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Cardio-respiratory performance of larval zebrafish
marine teleosts and its implications
for aerobic scope. Proc. Biol. Sci. 274,
431-438.
Langerhans, R. B., Layman, C. A.,
Shokrollahi, A. M., and DeWitt, T. J.
(2004). Predator driven phenotypic
diversification in Gambusia affinis.
Evolution 58, 2305-2318.
Leis, J. M. (2006). Are larvae of demersal
fishes plankton or nekton? Adv. Mar.
Biol. 51, 57-141.
Lindsey, B. W., Smith, F. M., and Croll, R.
P. (2010). From inflation to flotation:
contribution of the swimbladder to
whole-body density and swimming
depth during development of the
zebrafish (Danio rerio). Zebrafish 7,
85-96.
MacPhail, R. C., Brooks, J., Hunter,
D. L., Padnos, B., Irons, T. D., and
Padilla, S. (2009). Locomotion in lar-
val zebrafish: influence of time of
day, lighting and ethanol. Neurotox-
icology 30, 52-58.
Martinez, M., Bedard, M., Dutil, J.
D., and Guderley, H. (2004). Does
condition of Atlantic cod (Gadus
morhua) have a greater impact upon
swimming performance at Ucrit or
sprint speeds? J. Exp. Biol. 207,
979-990.
McLean, D. L., and Fetcho, J. R.
(2009). Spinal interneurons differ-
entiate sequentially from those dri-
ving the fastest swimming move-
ments in larval zebrafish to those
driving the slowest ones. ]. Neurosci.
29, 13566-13577.
Morinville, G. R., and Rasmussen, J.
B. (2006). Does life-history vari-
ability in salmonids affect habi-
tat use by juveniles? A compari-
son among streams open and closed
to anadromy. J. Anim. Ecol. 75,
693-704.
Muller, U. K., Stamhuis, E. J., and
Videler, J. J. (2000). Hydrodynamics
of unsteady fish swimming and the
effects of body size: comparing the
flow fields of fish larvae and adults.
J. Exp. Biol. 203, 193-206.
Muller, U. K., van den Boogaart, J. G.,
and van Leeuwen, J. L. (2008). Flow
patterns of larval fish: undulatory
swimming in the intermediate flow
regime. J. Exp. Biol. 211, 196-205.
Muller, U. K., and van Leeuwen,
J. L. (2004). Swimming of lar-
val zebrafish: ontogeny of body
waves and implications for locomo-
tory development. . Exp. Biol. 207,
853-868.
Nelson, J. A., Gotwalt, P S., Reidy,
S. P., and Webber, D. M. (2002).
Beyond Ucrit: matching swim-
ming performance tests to the
physiological ecology of the animal,
including a new fish 'drag strip.'Comp. Biochem. Physiol. A Mol.
Integr. Physiol. 133, 289-302.
Nilsson, G. E., Ostlund-Nilsson, S.,
Penfold, R., and Grutter, A. S.
(2007). From record performance to
hypoxia tolerance: respiratory tran-
sition in damselfish larvae settling
on a coral reef. Proc. Biol. Sci. 274,
79-85.
Pelster, B. (2002). Developmental plas-
ticity in the cardiovascular system
of fish, with special reference to the
zebrafish. Comp. Biochem. Physiol. A
Mol. Integr. Physiol. 133, 547-553.
Pelster, B., and Burggren, W. W.
(1996). Disruption of hemoglobin
oxygen transport does not impact
oxygen - dependent physiological
processes in developing embryos of
zebrafish (Danio rerio). Circ. Res. 79,
358-362.
Pelster, B., Singer, A. M., Siegele, M.,
and Schwerte, T. (2003). Influence
of swim training on cardiac activ-
ity, tissue capillarization, and mito-
chondrial density in muscle tissue
of zebrafish larvae. Am. . Physiol.
Regul. Integr. Comp. Physiol. 285,
R339-R347.
Plaut, I. I., and Gordon, M. (1994).
Swimming metabolism of wild-type
and cloned zebrafish Brachydanio
rerio. J. Exp. Biol. 194, 209-223.
Porter, M. E., Roque, C. M., and Long, J.
H. Jr. (2011). Swimming fundamen-
tals: turning performance of leopard
sharks (Triakis semifasciata) is pre-
dicted by body shape and postural
reconfiguration. Zoology (lena) 114,
348-359.
Partner, H. O., Schulte, P M., Wood, C.
M., and Schiemer, F. (2010). Niche
dimensions in fishes: an integra-
tive view. Physiol. Biochem. Zool. 83,
808-826.
Reid, D. P., Szanto, A., Glebe, B., Danz-
mann, R. G., and Ferguson, M. M.
(2005). QTL for body weight and
condition factor in Atlantic salmon
(Salmo salar): comparative analysis
with rainbow trout (Oncorhynchus
mykiss) and Arctic charr (Salvelinus
alpinus). Heredity 94, 166-172.
Ricker, W. E. (1979). "Growth rates
and models," in Fish Physiology, Vol.
8, Bioenergetics and Growth, eds W.
S. Hoar, D. J. Randall, and J. R.
Brett (New York: Academic Press),
677-743.
Rogge, J. R., and Warkentin, K. M.
(2008). External gills and adap-
tive embryo behavior facilitate syn-
chronous development and hatch-
ing plasticity under respiratory con-
straint. I. Exp. Biol. 211, 3627-3635.
Rombough, P J. (1988). "Respiratory
gas exchange, aerobic metabolism,
and effects of hypoxia during earlylife," in Fish Physiology, Vol. 11, Part
A, eds W. S. Hoar and D. J. Randall
(San Diego, CA: Academic Press),
59-161.
Rombough, P. J. (1998). Partitioning
of oxygen uptake between the gills
and skin in fish larvae: a novel
method for estimating cutaneous
oxygen uptake. J. Exp. Biol. 201,
1763-1769.
Rombough, P. J. (2006). "Developmen-
tal costs and the partition of meta-
bolic energy";' in Comparative Devel-
opmental Physiology: Contributions,
Tools and Trends, eds S. J. Warbur-
ton, W. W. Burggren, B. Pelster, C. L.
Reiber, and J. Spicer (Oxford: Oxford
University Press), 99-123.
Rombough, P. J., and Ure, D. (1991).
Partitioning of oxygen uptake
between cutaneous and branchial
surfaces in larval and juvenile
chinook salmon Oncorhynchus
tshawytscha. Physiol. Zool. 64,
717-727.
Sandblom, E., Farrell, A. P., Altimiras,
J., Axelsson, M., and Claireaux, G.
(2005). Cardiac preload and venous
return in swimming sea bass (Dicen-
trarchus labrax L.). J. Exp. Biol. 208,
1927-1935.
Schwerte, T., Prem, C., Mairosl, A., and
Pelster, B. (2006). Development of
the sympatho-vagal balance in the
cardiovascular system in zebrafish
(Danio rerio) characterized by power
spectrum and classical signal analy-
sis. J. Exp. Biol. 209, 1093-1100.
Schwerte, T., Voigt, S., and Pelster,
B. (2005). Epigenetic variations in
early cardiovascular performance
and hematopoiesis can be explained
by maternal and clutch effects in
developing zebrafish (Danio rerio).
Comp. Biochem. Physiol. A Mol.
Integr. Physiol. 141, 200-209.
Steele, S. L., Yang, X., Debiais-Thibaud,
M., Schwerte, T., Pelster, B., Ekker,
M., Tiberi, M.,and Perry, S. F. (2011).
In vivo and in vitro assessment of
cardiac beta-adrenergic receptors in
larval zebrafish (Danio rerio). J. Exp.
Biol. 214, 1445-1457.
Territo, P., and Burggren, W. W. (1998).
Cardio-respiratory ontogeny during
chronic carbon monoxide induced
hypoxemia in the clawed frog
Xenopus laevis. . Exp. Biol. 201,
1461-1472.
Thorsen, D. H., Cassidy, J. J., and Hale,
M. E. (2004). Swimming of lar-
val zebrafish: fin-axis coordination
and implications for function and
neural control. I. Exp. Biol. 207,
4175-4183.
Tierney, K. B., Patterson, D. A., and
Kennedy, C. J. (2009). The influ-
ence of maternal condition onoffspring performance in sockeye
salmon Oncorhynchus nerka. J. Fish
Biol. 75, 1244-1257.
van der Meulen, T., Schipper, H., van
den Boogaart, J. G., Huising, M. O.,
Kranenbarg, S., and van Leeuwen,
J. L. (2006). Endurance exercise dif-
ferentially stimulates heart and axial
muscle development in zebrafish
(Danio rerio). Am. . Physiol. Regul.
Integr. Comp. Physiol. 291, R1040-
R1048.
Wark, A. R., Greenwood, A. K., Tay-
lor, E. M., Yoshida, K., and Peichel,
C. L. (2011). Heritable differ-
ences in schooling behavior among
threespine stickleback populations
revealed by a novel assay. PLoS
ONE 6, e18316. doi:10.1371/jour-
nal.pone.0018316
Webb, P. W. (1975). Hydrodynamics and
Energetics ofFish Propulsion. Depart-
ment of the Environment Fisheries
and Marine Service, 190.
Webber, D. M., Boutilier, R. G., and
Kerr, S. R. (1998). Cardiac output
as a predictor of metabolic rate in
cod Gadus morhua. J. Exp. Biol. 201,
2779-2789.
Weibel, E. R., Bacigalupe, L. D., Schmitt,
B., and Hoppeler, H. (2004). Allo-
metric scaling of maximal meta-
bolic rate in mammals: muscle aer-
obic capacity as determinant fac-
tor. Respir. Physiol. Neurobiol. 140,
115-132.
Wieser, W. (1995). Energetics of fish
larvae, the smallest vertebrates. Acta
Physiol. Scand. 154, 279-290.
Conflict of Interest Statement: The
authors declare that the research was
conducted in the absence of any com-
mercial or financial relationships that
could be construed as a potential con-
flict of interest.
Received: 10 November 2011; accepted:
07 February 2012; published online: 24
February 2012.
Citation: Gore M and Burggren WW
(2012) Cardiac and metabolic physi-
ology of early larval zebrafish (Danio
rerio) reflects parental swimming
stamina. Front. Physio. 3:35. doi:
10.3389/fphys.2012. 00035
This article was submitted to Frontiers in
Aquatic Physiology, a specialty of Fron-
tiers in Physiology.
Copyright 2012 Gore and Burggren.
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Gore, Matthew & Burggren, Warren W. Cardiac and metabolic physiology of early larval zebrafish (Danio rerio) reflects parental swimming stamina, article, February 24, 2012; [Lausanne, Switzerland]. (https://digital.library.unt.edu/ark:/67531/metadc115198/m1/9/: accessed March 29, 2024), University of North Texas Libraries, UNT Digital Library, https://digital.library.unt.edu; crediting UNT College of Arts and Sciences.