The large catch increase of the 1960s and 1970s was largely due the seaward and southward expansion of industrial (notably trawl) fisheries from waters along the coasts of developed countries
of the Northern Hemisphere. When this expansion ended – in Antarctic waters – catches could increase only by fishing in deeper waters [8] and [9]. Scientists with expertise on fishes, fisheries and Navitoclax research buy deep-sea biology question whether deep-sea fisheries can be sustainable [9], [10], [11], [12], [13], [14], [15], [16], [17], [18] and [19]. A sound answer depends on but transcends ecology, taking ocean policy makers into the realms of economics and law. Despite sharing an Ancient Greek root (oikos, meaning household), ecology and economics have diverged in their world views, often leading their practitioners to differing strategies for managing our collective household, the biosphere, including the Z-VAD-FMK clinical trial 99% of its volume that is ocean. But there are fundamental similarities between ecology and economics. In fisheries it is commonplace to call populations “stocks,” alluding to their similarity to capital stocks in economics. Central to this paper is the analogy
between (a) the biomass of fish stocks and the productivity they generate, with (b) capital stocks (principal) and the dividends (or interest) they generate. With deep-sea fisheries as our focus, this paper examines what the authors are calling Clark’s Law, the seminal connection between Exoribonuclease the ecological and economic determinants of sustainability as first explained in Clark [20] and [21]. Using comparable metrics and combining insights and the evidence from fisheries, ecology, economics and international ocean governance, this
paper examines whether deep-sea fisheries can be sustainable. Governments and international governing organizations need to know this because maintaining biodiversity in the deep sea is crucial to biogeochemistry on a global scale, and hence to humankind [22] and [23]. Commercial fishing is occurring at increasing depths around the globe. Based on readily available catch data series and fish life history parameters, Morato et al. [24] showed that marine fisheries worldwide have operated at increased depths since the 1970s. In the high seas (i.e. beyond countries’ exclusive economic zones, EEZs), the increasing depth of fishing was more dramatic, some 250 m. They based this inference on the relative increase in the global catch of species (or higher taxa) known to occur in deeper waters, which have increased 7-fold since the mid-1960s [25]. As fisheries operated farther offshore and deeper, exploiting increasing portions of the ranges of marine species [26] and [27], they also exploited the deeper part of these species’ ranges.