Annelid Coelomic Fluid Proteins.

The coelomic cavity is part of the main body plan of annelids. This fluid filled space takes up a considerable volume of the body and serves as an important site of exchange of both metabolites and proteins. In addition to low molecular substances such as amino acids and glucose and lactate, the coelomic fluid contains different proteins that can arise through release from adjacent tissues (intestine) or from secretion by coelomic cells. In this chapter, we will review the current knowledge about the proteins in the annelid coelomic fluid. Given the number of more than 20,000 extant annelid species, existing studies are confined to a relatively few species. Most studies on the oligochaetes are confined to the earthworms-clearly because of their important role in soil biology. In the polychaetes (which might represent a paraphyletic group) on the other hand, studies have focused on a few species of the Nereidid family. The proteins present in the coelomic fluid serve different functions and these have been studied in different taxonomic groups. In oligochaetes, proteins involved antibacterial defense such as lysenin and fetidin have received much attention in past and ongoing studies. In polychaetes, in contrast, proteins involved in vitellogenesis and reproduction, and the vitellogenic function of coelomic cells have been investigated in more detail. The metal binding metallothioneins as well as antimicrobial peptides, have been investigated in both oligochaetes and polychaetes. In the light of the literature available, this review will focus on lipoproteins, especially vitellogenin, and proteins involved in defense reactions. Other annelid groups such as the Pogonophora, Echiura, and Sipuncula (now considered polychaetes), have not received much attention and therefore, this overview is far from being complete.

Crustacean Hemolymph Lipoproteins.

Lipoproteins mediate the transport of apolar lipids in the hydrophilic environment of physiological fluids such as the vertebrate blood and the arthropod hemolymph. In this overview, we will focus on the hemolymph lipoproteins in Crustacea that have received most attention during the last years: the high density lipoprotein/ß-glucan binding proteins (HDL-BGBPs), the vitellogenins (VGs), the clotting proteins (CPs) and the more recently discovered large discoidal lipoproteins (dLPs). VGs are female specific lipoproteins which supply both proteins and lipids as storage material for the oocyte for later use by the developing embryo. Unusual within the invertebrates, the crustacean yolk proteins-formerly designated VGs-are more related to the ApoB type lipoproteins of vertebrates and are now termed apolipocrustaceins. The CPs on the other hand, which are present in both sexes, are related to the (sex specific) VGs of insects and vertebrates. CPs serve in hemostasis and wound closure but also as storage proteins in the oocyte. The HDL-BGBPs are the main lipid transporters, but are also involved in immune defense. Most crustacean lipoproteins belong to the family of the large lipid transfer proteins (LLTPs) such as the intracellular microsomal triglyceride transfer protein, the VGs, CPs and the dLPs. In contrast, the HDL-BGBPs do not belong to the LLTPs and their relationship with other lipoproteins is unknown. However, they originate from a common precursor with the dLPs, whose functions are as yet unknown. The majority of lipoprotein studies have focused on decapod crustaceans, especially shrimps, due to their economic importance. However, we will present evidence that the HDL-BGBPs are restricted to the decapod crustaceans which raises the question as to the main lipid transporting proteins of the other crustacean groups. The diversity of crustaceans lipoproteins thus appears to be more complex than reflected by the present state of knowledge.

Lipoprotein-induced phenoloxidase-activity in tarantula hemocyanin.

Phenoloxidases play vital roles in invertebrate innate immune reactions, wound closure and sclerotization processes in arthropods. In chelicerates, where phenoloxidases are lacking, phenoloxidase-activity can be induced in the oxygen carrier hemocyanin in vitro by proteolytic cleavage, incubation with the artificial inducer SDS, or lipids. The role of protein-protein interaction has up to now received little attention. This is remarkable, as lipoproteins - complexes of proteins and lipids - are present at high concentrations in arthropod hemolymph. We characterized the three lipoproteins present in tarantula hemolymph, two high-density lipoproteins and one very high-density lipoprotein, and show that the two high-density lipoproteins have distinct structures: the more abundant high-density lipoprotein is an ellipsoid particle with axes of ~22.5 nm and ~16.8 nm, respectively. The second high-density lipoprotein, present only in trace amount, is a large discoidal lipoprotein with a diameter of ~38.4 nm and an on-edge thickness of ~7.1 nm. We further demonstrate that the interaction between lipoproteins and hemocyanin induces phenoloxidase activity in hemocyanin, and propose that this activation is due to protein-protein interaction rather than protein-lipid interaction, as neither lipid micelles nor lipid monomers were found to be activating. Activation was strongest in the presence of high-density lipoproteins; very high-density lipoproteins were found to be non-activating. This is the first time that the ability of lipoproteins to induce phenoloxidase activity of hemocyanin has been demonstrated, thus adding novel aspects to the function of lipoproteins apart from their known role in nutrient supply.

One precursor, three apolipoproteins: the relationship between two crustacean lipoproteins, the large discoidal lipoprotein and the high density lipoprotein/ß-glucan binding protein.

The novel discoidal lipoprotein (dLp) recently detected in the crayfish, differs from other crustacean lipoproteins in its large size, apoprotein composition and high lipid binding capacity, We identified the dLp sequence by transcriptome analyses of the hepatopancreas and mass spectrometry. Further de novo assembly of the NGS data followed by BLAST searches using the sequence of the high density lipoprotein/1-glucan binding protein (HDL-BGBP) of Astacus leptodactylus as query revealed a putative precursor molecule with an open reading frame of 14.7 kb and a deduced primary structure of 4889 amino acids. The presence of an N-terminal lipid bind- ing domain and a DUF 1943 domain suggests the relationship with the large lipid transfer proteins. Two-putative dibasic furin cleavage sites were identified bordering the sequence of the HDL-BGBP. When subjected to mass spectroscopic analyses, tryptic peptides of the large apoprotein of dLp matched the N-terminal part of the precursor, while the peptides obtained for its small apoprotein matched the C-terminal part. Repeating the analysis in the prawn Macrobrachium rosenbergii revealed a similar protein with identical domain architecture suggesting that our findings do not represent an isolated instance. Our results indicate that the above three apolipoproteins (i.e HDL-BGBP and both the large and the small subunit of dLp) are translated as a large precursor. Cleavage at the furin type sites releases two subunits forming a heterodimeric dLP particle, while the remaining part forms an HDL-BGBP whose relationship with other lipoproteins as well as specific functions are yet to be elucidated.

Glutathionyl-biliverdin IXα, a new heme catabolite in a marine annelid: Sex and cell specific accumulation.

We have isolated and characterized the green pigment accumulating in coelomic cells (eleocytes) of the common clam worm Nereis virens by means of RP-HPLC and ESI-tandem mass spectrometry. This pigment is a novel biliverdin-glutathione conjugate in which the glutathione is linked to the biliverdin-backbone via a thioether bond. The yolk precursor vitellogenin, a female-specific high-density lipoprotein (ρ = 1179 kg/m(3)) with a native molecular mass of ∼500 kDa and a subunit mass of ∼150 kDa, is capable of transporting this pigment as well as heme. The sex-independent large discoidal lipoprotein present in the coelomic fluid, which is sequestered by the eleocytes, could also be shown to transport heme. This renders both lipoproteins as heme-lipoproteins. As the vitellogenin is secreted by the eleocytes, this suggests the eleocytes as a metabolic hub linking the uptake of the potent pro-oxidant heme thought to arise from aged hemoglobin via the large discoidal lipoprotein and its conversion to a bile pigment-conjugate. The conjugate is exported from the eleocytes to the oocytes via vitellogenin leading to the accumulation of green yolk protein. In contrast, no such export route exists in male eleocytes resulting in an accumulation of the biliverdin-conjugate in these cells.

Lipid accumulation and metabolism in polychaete spermatogenesis: Role of the large discoidal lipoprotein.

In most oviparous animals, lipoprotein-mediated lipid transport plays an important role in the nutrient supply for the oocyte. In male gametes, lipids are used as energy substrates in spermatozoa but nothing is yet known about their origin and metabolism throughout spermatogenesis. The lipid profiles analyzed from different stages of male germ cell development in the marine annelid Nereis virens were found to undergo a dramatic change from primary triacylglycerides at the beginning of germ cell development to cholesterol and phospholipids at the end of development as demonstrated by HPLC with evaporative light scattering detection and mass spectrometry. The uptake of a large discoidal lipoprotein into the developing germ cells could be demonstrated by fluorescence labeling and electron microscopic techniques as well as by the presence of a lipoprotein receptor in the germ cells, thus establishing its role in lipid supply. The incorporated lipoprotein discs were found to be stored as intact complexes indicating that they are not readily degraded upon endocytotic uptake. The change in lipid composition during germ cell development reflects their metabolic activity, especially in spermatogonia. The high concentration of lipids maintained by spermatogonia during the early phase of gametogenesis seems to be required for the later rapid processes of meiosis and spermatocyte differentiation. At times when peak demand of lipids arises for membrane synthesis and increased metabolism, this may be met more efficiently by a rapid on-site mobilization of lipids instead of an external supply.

Extreme nucleoside concentrations in a marine annelid: a novel nucleoside storing cell in the polychaete Nereis virens.

A new type of free coelomic cell was isolated from the coelomic fluid of the polychaete Nereis virens. This cell type was present only during sexual maturation and only in males with fully developed spermatozoa. In vivo acridine orange staining and electron microscopy showed that this cell type consists mainly of a large acidic vacuole with a very low proportion of cytoplasm. This cell type stores extremely high concentration of purine nucleosides reaching concentrations of >700 millimolar on a cell weight basis. The nucleoside concentrations are the highest reported from any living cell so far. Inosine (280-711 micromol/g cell mass), guanosine (8-109 micromol/g), deoxyinosine (3-26 micromol/g) and deoxyguanosine (0.05-0.70 micromol/g) were the main nucleosides. The spectrum of nucleosides reflected that of the surrounding coelomic fluid suggesting their exogenous origin. In culture, labeled guanosine was effectively concentrated by the cells. The vacuole is the most likely storage compartment for the nucleosides and its acidic pH provides higher nucleoside solubility and prevents back diffusion by protonation of the nucleosides.

The Pandinus imperator haemolymph lipoprotein, an unusual phosphatidylserine carrying lipoprotein.

The haemolymph lipoprotein of the scorpion, Pandinus imperator was isolated and characterised. Contrary to the lipoproteins of insects and the discoidal HDL-lipoproteins of a crayfish and polychaete, the Pandinus lipoprotein consists of three instead of two apoproteins (apoPiLp I = 230 kDa, apoPiLp II = 130 kDa and apoPiLp III = 120 kDa). The apolipoproteins are arranged in varying stoichiometries as judged by cross-linking experiments. In lipoprotein samples from individual animals, the two smaller subunits occurred in a 1:1 stoichiometry, while the relative amount of the 230 kDa peptide varied. The lipoprotein is a slightly heart-shaped HDL with a diameter of approximately 15 nm. It is present in two densities of 1100 and 1190 kg/m(3), of which the latter is by far more abundant. The native molecular mass was estimated to be approximately 500 kDa. The lipid content was determined as 33.5% and consists of approximately 70% neutral lipids and approximately 30% phospholipids. Strikingly, 42.5% of the phospholipids is phosphatidylserine while phosphatidylcholine and phosphatidylethanolamine account for 55.1% and approximately 2.3%, respectively. Carbohydrate analysis suggests the presence of only high-mannose-type N-glycans. N-glycan profiling shows glycans corresponding to a size of 8.0-11.5 hexose units.

Lipoprotein mediated lipid uptake in oocytes of polychaetes (Annelida).

The uptake of the 1,1'-dioctadecyl-3,3,3',3'-tetramethylindocarbocyanine perchlorate (DiI)-labeled sex-unspecific Nereis lipoprotein was investigated in oocytes of the nereidid polychaetes Nereis virens and Platynereis dumerilii. The fluorescence label was first observed in endocytic vesicles (<1 microm diameter), which later fused to larger vesicles (2-3 microm); these were finally incorporated into existing unlabeled yolk granules (5-6 microm). In Platynereis oocytes, the fusion of endocytic vesicles was delayed in oocytes at their final stage of development compared with those at an early stage of development. Lipoprotein double-labeled with fluorescein isothiocyanate (FITC) and DiI revealed that both the protein and the lipid moiety remained co-localized during incorporation into the yolk granules of the oocyte. No labeling of the cytoplasmic lipid droplets was observed. In N. virens, unlabeled Nereis lipoprotein was effective as a competitive inhibitor of DiI-labeled Nereis lipoprotein. Ligand blot experiments demonstrated the presence of a lipoprotein receptor with an apparent molecular mass of 120 kDa, which is different from that of the known yolk protein receptor. This indicates the presence, in the polychaete oocyte, of two distinct receptors mediating yolk protein and lipoprotein uptake, respectively. Thus, the sex-unspecific lipoprotein contributes to the lipid supply of the growing oocyte in addition to the known uptake of the yolk-protein-associated lipids. The absence of label in the cytoplasmic lipid droplets, even after prolonged incubation with labeled lipoprotein, suggests that these lipids arise either by the breakdown and resynthesis of lipoprotein-derived lipids and/or by de novo synthesis within the oocyte.

A large discoidal lipoprotein present in only one of two closely related crayfish.

The hemolymph lipoproteins of two European freshwater crayfish, Astacus astacus and Astacus leptodactylus, were isolated and characterized. The former species possesses two sex-independent lipoproteins, which can be related to the formerly described high-density lipoprotein (HDL)/beta-glucan binding protein and very high-density lipoprotein/clotting protein from other crustaceans. The latter species, however, contains an additional third lipoprotein with a unique structure. It is a large discoidal HDL with a diameter of 42 nm, a thickness of 7 nm and a density of 1.1 g/ml. SDS-PAGE revealed two different apolipoproteins with molecular masses of 240 and 85 kDa, respectively, arranged in a 1:1 stoichiometry as judged from cross linking experiments. The lipid content of this lipoprotein was 67%, far higher than in every other crustacean lipoprotein described so far. The native molecular mass of this HDL-type lipoprotein was estimated to be about 930 kDa. The lipid content of the other lipoproteins ranged between 25 and 30% for the HDL/beta-glucan binding protein and 6-8% for the VHDL/clotting protein.

A discoidal lipoprotein from the coelomic fluid of the polychaete Nereis virens.

A discoidal lipoprotein was isolated from the coelomic fluid of the polychaete, Nereis virens, by density gradient centrifugation. The lipoprotein was present in both sexes and moved as a uniform band in an agarose gel. The average diameter of the lipoprotein particles determined by electron microscopy was 42 nm with a thickness of 10 nm. SDS electrophoresis showed two apoprotein subunits with molecular masses of 247 and 85 kDa, respectively. In lectin blots, both apoproteins were reactive with Concanavalin A indicating the presence of N-glycans. The small subunit was also reactive with peanut lectin, indicating additional O-glycosylation. The total lipid content was 48% and consisted mainly of phospholipids and some diglycerides as judged by thin layer chromatography. The estimated native molecular mass of N. virens lipoprotein ( approximately 675 kDa) lies in the range of vertebrate high-density lipoprotein and insect lipophorins. The size of the apoproteins is similar to those found in insects, while the composition of the lipid fraction is more similar to that of crustacean lipoproteins.

Beta-Alanine and other free amino acids during salinity adaptation of the polychaete Nereis japonica.

The free amino acid pool was measured in the body wall muscle and in coelomic cells (eleocytes) of the polychaete Nereis japonica following adaptation to salinities between 6 and 44 per thousand. Beta-Alanine and glycine were the major amino acids comprising 35-60% of the total free amino acid pool in the body wall. In eleocytes, glutamate and lysine in addition to beta-alanine and glycine were the dominant free amino acids. In the body wall, the concentrations of beta-alanine were closely correlated with the ambient salinity between 12 and 35 per thousand. The concentrations of glycine rose initially but remained unchanged at concentrations above 26 per thousand. In both body wall and eleocytes, the mean total primary amine concentrations were correlated with the ambient salinities between 12 and 35 per thousand. The sum of amino acids determined by HPLC showed the same correlation in both tissues, but accounted only for 60-85% of the concentrations of total primary amines. The total protein content of the body wall was slightly higher at 44 per thousand compared to the lower salinities indicating dehydration of the tissues. Eleocytes swell at 6 per thousand and showed irregular amino acid concentrations indicating a loss of metabolic integrity.