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Shahram Kaboodvandpour

Shahram Kaboodvandpour

Academic rank: Assistant Professor
ORCID:
Education: PhD.
ScopusId: 17135001200
HIndex:
Faculty: Faculty of Natural Resources
Address: Shahram Kaboodvandpour, Environmental Sciences Department, Natural Resources Faculty, University of Kurdistan, P.O.Box 416, Sanandaj, Iran. Post code: 66177-15175
Phone: 087 33620551

Research

Title
Does the house mouse self-regulate its density in maturing sorghum and wheat crops?
Type
JournalPaper
Keywords
intraspecific competition; intrinsic population regulation; Mus domesticus; population eruption; rate of increase
Year
2008
Journal JOURNAL OF ANIMAL ECOLOGY
DOI
Researchers Shahram Kaboodvandpour ، Luke K-P Leung

Abstract

One of the central questions in population ecology and management is: what regulates population growth? House mouse Mus domesticus L. populations erupt occasionally in grain-growing regions in Australia. This study aimed to determine whether mouse populations are self-regulated in maturing sorghum and wheat crops. This was assessed by examining food supply to mice (i.e. yield) and the relationship between initial mouse density (DI) and density at harvest (DH). Eight levels of DI ranging from 89 to 5555 mice ha−1 were introduced to sorghum at the hard dough stage and to wheat crops at the milky stage in mouse-proofed pens. DH was measured by trapping out mice 49 days after the introduction. 2There were at least 3·11 tonnes ha−1 of wheat and 1·85 tonnes ha−1 of sorghum grain available for mice at harvest. The estimated relationship between DI and DH was asymptotic exponential, with DH initially increasing almost linearly with DI. When DI was above c. 500 mice ha−1, DH increased asymptotically with DI and then saturated at c. 3100 mice ha−1. The asymptotic increases in and saturation of DH was due partly to more young mice being born and recruited in pens treated with lower levels of DI. 3Our findings indicated that mouse densities in maturing cereal crops were driven by a numerical response of mice to the abundant supply of grain, modified by some unknown self-regulation mechanism that reduced this numerical response of mice at higher mouse densities. The mechanism was possibly spacing behaviours. Although the nature of this self-regulation mechanism is not known our model is, nevertheless, useful for predicting increases and eruptions in mouse population density in sorghum and wheat crops. Understanding the nature of this mechanism may provide insights into population processes that can be exploited in controlling mice in cereal crops