Family Report for: Yolk-Protein_dipter

In most oviparous animals, including insects, vitellogenin (Vg) is the major yolk protein precursor. However, in the higher Diptera (cyclorrhaphan flies), a class of proteins homologous to lipoprotein lipases called yolk polypeptides (YP) are accumulated by oocytes instead of Vg, which is not produced at all. Lepidopterans (moths) produce Vg as the major yolk protein precursor, but also manufacture a class of minor yolk proteins referred to as egg-specific proteins (ESP) or YP2s. Although the lepidopteran ESP/YP2s are related to lipoprotein lipases, previous attempts to directly demonstrate their homology with higher-dipteran YPs were unsuccessful. In this paper, a multiple alignment of amino acid sequences was constructed using a shared lipid binding motif as an anchor, to demonstrate that lepidopteran ESP/YP2s, higher-dipteran YPs, and lipoprotein lipases are indeed homologous. Phylogenetic analyses of the aligned sequences were performed using both distance-based and parsimony strategies. It is apparent that the higher dipterans did not requisition a lipoprotein lipase to replace Vg as a yolk protein precursor, but instead utilize a class of proteins with an evolutionary history of use as minor constituents of yolk in other insects.

The yolk protein (yp) genes encode the major nutritional polypeptides deposited in developing oocytes for subsequent utilization during embryogenesis, and represent a highly conserved family of genes in higher Diptera. Originally isolated from Drosophila melanogaster, they are expressed in a temporal-, tissue- and sex-specific manner in all species in which they have been identified. We report here the isolation of cDNAs encoding three independent yolk proteins from the common housefly, Musca domestica. Expression of the three M. domestica yp genes is analysed both by Northern and in-situ hybridization. We discuss in an evolutionary context both the significance of the expression patterns, and regions of apparent polypeptide sequence divergence.

The major proteins stored in the yolk of developing oocytes are thought to provide a nutritional store for utilization during embryogenesis. They seem to fall into two major families of proteins. The first are called vitellogenins and are found in frog, chicken, nematode, fish, and some insects such as the boll weevil. The other group are called yolk proteins and are found in dipteran insects such as fruitfly, housefly, fleshfly, and blue-bottles. Both groups are the major proteins found in the oocyte and are female-specific proteins endocytosed from the serum or hemolymph. The yolk protein group were found to have sequence similarity to the triacylglycerol lipases and lipoprotein lipases of vertebrates, including rat, pig, and human. The yolk proteins do not have lipase activity, but the sequences conserved between yolk proteins and lipases surround the active site where there are interactions with lipids. The likely reason for the presence of this domain in the yolk proteins is to bind a steroid hormone in a storage form conjugated to lipids. This permits the storage of the hormone in an inactive form until the yolk proteins are degraded, when it can be released from its conjugate to induce developmental decisions in embryogenesis. They may also transport lipids into the oocyte for use in embryogenesis. Whilst the vitellogenin family of proteins do not share this homology with the lipases they do have similarity to the human serum protein, apolipoprotein B, which also has a role in binding lipids. These findings are discussed in relation to the evolution and functions of lipases, apolipoproteins, vitellogenins, and yolk proteins. Experiments aimed at isolating genes encoding lipases in insects and at further elucidating the function of the yolk proteins are suggested.

Vitellogenins, cyclorraphan yolk proteins and lepidopteran minor yolk proteins are three classes of female-specific proteins that serve as an embryonic nutritional store. Similarity to vertebrate lipid-binding proteins was established for vitellogenins and yolk proteins, vitellogenins being related to apolipoprotein B and yolk proteins to lipases. Recently, similarity between yolk proteins and minor yolk proteins was reported and it was suggested that yolk proteins are more related to minor yolk proteins than to vertebrate lipases. In this study, we cloned five additional yolk proteins from the grey fleshfly Neobellieria bullata, formerly known as Sarcophaga bullata. We used this sequence data, combined with sequence data retrieved from the NCBI protein database to evaluate the yolk protein-lipase and the yolk protein-minor yolk protein relationship. We found no similarity between yolk proteins and minor yolk proteins, but we showed that yolk proteins are related to a family of lipases containing vertebrate hepatic and pancreatic lipases while minor yolk proteins are related to a family of lipases containing vertebrate gastric and lingual lipases. The fact that three different classes of yolk storage proteins show similarity to three different classes of vertebrate lipid-binding proteins strongly suggests that this lipid-binding feature is important for insect yolk storage proteins.

In most oviparous animals, including insects, vitellogenin (Vg) is the major yolk protein precursor. However, in the higher Diptera (cyclorrhaphan flies), a class of proteins homologous to lipoprotein lipases called yolk polypeptides (YP) are accumulated by oocytes instead of Vg, which is not produced at all. Lepidopterans (moths) produce Vg as the major yolk protein precursor, but also manufacture a class of minor yolk proteins referred to as egg-specific proteins (ESP) or YP2s. Although the lepidopteran ESP/YP2s are related to lipoprotein lipases, previous attempts to directly demonstrate their homology with higher-dipteran YPs were unsuccessful. In this paper, a multiple alignment of amino acid sequences was constructed using a shared lipid binding motif as an anchor, to demonstrate that lepidopteran ESP/YP2s, higher-dipteran YPs, and lipoprotein lipases are indeed homologous. Phylogenetic analyses of the aligned sequences were performed using both distance-based and parsimony strategies. It is apparent that the higher dipterans did not requisition a lipoprotein lipase to replace Vg as a yolk protein precursor, but instead utilize a class of proteins with an evolutionary history of use as minor constituents of yolk in other insects.

The yolk protein (yp) genes encode the major nutritional polypeptides deposited in developing oocytes for subsequent utilization during embryogenesis, and represent a highly conserved family of genes in higher Diptera. Originally isolated from Drosophila melanogaster, they are expressed in a temporal-, tissue- and sex-specific manner in all species in which they have been identified. We report here the isolation of cDNAs encoding three independent yolk proteins from the common housefly, Musca domestica. Expression of the three M. domestica yp genes is analysed both by Northern and in-situ hybridization. We discuss in an evolutionary context both the significance of the expression patterns, and regions of apparent polypeptide sequence divergence.

The major proteins stored in the yolk of developing oocytes are thought to provide a nutritional store for utilization during embryogenesis. They seem to fall into two major families of proteins. The first are called vitellogenins and are found in frog, chicken, nematode, fish, and some insects such as the boll weevil. The other group are called yolk proteins and are found in dipteran insects such as fruitfly, housefly, fleshfly, and blue-bottles. Both groups are the major proteins found in the oocyte and are female-specific proteins endocytosed from the serum or hemolymph. The yolk protein group were found to have sequence similarity to the triacylglycerol lipases and lipoprotein lipases of vertebrates, including rat, pig, and human. The yolk proteins do not have lipase activity, but the sequences conserved between yolk proteins and lipases surround the active site where there are interactions with lipids. The likely reason for the presence of this domain in the yolk proteins is to bind a steroid hormone in a storage form conjugated to lipids. This permits the storage of the hormone in an inactive form until the yolk proteins are degraded, when it can be released from its conjugate to induce developmental decisions in embryogenesis. They may also transport lipids into the oocyte for use in embryogenesis. Whilst the vitellogenin family of proteins do not share this homology with the lipases they do have similarity to the human serum protein, apolipoprotein B, which also has a role in binding lipids. These findings are discussed in relation to the evolution and functions of lipases, apolipoproteins, vitellogenins, and yolk proteins. Experiments aimed at isolating genes encoding lipases in insects and at further elucidating the function of the yolk proteins are suggested.