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Adult Rhinocyllus conicus. L.T.Kok |
Rhinocyllus conicus
(Coleoptera: Curculionidae)
by L. T. Kok, Department of Entomology
Virginia Institute of Technology and State University
Blacksburg VA 24061 |
Rhinocyllus conicus is a native of southern and central Europe,
North Africa, and western Asia. This thistle-head weevil was the first
insect introduced into North America for the biological control of musk
or nodding thistle. It was collected from the Rhine Valley in France and
released in Canada in 1968. In 1969, it was introduced into California,
Virginia, and Montana. Subsequently, it was relocated from Virginia to
other states in the USA.
Appearance
The adults are dark brown in color and about 10 to 15 mm long. In early
spring, they are yellowish brown in color due to the yellow tufts of hair
on their wings. As they age, they lose some of these hairs and turn brownish
black.
Habitat
Musk thistle and plumeless thistles are introduced Eurasian noxious
weeds in pastures, rangelands, croplands, and along state highways in many
parts of the USA. Their success is largely due to their prolific seed production,
seed longevity, competitive ability of the plants, and the lack of natural
enemies.
 
Left: Thistle stand before weevil release. Right:
Thistle stand after weevil release, 6 years later. L.T.Kok (both)
Pests Attacked
This weevil is quite host specific and feeds mainly on thistles belonging
to the Carduus, Cirsium and Silybum group in the family Asteraceae.
None of the economical plants belonging to the same family is attacked
by these weevils.
Life Cycle
R. conicus overwinters in the adult stage. It becomes active
in mid to late April, depending on temperature. Each female lays about
100-200 eggs. Oviposition is well synchronized with musk thistle development.
Eggs are laid on the bracts of developing buds and hatch in about 6 days.
Newly hatched larvae feed through the bracts into the buds. The larvae
feed on the receptacle and prevent the production of viable seeds. They
complete development in 4 to 6 weeks and turn into pupae in the thistle
heads. The new adult emerges in 7-10 days. These new adults do not stay
on the plants for long. They seek shelter and pass the summer in hiding,
and then hibernate in winter. They re-emerge in spring to lay eggs before
dying. There is one generation a year.
Relative Effectiveness
This thistle-head weevil is very effective in the control of musk or
nodding thistle. The first success in biological control of musk thistle
was documented in 1975 soon after the weevils were released in Virginia.
Typical musk thistle stand reductions of 80-95% occurred in sites where
the weevil became established. However, it only provides partial control
of plumeless thistle because the egg laying period of the weevil only covers
the development of the terminal thistle heads, but not the lateral heads.
Pesticide Susceptibility
This weevil is susceptible to the commonly used insecticides and thus
should not be exposed to insecticidal sprays. It is not directly affected
by commonly used herbicides and can be used in conjunction with herbicides
for thistle control. Larval development is indirectly affected by herbicides
if the thistle dies before larval feeding is completed. Herbicides are
best applied after the insect has completed development.
Commercial Availability
R. conicus is available commercially and is shipped in the adult
stage (see the off-site publication, Suppliers of Beneficial Organisms in North America). Collections of the overwintered adults in early spring must be released
without delay to allow them to lay their eggs before dying. Adults of the
new generation that are collected in the summer will not lay eggs until
the following spring. Thus, they can be released anytime after collection.
These weevils will hibernate and the survivors that successfully overwinter
will lay eggs in the spring.
References
Kok, L. T. and Surles, W. W. 1975. Successful biocontrol of musk thistle
by an introduced weevil, Rhinocyllus conicus. Environ. Entomol.
4:1025-1027.
Rowe, D. J. and Kok, L. T. 1985. Determination of larval instars, and
comparison of field and diet-reared larval stages of Rhinocyllus conicus
(Col.: Curculionidae). Virginia J. Sci, 36:277-280.
Smith, L. M., Ravlin, F. W., Kok, L. T., and Mays, W. T. 1984. Seasonal
model of the interaction between Rhinocyllus conicus (Coleoptera:
Curculionidae) and its weed host, Carduus thoermeri (Campanulatae: Asteraceae).
Environ. Entomol. 13:1417-1426.
Surles, W. W. and Kok, L. T. 1977. Ovipositional preference and synchronization
of Rhinocyllus conicus with Carduus nutans and C. acanthoides.
Environ. Entomol. 6:222-224.
Surles, W. W., Kok, L. T., and Pienkowski, R. L. 1974. Rhinocyllus
conicus establishment for biocontrol of thistles in Virginia. Weed
Sci. 22:1-3.
Trumble, J. T. and Kok, L. T. 1980. Integration of a thistle-head weevil
and herbicide for Carduus thistle control. Prot. Ecol. 2:57-64.
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law.
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Use of this material for educational purposes is encouraged. Please notify the
editors of such use and cite the
author (if credited on the page you are using). A recommended form for citing this website is:
Weeden, C.R., A. M. Shelton, and M. P. Hoffman. Biological Control: A Guide to Natural Enemies in North America.
http://www.nysaes.cornell.edu/ent/biocontrol/ accessed (date).
Suggestions, corrections, and/or comments are appreciated: Contact
Tony Shelton (ams5@nysaes.cornell.edu).
http://www.nysaes.cornell.edu/ent/biocontrol/weedfeeders/rhinocyllus_c.html
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