Three new species of saddled loricariid catfishes, and a review of Hemiancistrus, Peckoltia, and allied genera (Siluriformes)

(Figs 2–4). CORBIDI 14685, an adult male (Figs 2–4) from 13.5806 S, 75.2449 W (WGS84), Chicchobamba, upstream of Represa Negrayccassa, upper drainage of the Huaytará river, 3900 m, Provincia Huaytará, Región Huancavelica, Peru, collected by A. Catenazzi, V. Vargas García, and M. Jaico Huayanay

We describe a new species of Telmatobius from the Pacific slopes of the Andes in central Peru. Specimens were collected at 3900 m elevation near Huaytará, Huancavelica, in the upper drainage of the Pisco river. The new species has a snout–vent length of 52.5 ± 1.1 mm (49.3–55.7 mm, n = 6) in adult females, and 48.5 mm in the single adult male. The new species has bright yellow and orange coloration ventrally and is readily distinguished from all other central Peruvian Andean species of Telmatobius but T. intermedius by having vomerine teeth but lacking premaxillary and maxillary teeth, and by its slender body shape and long legs. The new species differs from T. intermedius by its larger size, flatter head, and the absence of cutaneous keratinized spicules (present even in immature females of T. intermedius), and in males by the presence of minute, densely packed nuptial spines on dorsal and medial surfaces of thumbs (large, sparsely packed nuptial spines in T. intermedius). The hyper-arid coastal valleys of Peru generally support low species richness, particularly for groups such as aquatic breeding amphibians. The discovery of a new species in this environment, and along a major highway crossing the Andes, shows that much remains to be done to document amphibian diversity in Peru.

The Tropical Andes are characterized by a large diversification of the aquatic frogs of the genus Telmatobius Wiegmann, 1834. Sixty-two species are currently recognized in this genus (AmphibiaWeb 2014; Aguilar and Valencia 2009; Frost 2014; including species previously assigned to Batrachophrynus Peters, 1873). The altitudinal distribution of Telmatobius ranges from 1000 m to 5400 m (De la Riva and Harvey 2003; Seimon et al. 2007), and its longitudinal distribution extends from the equator (T. niger Barbour & Noble, 1920, whose populations have been extirpated in Ecuador; Merino-Viteri et al. 2005) to 29°S, on the eastern slopes of the Argentinean Andes (T. contrerasi Cei, 1977). Twenty-eight species of Telmatobius are distributed in Peru (Lehr 2005; AmphibiaWeb 2014), but of these only five [T. arequipensis Vellard, 1955; T. intermedius Vellard, 1955; T. jelskii (Peters, 1873); T. peruvianus Wiegmann, 1834; T. rimac Schmidt, 1954] are known to occur in the hyper-arid coastal valleys that drain directly into the Pacific Ocean.

During October 2012 we made several surveys for the Biodiversity and Monitoring Assessment Program of the Smithsonian Conservation Biology Institute’s Center for Conservation Education and Sustainability (Catenazzi et al. 2013a; Catenazzi et al. 2013b). During one of these surveys, we found a population of Telmatobius in the upper drainage of the Huaytará river (Region of Huancavelica), a tributary of the Pisco river in the Pacific slopes of the central Peruvian Andes. Individuals of this population possess traits that do not correspond to the morphological characteristics of other species found in the arid coastal valleys of central Peru (Fig. 1), namely T. rimac to the north and T. intermedius to the south (Vellard 1951; Schmidt 1954; Lehr 2005). Therefore, here we describe the new species and provide a diagnosis to differentiate it from congeneric forms.

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Mass animal die-offs may be increasing, new research shows

Large numbers of dead sunfish and largemouth bass in April 2014 following a severe winter on Wintergreen Lake, Kalamazoo County, Michigan. (Photo courtesy of G. Mittelbach)

Mass die-offs of animals may be increasing in frequency and — for birds, fishes, and marine invertebrates — in severity as well, according to a study of 727 mass mortality events since 1940.

Despite the ecological importance of individual mass mortality events, in which a larger than normal number of individuals die within a population, little research has been conducted on patterns across mass mortality events. The new study will help researchers better assess trends in mass mortality events and their causes, according to the authors of the paper in the Jan. 12 issue of the Proceedings of the National Academy of Sciences.

“The initial patterns are surprising, in terms of the documented changes to frequencies of occurrences, magnitudes of each event, and the causes of mass mortality,” said Samuel Fey, a postdoctoral fellow in the Department of Ecology and Evolutionary Biology at Yale and co-lead author of the paper. “These data also show that we have a lot of room to improve how we document and study these types of rare events.”

Fey, along with fellow researchers at the University of San Diego and University of California-Berkeley, report that the magnitude of the die-offs has increased in birds, fishes, and marine invertebrates, held steady among mammals, and decreased in frogs and amphibians. The authors recognized that more scientific research has been done on mass mortality events in the last few decades but said even accounting for this “discovery bias” does not explain all of the increase in such events. The increase in mass mortality events appears to be associated with a rise in disease emergence, biotoxicity, and multiple interacting stressors, they note.

Overall, disease was the primary culprit, accounting for 26% of the mass die-offs. The impacts of direct human activity, primarily from environmental contamination, caused 19% of such events. Another major cause was biotoxicity triggered by events such as algae blooms, rapid increases of algae in water systems. Processes directly influenced by climate — such as weather extremes, thermal stress, oxygen stress, or starvation — also contributed accounted collectively for about 25% of mass mortality events.

The most severe events were those with multiple causes, the paper shows.

“This study should improve our understanding of the continuum of mortality patterns and processes that exist between background mortality levels and species-level extinctions,” Fey said.

Adam M. Siepielski of the University of San Diego was co-lead author of the paper. Stephanie M. Carlson of the University of California-Berkeley was senior author. Fey began working on this research while a graduate student at Dartmouth College.

Source: Yale University

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Cone snail venom holds promise for medical treatments for cancer, addiction

Professor Frank Marí in the Charles E. Schmidt College of Science at Florida Atlantic University holds a live Conus regius, a particular species of cone snail collected by the Marí group at the Florida Keys. Credit: Professor Anton Oleinik

While considered a delicacy in some parts of the world, snails have found a more intriguing use to scientists and the medical profession offering a plethora of research possibilities. Cone snails are marine mollusks, just as conch, octopi and squid, but they capture their prey using venom. The venom of these marine critters provides leads for detection and possible treatment of some cancers and addictions.

Frank Marí, Ph.D., professor in the Department of Chemistry and Biochemistry in FAU's Charles E. Schmidt College of Science at Florida Atlantic University, has focused his research on cone snail venom and has published a study in the current issue of the Journal of Biological Chemistry.

"The venom produced by these animals immobilizes prey, which can be worms, other snails and fish," said Marí. "The venom is an extraordinary complex mixture of compounds with medicinal properties."

The venom components selectively target cells in the body and make them valuable drug leads and powerful molecular tools for understanding the human body's processes. One class of venom components is the alpha-conotoxins, named so because they target nicotinic receptors that are central to a range of diseases such as Alzheimer's disease, schizophrenia, tobacco addiction and lung cancer.

The venom of a particular species of cone snail, Conus regius, collected by the Marí group at the Florida Keys, is particularly rich in alpha conotoxins. Aldo Franco, Ph.D., who worked in Marí's lab, described more than ten new alpha-conotoxins in his Ph.D. dissertation at FAU. 

Among these, they found RegIIA, a compound that potently blocked the alpha3beta4 nicotinic receptor. This particular receptor when activated can be associated with lung cancer and nicotine addiction.

"We investigated in detail how RegIIA interacts with the alpha3beta4 nicotinic receptors and embarked on engineering new compounds that were more specific toward alpha3beta4 receptors and not other nicotinic receptors," said Marí. "Our aim is to open new avenues for cancer and addiction research inspired on compounds from marine animals."

Cone snails can be found throughout the Florida coast at different depths. Marí and his team regularly collect these animals using SCUBA and sometimes using deep-water submarines.

Source: Florida Atlantic University

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Climate change projected to drive species northward

Coho salmon are among the species anticipated to shift northward with climate change. Credit: NOAA Fisheries

Anticipated changes in climate will push West Coast marine species from sharks to salmon northward an average of 30 kilometers per decade, shaking up fish communities and shifting fishing grounds, according to a new study published in Progress in Oceanography.

The study suggests that shifting species will likely move into the habitats of other marine life to the north, especially in the Gulf of Alaska and Bering Sea. Some will simultaneously disappear from areas at the southern end of their ranges, especially off Oregon and California.

"As the climate warms, the species will follow the conditions they're adapted to," said Richard Brodeur, a NOAA Fisheries senior scientist at the Northwest Fisheries Science Center's Newport Research Station and coauthor of the study. "We're going to see more interactions between species and there will be winners and losers that we cannot foresee."

The study, led by William Cheung of the University of British Columbia, estimated changes in the distribution of 28 near-surface fish species commonly collected by research surveys in the northeast Pacific Ocean. The researchers used established global climate models to project how the distribution of the fish would shift by 2050 as greenhouse gases warm the atmosphere and, in turn, the ocean surface.

Brodeur cautioned that like any models, climate models carry uncertainty. While they provide a glimpse of the most likely changes in global climate, they may be less accurate when estimating more fine-scale, local changes.

"Nothing is certain," he said, "but we think we have a picture of the most likely changes."
Some species shifts are already being documented as West Coast waters are warming: predatory Humboldt squid from Central and South America have invaded the West Coast of North America in recent years, albacore have shifted to more northerly waters and eulachon have disappeared from warming waters at the southern end of their range.

"Thinking more broadly, this re-shuffling of marine species across the whole biological community may lead to declines in the beneficial functions of marine and coastal ecosystems," said Tom Okey, a Pew Fellow in Marine Conservation at the University of Victoria and a coauthor of the study. "These declines may occur much more rapidly and in more surprising ways than our expected changes in species alone."

The study anticipates warm-water species such as thresher sharks and chub mackerel becoming more prominent in the Gulf of Alaska and off British Columbia. Some predators such as sea lions and seabirds, which rear their young in fixed rookeries or colonies, may find the fish they usually prey on moving beyond predators' usual foraging ranges.

"If their prey moves farther north, they either have to travel farther and expend more energy to get to them, or find something else to eat," Brodeur said. "It's the same thing for fishermen. If it gets warmer, the fish they depend on are going to move up north and that means more travel time and more fuel will be needed to follow them, or else they may need to switch to different target species. It may not happen right away but we are likely to see that kind of a trend."

El Nino years, when tropical influences temporarily warm the eastern Pacific, offer a preview of what to expect as the climate warms.

Shifts in marine communities may be most pronounced in high-latitude regions such as the Gulf of Alaska and Bering Sea, which the study identifies as "hotspots" of change. Cold-water species such as salmon and capelin have narrower temperature preferences than warmer water species, making them more sensitive to ocean warming and likely to respond more quickly.

An intrusion of warm-water species into cooler areas could lead to significant changes in marine communities and ecosystems. The diversity of northern fish communities, now often dominated by a few very prolific species such as walleye pollock, may increase as southern species enter the region, leading to new food web and species interactions.

Source: NOAA Fisheries West Coast Region

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