Cytoskeletal organization of limulus amebocytes pre- and post-activation: comparative aspects

One of the major functions of circulating Limulus amebocytes is to effect blood coagulation upon receipt of appropriate signals. However, the hypothesis that Limulus amebocytes are fundamentally similar to vertebrate thrombocytes and platelets has not been tested sufficiently in previous studies of their cytoskeletal organization. Whereas the earlier data were derived from transmission electron microscopy (TEM) of thin sections of a limited number of cells, improved fluorescence labeling methods that retain cell morphology have now enabled us to survey F-actin and microtubule organization in intact individual amebocytes and in large amebocyte populations pre- and post-activation. Anti-tubulin immunofluorescence showed the marginal band (MB) of microtubules to be ellipsoidal in most unactivated cells, with essentially no other microtubules present. However, minor subpopulations of cells with discoidal or pointed shape, containing corresponding arrangements of microtubules suggestive of morphogenetic intermediates, were also observed. Texas-red phalloidin labeled an F-actin-rich cortex in unactivated amebocytes, accounting for MB and granule separation from the plasma membrane as visualized in TEM thin sections, and supporting earlier models for MB maintenance of flattened amebocyte morphology by pressure against a cortical layer. Shape transformation after activation by bacterial lipopolysaccharide was attributable principally to spiky and spreading F-actin in outer cell regions, with the MB changing to twisted, nuclei-associated forms and eventually becoming unrecognizable. These major pre- and post-activation cytoskeletal features resemble those of platelets and non-mammalian vertebrate thrombocytes, supporting recognition of the Limulus amebocyte as a representative evolutionary precursor of more specialized clotting cell types.     

Determination of bacterial number and biomass in the marine environment.

Three techniques for the measurement of bacterial numbers and biomass in the marine environment are described. Two are direct methods for counting bacteria. The first employs an epifluorescence microscope to view bacteria that have been concentrated on membrane filters and stained with acridine orange. The second uses a transmission electron microscope for observing replicas of bacteria that are concentrated on membrane filters. The other technique uses Limulus amebocyte lysate, an aqueous extract from the amebocytes of the horseshoe crab, Limulus polyphemus, to quantitate lipopolysaccharide (LPS) in seawater samples. The biomass of gram-negative (LPS containing) bacteria was shown to be related to the LPS content of the samples. A factor of 6.35 was determined for converting LPS to bacterial carbon.     

Determination of bacterial number and biomass in the marine environment.

Three techniques for the measurement of bacterial numbers and biomass in the marine environment are described. Two are direct methods for counting bacteria. The first employs an epifluorescence microscope to view bacteria that have been concentrated on membrane filters and stained with acridine orange. The second uses a transmission electron microscope for observing replicas of bacteria that are concentrated on membrane filters. The other technique uses Limulus amebocyte lysate, an aqueous extract from the amebocytes of the horseshoe crab, Limulus polyphemus, to quantitate lipopolysaccharide (LPS) in seawater samples. The biomass of gram-negative (LPS containing) bacteria was shown to be related to the LPS content of the samples. A factor of 6.35 was determined for converting LPS to bacterial carbon.     

Limulus amebocyte clotting cascade: Roles of endotoxin and adenylate cyclase

Endotoxin, the lipopolysaccharide from the cell wall of Gram-negative bacteria, causes blood clotting in the horseshoe crab,Limulus polyphemus. Minute amounts of endotoxin stimulate the amebocytes in the blood to undergo exocytosis, which release the contents of their secretory granules to form a clot. An endotoxin-binding protein that possesses calmodulin-like activity has been isolated from the amebocyte plasma membrane. This endotoxin-binding protein can activate adenylate cyclase fromBordetella pertussis to the same extent as rat testes calmodulin. The effect of endotoxin and the endotoxin-binding protein on cyclic AMP synthesis inLimulus amebocytes was examined. Amebocytes exposed to endotoxin have increased levels of intracellular cyclic AMP. Amebocyte membranes contain an adenylate cyclase which is stimulated by NaF, guanosine (β,r-imido)triphosphate, and for skolin. This adenylate cyclase is also stimulated by the endotoxin-binding protein and calcium. Exposure of amebocytes to forskolin or dibutyryl cyclic AMP are stimulated to secrete clot components. Activation of adenylate cyclasein vivo by endotoxin via the endotoxin-binding protein may be one of the ways in which endotoxin stimulates secretion. It is suggested that endotoxin may have two actions in theLimulus system: (1) binding of endotoxin to the endotoxin-binding protein activates adenylate cyclase, promoting secretion by the amebocytes; and (2) endotoxin catalyzes a reaction on the secreted material to form a blood clot. This latter reaction is not elicited by forskolin or dibutyryl cyclic AMP.     

Endotoxin-induced degranulation of the Limulus amebocyte

Exocytosis and gelation of the granule contents of the amebocyte of Limulus polyphemus have been studied in a perfusion chamber observed with Nomarski differential interference contrast microscopy. Degranulation in response to bacterial endotoxin or the ionophore A23187 was significantly inhibited by the anion channel blocking agents suramin, SITS, DNDS and sodium isethionate. db-cAMP, PGI₂ and theophylline also succeeded in imparing degranulation of the amebocytes. All of the agents tested produced inhibition of degranulation which was readily reversed by washing the system free of the inhibitor and rechallenging the amebocytes with either endotoxin or the ionophore. After isolation in vitro, amebocytes underwent spontaneous degranulation in the absence of endotoxin at a rate 1–2 orders of magnitude slower than in the presence of endotoxin. Gelation of the clottable protein released from the amebocyte granules could occur in the absence of endotoxin. This is the first demonstration of gelation under endotoxin-free conditions.     

Selection of a standard culture medium for primary culture of <Emphasis Type="Italic">Limulus polyphemus</Emphasis> Amebocytes

Summary This study provides information relevant to future research aimed at producing Limulus Amebocyte Lysate (LAL) in vitro, which would potentially reduce the need to harvest and bleed horseshoe crabs as in the current methods of LAL production. To address the need for primary culture of horseshoe crab amebocytes, this study tested the effects of a variety of standard insect cell culture media on amebocyte morphology and viability after 7 d of maintenance. Amerbocyte morphology was least altered from in vivo form in Grace’s Modified Insect Medium, with no observed degranulation of cells, as compared to the other media tested. There were significant differences in amebocyte viability among the six insect cell culture media tested. Grace’s Modified Insect Medium sustained viability of 77.2±5.1% (mean ± standard deviation) of amebocytes, followed distantly by Grace’s Insect Medium with 35.1±8.7% amebocyte viability. Results indicate that Grace’s Modified Insect Medium with horseshoe crab serum supplementation was the best candidate of the six media tested for future medium optimization for Limulus amebocyte requirements.     

Limulus amebocyte clotting cascade: Roles of endotoxin and adenylate cyclase

Endotoxin, the lipopolysaccharide from the cell wall of Gram-negative bacteria, causes blood clotting in the horseshoe crab,Limulus polyphemus. Minute amounts of endotoxin stimulate the amebocytes in the blood to undergo exocytosis, which release the contents of their secretory granules to form a clot. An endotoxin-binding protein that possesses calmodulin-like activity has been isolated from the amebocyte plasma membrane. This endotoxin-binding protein can activate adenylate cyclase fromBordetella pertussis to the same extent as rat testes calmodulin. The effect of endotoxin and the endotoxin-binding protein on cyclic AMP synthesis inLimulus amebocytes was examined. Amebocytes exposed to endotoxin have increased levels of intracellular cyclic AMP. Amebocyte membranes contain an adenylate cyclase which is stimulated by NaF, guanosine (,r-imido)triphosphate, and for skolin. This adenylate cyclase is also stimulated by the endotoxin-binding protein and calcium. Exposure of amebocytes to forskolin or dibutyryl cyclic AMP are stimulated to secrete clot components. Activation of adenylate cyclasein vivo by endotoxin via the endotoxin-binding protein may be one of the ways in which endotoxin stimulates secretion. It is suggested that endotoxin may have two actions in theLimulus system: (1) binding of endotoxin to the endotoxin-binding protein activates adenylate cyclase, promoting secretion by the amebocytes; and (2) endotoxin catalyzes a reaction on the secreted material to form a blood clot. This latter reaction is not elicited by forskolin or dibutyryl cyclic AMP.A preliminary report of this work has been presented elsewhere (Liu and Liang, 1984).     

Beginning of exocytosis captured by rapid-freezing of Limulus amebocytes

Structural changes underlying exocytosis evoked by the application of endotoxin to Limulus amebocytes were studied at the level of detail afforded by freeze-fracture and freeze-substitution techniques combined with the time resolution of direct rapid-freezing. The results with amebocytes prepared in this manner differed from those with other secretory cells prepared by conventional means. Exocytosis begins within seconds of endotoxin treatment when the plasmalemma invaginates to form pedestallike appositions with peripheral secretory granules. The juxtaposed membranes at these pedestal appositions form several punctate pentalaminar contacts, but examination of freeze-fractured pedestals failed to reveal any corresponding changes in the intramembrane particle distribution. Small secretory granule openings or pores, which are very infrequent, appear within the first 5 s after endotoxin treatment. These pores rapidly widen and this widening is immediately followed by the sequential dissolution of the granule contents, which then move into the surrounding extracellular space. Cytoplasmic filaments connecting the plasmalemma with the granule membrane are suitably deployed to be responsible for the plasmalemma invaginations. How pores begin is not certain, but the appearance of clear spaces between the granule core and the granule membrane at this point in exocytosis supports the possibility of a role of osmotic forces.     

Bactericidal activity of amebocytes from the horseshoe crab, Limulus polyphemus

The role of amebocytes in the host defense mechanisms of the horseshoe crab, Limulus polyphemus, was examined in a series of in vitro systems. Amebocytes were assayed for their ability to kill one of four bacterial strains in the presence or absence of hemolymph factors. No significant cidal effect was seen with unsupplemented amebocytes during the 1-hr incubation period. Escherichia coli was significantly inactivated when incubated with amebocytes plus either homologous pooled serum or plasma; Aerococcus viridans, Serratia marcescens, and Micrococcus luteus were not. The results are similar to those previously reported for serum from L. polyphemus and suggest an opsonizing activity in the fluid hemolymph.     

Some cytologic characteristics of the hemocytes of Limulus during clotting

The hemolymph of the horseshoe crab, Limulus (Xiphosura) polyphemus, contains a single cell type. The hemocytes are ovoid and contain many refractile granules. One-half to one minute after the onset of clotting the hemocytes swell and a hyaline cytoplasmic ring, essentially devoid of granules, appears about their circumference. During this time the granules disperse and the nucleus becomes visible. Three to five minutes following the initiation of clotting, the cell extends long pseudopodial processes. Phase contrast time-lapse cinematography reveals that the cells are extremely motile during this phase. Concomitant with these changes, many of the granules lose their refractility and one by one disappear from the cytoplasm leaving what appears to be a vacuole. Electron micrographs of native (un-clotted) hemocytes and of clots fixed in glutaraldehyde and post-fixed in osmium reveal that the membrane-bounded granules of native cells are very dense and homogeneous with no evidence of an internal structure. One-half to one minute after clotting, however, they become less dense and 250 Å microtubules spaced at ca. 500 Å intervals appear parallel to the long axis of the granule. Further degradation of the granule ensues and involves (a) change to a spherical shape, and (b) further decrease in density and better resolution of the microtubules. The microtubular component subsequently disintegrates leaving a membrane-bounded granule containing particulate material. Finally, the membrane of the granule fuses with the plasma membrane and the components of the granule are dispersed in the plasma where they presumably contribute to the formation of the gelatinous clot.     

N epsilon(gamma-glutamyl)lysine crosslinks in the blood clot of the horseshoe crab, Limulus polyphemus.

Clots were allowed to form in samples of whole blood taken from the American horseshoe crab, Limulus polyphemus, in the absence and presence of dansylcadaverine (16), and were analyzed for their contents of N epsilon(gamma-glutamyl)lysine and gamma-glutamyl-dansylcadaverine. Clots obtained without dansylcadaverine yielded significant amounts of N epsilon(gamma-glutamyl)lysine product. Clots formed in the presence of dansylcadaverine yielded only gamma-glutamyl-dansylcadaverine. Formation of these products reflects on the activity of transglutaminase released from the blood cells during coagulation.     

An 18.5 kDa protein from the amebocyte of Limulus polyphemus, homologous to the previously described amebocyte aggregation factor, expresses alternative phospholipase A2 activity

A protein expressing phospholipase A2 activity was purified from the granular amebocyte of the horseshoe crab, Limulus polyphemus by cation-exchange, size-exclusion chromatography and semi-preparative reverse-phase-high pressure liquid chromatography (RP-HPLC). The protein had an apparent mass of 17.7 kDa by SDS-polyacrylamide gel electrophoresis (SDS-PAGE), but a more accurate estimate of 18.5 kDa was assigned by electrospray ionization-mass spectrometry (ESI-MS). A partial sequence of this protein demonstrated total sequence homology with an 18.5 kDa protein with cell aggregating properties from Limulus reported by Fujii et al. [J. Biol. Chem. 267:22452.]. In these studies, the Limulus protein demonstrated a positive cross-reaction to polyclonal anti-human recombinant phospholipase A2 (group II, 14 kDa). The protein did not display a significant loss of biological activity after boiling, but all enzymatic activity was lost after boiling in the presence of the reducing agent betamercaptoethanol (beta-mercaptoethanol). The Limulus protein was inhibited by manoalide, a covalent irreversible phospholipase A2 inhibitor, in a dose-dependent fashion with 50% inhibition occurring at a concentration of 0.48 microM. The Limulus protein displayed no activity in a triglyceride lipase assay. These studies characterize an alternative phospholipase A2 activity for the previously described 18.5 kDa protein from the L. polyphemus amebocyte.     

Blood Collection from the American Horseshoe Crab, Limulus Polyphemus

The horseshoe crab has the best-characterized immune system of any long-lived invertebrate. The study of immunity in horseshoe crabs has been facilitated by the ease in collecting large volumes of blood and from the simplicity of the blood. Horseshoe crabs show only a single cell type in the general circulation, the granular amebocyte. The plasma has the salt content of sea water and only three abundant proteins, hemocyanin, the respiratory protein, the C-reactive proteins, which function in the cytolytic destruction of foreign cells, including bacterial cells, and α2-macroglobulin, which inhibits the proteases of invading pathogens. Blood is collected by direct cardiac puncture under conditions that minimize contamination by lipopolysaccharide (a.k.a., endotoxin, LPS), a product of the Gram-negative bacteria. A large animal can yield 200 - 400 mL of blood. For the study of the plasma, blood cells are immediately removed from the plasma by centrifugation and the plasma can then be fractionated into its constituent proteins. The blood cells are conveniently studied microscopically by collecting small volumes of blood into LPS-free isotonic saline (0.5 M NaCl) under conditions that permit direct microscopic examination by placing one of more LPS-free coverglasses on the culture dish surface, then mounting those coverglasses in simple observation chambers following cell attachment. A second preparation for direct observation is to collect 3 - 5 mL of blood in a LPS-free embryo dish and then explanting fragments of aggregated amebocytes to a chamber that sandwiches the tissue between a slide and a coverglass. In this preparation, the motile amebocytes migrate onto the coverglass surface, where they can readily be observed. The blood clotting system involves aggregation of amebocytes and the formation of an extracellular clot of a protein, coagulin, which is released from the secretory granules of the blood cells. Biochemical analysis of washed blood cells requires that aggregation and degranulation does not occur, which can be accomplished by collecting blood into 0.1 volumes of 2% Tween-20, 0.5 M LPS-free NaCl, followed by centrifugation of the cells and washing with 0.5 M NaCl.Open in a separate windowClick here to view.^{(81M, flv)}     

A sensitive substrate for the clotting enzyme in horseshoe crab hemocytes.

An endotoxin-activated hemocyte lysate from horseshoe crab (Tachypleus and Limulus) was found to hydrolyze specifically BZ-Ile-Glu-Gly-Arg-p-nitroanilide, which was recently introduced as the substrate for assay of the blood coagulation factor, Factor Xa. Further, this amidase activity increased by increasing the concentration of bacterial endotoxin (Salmonella minnesota R595) added to the lysate. Thus, the measurement of the amidase activity in the hemocyte lysate can be very useful to detect and determine the endotoxin.     

Morphology of the granular hemocytes of the Japanese horseshoe crabTachypleus tridentatus and immunocytochemical localization of clotting factors and antimicrobial substances

Summary The structure of hemocytes in the normal state and during blood coagulation, and the intracellular localization of three clotting factors and two antimicrobial factors were examined in the Japanese horseshoe crabTachypleus tridentatus. Two types of hemocytes were found in the circulating blood: non-granular and granular hemocytes. The latter contained numerous dense granules classed into two major types: L- and D-granules. The L-granules were larger (up to 1.5 m in diameter) and less electron-dense than the D-granules (less than 0.6 m in diameter). The L-granules contained three clotting factors and one antimicrobial factor, whereas the D-granules exclusively contained the other antimicrobial factor. After treatment with endotoxin, the L-granules were released more rapidly than the D-granules, although almost all granules were finally exocytosed. The granular hemocyte possessed a single Golgi complex; possible precursor granules of L-granules and D-granules contained tubular and condensed dense material, respectively. These data are discussed in relation to the self-defense mechanisms of the horseshoe crab.     

Complete cDNA sequence of SAP-like pentraxin from Limulus polyphemus: implications for pentraxin evolution

The serum amyloid P component (SAP)-like pentraxin Limulus polyphemus SAP is a recently discovered, distinct pentraxin species, of known structure, which does not bind phosphocholine and whose N-terminal sequence has been shown to differ markedly from the highly conserved N terminus of all other known horseshoe crab pentraxins. The complete cDNA sequence of Limulus SAP, and the derived amino acid sequence, the first invertebrate SAP-like pentraxin sequence, have been determined. Two sequences were identified that differed only in the length of the 3' untranslated region. Limulus SAP is synthesised as a precursor protein of 234 amino acid residues, the first 17 residues encoding a signal peptide that is absent from the mature protein. Phylogenetic analysis clusters Limulus SAP pentraxin with the horseshoe crab C-reactive proteins (CRPs) rather than the mammalian SAPs, which are clustered with mammalian CRPs. The deduced amino acid sequence shares 22% identity with both human SAP and CRP, which are 51% identical, and 31-35% with horseshoe crab CRPs. These analyses indicate that gene duplication of CRP (or SAP), followed by sequence divergence and the evolution of CRP and/or SAP function, occurred independently along the chordate and arthropod evolutionary lines rather than in a common ancestor. They further indicate that the CRP/SAP gene duplication event in Limulus occurred before both the emergence of the Limulus CRP variants and the mammalian CRP/SAP gene duplication. Limulus SAP, which does not exhibit the CRP characteristic of calcium-dependent binding to phosphocholine, is established as a pentraxin species distinct from all other known horseshoe crab pentraxins that exist in many variant forms sharing a high level of sequence homology.     

Culture of amebocytes in a nutrient mist bioreactor

Summary We report the first use of nutrient mist bioreactor (NMB) technology to culture animal cells. The nutrient mist approximated the amebocyte stem tissue’s natural environment, which is a thin layer of fluid in the gill leaflets of the horseshoe crabLimulus polyphemus. NMB culture was tried in an attempt to increase production of amebocytes, which are the source of theLimulus Amebocyte Lysate (LAL), the basis for a sensitive and commercially valuable endotoxin assay. Amebocyte growth in the nutrient mist bioreactor is comparable to growth in liquid medium. However, the current design of the bioreactor presents problems for primary cultures such as ours where a pyrogen-free environment is necessary and fungal decontamination is difficult.     

Further studies on lipopolysaccharide-sensitive serine protease zymogen (factor C): its isolation from Limulus polyphemus hemocytes and identification as an intracellular zymogen activated by alpha-chymotrypsin, not by trypsin

An intracellular serine protease zymogen, factor C, is an initiator in the hemolymph coagulation system of horseshoe crab. We purified this zymogen from the hemocytes of the American horseshoe crab, Limulus (L.) polyphemus, the objective being to compare its properties with those of the Japanese horseshoe crab, Tachypleus (T.) tridentatus, factor C. The purified zymogen L.-factor C showed similar properties to those of T.-factor C, in terms of molecular mass (123,000), amino acid composition (1,011 residues), subunit structure (two chains), and antigenicity. Like the zymogen T.-factor C, this zymogen was also activated autocatalytically in the presence of bacterial lipopolysaccharide (LPS) and its synthetic lipid A analogue. A most interesting finding is that both protease zymogens are rapidly activated by alpha-chymotrypsin or rat mast cell chymase, but not by trypsin. The active enzyme factor C showed alpha-thrombin-like specificity toward synthetic tripeptide substrates. This factor C was also strongly inhibited by an alpha-thrombin inhibitor, D-Phe-Pro-Arg-chloromethyl ketone. Thus, the enzymatic properties of factor C are similar to those of mammalian alpha-thrombin. On the other hand, the coagulation cascade system present in the hemocyte lysate was activated when chymotrypsin, free from LPS, was added to the lysate used to detect the endotoxins. The implication of our findings is that the chymotrypsin-catalyzed initiation of the horseshoe crab coagulation system is unique, since all known mammalian coagulation, fibrinolysis and complement systems are initiated by trypsin-like enzymes.