produce long-lived diapausing egg banks (De Stasio,1989; Hairstonet al., 1995;
Ca ́ceres,1998 ; Brendonck & De Meester,2003 ; Vandekerkhoveet al., 2005 ), which
lower local extinction risk. Such dormancy can be seen to represent dispersal
in time, and theoretical and empirical data predict trade-offs between spatial
and temporal dispersal (Venable & Lawlor,1980 ; Levin, Cohen & Hastings,1984 ;
Hairston & Ca ́ceres,1996 ), suggesting that dispersal rate may actually be lower in
taxa whose eggs can remain dormant for long periods. This may impact on the
timing of local colonization events (Ca ́ceres & Soluk,2002 ), but over larger spatial
and temporal scales the production of resting propagules is likely to lead to larger
ranges due to increased propensity for long-distance dispersal.
Adult body size is well documented for the canthocamptid species considered
by Rundleet al.(2000; 2002b), and reanalysis of these data reveal a consistent
tendency for widespread taxa to be larger than their restricted relatives, at both
a global and European scale (Fig.10.4). Mechanisms that may underlie this
apparent trend are unclear, but may relate to relative reproductive output: if
larger-bodied taxa have higher fecundity this may increase the likelihood of
long-range dispersal. Studies of other groups such as Cladocera would be useful
here, as would comparative data on egg size, survivorship and estimates of
effective dispersal distances.
As discussed above, the dispersal biology of many passively-dispersing fresh-
water taxa has similarities with that in seed plants. Levinet al.(2003) note
that modelling studies of seed dispersal demonstrate that both mean dispersal
distance and the overall distribution of dispersal distance are critical in0.40.50.60.70.8European GlobalAdult body length (mm)Figure 10.4Mean body size (SE) of freshwater canthocamptid copepods, which can be
considered as geographically restricted, i.e. found in one area of endemicity (white bars),
or widespread, i.e. found in>1 area of endemicity (grey bars), at global and Western
European scales. Widespread species were significantly larger for both global
(T 40 ¼2.02, p¼0.015) and European (T 81 ¼1.99, p<0.050) data.198 S. D. RUNDLEET AL.