Diego Bernal

Mammal-like muscles power swimming in a cold-water shark

Effects of temperature on muscle contraction and powering movement are profound, outwardly obvious, and of great consequence to survival. To cope with the effects of environmental temperature fluctuations, endothermic birds and mammals maintain a relatively warm and constant body temperature, whereas most fishes and other vertebrates are ectothermic and conform to their thermal niche, compromising performance at colder temperatures. However, within the fishes the tunas and lamnid sharks deviate from the ectothermic strategy, maintaining elevated core body temperatures that presumably confer physiological advantages for their roles as fast and continuously swimming pelagic predators. Here we show that the salmon shark, a lamnid inhabiting cold, north Pacific waters, has become so specialized for endothermy that its red, aerobic, locomotor muscles, which power continuous swimming, seem mammal-like, functioning only within a markedly elevated temperature range (20–30 °C). These muscles are ineffectual if exposed to the cool water temperatures, and when warmed even 10 °C above ambient they still produce only 25–50% of the power produced at 26 °C. In contrast, the white muscles, powering burst swimming, do not show such a marked thermal dependence and work well across a wide range of temperatures.

Hematological indicators of stress in longline-captured sharks ☆

For many shark species, little information exists about the stress response to capture and release in commercial longline fisheries. Recent studies have used hematological profiling to assess the secondary stress response, but little is known about how, and to what degree, these indicators vary interspecifically. Moreover, there is little understanding of the extent to which the level of relative swimming activity (e.g., sluggish vs. active) or the general ecological classification (e.g., coastal vs. pelagic) correlates to the magnitude of the exercise-induced (capture-related) stress response. This study compared plasma electrolytes (Na(+), Cl(-), Mg(2+), Ca(2+), and K(+)), metabolites (glucose and lactate), blood hematocrit, and heat shock protein (Hsp70) levels between 11 species of longline-captured sharks (n=164). Statistical comparison of hematological parameters revealed species-specific differences in response to longline capture, as well as differences by ecological classification. Taken together, the blood properties of longline-captured sharks appear to be useful indicators of interspecific variation in the secondary stress response to capture, and may prove useful in the future for predicting survivorship of longline-captured sharks where new technologies (i.e., pop-up satellite tags) can verify post-release mortality.

Evidence for Temperature Elevation in the Aerobic Swimming Musculature of the Common Thresher Shark, Alopias vulpinus

Abstract This paper reports on the in vivo temperature measurements for slow-twitch, red aerobic muscle (RM) and fast twitch, white muscle (WM) of 24 Common Thresher Sharks, Alopias vulpinus, captured off the coast of Southern California. Mean (± SE) RM temperature elevation was 2.33 ± 0.30 C warmer than the ambient sea surface temperature (SST, 19.13 ± 0.22 C) and 2.25 ± 0.35 C warmer than the coldest WM temperature measured (19.23 ± 0.30 C). The maximum RM temperature elevation was 5.4 C above SST and up to 7.6 C above the WM. Nine Common Thresher Sharks exhibited RM temperatures that exceeded 3.0 C above SST. No significant relationship was found between fish total length and RM temperature elevation. Although there was individual variability in RM temperature elevation, this study documents that the Common Thresher Shark is capable of significantly elevating its RM temperature above that of the ambient conditions.

The functional role of the caudal fin in the feeding ecology of the common thresher shark Alopias vulpinus

This study tests the hypothesis that the common thresher shark Alopias vulpinus uses its elongate caudal fin to both produce thrust and immobilize prey during feeding. Underwater video recorded in southern California from 2007 to 2009 revealed 34 feeding events, all of which were initiated with the upper lobe of the caudal fin.

The vascular morphology and in vivo muscle temperatures of thresher sharks (Alopiidae).

The thresher sharks comprise a single family (Alopiidae) of pelagic sharks most easily recognized by the elongate dorsal lobe of their caudal fin. Despite morphological similarities among the alopiids, the common thresher (Alopias vulpinus) is unique in that its red, aerobic myotomal muscle (RM) is medially positioned (i.e., closer to the vertebrae), its systemic blood is supplied through a lateral circulation which give rise to counter‐current heat exchanging retia, and it is capable of regional RM endothermy. Despite this information, it remains unknown if the other two alopiid species (bigeye thresher, Alopias superciliosus and pelagic thresher, Alopias pelagicus) also possess some or all of the characteristics related to regional RM endothermy. Thus, this study aimed to 1) document the presence of vascular specializations necessary for heat retention and RM endothermy and 2) measure the in vivo muscle temperatures of all three alopiid species. Laboratory dissections of the thresher species showed that only A. vulpinus possesses the lateral branching of the dorsal aorta giving rise to a lateral subcutaneous circulation and retial system, and that RM temperatures are elevated relative to ambient temperature. By contrast, both A. pelagicus and A. superciliosus have a similar systemic blood circulation pathway, in which the dorsal aorta and postcardinal vein form the basis for the central circulation and in vivo RM temperature measurements closely matched those of the ambient temperature at which the sharks were captured. Collectively, the vascular anatomy and in vivo temperature data suggest that only one species of thresher shark (A. vulpinus) possesses the requisite vascular specializations (i.e., lateral subcutaneous vessels and retia mirabilia) that facilitate RM endothermy. J. Morphol. 2011.

Function of the medial red muscle during sustained swimming in common thresher sharks: Contrast and convergence with thunniform swimmers☆

Through convergent evolution tunas and lamnid sharks share thunniform swimming and a medial position of the red, aerobic swimming musculature. During continuous cruise swimming these muscles move uniformly out of phase with local body curvature and the surrounding white muscle tissue. This design results in thrust production primarily from the caudal fin rather than causing whole-body undulations. The common thresher shark (Family Alopiidae) is the only other fish known to share the same medial red muscle anatomy as the thunniform swimmers. However, the overall body shape and extremely heterocercal caudal fin of the common thresher is not shared with the thunniform swimmers, which have both fusiform bodies and high aspect-ratio, lunate caudal fins. Our study used sonomicrometry to measure the dynamics of red and white muscle movement in common thresher sharks swimming in the ocean to test whether the medial position of red muscle is associated with uncoupling of muscle shortening and local body bending as characteristic of thunniform swimmers. Common threshers ( approximately 60-100kg) instrumented with sonomicrometric and electromyographic (EMG) leads swam alongside of the vessel with a tail-beat frequency of approximately 0.5Hz. EMG signals confirmed that only the red muscle was active during sustained swimming. Despite the more medial position of the red muscle relative to the white muscle, its strain was approximately 1.5-times greater than that of the overlying white muscle, and there was a notable phase shift between strain trajectories in the red muscle and adjacent white muscle. These results suggest an uncoupling (shearing) of the red muscle from the adjacent white muscle. Although the magnitude of the phase shift between red and white muscle strain was relatively constant within individuals, it varied among sharks, ranging from near zero (red and white in phase) to almost 180 degrees out of phase. This extent in variability has not been documented previously for thunniform swimmers with a medial red muscle position and may be a characteristic of the threshers unique body and caudal fin morphology. Nonetheless, the uncoupling of red and white muscle strain remains a consistent character associated with fishes having a medially positioned red muscle.

Sharing the water column: physiological mechanisms underlying species-specific habitat use in tunas

Abstract Tuna species support some of the world’s largest commercial and recreational fisheries. Their extensive migratory patterns expose them to multiple national and international fisheries and fishery management regimes. Several prized species have become the focus of global conservation efforts and there is a growing worldwide interest in establishing optimal strategies for sustainable tuna fisheries. Although this task has proven to be very challenging, it has taken on a new sense of urgency in the face of the potential effects of global climate change. A better understanding of the interactions between environmental conditions and tuna physiology and how they affect tuna behavior will offer population and stock assessment modelers and fisheries biologists a more mechanistic understanding of tuna distribution patterns and may help predict changes in both geographic and depth-related movement patterns. Indeed, physiological data comprise a growing component of multi-trait analysis approaches to species conservation. Our review aims to summarize what is known about differences among tuna species in distribution patterns, tolerances to environmental conditions, and physiological characteristics that correlate with the capacity to inhabit cooler (deeper, higher latitude) and even hypoxic waters. To achieve this goal, we discuss how these physiological traits are associated with habitat partitioning within the three-dimensional oceanic environment and with niche expansion into cooler and hypoxic waters. We also point out areas where additional research is needed to predict more accurately how future changes in oceanographic conditions will affect the distributions and movement patterns of tunas and their availability to fisheries.

Free-swimming swordfish, Xiphias gladius, alter the rate of whole body heat transfer: morphological and physiological specializations for thermoregulation

Original Article Free-swimming swordfish, Xiphias gladius, alter the rate of whole body heat transfer: morphological and physiological specializations for thermoregulation Ashley Stoehr*, Joshua St. Martin, Scott Aalbers, Chugey Sepulveda, and Diego Bernal Department of Biology, University of Massachusetts Dartmouth, 285 Old Westport Road, Dartmouth, MA 02747, USA Pfleger Institute of Environmental Research, PIER, 210 S Coast Highway F, Oceanside, CA 92054, USA *Corresponding author: tel: þ508 999 8208; fax: þ508 999 8217; e-mail: astoehr@umassd.edu