Lake trophic structure is a result of complex interactions among consumers and their resources. Algal productivity is channeled to higher trophic levels, which in turn structure planktonic consumer food webs and control algal biomass through cascading trophic interactions (Shapiro 1980, Carpenter et al. 1985. Top predators also affect benthic food web structure (Bronmark et al. 1992). However, cascading effects in benthic food webs are confounded by habitat complexity in the littoral zone and accumulation of organic matter in lake sediments (Crowder and Cooper 1982, Gilinsky 1984, Hershey 1985, 1992, Carpenter and Lodge 1986). Thus, benthic-pelagic coupling is not well integrated into the current understanding of lake trophic dynamics. However, because arctic lake food webs are dominated by benthic-pelagic interactions, a model that focuses on planktonic food webs does not describe them well. Lake ecosystems are embedded within the landscape but have rarely been studied in that context. One of the best contexts to examine this question is the Arctic, where geomorphic constraints on fish distribution are especially apparent because the fish community is small and geographically constrained. The benthic and pelagic invertebrate communities are also not species rich, although their trophic diversity is similar to that found in temperate lakes. The arctic landscape therefore provides a unique opportunity to resolve the relationships between geomorphic setting, fish distribution, and lake trophic structure. A unifying conceptual model of the arctic landscape is the geomorphic-trophic hypothesis (Figure 1). This model integrates lake processes into their geomorphic setting by illustrating how the stream network constrains or channels the dispersal of fish and links fish dispersal with fish control of lake food webs; because landscape criteria control the distribution of fishes, and fish control lake trophic structure, the landscape indirectly controls lake trophic structure. Similar principles have been applied to fish distributions in other systems (see Magnuson et al. 1998), and landscape factors are also known to affect hydrologically driven chemical parameters, which may in turn have implications for food web structure (Kratz et al. 1991(Kratz et al. , 1997). According to the geomorphic-trophic hypothesis for arctic lake food webs, extant and paleological landscape BECAUSE LANDSCAPE CRITERIA CONTROL THE DISTRIBUTION OF FISHES, AND FISH CONTROL LAKE TROPHIC STRUCTURE, THE LANDSCAPE INDIRECTLY CONTROLS LAKE TROPHIC STRUCTUREconstraints provide a template resulting in lakes with six different types of fish communities (Figure 1): lakes dominated by lake trout (Salvelinus namaycush) but also usually containing grayling (Thymallus arcticus), sculpin (Cottus cognatus), burbot (Lota Iota), round whitefish (Prosopium cylindraceum), and, rarely, arctic char (Salvelinus alpinus); lakes containing arctic char and sculpin; lakes with grayling and sculpin; lakes with grayling only throughout the year; lakes with grayling in the...
