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The Relationship between the Maximum Temperature and the Seasonal Longevity of Glossina submorsitans, Newst., and G. tachinoides, Westw., in Northern Nigeria

Published online by Cambridge University Press:  10 July 2009

T. A. M. Nash
T. A. M. Nash
Affiliation:
Entomologist, Tsetse Investigation, N. Nigeria.
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Extract

1. There is considerable seasonal variation in the longevity of G. submorsitans and G. tachinoides, and these variations are negatively correlated with the fluctuations in the maximum temperature curve, i.e., as the temperature rises longevity decreases, as the temperature falls so longevity increases.

2. The cycle is as follows:—The rains commence and temperature falls, longevity increases and remains high throughout the rains. The wet season ends, temperature rises and longevity descreases. The cold spell intervenes and longevity becomes maximal. The cold weather ends, the temperature soars up and longevity becomes minimal, remaining low until the new rains commence.

3. Maximum temperature is considered to be the dominant factor; favourable humidity cannot increase longevity unless the maximum temperature is favourable.

4. The oldest individuals occur in the rains, but the average longevity is highest in the cold season, when both temperature and humidity are favourable.

5. In both species females tend to live longer than males.

6. In the field G. tachinoides males appear to live rather longer than the males of G. submorsitans.

7. It is doubtful whether wild flies of either species live much more than 2½ to 3 months under the most favourable conditions; it is probable that in the hottest weather longevity is curtailed to a month or less, and that the production of puparia is seriously affected when the rains are late and the hot weather is prolonged.

Type
Original Articles
Information
Bulletin of Entomological Research , Volume 27 , Issue 2 , July 1936 , pp. 273 - 279
Copyright
Copyright © Cambridge University Press 1936

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References

Buxton, P. A. & Lewis, D. F. (1934). Climate and tsetse-flies: Laboratory studies upon Glossina submorsitans and tachinoides.—Phil. Trans. Roy. Soc. London (B) 224, pp. 175240.Google Scholar
Carpenter, G. D. H. (1912). Progress report on investigations into bionomics of Glossina palpalis.—Rep. Sleeping Sickness Comm. Roy. Soc., no. 12, p. 79.Google Scholar
Carpenter, G. D. H. (1913). Second report on bionomics of Glossina fuscipes (= palpalis) of Uganda.—Rep. Sleeping Sickness Comm. Roy. Soc., no. 14, p. 1.Google Scholar
Fraser, A. D. & Duke, H. L. (1912). Various experiments.—Rep. Sleeping Sickness Comm. Roy. Soc., no. 12, p. 75.Google Scholar
Harris, R. H. (1930). Report on the bionomics of the tsetse fly (Glossina pallidipes Aust.).—The Natal Witness, Pietermaritzburg.Google Scholar
Kinghorn, A. (1912). Notes on the preliminary stages of Glossina morsitans, Westw.—Bull, Ent. Res., 2, p. 291.CrossRefGoogle Scholar
Nash, T. A. M. (1935). The effect of high maximum temperatures upon the longevity of Glossina submorsitans and G. tachinoides.—Bull. Ent. Res., 26, p. 103.CrossRefGoogle Scholar
Nash, T. A. M. (1936). The part played by microclimates in enabling Glossina submorsitans and G. tachinoides to withstand the high temperatures of a West African dry season.—Bull. Ent. Res., 27, p. 339.CrossRefGoogle Scholar