Mitochondrial genomes suggest rapid evolution of dwarf California Channel Islands foxes (Urocyon littoralis).

Island endemics are typically differentiated from their mainland progenitors in behavior, morphology, and genetics, often resulting from long-term evolutionary change. To examine mechanisms for the origins of island endemism, we present a phylogeographic analysis of whole mitochondrial genomes from the endangered island fox (Urocyon littoralis), endemic to California's Channel Islands, and mainland gray foxes (U. cinereoargenteus). Previous genetic studies suggested that foxes first appeared on the islands >16,000 years ago, before human arrival (~13,000 cal BP), while archaeological and paleontological data supported a colonization >7000 cal BP. Our results are consistent with initial fox colonization of the northern islands probably by rafting or human introduction ~9200-7100 years ago, followed quickly by human translocation of foxes from the northern to southern Channel Islands. Mitogenomes indicate that island foxes are monophyletic and most closely related to gray foxes from northern California that likely experienced a Holocene climate-induced range shift. Our data document rapid morphological evolution of island foxes (in ~2000 years or less). Despite evidence for bottlenecks, island foxes have generated and maintained multiple mitochondrial haplotypes. This study highlights the intertwined evolutionary history of island foxes and humans, and illustrates a new approach for investigating the evolutionary histories of other island endemics.

Pleistocene to historic shifts in bald eagle diets on the Channel Islands, California.

Studies of current interactions among species, their prey, and environmental factors are essential for mitigating immediate threats to population viability, but the true range of behavioral and ecological flexibility can be determined only through research on deeper timescales. Ecological data spanning centuries to millennia provide important contextual information for long-term management strategies, especially for species that now are living in relict populations. Here we use a variety of methods to reconstruct bald eagle diets and local abundance of their potential prey on the Channel Islands from the late Pleistocene to the time when the last breeding pairs disappeared from the islands in the mid-20th century. Faunal and isotopic analysis of bald eagles shows that seabirds were important prey for immature/adult eagles for millennia before the eagles' local extirpation. In historic times (A.D. 1850-1950), however, isotopic and faunal data show that breeding bald eagles provisioned their chicks with introduced ungulates (e.g., sheep), which were locally present in high densities. Today, bald eagles are the focus of an extensive conservation program designed to restore a stable breeding population to the Channel Islands, but native and nonnative prey sources that were important for bald eagles in the past are either diminished (e.g., seabirds) or have been eradicated (e.g., introduced ungulates). In the absence of sufficient resources, a growing bald eagle population on the Channel Islands could expand its prey base to include carrion from local pinniped colonies, exert predation pressure on a recovering seabird population, and possibly prey on endangered island foxes.

Does the order of invasive species removal matter? The case of the eagle and the pig.

BACKGROUND: Invasive species are recognized as a primary driver of native species endangerment and their removal is often a key component of a conservation strategy. Removing invasive species is not always a straightforward task, however, especially when they interact with other species in complex ways to negatively influence native species. Because unintended consequences may arise if all invasive species cannot be removed simultaneously, the order of their removal is of paramount importance to ecological restoration. In the mid-1990s, three subspecies of the island fox Urocyon littoralis were driven to near extinction on the northern California Channel Islands owing to heightened predation by golden eagles Aquila chrysaetos. Eagles were lured to the islands by an abundant supply of feral pigs Sus scrofa and through the process of apparent competition pigs indirectly facilitated the decline in foxes. As a consequence, both pigs and eagles had to be removed to recover the critically endangered fox. Complete removal of pigs was problematic: removing pigs first could force eagles to concentrate on the remaining foxes, increasing their probability of extinction. Removing eagles first was difficult: eagles are not easily captured and lethal removal was politically distasteful. METHODOLOGY/PRINCIPAL FINDINGS: Using prey remains collected from eagle nests both before and after the eradication of pigs, we show that one pair of eagles that eluded capture did indeed focus more on foxes. These results support the premise that if the threat of eagle predation had not been mitigated prior to pig removal, fox extinction would have been a more likely outcome. CONCLUSIONS/SIGNIFICANCE: If complete eradication of all interacting invasive species is not possible, the order in which they are removed requires careful consideration. If overlooked, unexpected consequences may result that could impede restoration.

Evaluation of Misoprostol and Analogs as Inhibitors of T-Cell Activation.

Prostaglandin E(2) (PGE(2)) is known to inhibit in vitro T-cell responses to mitogenic and antigenic stimuli. Interaction of PGE(2) with a G protein-coupled receptor activates adenylyl cyclase, leading to cAMP formation and inhibition of interleukin-2 (IL-2) production and T-cell proliferation. Despite these effects, the application of PGE(2) as an anti-inflammatory agent has been compromised by its unfavorable pharmacodynamic and side-effect profile. Because of the potential utility of synthetic analogs as prostaglandin-based therapeutics, we evaluated the effect of misoprostol and over 100 structural analogs on cAMP formation and T-cell activation. Our results indicate that micromolar concentrations of misoprostol and particular analogs elicited a rapid and substantial rise in cAMP levels in human peripheral blood mononuclear cells. Analogs which increased cAMP also suppressed IL-2 production and T-cell growth in vitro, whereas those devoid of suppressive activity weakly induced nucleotide synthesis. Despite extensive chemical alteration of the prostanoid structure, no single analog was superior to misoprostol in inducing cAMP or modulating T-cell activity. Misoprostol and suppressive analogs were also evaluated in vivo in a murine model of antigen-induced T-cell proliferation. Prostaglandins, administered at maximum tolerable doses, were ineffective in blocking a T-cell response to alloantigenic stimulation, whereas cyclosporine and prednisolone were potent inhibitors of this response. Overall, our results indicate that misoprostol and related analogs suppress T-cell activation in vitro but require concentrations 1000-fold greater than the low nanomolar plasma levels achieved with clinical doses of misoprostol. Whether misoprostol analogs of sufficient potency can be developed for pharmacologic attentuation of T-cell activation in vivo remains to be determined.

A MORPHOLOGIC AND GENETIC STUDY OF THE ISLAND FOX, UROCYON LITTORALIS.

The Island Fox, Urocyon littoralis, is a dwarf form found on six of the Channel Islands located 30-98 km off the coast of southern California. The island populations differ in two variables that affect genetic variation: effective population size and duration of isolation. We estimate that the effective population size of foxes on the islands varies from approximately 150 to 1,000 individuals. Archeological and geological evidence suggests that foxes likely arrived on the three northern islands minimally 10,400-16,000 years ago and dispersed to the three southern islands 2,200-4,300 years ago. We use morphometrics, allozyme electrophoresis, mitochondrial DNA (mtDNA) restriction-site analysis, and analysis of hypervariable minisatellite DNA to measure variability within and distances among island fox populations. The amount of within-population variation is lowest for the smallest island populations and highest for the mainland population. However, the larger populations are sometimes less variable, with respect to some genetic measures, than expected. No distinct trends of variability with founding time are observed. Genetic distances among the island populations, as estimated by the four techniques, are not well correlated. The apparent lack of correspondence among techniques may reflect the effects of mutation rate and colonization history on the values of each genetic measure.