Endocrine manipulations of spawning in cultured fish: from hormones to genes
Y.
Zohar, C.C. Mylonas-2001
Aquaculture,
197 (1-4): 99-136
(Reproductive
Biotechnology in Finfish Aquaculture
Oceanic Institute, Hawaii, USA, 4 - 7 October 1999
Edited by C.-S. Lee, E. Donaldson and N. Bromage)
Abstract:
Almost
all fish reared in captivity exhibit some form of reproductive dysfunction.
In females, there is often failure to undergo final oocyte maturation,
ovulation and spawning; while in males milt production may be reduced and of
low quality. These dysfunctions are due to the fact that fish in captivity
do not experience the conditions of the spawning grounds, and as a result
there is a failure of the pituitary to release the maturational gonadotropin,
luteinizing hormone (LH). Reproductive hormones have been utilized since the
1930s to stimulate reproductive processes and induce ovulation/spermiation
and spawning. The first methods employed freshly ground pituitaries
collected from reproductively mature fish, which contained gonadotropins
(mainly LH) and induced steroidogenesis and gonadal maturation. Eventually,
purified gonadotropins became available, both of piscine and mammalian
origin, e.g., carp or salmon gonadotropin, and human chorionic gonadotropin.
In the 1970s, spawning induction methods begun employing the newly
discovered gonadotropin-releasing hormone (GnRH), which induces the
secretion of the fish's own gonadotropin from the pituitary, thereby
overcoming the endocrine failure observed in captive broodstocks.
Development of highly potent, synthetic agonists of GnRH (GnRHa) constituted
the next generation of hormonal manipulation therapies, and created a surge
in the use of hormones to control reproductive processes in aquaculture. The
most recent development is the incorporation of GnRHa into polymeric
sustained-release delivery systems, which release the hormone over a period
of days to weeks. These delivery systems alleviate the need for multiple
treatments and induce (a) long-term elevation in sperm production and (b)
multiple spawning in fish with asynchronous or multiple-batch
group-synchronous ovarian physiology. Based on the recent discovery of GnRH
multiplicity in fish and the increasing understanding of its functional
significance, new GnRH agonists can be designed for more potent, affordable
and physiologically-compatible spawning induction therapies. Future
strategies for improved spawning manipulations will be based on
understanding the captivity-induced alterations in the GnRH system, and on
new approaches for their repair at the level of GnRH gene expression and
release.
(Center
of Marine Biotechnology, University of Maryland Biotechnology Institute, 701
E. Pratt Street, Baltimore, MD 21202, USA, Tel.: +1-410-234-8803; fax:
+1-410-234-8896, e-mail: zohar@umbi.umd.edu)