We
humans are obsessed about time. Our lives are structured around time. We take time management workshops with a
false belief that we can manage time.
Yet, we can only manage to prioritize activities, not time. My alarm rings at 6:00am,
I fail to notice a sunrise at 6:29am, eat, shower, start my commute (clock in
my car reads 7:34am), arrive to many auto-scheduled emails, approve time
sheets, grade assignments, impose late submission penalties, attend committee
meeting at 10:00am, arrive to class at 12:20pm, dismiss class promptly at
1:10pm, and the whole day is scheduled like that. The sun sets at 8:06pm and I might
ponder the peculiar nature of time in our modern world. Our obsession with time has a very long evolutionary
history that is evident in all animals.
The
lyrics from The Chicago Transit Authority’s hit song, “Does Anybody Really Know
What Time It Is?” (1969), questions this obsession with time
“As I
was walking down the street one day
A man came up to me and asked me what the time was that was
On my watch, yeah
And I said
Does anybody really know what time it is
I don't
Does anybody really care
If so I can't imagine why
About time
We've all got time enough to cry”
A man came up to me and asked me what the time was that was
On my watch, yeah
And I said
Does anybody really know what time it is
I don't
Does anybody really care
If so I can't imagine why
About time
We've all got time enough to cry”
The song is about caring, the human
condition, and human emotions. The song
was written at a time when many soldiers were dying in Viet Nam and yet the rich and
privileged appeared to be unconcerned. Listen
here. Humans care too much about time, and not enough about things that matter. Fish, on the other hand, live their lives with
an internal clock that controls timing of biological processes.
Deep
within our brain sits a very small endocrine gland called the pineal
gland. It's the size of a pea, and this
tiny pineal gland secretes the melatonin. Melatonin is a hormone that helps
regulate human sleep and wake cycles.
When light hits the retina, a message is sent to your hypothalamus, and
nerve fibers transmit this message down the spinal cord to sympathetic nerve
cells that then ascend back up to the pineal gland. Message is received and melatonin secretion
ceases. It’s time to wake up!
In
the fishes, a very similar mechanism is at work to allow a fish to track
changes in day length and time development and maturation of the gonads. Fish, like
other animals, secrete melatonin at night and exhibit circadian rhythms. Melatonin levels regulate activity of
fishes. Nocturnal fishes became active
when melatonin levels increase, whereas diurnal fishes become active when
melatonin levels are low. Fish do not
sleep in the same way humans do. For one
thing, they have no eyelids so the eye remains open. Metabolism and behaviors slow, but they don’t
appear to have deep sleep REM cycles (Laming 1981).
Hagfishes
and the lampreys, the most primitive fishes, have the capacity to detect light and dark. Hagfish have no eyes
and no pineal gland, but do possess primitive photoreceptors that have nerve
connections to brain. The
lamprey eye develops slowly during larval stage, but is functional early in
life. Lampreys also have a pineal gland
at the top of head above brain. The
tissue overlying the pineal gland is transparent in the larval stage and
translucent in the adult. It appears the
photosensitive pineal functions in an analogous manner as the retina
photoreceptors in the human. The molecular mechanisms are the subject of ongoing studies of evolution of vertebrate
photoreceptors (Mano and Fukada 2007) and the pervasive influence of circadian
rhythms. The blind Mexican tetra has
been cut off from cues of the rising and setting sun; it has no circadian rhythms.
Parapinopsin (A) and rhodopsin (B) pigments are expressed in different regions of photoreceptor cells Photo from Koyanagi et al. (2004). P=pineal, PP=parapineal, L=lumen, and S=pineal stalk. (Scale bar=100 μm) Source |
In
the lamprey, the pineal gland has two components, a pineal (upper gland in
photo) and a parapineal (lower gland in photo).
Each has two parts with UV and visible light sensitive regions. Research
on the lamprey pineal gland confirmed that visible light excites the pineal,
while UV light inhibits the pineal response (Koyanagi et al. 2004). Therefore, the lamprey really do know what
time it is!
Zebrafish
is a valuable vertebrate model due to fast development, short generation time,
and a large number of embryos.
Consequently, they are frequent subjects for the study of the circadian
clock and the pineal gland. The pineal
gland develops early in the zebrafish, is photoreceptive and contains an
intrinsic circadian oscillator that controls many physiological and behavioral
processes.
Location of pineal gland in zebrafish (top) and zebrafish embryo. Photos by Yoav Gothilf |
Zebrafish have a gene, aanate (or for a long version, that would be aralkylamine-N-acetyltransferase), that exhibits clock-controlled rhythms (Gothilf et al. 1999). Imagine a gene that is light sensitive; light is mandatory to set the circadian clock in zebrafish. The gene exists in every cell allowing for the study of this “clock gene” in zebrafish cell lines (Vallone et al. 2005). The clock gene has a circadian rhythm in gene expression, which translates to circadian rhythms in metabolism and behavior in the zebrafish.
What
does this mean to the practicing fish worker? Circadian rhythms in fish are established by
the prevailing day/night cycles. Maintenance of the circadian rhythms is important to the well-being of fish. It is
possible to control photo and thermal cycles and reduce the time needed for reproductive
maturation in captive, farmed fish (Blythe et al. 1994). Alternatively, hormone
injections may advance gonadal development.
Light and dark cycles and feeding times can also be controlled to
optimize growth and survival of fish in captivity. Fish are also great subjects for school
science projects. Novice scientists can
observe the daily activity patterns of fish in an aquarium and experiment with
changing time of day when lights are turned on. They study fish! They become more curious! They begin to contemplate life! They begin to really know what matters!
References
Blythe, W.G., L.A.
Helfrich, and G. Libey. 1994. Induced maturation of striped bass (Morone saxatilis) exposed to 6-, 9-, and
12-month photothermal regimes. Journal of the World Aquaculture Society 25:183-192.
Gothilf, Y, et al. 1999.
Zebrafish serotonin N-acetyltransferase-2: marker for development of pineal photoreceptors and circadian clock function. Endocrinology 140:4895-4903.
Koyanagi, M., et al. 2004. Bistable UV pigment in the lamprey pineal. Proceedings of the National
Academy of Sciences 101:6687-669.
Laming, P.R. 1981. Brain mechanisms of behaviour in lower
vertebrates. (Society for Experimental
Biology Seminar Series). Cambridge
University Press, Oxford. 332 pp.
Mano, H., and Y. Fukada.
2007. A median third eye: pineal gland retraces evolution of vertebrate photoreceptive organs. Photochemistry
and Photobiology 83(1):11-18. DOI:
10.1562/2006-02-24-IR-813.
Noche, R.R., P.N. Lu, L.
Goldstein-Kral, E. Glasgow, and J.O. Liang. 2011. Circadian rhythms in the pineal organ persist in zebrafish larvae that lack ventral brain. BMC Neurosciences 12:7. DOI:10.1186/1471-2202-12-7.
Vallone, D., K. Lahiri,
T. Dickmeis, and N.S. Foulkes. 2005.
Zebrafish cell clocks feel the heat and see the light! Zebrafish 2(3):171-187. DOI:
10.1089/zeb.2005.2.171