SUPPRESSION OF PLANT PARASITIC NEMATODES AND ARTHROPOD PESTS BY VERMICOMPOST ‘TEAS’

Clive A. Edwards, Norman Q. Arancon, Eric Emerson, and Ryan Pulliam

Soil Ecology Laboratory
The Ohio State University
Columbus, OH

INTRODUCTION

The production and use of aqueous extracts of thermophilic composts and vermicomposts, commonly termed
‘teas’, has expanded rapidly in the last 2-3 years, particularly since there is now a range of commercial ‘tea
brewing’ equipment available that can produce large or small quantities of ‘teas’.  Unfortunately, there are
relatively few published scientific studies which have reviewed the methods of production and uses of compost
or vermicompost ‘teas’, optimal dilutions or application rates.

These ‘teas’ have been used extensively, particularly by organic gardeners and farmers, to promote plant
growth by application to soils as drenches, and to suppress plant diseases by soil or foliar sprays, and these
uses are still increasing as their methods of application and effectiveness is gradually being established.

PRODUCTION OF VERMICOMPOST ‘TEAS’

Research in our laboratory has shown clearly that some form of agitation or aeration during production of
vermicompost ‘teas’ is necessary, if the ‘teas’ are to be effective in promoting crop growth and suppressing
pests and diseases.  We have research under way into the ‘shelf-life’ of vermicompost ‘teas’ under different
temperatures and in a range of containers.  We have demonstrated the transport of microbial activity and
diversity, key nutrients, and enzymatic activity from solid vermicomposts into ‘teas’.  Additionally, all our
experience of the use of ‘teas’ in greenhouse trials has confirmed that the sooner a vermicompost ‘tea’ is used
after it is ‘brewed’, the more effective it is in influencing plant growth and in suppressing pests and diseases.  
We have tested vermicompost ‘teas’ extracted from vermicomposts, that were produced from a range of
animal manures such as pig or cattle wastes, as well as paper and food wastes, and all have been effective in
promoting plant growth and disease suppression, independent of nutrient supply.  After many laboratory and
greenhouse trials, we decided that the optimal quantities of solid vermicomposts to water ratios were: 1:5
(20%), 1:10 (10%) and 1:20 (5%).

EFFECTS OF VERMICOMPOST ‘TEAS’ ON PLANT PARASITIC NEMATODES

We have demonstrated clearly that solid vermicomposts can suppress plant parasitic nematodes in the field
(Arancon et al, 2003).  Our experiments on the effects of vermicompost ‘teas’ on nematodes were in the
laboratory and greenhouse, in soils that had been artificially infested with the root knot of nematode
(Meloidogyne incognita), which is a very serious pest of a wide range of crops all over the world.  Six-week-old
tomato seedlings were transplanted into 10 cm diameter pots containing a sand:loam (1:3) soil mixture to
which the test ‘tea’ treatments were applied.  Drench treatments of ‘teas’ were applied at seedling
transplanting, and every two weeks thereafter.  One week after transplanting 10,000 Meloidogyne hapla eggs
were added to each plant pot in suspension in tap water.  The eggs were collected from cultures maintained
on infested tomato plants.  Each treatment was replicated four times.  Pots into which tomato plants had been
transplanted were arranged on benches in a completely randomized design and the greenhouse was
maintained at 25˚ C.  Plants were watered regularly with tempered line water.  Thirty days after infestation with
nematodes, soil was removed from the pots and the roots were washed to assess the extent of root damage
and the numbers of root knots.  The washed roots were rated for numbers of root knot galls and the numbers
of galls per unit wet weight of roots counted.  The effects of the nematodes on plant height were determined
by growth measurements, including heights, leaf areas, fresh and the dry weights of leaves from plant tops
and the dry weights of all above-ground tissues at the end of the experiment.























Figure 1. A comparison of tomato plants infested with Meloidogyne hapla and treated with vermicompost or
thermophilic compost ‘teas’. Plants were grown in MM360 with all needed nutrients supplied.

The relative growth of the tomato plants in response to the nematode infestations after 30 days, are illustrated
in Figure 1.  The differences in growth between treatments, in response to the vermicompost ‘teas’ were
spectacular, and the reductions in numbers of root knot galls on the tomato roots in response to the
vermicompost ‘tea’ applications was considerable (Figures 2 and 3).  These effects of vermicompost ‘teas’ on
plant parasitic nematode attacks were very similar to those in experiments that used solid vermicompost
substituted into Metro-Mix 360 in the greenhouse (Arancon et al 2003).


























Figure 2. Numbers of galls of Meloidogyne hapla on the roots of tomato plants grown in soil treated with
different dilutions of aerated vermicompost and compost ‘teas’.


































Figure 3. The roots of tomato plants infested with Meloidogyne hapla and treated with 5%, 10%, 20% aerated
vermicompost ‘teas’ or 20% thermophilic compost ‘tea’ compared with those treated with only water (control).

EFFECTS OF VERMICOMPOST ‘TEAS’ ON ARTHROPOD PESTS

We have shown that solid vermicomposts can suppress spider mite, mealy bug, and aphid populations in the
field (Arancon et al 2007).  For our preliminary experiments into the suppression of arthropod pests by
vermicompost ‘teas’, we chose two important groups of plant pests, aphids, and spider mites.  For the spider
mite experiments, four tomato plants were placed into each 0.2 mm mesh cage (40 cm x 30 cm x 30), and 100
two-spotted spider mites (Tetranychus sp.) were released into each infested cage, with four replicate cages
for each treatment.  The plants were treated with either water (control), aerated thermophilic 20% compost
‘tea’, or aerated 5%, 10%, or 20% vermicompost ‘tea’, produced from food waste vermicompost.  The damage
to the plants in these cages was assessed on a damage rating of 0 (no damage) to 5 (100% damage), eight
days after pests were introduced into the cages.  There were four replicate cages with no spider mite
infestations, in order to assess any changes in leaf weights caused by the spider mite infestations.

Because spider mites are so small we did not count them, instead we assessed the amounts of the distinct
damage that they caused to the plants.  All three soil application rates of vermicompost ‘teas’ decreased the
amounts of damage by the spider mites compared with the water control significantly (P < 0.05).  By
comparison the traditional thermophilic compost tea had no significant effect on the spider mite damage.  

We used the same experimental protocol in experiments on aphids.  In these experiments, 100 aphids (Myzus
persicae) were released onto four tomato plants, in each of the cages infected with aphids.  A set of cages
that had no aphid infestations was used to assess any changes in leaf weights caused by the aphids.  The
numbers of aphids on each plant were counted 13 days after infestation.  The results are summarized in
Figure 4.  Clearly, all three dilutions of aerated vermicompost ‘teas’ suppressed the aphid populations
significantly (P < 0.05) compared with the water control treatment whereas the aerated thermophilic compost
‘tea’ had no significant effects on the aphid populations.































Figure 4. Numbers of aphids on tomato plants, 13 days after 100 aphids had been released into each cage
containing four tomato plants in separate pots. Plants were grown in MM360 (with all needed nutrients
supplied)

These results on the suppression of aphids and spider mites by vermicompost ‘teas’ were very similar to those
obtained from growing plants in the greenhouse in Metro Mix 360, substituted with a range of solid
vermicomposts (Arancon et al 2007).  The suppression of aphids is particularly important since they are key
vectors in the transmission of plant viruses. It seems clear that there is a good potential for suppression of
arthropod pests by both vermicomposts and vermicompost ‘teas’ using methods very acceptable to organic
growers and farmers.

Further Reading

Arancon, N.Q., Yardim, E., Edwards, C.A., Lee, S., 2003.  The Trophic diversity of nematode communities in
soils treated with vermicomposts.  Pedobiologia 47, 736-740.

Arancon, N.Q., Edwards, C.A., Oliver, T.J., Byrne, R.J. 2007 Suppression of two-spotted spider mite
(Tetranychus urticae), mealy bugs (Pseudococcus) and aphid (Myzus persicae) populations and damage by
vermicomposts.  Crop Protection 26, 26-39.

http://www.southernsare.org/News-and-Media/Press-Releases/NCSU-Research-Explains-How-Vermicompost-
Amended-Soils-Ward-Off-Crop-Pests