Fish egg yolk is largely derived from vitellogenins, which are synthesized in the liver, taken up from the maternal circulation by growing oocytes via receptor-mediated endocytosis and enzymatically processed into yolk proteins that are stored in the ooplasm. Lipid droplets are another major component of fish egg yolk, and these are mainly composed of neutral lipids that may originate from maternal plasma lipoproteins. This review aims to briefly summarize our current understanding of the molecular mechanisms underlying yolk formation in fishes. A hypothetical model of oocyte growth is proposed based on recent advances in our knowledge of fish yolk formation.
Egg quality in fishes has been a topic of research in aquaculture and fisheries for decades as it represents an important life history trait and is critical for captive propagation and successful recruitment. A major factor influencing egg quality is proper yolk formation, as most fishes are oviparous and the developing offspring are entirely dependent on stored egg yolk for nutritional sustenance. These maternally derived nutrients consist of proteins, carbohydrates, lipids, vitamins, minerals, and ions that are transported from the liver to the ovary by lipoprotein particles including vitellogenins. The yolk composition may be influenced by broodstock diet, husbandry, and other intrinsic and extrinsic conditions. In addition, a number of other maternal factors that may influence egg quality also are stored in eggs, such as gene transcripts, that direct early embryonic development. Dysfunctional regulation of gene or protein expression may lead to poor quality eggs and failure to thrive within hours of fertilization. These gene transcripts may provide important markers as their expression levels may be used to screen broodstock for potential spawning success. In addition to such intrinsic factors, stress may lead to ovarian atresia or reproductive failure and can impact fish behavior, fecundity, and ovulation rate. Finally, postovulatory aging may occur when eggs become overripe and the fish fails to spawn in a timely fashion, leading to low fertility, often encountered during manual strip spawning of fish.
Recent investigations have revealed multiplicity in maternal yolk precursors and their corresponding ovarian lipoprotein receptors (LRs) in diverse oviparous vertebrates, including fishes. This mini-review describes further evidence for the system of fish egg yolk formation mediated by multiple ovarian LRs, which have been obtained by studies utilizing a combination of conventional molecular and biochemical analyses, and modern proteome and transcriptome technologies. A hypothetical "multiple ovarian LR" model is proposed based on our current and previous knowledge of fish yolk formation.
Large amounts of neutral lipids (NLs) are stored as lipid droplets in the ooplasm of fish oocytes, providing an essential energy resource for developing embryos and larvae. However, little is known about the origin of such lipids or about mechanisms underlying their uptake and accumulation in oocytes. We have proposed a model for this lipidation of teleost oocytes, as follows: very low density lipoprotein (Vldl) is metabolized by lipoprotein lipase (Lpl) outside and/or inside of the oocyte and the resulting fatty acids (FAs) are then utilized for de novo biosynthesis of NLs. As a first step toward verification of this model, cDNAs for genes encoding two types of Lpl, lpl and lpl2, were cloned from the ovary of cutthroat trout, Oncorhynchus clarki. Examination of Lpl polypeptide sequences deduced from the cDNAs revealed features similar to LPLs/Lpls in other species, including several conserved structural and functional domains. Both types of lpl mRNA were highly expressed in lipid storage tissues (e.g., adipose tissue, muscle, and ovary) and were predominantly expressed in the granulosa cells of ovarian follicles. Ovarian lpl1 mRNA levels showed a remarkable peak in April (early oocyte lipid droplet stage) and then decreased to low values sustained until November (mid-vitellogenesis), after which time a small peak in lpl1 gene expression was observed in December (late vitellogenesis). The mRNA levels of lpl2 also were elevated in April and were highest in June (late lipid droplet stage), but did not show other pronounced changes. These results suggest that, in the cutthroat trout, Vldl is metabolized by the action of Lpls in the granulosa cell layer to generate free FAs for uptake and biosynthesis of neutral lipids by growing oocytes.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.