi
F i g . 2 . Yield and Vk ~ r r h i z a l
e f f i c i e n c y (M/I~ in %) f o r e a r s and shoots of the P and FI genera-
tions of a ~eciprocal cross betwen the African High Yield£ng wheat Variety 'Euanca' (I~) and the v i l d formTriticum aesti~n rotuMatum (re), non-inoculated or inootlate(1 with the t/1 ~eorrtizal fungus Gl~u& ~ o t i $ arid fertilized with Fed~ or NCP. - - - : 100 % no e f f e c t by V ~
Z?8
Tab.2. Effect of ~xx:ulati~ with Glomus manihotis ot~ pa~'~tal and Fs geaerations of reciprocal "cx~ses l ~ t ~ . n the /~rican High Yielding wheat Variety 'Huanca'(HU) and the wild form Tt'iticum ae~tima n~tundatum f ~ t i l i ~ d with I~P, I~ = n~-hx:~'~ated, H = :inoculated with ¢J_~.,= m m ~ t i s * = significant d i f f ~ between NH and H f~r laD ~k o = significant d i f f e r , races betwe~l the reciprocal ¥, for laD St Dry w e i g h t Straw
Ear
H/NH M
'Ruanca'
1471
2705*
184
976
HU x r o r o x HU
962 1610
2418" 2531"
251 157
755 *1158
801
2838*
357
741
LSD 5 q , s e p e r a t e f o r NH and H LSD 5q
508
Shoot
H/NH
NM
r, ae.rotundatum
(mglpot)
in ~
I~
M
Hl(
M
212
2447
4772*
195
1519". 201 1439 124
1716 s2768
3937* 3970
229 143
1542
4157"
270
682
n.s
2067*
1993'
216
n.s. 663
H/~
in ~
269
495 361
Shoot P concentration (ug.Plg) NM )[
983 Shoot P uptake
NM
M
Root length (u/pot) Nil N
'Huan¢~'
2,33
2,51
5,73
11,86"
31
82*
HU x r o r o x HU
1,99 1,96
1,72 1,74
3,48 5,28
6,65* 6,84
26 e37
91" 84*
T.ae.rotundatum
2,01
1,67
3,09
6,86*
32
99*
n.s.
0,3~ 0.41
1,61
bSD 5~,seperate f o r I~H and H LSD 5~
1,72 1,58
n.8.n.8
21
in
279 Discussion The e x t e r n a l hyphae can absorb n u t r i e n t s ,
e s p e c i a l l y with low m o b i l i t y in s o i l
s o l u t i o n l i k e P, Zn and Cu, from a much l a r g e r s o i l volume than the absorbing zone
surrounding
monocotylellous
a
non-mycorrhizal
wheat
with
a
fine
root
{Howeler
branched,
et
extensive
~1.
root
1987).
system
The
has
an
e x c e l l e n t c a p a c i t y for n u t r i e n t uptake from the s o i l and is l e s s dependent upon v e s i c u l a r a r b u s c u l a r mycorrhiza (VAN) than many o t h e r p l a n t s and Khan 1977,
Jacobsen and Nielsen
1983).
Yet t h i s
(Nc Key 1966, Sail
study shows
that
wheat
y i e l d s can be c o n s i d e r a b l y increased by VA mycorrhizal i n f e c t i o n . The FePO4 treatment
used here r e p r e s e n t s
an extreme P d e f i c i e n c y so that
wheat p l a n t s remained small and did not t i l l e r .
the
Although VA mycorrhiza i s most
e f f e c t i v e and a c c e l e r a t e s plant growth, when the P supply in the s o i l is limited as i t
is
here.
Tillering
mycorrhizal e f f i c i e n c y
is
is
an important
estimated
y i e l d component in
by i t s
effect
wheat
and the
on the y i e l d of
the host
p l a n t . Therefore more s c r e e n i n g s under moderate P d e f i c i e n c y are neces~aryo Some wild wheats e v i d e n t l y posses high VA mycorrhizal e f f i c i e n c i e s with b e t t e r grain y i e l d s of the i n o c u l a t e d p l a n t s , and t h i s p r o p e r t y can be t r a n s f e r r e d to a n o n - e f f i c i e n t HYV. But the conclusion about the i n h e r i t a n c e of the VAN must be handled c a r e f u l l y , of
fungus,
plant
fertilization
because t h e r e and
are strong i n t e r a c t i o n s between the genotypes
environmental
conditions.
For
example
with
HCP
G. manihoti$ acted p a r a s i t i c a l l y in the year 1985, but enhanced
growth of both p a r e n t a l v a r i e t i e s
in 1976 with the s u e
experimental design but
d i f f e r e n t weather c o n d i t i o n s . The wide v a r i a t i o n
GZomu$ manibotis. influenced
by
in But
infection the
environment
rate
indicated
susceptibility and
fungus
used
s y c o r r h i z a l e f f i c i e n c i e s of some v a r i e t i e s tested
over s e v e r a l years
to measure
of
a varied
a variety (Nosse
susceptibility
seems to
1975).
for
be s t r o n g l y
Therefore
the
VA
, and P and Fs g e n e r a t i o n s is being
the g e n e t i c a l
v a r i a n c e s . The r e s u l t s are not yet published.
and environment-dependent
280
References GTaw D, Moawad A and Rehn S 1979 Host specifity and the effectiveness of VA nrfx~rhiza. Zeitschrift f~r Icker- und Pflanzenban~ 85-98. Halq~ann D S 1978 Interactions between n~-parasitic soil microorganL~s and plants. E~do~rrhizae. Eds. Y R ~ s and S V Krupa. pp 401-442.Elsevier, Amsterdam.
/~
Howeler R H Sieverding E and Saif S 1987 Practical aspects of .~mrrhizal tecImolcgy in scee tropical crops and pastures.Plant and Soil 100, 249-283. Jakobsan J and Nielsen N E 1983 Vesicular - arbescular )f~corrhiza in f i e l d ~ crops. 1. rhiza infection in cereals and peas at various times .and soil-depths, l~w Phytol. 93, 401-413. Jetsam A 1985 Evaluation of V~ - ~ r r h i z a as a parameter in b r e e d ~ field - pees. Rapist for erhvervsforkenxldannelse. ~" 102 under &TV. Koch R and Noawad A 1977 ~tineralstoffauall~e in Pflanze~aterial und ~,korrhizainfekticmpr~ung in ~trzeln. Institut f~r Trepischen und Subtrepischan Pflanzenbau, GStting~.FRG. Krishua K R, Sherry K 0, Dart P J and Andrew D J 1985 Ganotype dependent variation in u~orrhizal colcnization and response to inoculation of pearl millet. Plant and Soil ~ 113-125. Krishna K R and Villims
H 1987 Vesicular-arbescular myonrrhiza and gonotlq)e efEect on peanut
syehiosin and growth. 2b Proceeding of the ?th North American Conference on Mycorrhizae, Hay 3-8, 1987, Gainesville Florida, USA. K~n~ies B 1955 Colormtrisohe Besti~em~ kleinster F,e~an Phcepborsiure mit .Vanadatmoll~lat. Phos~s~ure ~ 64-72. Mc Key J 1966 The wheat plant as a model in adepti~n to high productivity m~ler differe~t anv~.~.~,~s. ~ ~ljeprivredna 1_,4 3?-48. Noaead M 1979 ~opl~siolo0y of vesicular-arbuscular ~rorrhiza in the tropics. In The Soil-soot Interface. Eds. J L Harley and Scott Ruasel R. pp 197 209. Acsdmic Press, I~lon, ~reat Britain,. Mosse B 1973 Mvances in the s t u ~ of vesicular-arbescalar , ~ r h i z a .
Ann. Rev. Iq~pathol. I1, 171.
Hosse B 1975 b'pecifit~ in VAIt n, ~kn~,orrhizas. ~ k F E Sanders. pp 469-484. Acadenic Press, London, G~at Britain. Ne~an E I 1966 A method oE estimating the total length of root in a sample. J. AI~I. Ecol. 3, 139 Phillips J M a ~ Hal~m D ~ 1970 ~ procedures for clearing roots and staining parasitic and V~ ~ o r r h i z a l f u j i for rapid assesmmt of infection. Trans. B. M~col. SOc. 55, 158-180.
~ i f S R and ~ m A G 1975 The influence of season and stage of develolm~t of plant on ~b~0ne e~corrhiza of field-groom ,heat. Canadian~ of ~icrihiolo~ 21, 1020-1024. $ieverding E 1980 Einflu~ der Rxlanfeuchte aof die E~fektivit&t der VA - I ~ T h i Z a .
Diss.
~ttin~, ~. 8teffan H 1985 Enteicklur~ der ) ~ , - h i z a
in l~ltorpflanzen bei Einfl~6 untarschiedlicher ~irtschafts~.isan. i f o a m, Zeitschrift f~r ~kologische Landeirtschaft 5_,3 6-8.
Yc~g J L, Davis E A and Rose S L 1985 End~q,~Thlzal fungi in breeder .heats and triticale cultivars field-grown on fertile soil. Agronc~ Journal ?7, 219-224.
Manske, G.G.B., 1989: Genetical VA mycorrhlza with spring E n v i r o n . , 29: 2 7 3 - 2 8 0 .
analysis wheat.
of the efficiency of ~grlc. Ecosystems