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What are arbuscular
mycorrhizal fungi?
Mycorrhizal associations are formed by fungi. These associations should
not be confused with rhizobial associations,which are symbiotic associations
with bacteria that result in nitrogen-fixing nodules. Two major groups of fungi form
mycorrhizal associations: ectomycorrhizal fungi and endomycorrhizal fungi.
Ectomycorrhizas associate
not be confused with rhizobial associations,which are symbiotic associations
with bacteria that result in nitrogen-fixing nodules. Two major groups of fungi form
mycorrhizal associations: ectomycorrhizal fungi and endomycorrhizal fungi.
Ectomycorrhizas associate
mainly with temperate-zone trees such
as pine, poplar, and willow. These
fungi form sheaths around their host’s
root surfaces. Most ectomycorrhizas can be grown in
pure culture.
pure culture.
Endomycorrhizas form associations with
most plants (approximately 80 percent of all plant species).
These fungi cannot be grown in pure culture but
must be grown in association with plant roots. They form
branched structures called arbuscules within the host’s
root cells, and thus they are known as
root cells, and thus they are known as
arbuscular mycorrhizal
fungi
. The arbuscules are sites of nutrient exchange
between the fungus and the host. This manual
focuses on arbuscular mycorrhizal fungi.
The associations that arbuscular mycorrhizal fungi
form with plants are called symbiotic associations because
they are usually beneficial to both organisms. In
they are usually beneficial to both organisms. In
exchange for carbohydrates produced by the host through
photosynthesis, the fungi help the plant take up water
and immobile soil nutrients such as phosphorus (P), copper,
and zinc. The fungus extends from the plant root
and expands the volume of soil that the root system can
explore by itself.
photosynthesis, the fungi help the plant take up water
and immobile soil nutrients such as phosphorus (P), copper,
and zinc. The fungus extends from the plant root
and expands the volume of soil that the root system can
explore by itself.
Manual on Arbuscular Mycorrhizal Fungus
Production and Inoculation Techniques
S.C. Miyasaka
1, M. Habte1, J.B. Friday2, and E.V. Johnson1
Departments of
1Tropical Plant and Soil Sciences and 2Natural Resources and Environmental Management
To have beneficial associations
between the fungus and plant roots, a
low but sufficient
level of P in the soil
or rooting medium is needed. If the
soil P level is extremely low, the fungus
can be parasitic (harmful to the
plant) rather than beneficial, because
it will compete with the plant for
it will compete with the plant for
available P. When soil P is high (above
“sufficient”), the plant can obtain
enough P without the fungus, and the
association will not be formed.
For a more detailed explanation of
arbuscular mycorrhizal fungi, obtain
the CTAHR publication
“sufficient”), the plant can obtain
enough P without the fungus, and the
association will not be formed.
For a more detailed explanation of
arbuscular mycorrhizal fungi, obtain
the CTAHR publication
Arbuscular
Mycorrhizas: Producing and Applying Arbuscular Mycorrhizal
Inoculum
by M. Habte and N.W. Osorio. This book
may be purchased from CTAHR; obtain an order form at
.
Why should plants be inoculated with
arbuscular mycorrhizal fungus?
In many tropical soils, P availability is limited due to Pfixation.
Plants inoculated with arbuscular mycorrhizal
fungi in the nursery are better able to obtain P when
fungi in the nursery are better able to obtain P when
they are later planted into low-P soils. In addition, the
association helps the plant obtain water, which is critical
to plant survival and growth under dry conditions.
The amount of P fertilizer that needs to be applied
to a plant or crop is reduced when effective arbuscular
mycorrhizal associations have been formed. In addition
to the benefit of lowering fertilizer costs, reducing P
applications can help maintain environmental water
quality. Erosion of soil from fields with high P levels
Mycelia of an arbuscular mycorrhizal fungus
emerge from a root; the spherical bodies
are vesicles (fungal storage organs).
SCM-5 Arbuscular Mycorrhizal Fungus Production and Inoculation Techniques CTAHR — July 2003
2
often results in P enrichment of water bodies, which
causes excessive growth (“blooms”) of algae.
When should plants be inoculated with
arbuscular mycorrhizal fungus?
First, the particular plant species of interest must be able
to form effective associations with arbuscular mycorrhizal
fungi and be dependent on these associations for
nutrient exchange. A few plant families have species that
do not form mycorrhizal associations (e.g., Brassicaceae,
the mustard family, and Chenopodiaceae, the goosefoot
family). Table 1 lists selected food and tree crops that
are moderately, highly, or very highly dependent on associations
with arbuscular mycorrhizal fungi.
Second, an association between an arbuscular mycorrhizal
fungus and plant roots will be beneficial to the
plant when it is grown under low P or dryland (i.e., lowrainfall,
non-irrigated) conditions. If you are expecting
to plant seedlings in a soil that is known to be low in P
(e.g., volcanic ash soils along the Hamakua Coast of
Hawaii, or highly weathered red clay oxisols on Oahu
and Kauai) or in areas with low rainfall and no availability
of irrigation, then you should consider inoculating
seedlings in the nursery with an effective arbuscular
mycorrhizal fungus. For further information about soil
P in Hawaii, read
association helps the plant obtain water, which is critical
to plant survival and growth under dry conditions.
The amount of P fertilizer that needs to be applied
to a plant or crop is reduced when effective arbuscular
mycorrhizal associations have been formed. In addition
to the benefit of lowering fertilizer costs, reducing P
applications can help maintain environmental water
quality. Erosion of soil from fields with high P levels
Mycelia of an arbuscular mycorrhizal fungus
emerge from a root; the spherical bodies
are vesicles (fungal storage organs).
SCM-5 Arbuscular Mycorrhizal Fungus Production and Inoculation Techniques CTAHR — July 2003
2
often results in P enrichment of water bodies, which
causes excessive growth (“blooms”) of algae.
When should plants be inoculated with
arbuscular mycorrhizal fungus?
First, the particular plant species of interest must be able
to form effective associations with arbuscular mycorrhizal
fungi and be dependent on these associations for
nutrient exchange. A few plant families have species that
do not form mycorrhizal associations (e.g., Brassicaceae,
the mustard family, and Chenopodiaceae, the goosefoot
family). Table 1 lists selected food and tree crops that
are moderately, highly, or very highly dependent on associations
with arbuscular mycorrhizal fungi.
Second, an association between an arbuscular mycorrhizal
fungus and plant roots will be beneficial to the
plant when it is grown under low P or dryland (i.e., lowrainfall,
non-irrigated) conditions. If you are expecting
to plant seedlings in a soil that is known to be low in P
(e.g., volcanic ash soils along the Hamakua Coast of
Hawaii, or highly weathered red clay oxisols on Oahu
and Kauai) or in areas with low rainfall and no availability
of irrigation, then you should consider inoculating
seedlings in the nursery with an effective arbuscular
mycorrhizal fungus. For further information about soil
P in Hawaii, read
Predicting Soil Phosphorus Requirements
by N.V. Hue, H. Ikawa, and X. Huang in
Plant
Nutrient Management in Hawaii’s Soils: Approaches for
Tropical and Subtropical Agriculture
. The article is available
on the Web at
http://www.ctahr.hawaii.edu/freepubs
under the category Soil and Crop Management.
Third, the presence of existing populations of mycorrhizal
fungi in the field soil will determine whether
you need to inoculate seedlings in the nursery. If the
soil contains a large population of arbuscular mycorrhizal
soil contains a large population of arbuscular mycorrhizal
fungi that will form effective associations with
the plants you are growing, then you do not need to inoculate
seedlings in the nursery. If the soil has low populations
of indigenous mycorrhizal fungi, you should inoculate
your seedlings in the nursery.
Low soil P can occur because the soil layers rich in
P have been eroded. Low populations of indigenous
mycorrhizal fungi can occur when the soil has previously
supported either a predominance of plants that are
non-mycorrhizal (e.g., cabbage, broccoli) or plants that
are not dependent on mycorrhizal associations (e.g.,
kikuyugrass).
How can you tell if your plant is dependent on mycorrhizal
associations or if your site contains effective
arbuscular mycorrhizal fungi? One way is to inoculate
half of a batch of seedlings in the nursery with mycorrhizal
fungi and leave the other half uninoculated. Then,
observe the growth of the seedlings after planting in the
field. If there are visible differences, with inoculated
seedlings showing greater growth, then in the future you
should inoculate all the seedlings in the nursery. Alternatively,
you could take soil samples from at least three
locations within the field, mix them, place the mixture
in three 6-inch pots, plant corn seeds (or seeds of another
known host species, such as sorghum), and after
six weeks have a laboratory determine whether mycorrhizal
associations have developed. To determine the
presence of mycorrhizal associations, wash a sample of
fine roots from the nursery-grown plants and send it to
CTAHR’s Agricultural Diagnostic Service Center.
(Contact ADSC for information on service fees; call
808-956-5434 or e-mail
the plants you are growing, then you do not need to inoculate
seedlings in the nursery. If the soil has low populations
of indigenous mycorrhizal fungi, you should inoculate
your seedlings in the nursery.
Low soil P can occur because the soil layers rich in
P have been eroded. Low populations of indigenous
mycorrhizal fungi can occur when the soil has previously
supported either a predominance of plants that are
non-mycorrhizal (e.g., cabbage, broccoli) or plants that
are not dependent on mycorrhizal associations (e.g.,
kikuyugrass).
How can you tell if your plant is dependent on mycorrhizal
associations or if your site contains effective
arbuscular mycorrhizal fungi? One way is to inoculate
half of a batch of seedlings in the nursery with mycorrhizal
fungi and leave the other half uninoculated. Then,
observe the growth of the seedlings after planting in the
field. If there are visible differences, with inoculated
seedlings showing greater growth, then in the future you
should inoculate all the seedlings in the nursery. Alternatively,
you could take soil samples from at least three
locations within the field, mix them, place the mixture
in three 6-inch pots, plant corn seeds (or seeds of another
known host species, such as sorghum), and after
six weeks have a laboratory determine whether mycorrhizal
associations have developed. To determine the
presence of mycorrhizal associations, wash a sample of
fine roots from the nursery-grown plants and send it to
CTAHR’s Agricultural Diagnostic Service Center.
(Contact ADSC for information on service fees; call
808-956-5434 or e-mail
adsc@ctahr.hawaii.edu. Put the
sample in a plastic bag with a damp paper towel to maintain
moisture, and keep it as cool as possible. On Oahu,
samples can be delivered to ADSC on the UH-Manoa
campus at 1910 East-West Road, Sherman Laboratory,
Room 134. On Kauai, Maui, Molokai, or Hawaii, deliver
Room 134. On Kauai, Maui, Molokai, or Hawaii, deliver
samples to the nearest office of the CTAHR Cooperative
Extension Service.)
Extension Service.)
Table 1. Dependency of selected trees and food crops on arbuscular mycorrhizal associations (Miyasaka and Habte 2001).
Moderately dependent Highly dependent Very highly dependent
Acacia koa, koa Allium cepa, onion Leucaena leucocephala, koa haole
Acacia mangium Carica papaya, papaya Manihot esculenta, cassava
Acacia mangium Carica papaya, papaya Manihot esculenta, cassava
Colocasia esculenta, kalo, taro Senna siamea, pheasantwood Sophora chrysophylla, m
ämane
Gliricidia sepium, madre de cacao Coffea arabica, coffee
Sesbania grandiflora, katurai Falcataria moluccana, albizia
3
SCM-5 Arbuscular Mycorrhizal Fungus Production and Inoculation Techniques CTAHR
— July 2003
How is arbuscular mycorrhizal
fungus inoculum produced?
1.
Surface-sterilize seeds of a host plant, such as corn
or sorghum, using a 10% solution of household bleach:
1 volume of bleach (containing 5% sodium hypochlorite)
plus 9 volumes of water. Soak the seeds in the solution
for approximately 5–10 minutes.
2.
Germinate the seeds by placing them between moistened
paper towels on a plate placed in a loosely sealed
plastic bag. Corn seeds will germinate within two to three
days.
3.
It is essential to select a medium with low phosphorus
.
.
An appropriate nursery medium for producing
arbuscular mycorrhizal inoculum contains a low level of
P. Do not use a nursery medium that contains P fertilizer.
If there is much P available in the planting medium, the
fungi will not form associations with the seedlings. Our
fungi will not form associations with the seedlings. Our
recommended medium is crushed basaltic rock with a
diameter less than
diameter less than
1⁄8 inch (available from some concrete
or aggregate suppliers). This medium was selected because
it contains very low levels of available plant nutrients
(including P). Alternative media are quartz sand (not
coral sand), available from some agricultural suppliers,
or a mixture of 1 volume of peat moss with 3 volumes of
or a mixture of 1 volume of peat moss with 3 volumes of
either vermiculite, perlite, or volcanic cinder.
4.
It is critical that the medium be sterilized to ensure
good mycorrhizal infection
. If it is not sterilized, there
is a chance that microorganisms present in the medium
will inhibit the formation of mycorrhizal associations.
In an autoclave or pressure cooker, heat the medium for
60 minutes. In a steam-sterilizer, heat it at 200
°F for 60
minutes. Let the medium cool and use it immediately.
5.
Place the medium in 6–10-inch diameter pots. To prevent
escape of medium, seal the large bottom holes with
tape, but poke small holes to allow drainage of water.
6.
Obtain a starter-culture of arbuscular mycorrhizal
inoculum from a commercial source or researchers working
on mycorrhizal fungi. A starter culture of
Glomus
aggregatum
may be obtained from Dr. Mitiku Habte,
CTAHR, but this is subject to availability. Thoroughly
mix the culture into the medium at 1 volume of inoculum
to 20 volumes of medium. Or, put
1⁄2 ounce (5–10
grams) of inoculum into each planting hole when planting
the germinated seeds.
7.
Plant 2–6 germinated seeds in each pot. The object
is to maximize root development in the pot so that the
medium is completely filled with a mass of roots.
8.
Place the pots in a greenhouse or in a well lighted
area under a rain shelter to minimize contamination from
microorganisms carried by rain or wind.
9.
Water the plants once a day until water begins to drip
from the bottom of the pot.
10.
Apply 1 teaspoon per pot of a low-P, slow-release
fertilizer, such as 19-5-12 Apex
® Foliage Fertilizer or
another low-P (e.g., 17-6-10), slow-release fertilizer. Or,
make your own low-P fertilizer using the following
recipe (adapted from a manual by J.N. Gemma and R.E.
Koske, available on the Web at
http://www.hawaii.edu/
scb/scinativ_mycor.html
). Mix into 2 gallons of water
1
1⁄3 teaspoons (6 g) of Peters Professional® 15-0-15 fertilizer,
1
⁄5 teaspoon (0.9 g) of epsom salts (MgSO4), and
1.5 milliliters of a concentrated phosphate fertilizer solution
called Quick Start
TM (4-12-4) made by Miracle-
Gro
®. (These materials are available from some garden
shops and fertilizer companies). You can measure milliliters
using a simple measuring spoon for liquid medicines
obtainable at most drug stores.) Apply 1 cup of
fertilizer solution once a week to each pot.
11.
Associations between the host plant roots and the
arbuscular mycorrhizal fungi should form in approximately
six weeks, depending on temperature and sunlight.
To confirm that mycorrhizal associations have
formed, excavate several roots containing fine branches
after six weeks and send to CTAHR’s Agricultural Diagnostic
after six weeks and send to CTAHR’s Agricultural Diagnostic
Service Center for determination of mycorrhizal
associations (see instructions for sending on page 2).
associations (see instructions for sending on page 2).
12.
To produce a mycorrhizal inoculum containing
spores, continue growing the host plant for 16 weeks.
Withhold water beginning at 14 weeks after planting.
At 16 weeks, remove the plant tops and discard them.
Dump the medium and roots from the pots onto a clean
tray. Cut up the dried roots with scissors, mix the fragments
tray. Cut up the dried roots with scissors, mix the fragments
with the medium, and store this as a “crude inoculum”
in a refrigerator or a cool, dry location. It can
be stored for up to one year.
in a refrigerator or a cool, dry location. It can
be stored for up to one year.
SCM-5 Arbuscular Mycorrhizal Fungus Production and Inoculation Techniques CTAHR
— July 2003
4
How are plants inoculated in the nursery?
1.
Surface-sterilize the seeds. For example, for koa seeds,
soak them in a 10% solution of household bleach (1 volume
of bleach plus 9 volumes water) for 5–10 minutes.
For other plant species, you may need to try more dilute
concentrations of bleach solution or a shorter soaking duration
to ensure surface-sterilization without harming the
to ensure surface-sterilization without harming the
seeds. Test a few seeds before treating large batches to be
sure that the treatment will not inhibit their germination.
For seeds that have seed-coat dormancy, additional
treatment may be needed to ensure good germination.
For example, koa seeds can be immersed in hot water
removed from the stove after it reaches boiling, and
soaked overnight.
sure that the treatment will not inhibit their germination.
For seeds that have seed-coat dormancy, additional
treatment may be needed to ensure good germination.
For example, koa seeds can be immersed in hot water
removed from the stove after it reaches boiling, and
soaked overnight.
2.
Germinate the seeds between moistened paper towels
on a plate enclosed in a loosely sealed plastic bag.
Alternatively, if you have developed an effective surface
sterilization technique, you could plant ungerminated
seeds directly into the potting media.
3.
Selection of a medium with low P is critical to successful
development of mycorrhizal fungus associations
with plant roots
. We have successfully used a mixture
of 1 volume of volcanic ash soil (a highly P-fixing
soil collected along the Hamakua Coast) with 1 volume
of Sunshine
® Mix #2 from Sun GroTM, or a mixture of 1
volume of volcanic ash soil with 1 volume of Sunshine
Mix #2 and 1 volume of crushed basaltic rock. Or, use 1
volume of peat moss (for example, Sunshine Mix #2)
mixed with 3 volumes of either vermiculite, perlite, or
volcanic cinder.
volcanic cinder.
4.
Sterile medium is critical to success in developing
mycorrhizal fungus associations with plant
roots
. To prevent pathogen problems or competition
from other microorganisms, sterilize the nursery
medium in an autoclave or pressure cooker for
60 minutes. Or, use a steam-sterilizer and raise the
temperature of the medium to 200
°F for 60 minutes.
In the case of soil, let it cool and aerate for 2–
7 days to allow release of possible toxins generated
by heating.
5.
Inoculate the nursery medium with arbuscular
mycorrhizal inoculum at a rate of 1 volume of inoculum
to 20 volumes of medium.
6.
Plant surface-sterilized seeds in pots containing
the sterilized medium. Or, put
1⁄2 ounce (5–10
grams) of inoculum into each planting hole before sowing
the seeds.
7.
Water daily until water begins to flow out of the bottom
of the pot.
8.
Apply a low-P, slow-release fertilizer such as 19-5-
12 Apex
® Foliage Fertilizer or another low-P (such as
17-6-10), slow-release formulation. Alternatively, make
your own low-P fertilizer as described earlier (Step 10
under
How is arbuscular mycorrhizal fungus inoculum
produced?
). The amount of fertilizer applied depends
on your plant species and pot size. You will need to determine
the proper amount through careful observation
of plant growth. For example, for koa seedlings grown
in Super Cell tubes (10 cubic inches, #SC-10, Steuwe
and Sons, Inc.), we applied 10 milliliters per tube per
and Sons, Inc.), we applied 10 milliliters per tube per
week.
9.
After six weeks, confirm presence of arbuscular mycorrhizal
fungus associations by submitting root samples
to ADSC as described on page 2.
References
Miyasaka, S.C., and M. Habte. 2001. Plant mechanisms and mycorrhizal
symbioses to increase phosphorus uptake efficiency.
Commun. Soil Sci. Plant Anal. 32: 1101–1147.
Corn in a 10-inch pot ready to be harvested for inoculum.
The koa at right grew better in a low-P
Commun. Soil Sci. Plant Anal. 32: 1101–1147.
Habte, M., and N.W. Osorio. 2001. Arbuscular mycorrhizas: producing
and applying arbuscular mycorrhizal inoculum. CTAHR,
Univ. of Hawaii, Honolulu. 47 pp.
Silva, J.A., and R.S. Uchida (eds.). 2000. Plant nutrient management
in Hawaii’s soils: approaches for tropical and subtropical
agriculture. CTAHR, Univ. of Hawaii, Honolulu. 158 pp.
Gemma, J.N., and R.E. Koske. <www.hawaii.edu/scb/
scinativ_mycor.html>
and applying arbuscular mycorrhizal inoculum. CTAHR,
Univ. of Hawaii, Honolulu. 47 pp.
Silva, J.A., and R.S. Uchida (eds.). 2000. Plant nutrient management
in Hawaii’s soils: approaches for tropical and subtropical
agriculture. CTAHR, Univ. of Hawaii, Honolulu. 158 pp.
Gemma, J.N., and R.E. Koske. <www.hawaii.edu/scb/
scinativ_mycor.html>
Corn in a 10-inch pot ready to be harvested for inoculum.
The koa at right grew better in a low-P
soil when inoculated with fungus
.
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