Withdrawal of water for human needs

Withdrawal of water for human needs can reduce the total amount of water available to
aquatic biota (resulting in low stream flows and declining lake levels), reduce seasonal
BUYING TIME: A USER'S MANUAL 205
CHAPTER 8
variability in flows, and lead to large losses of habitat, particularly valuable edge habitats
that are used for spawning or rearing (Tyedmers and Ward, 2001). Withdrawal of
groundwater for agriculture in adjacent areas can completely dry up valuable wetlands,
even if the habitat itself is protected (McDowall, 1984). Water that is withdrawn from
freshwater systems is often returned in the form of household wastewater, agricultural
runoff, or industrial cooling water, with reduced quality (increased pollutants, changes
in nutrient load) and altered temperature.
FILLING OR DRAINING SHALLOW HABITATS
Wetlands throughout the world have been filled or drained for development or agriculture
(Brinson and Malvarez, 2002; Junk, 2002). These habitats have traditionally been
regarded as useless in their natural state, and many countries have provided subsidies to
encourage the conversion of wetlands to agricultural land. Thankfully, the valuable
ecosystem services that wetlands provide, including water purification, groundwater
recharge, and flood control, are becoming more widely appreciated (National Research
Council, 1995).
Invasive species
Apart from direct alterations of system hydrology, the most serious threat to freshwater
ecosystems in many areas is the presence of invasive, non-native species. Invaders are
often adaptable generalists who breed and disperse quickly, endangering native species
through highly efficient competition, predation, or habitat alteration.
DELIBERATE INTRODUCTIONS
The deliberate introduction of non-native species for commercial or recreational fishing
is widespread; for example, approximately 80% of the alpine lakes in the western United
States have been stocked with non-native fish (Bahls, 1992). In many areas, lakes and
streams are continuously re-stocked to maintain populations. Although these fisheries
generate enormous income, the effects on freshwater communities can be devastating.
Hundreds of native fish species in North America are threatened, and competition or
predation by non-natives is the primary threat to many of these species (Allan and
Flecker, 1993; Schindler, 2001). In Lake Victoria, increased predation and competition
due to the introduction of the Nile perch and several non-native tilapiine species (in addition
to ongoing environmental changes in the lake), led to the extinction of up to 200
endemic cichlid species within a few decades (Ogutu-Ohwayo, 1990; Witte et al., 1992).
ACCIDENTAL INTRODUCTIONS
Many species are introduced to and spread throughout freshwater ecosystems accidentally—for
example, non-native species can be attached to boats or transported in ballast
or bilge water. The zebra mussel, which is native to Europe, was accidentally introduced
to the Great Lakes in 1986 through ballast water. It has altered water chemistry through
highly efficient filter feeding, outcompeted populations of native mussels, and fouled
boats, docks, and power plant intakes, costing millions of dollars in damage (Cooley,
1991; Effler et al., 1996; Nalepa et al., 1996). Several species of native mussels, clams,
206 WORLD WILDLIFE FUND
and commercially important fish are threatened directly or indirectly by its presence
(Nalepa et al., 1996; Roberts, 1990).