Craig is temporarily a post-doctoral fellow at the Monterey Bay Aquarium Research Institute who is looking for a permanent position. He spends most of his time balancing his overwhelming geekdom with normalcy so he can function in the real world. Luckily his wife likes his geekiness.
Peter Etnoyer is a Graduate Research Associate at the Harte Research Institute for Gulf of Mexico Studies, Texas A&M University-Corpus Christi. He studies deep corals and ocean fronts, and he loves to be on the water.
Kevin Zelnio is a Graduate Student Researcher at Penn State studying the ecology of hydrothermal vent and methane seep communities. He raises awareness of the plight of the spineless through folk music.
New cool research from Wagner et al. that despite the lack of "day" and "night", deep-sea fish experience daily cycles. What is the trigger? Diurnal changes in bottom currents corresponding to tidal fluctuations. The below graphs shows current direction and velocity on deep-sea floor in the NE Atlantic Ocean indicating 12.5 hour tidal cycles.
The researchers followup by measuring pineal and retinal melatonin in two bottom-dwelling fish, a grenadier Coryphaenoides armatus and a deep-sea eel Synaphobranchus kaupii(below). They additionally quantified the release of melatonin in cultures of isolated pineal organs and retinae in S. kaupii.
Coryphaenoides armatus
Synaphobranchus kaupii, Cambraia Duarte, P.M.N. (c)ImagDOP
Both fish exhibited signs or synchronicity an periodicity in melatonin implying an 'internal clock' (figure below, click for larger). Furthermore, peak values correspond to the beginning of the lunar day and night with lower values during the second half of lunar day and night and during moonrise and moonset. The researchers suggest that fish "perceive these cyclic cues with the help of their lateral line system and use this information as an alternative to
photic stimuli to synchronise the various endogeous oscillators to the physical environment."
Life Science
Comments
Very interesting, although it begs the question of just what this cyclical pattern might offer in terms of an evolutionary advantage (an alternate hypothesis might be that such a physiological response is simply an extant remnant of a system from the shallows). Vertical movement patterns are common in both epipelagic and mesopelagic teleost fishes. Is it then simply an internal patterning to take advantage of changing prey availability with current velocity and direction? Time to check out the full article, indeed...
Thanks for the posting, Craig.
Posted by: FishGuyDave | November 7, 2007 4:57 PM
Also, some recently published work done with some Alvinocaris shrimp in our cold room tanks have some interesting results related to day night activity. You can see the abstract here.
Posted by: kevin z | November 8, 2007 4:24 PM