Evidence for the utilization of extracellular [γ-32P]ATP for the phosphorylation of intracellular proteins in the squid giant axon

Proteins in the squid giant axon were labeled with ³²P by in vitro incubation of isolated axoplasm with radioactive [γ-³²P]adenosine triphosphate (ATP) and separated by polyacrylamide sodium dodecyl sulfate gel electrophoresis. The two major phosphorylated regions on the gel had molecular weights of 400 000 and 200 000. These two peaks appear to be neurofilament proteins of squid axoplasm. The same set of proteins was phosphorylated in the axoplasm regardless of whether the [γ-³²P]ATP was applied in situ intracellularly or extracelarly. These results suggest that ATP in the extracellular space is, by some ATP-translocation mechanism, utilized in the process of intracellular phosphorylation. Measurements of the apparent influx of ATP across the squid axon membrane yielded results consistent with the view that ATP in the extracellular fluid could be transported into the axoplasm.     

Calcium-Activated Proteolysis of Neurofilament Proteins in the Squid Giant Neuron

The phosphorylation and proteolysis of squid neurofilament proteins by endogenous kinase and calcium-activated protease activities, respectively, were studied. When axoplasm was incubated in the presence of [gamma-32P]ATP, most of the phosphate was incorporated into two neurofilament proteins: a 220-kilodalton (NF-220) and a high-molecular-weight (HMW) protein. When this phosphorylated axoplasm was subjected to endogenous calcium-activated proteolysis, two significant phosphorylated fragments were generated, i.e., a soluble 110K fragment and a pelletable 100K fragment. Immunochemical and other analyses suggest that the pelletable 100K fragment contains the common helical neurofilament rod region and that the soluble 110K protein is the putative side arm of the NF-220. In contrast, neither the HMW or the NF-220 was detected in the region of the stellate ganglion which contains the cell bodies of the giant axon. However, this region did contain a number of proteins that were sensitive to calcium-activated proteolysis and reacted with a monoclonal intermediate filament antibody. This intermediate filament antibody reacts with most of the axoplasmic proteins that copurify with neurofilaments, i.e., in the order of their intermediate filament antibody staining intensity, a 60K, 65K, 220K, and 74K protein. In the cell body preparation, the intermediate filament antibody labeled, in order of their staining intensity, a 65K, 60K, 74K, and 180K protein. In both the axoplasmic and cell body preparations, endogenous calcium-activated proteolysis generated characteristic fragments that could be labeled with the anti-intermediate filament antibody.     

Principal neurofilament-associated protein kinase in squid axoplasm is related to casein kinase I

A cytoskeletal extract of pure axoplasm, highly enriched with neurofilaments (ANF), was prepared from the giant axon of the squid. This ANF preparation also contained potent kinase activities which phosphorylated the Mr greater than 400,000 (high molecular weight) and Mr 220,000 squid neurofilament protein subunits. High salt (1 M) extraction of this ANF preparation solubilized most of the neurofilament proteins and kinase activities and gel filtration on an AcA 44 column separated these two components. The neurofilaments eluted in the void volume of the column while the kinase activities eluted in the 17-44-kDa range of the column. Two major kinase activities were measured in this peak of activity. One of these strongly phosphorylated the phosphate acceptor peptide Leu-Arg-Arg-Ala-Ser-Leu-Gly (Kemptide) and was completely inhibited by the selective inhibitor of cAMP-dependent kinase Thr-Thr-Tyr-Ala-Asp-Phe-Ile-Ala-Ser-Gly-Arg-Thr-Gly-Arg-Arg-Asn-Ala-Ile- NH2 (Wiptide). Since addition of cAMP did not stimulate activity, this suggested that this kinase was a free catalytic subunit of cAMP-dependent kinase associated with the neurofilaments. The second kinase activity most effectively phosphorylated alpha-casein, and this activity was not affected by Wiptide. The alpha-casein phosphorylating activity (ANF kinase) was the principal activity responsible for neurofilament protein phosphorylation, and was not inhibited by various inhibitors against second messenger regulated kinases, suggesting it was related to the casein kinase family. Four lines of evidence indicate ANF kinase was similar to casein kinase I. These were: 1) the apparent molecular weight determined by gel filtration and the chromatographic elution profile on phosphocellulose column corresponded to casein kinase I; 2) heparin, an inhibitor of casein kinase II at 2-5 micrograms/ml, stimulated both ANF kinase and purified casein kinase I at these concentrations, while CKI-7, a relatively selective inhibitor of casein kinase I, inhibited ANF kinase in a comparable dose-response fashion; 3) purified casein kinase I strongly phosphorylated both ANF protein subunits (like ANF kinase) whereas casein kinase II was relatively ineffective; and 4) tryptic peptide maps of the HMW and Mr 220,000 neurofilament proteins after phosphorylation by ANF kinase or purified casein kinase I showed similar 32P-peptide patterns.     

Characterization of a cyclic nucleotide- and calcium-independent neurofilament protein kinase activity in axoplasm from the squid giant axon

The phosphorylation activity associated with a neurofilament-enriched cytoskeletal preparation isolated from the squid giant axon has been studied and compared to the phosphorylation activities in intact squid axoplasm. The high molecular weight (greater than 300 kDa) and 220-kDa neurofilament proteins are the major endogenous substrates for the kinases in the axoplasm and the neurofilament preparation, whereas 95- and less than 60-kDa proteins are the major phosphoproteins in the ganglion cell preparation. The squid axon neurofilament (SANF) protein kinase activity appeared to be both cAMP and Ca2+ independent and could phosphorylate both casein (Km = 40 microM) and histone (Km = 180 microM). The SANF protein kinase could utilize either ATP or GTP in the phosphotransferase reaction, with a Km for ATP of 58 microM and 129.4 microM for GTP when casein was used as the exogenous substrate; and 25 and 98.1 microM for ATP and GTP, respectively, when the endogenous neurofilament proteins were used as substrates. The SANF protein kinase activity was only slightly inhibited by 2,3-diphosphoglycerate and various polyamines at high concentrations and was poorly inhibited by heparin (34% inhibition at 100 micrograms/ml). The failures of heparin to significantly inhibit and the polyamines to stimulate the SANF protein kinase indicate that it is not a casein type II kinase. The relative efficacy of GTP as a phosphate donor indicates that SANF protein kinase differs from known casein type I kinases. Phosphorylated (32P-labeled) neurofilament proteins were only slightly dephosphorylated in the presence of axoplasm or stellate ganglion cell supernatants, and the neurofilament-enriched preparation did not dephosphorylate 32P-labeled neurofilament proteins. The axoplasm and neurofilament preparations had no detectable protein kinase inhibitor activity, but a strong inhibitor activity, which was not dialyzable but was heat inactivatable, was found in ganglion cells. This inhibitor activity may account for the low phosphorylation activity found in the stellate ganglion cells and may indicate inhibitory regulation of SANF protein kinase activity in the ganglion cell bodies.     

Squid neurofilaments. Phosphorylation and Ca2+-dependent proteolysis in situ.

Three major polypeptides co-purify with neurofilaments from squid (Loligo forbesi) axoplasm: P60 (apparent Mr 60,000), P200 (apparent Mr 200,000) and Band 1 (apparent Mr 400,000). Anti-IFA, a monoclonal antibody that recognizes an epitope common to all classes of intermediate filaments, binds to P200 and P60. When axoplasm is incubated with [32P]Pi, the major phosphorylated polypeptides are P200 and Band 1. We have investigated Ca2+-dependent proteolysis of [32P]phosphorylated axoplasm in order to localize the major sites of phosphorylation and to probe the arrangement of the polypeptides in the filament. The proteinase preferentially cleaves P200 and Band 1, liberating the phosphorylated domains. Analysis of proteolysed filaments by electron microscopy and gel electrophoresis shows that most of P200 and Band 1 can be cleaved while still maintaining intact filaments. We suggest that P200 is initially cleaved within a single highly sensitive region, generating two major fragments called P100p (apparent Mr 100,000) and P110s (apparent Mr 110,000). P100p contains the Anti-IFA epitope and co-sediments with filaments, whereas P110s is highly phosphorylated and does not sediment with filaments. Band 1 is cleaved to produce a soluble high-Mr fragment that is phosphorylated and that represents a major portion of the undigested component, whereas P60 is relatively resistant to limited proteolysis. Thus proteolysis appears to define two major filament domains: a conserved core that forms the backbone of the filament, and a highly phosphorylated peripheral region that is not essential for filament integrity.     

Phosphorylation of specific polypeptides in isolated murine splenocyte nuclei which is controlled by cyclic nucleotides

Murine splenocyte nuclei were phosphorylated with a less than 10(-5) M concentration of [gamma-32P]ATP at 0 degrees C and the phosphorylated nuclear proteins were analyzed by SDS-polyacrylamide gel slab electrophoresis and Sephadex gel filtration column chromatography. Two polypeptides of 10K and 11K daltons were predominantly phosphorylated. These polypeptides were likely linked by a disulfide bond to form a nonhistone protein of 21K daltons. Both phosphoserine and phosphothreonine were detected in the hydrolysate of the 10.5K dalton polypeptide, while phosphoserine was predominant in the 10K dalton polypeptide. Maximal activation of phosphorylation by cAMP of both polypeptides was shown at a concentration of 10(-6) M. On the contrary, cGMP activated phosphorylation of the 10K dalton polypeptide at 10(-8) M and at 10(-4) M. The phosphorylation of the 10.5K polypeptide was not activated by 10(-4) M cGMP and suppression of the phosphorylation was seen in both polypeptide chains by cAMP at higher concentrations.     

Stable polymers of the axonal cytoskeleton: the axoplasmic ghost

We have examined the monomer-polymer equilibria which form the cytoskeletal polymers in squid axoplasm by extracting protein at low concentrations of monomer. The solution conditions inside the axon were matched as closely as possible by the extraction buffer (buffer P) to preserve the types of protein associations that occur in axoplasm. Upon extraction in buffer P, all of the neurofilament proteins in axoplasm remain polymerized as part of the stable neurofilament network. In contrast, most of the polymerized tubulin and actin in axoplasm is soluble although a fraction of these proteins also exists as a stable polymer. Thus, the axoplasmic cytoskeleton contains both stable polymers and soluble polymers. We propose that stable polymers, such as neurofilaments, conserve cytoskeletal organization because they tend to remain polymerized, whereas soluble polymers increase the plasticity of the cytoskeleton because they permit rapid and reversible changes in cytoskeletal organization.     

The location of phosphorylation sites and Ca2+-dependent proteolytic cleavage sites on the major neurofilament polypeptides from Myxicola infundibulum.

1. When axoplasm is incubated with [32P]Pi the main phosphorylated components are the neurofilament polypeptides. 2. Activation with Ca2+ of the proteinase present in axoplasm causes degradation of these neurofilaments and the peptides produced by this reaction have been analysed by fingerprinting. 3. Fingerprinting shows that initially the Ca2+-activated proteinase cleaves the neurofilament polypeptides at three major sites producing polypeptides with mol.wts. 70,000, 50,000 and 47,000. 4. These polypeptides sediment with filaments, originate from the tail-region of the molecule and contain a little radioactive label. 5. As these polypeptides are produced, other polypeptides that come from the head-region of the molecule are liberated as soluble products that contain the bulk of the radioactivity. 6. Fingerprinting therefore shows that at least two regions on the molecule are phosphorylated and that the major one is located towards the head-end of the polypeptides.     

Topographic regulation of cytoskeletal protein phosphorylation by multimeric complexes in the squid giant fiber system

In mammalian and squid nervous systems, the phosphorylation of neurofilament proteins (NFs) seems to be topographically regulated. Although NFs and relevant kinases are synthesized in cell bodies, phosphorylation of NFs, particularly in the lys‐ser‐pro (KSP) repeats in NF‐M and NF‐H tail domains, seem to be restricted to axons. To explore the factors regulating the cellular compartmentalization of NF phosphorylation, we separated cell bodies (GFL) from axons in the squid stellate ganglion and compared the kinase activity in the respective lysates. Although total kinase activity was similar in each lysate, the profile of endogenous phosphorylated substrates was strikingly different. Neurofilament protein 220 (NF220), high‐molecular‐weight NF protein (HMW), and tubulin were the principal phosphorylated substrates in axoplasm, while tubulin was the principal GFL phosphorylated substrate, in addition to highly phosphorylated low‐molecular‐weight proteins. Western blot analysis showed that whereas both lysates contained similar kinases and cytoskeletal proteins, phosphorylated NF220 and HMW were completely absent from the GFL lysate. These differences were highlighted by P13^suc1 affinity chromatography, which revealed in axoplasm an active multimeric phosphorylation complex(es), enriched in cytoskeletal proteins and kinases; the equivalent P13 GFL complex exhibited six to 20 times less endogenous and exogenous phosphorylation activity, respectively, contained fewer cytoskeletal proteins and kinases, and expressed a qualitatively different cdc2‐like kinase epitope, 34 kDa rather than 49 kDa. Cell bodies and axons share a similar repertoire of molecular consitutents; however, the data suggest that the cytoskeletal/kinase phosphorylation complexes extracted from each cellular compartment by P13 are fundamentally different. © 1999 John Wiley & Sons, Inc. J Neurobiol 40: 89–102, 1999     

A CALCIUM ACTIVATED PROTEASE IN SQUID AXOPLASM

Evidence for a protease in squid axoplasm which is selectively activated by Ca²⁺ and blocked by SH-inhibitors is presented. This protease appears to be particularly effective in degrading squid neurofilament proteins, but also extensively degrades various other major protein components in axoplasm.     

Neurofilamentous network and filamentous matrix preserved and isolated by different techniques from squid giant axon

The contribution of the neurofilamentous network to the structure of the squid giant axon was analyzed electron-microscopically. Axial 10-nm filaments cross-linked by radial 5-nm bridges form a network that is present in preparations prepared by a variety of techniques. The axoplasm is differentiated into dense and less dense regions. In the presence of Co(II) ions, the neurofilamentous network was remarkably well preserved and appeared to be associated with a dense web of fine filament matrix, which also was identified in extracted axoplasm and in fractions enriched with neurofilament protein complex. In the presence of La(III) ions, the neurofilamentous network had a coarse and open appearance. The stereo images of extracted and critical-point dried axoplasm suggested that the neurofilamentous network contains ordered lattice-like regions. Extracted preparations of extruded axoplasm and fractions enriched with neurofilament protein complex suggested that the properties of the network are determined by the neurofilament protein complex. It is proposed that the neurofilamentous network is the essential determinant of the form of the axon, and that the order within the network is determined by the radial components of the network. The structures observed in the different preparations are not artifacts, but rather are related closely to their native state in the axon.     

Inhibition of Fast Axonal Transport by Pathogenic SOD1 Involves Activation of p38 MAP Kinase

Dying-back degeneration of motor neuron axons represents an established feature of familial amyotrophic lateral sclerosis (FALS) associated with superoxide dismutase 1 (SOD1) mutations, but axon-autonomous effects of pathogenic SOD1 remained undefined. Characteristics of motor neurons affected in FALS include abnormal kinase activation, aberrant neurofilament phosphorylation, and fast axonal transport (FAT) deficits, but functional relationships among these pathogenic events were unclear. Experiments in isolated squid axoplasm reveal that FALS-related SOD1 mutant polypeptides inhibit FAT through a mechanism involving a p38 mitogen activated protein kinase pathway. Mutant SOD1 activated neuronal p38 in mouse spinal cord, neuroblastoma cells and squid axoplasm. Active p38 MAP kinase phosphorylated kinesin-1, and this phosphorylation event inhibited kinesin-1. Finally, vesicle motility assays revealed previously unrecognized, isoform-specific effects of p38 on FAT. Axon-autonomous activation of the p38 pathway represents a novel gain of toxic function for FALS-linked SOD1 proteins consistent with the dying-back pattern of neurodegeneration characteristic of ALS.     

Identification, synthesis, and characterization of the yolk polypeptides of Plodia interpunctella

The mature eggs of Plodia interpunctella were found to contain four major polypeptides. These yolk polypeptides (YPs) were found to have approximate molecular weights of 153,000 daltons (YP1), 69,000 daltons (YP2), 43,000 daltons (YP3), and 33,000 daltons (YP4) as determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE). In addition, we found YP1 was resolved by a 5% polyacrylamide gel into two separate polypeptides of 153,000 and 147,000 daltons. All of the YPs could be labeled in vivo or in vitro with [35S]-methionine. Yolk peptide 1 and YP3 were synthesized by fat body of pharate adult and adult females and secreted into the hemolymph. Yolk peptide 2 and YP4 were synthesized and secreted into incubation medium by ovaries that contained vitellogenic oocytes, but these polypeptides were not found in the hemolymph. Fat bodies of males synthesized and secreted an immunoprecipitable polypeptide similar to YP3 as well as immunoprecipitable polypeptides larger than 200,000 daltons that had no counterparts in the oocytes. Peptide mapping by protease digestion showed each YP to be cleaved into unique fragments, suggesting that no precursor-product relationship exists between the YPs. Ion exchange chromatography and gel permeation chromatography separated that yolk proteins into two groups with approximate molecular weights of 462,000 and 264,000 daltons. By resolving these peaks on SDS-PAGE, it was found that YP1 and YP3 formed the 462,000-dalton yolk protein and YP2 and YP4 formed the 264,000-dalton yolk protein.     

Production and purification of human MG63 cell interferon

MG63 cells induced by Sendai virus were a convenient source of human interferon, which was of the beta type in antigenicity. When analyzed by SDS-polyacrylamide gel electrophoresis (SDS-PAGE), the interferon migrated as a single component with a molecular weight of 22,000 daltons. It was purified to apparent homogeneity by chromatography on Blue Sepharose, followed by SDS-PAGE, and estimated to have a specific activity of 4 x 10(8) international units/mg of protein.     

Plasma membrane phosphoproteins in normal and Rous sarcoma virus transformed chick embryo fibroblasts: characterization by in vitro phosphorylation.

Plasma membranes isolated from normal and RSV transformed chick embryo fibroblasts were phosphorylated in vitro using endogenous protein kinase and ATP (gamma32P) and the labeled phosphoproteins were analyzed by SDS-PAGE. A number of protein phosphorylation changes were observed following transformation, however in most cases they were relatively small quantitative differences. The four major changes were in proteins of 47,000, 58,000, 75,000 and 135,000 daltons. Decreased phosphorylation of the 47,000 dalton polypeptide was found in transformed cell membranes but this alteration was shown to be due to differences in cell growth rather than transformation. Increase phosphorylation of the 75,000 dalton protein was at least partially related to virus infection. However, increased phosphorylation of the 58,000 and 135,000 dalton polypeptides were entirely transformation specific.     

Protein phosphorylation in Streptomyces albus

The phosphorylated proteins of Streptomyces albus, radioactively labeled with [32P]orthophosphate have been analyzed by gel electrophoresis and autoradiography. More than 10 protein species were found to be phosphorylated. With [32P]ATP as substrate cell free extracts phosphorylated endogenous proteins in vitro which were predominantly phosphorylated in vivo. From cell extract which exhibited active phosphorylated in vitro, a protein kinase has been partially purified. The kinase activity was identified in fractions corresponding to a 90 kDa protein.     

A guanosine 5′-triphosphate-dependent protein kinase is localized in the outer envelope membrane of pea chloroplasts

A guanosine 5-triphosphate (GTP)-dependent protein kinase was detected in preparations of outer chloroplast envelope membranes of pea (Pisum sativum L.) chloroplasts. The protein-kinase activity was capable of phosphorylating several envelope-membrane proteins. The major phosphorylated products were 23- and 32.5-kilo-dalton proteins of the outer envelope membrane. Several other envelope proteins were labeled to a lesser extent. Following acid hydrolysis of the labeled proteins, most of the label was detected as phosphoserine with only minor amounts detected as phosphothreonine. Several criteria were used to distinguish the GTP-dependent protein kinase from an ATP-dependent kinase also present in the outer envelope membrane. The ATP-dependent kinase phosphorylated a very different set of envelope-membrane proteins. Heparin inhibited the GTP-dependent kinase but had little effect upon the ATP-dependent enzyme. The GTP-dependent enzyme accepted phosvitin as an external protein substrate whereas the ATP-dependent enzyme did not. The outer membrane of the chloroplast envelope also contained a phosphotransferase capable of transferring labeled phosphate from [-³²P]GTP to ADP to yield (-³²P]ATP. Consequently, addition of ADP to a GTP-dependent protein-kinase assay resulted in a switch in the pattern of labeled products from that seen with GTP to that typically seen with ATP.Abbreviations GDP (GMP, GTP) guanosine 5-diphosphate (mono-, tri-); kDa-kilodalton - S_0.5 concentration of substrate supporting half-maximal velocity - SDS-PAGE sodium dodecyl sulfate-polyacrylamide gel electrophoresis - Tricine N-(2-hydroxy-1,1-bis(hydroxymethyl)ethyl)glycine     

Characterization of the major phosphoprotein and its kinase on the surface of the rat adipocyte

Intact rat fat cells exposed to 12.5 microM [gamma-32P]ATP incorporate label into specific proteins within minutes. By solubilizing the reaction mixture with SDS which by passes the subcellular fractionation steps, the labeled proteins can be identified in autoradiographs of SDS-PAGE gels. The most prominently labeled protein has an Mr of 42,000. Localization of this component to the cell surface can be made on the basis of inhibition of phosphorylation by addition of a protein derived from the rat brain with protein kinase inhibitory property, susceptibility of the phosphorylated protein to tryptic digestion, whereas the unphosphorylated protein is unaffected by digestion with trypsin (15 min), inhibition of phosphorylation of this protein after brief exposure to melittin, and the consistent observation that more label is associated with the 42,000 Mr band in homogenates and permeabilized cells than in comparable numbers of intact cells exposed to the same amount of label. A 42,000 Mr phosphoprotein is also present in mitochondria which is most likely the alpha subunit of pyruvate dehydrogenase. To rule out the possibility that the cell surface protein might be a mitochondrial contaminant from broken cells, 32Pi-labeled and [gamma-32P]ATP-labeled cells were solubilized with Triton and chromatographed on a rabbit anti-pyruvate dehydrogenase antibody-Sepharose 4B column. A single labeled peak was detected upon elution of the bound fraction only in the 32Pi-labeled sample, and not in the [gamma-32P]ATP-labeled sample. Subcellular fractionation studies of intact cells labeled with [gamma-32P]ATP showed differences in the recovery of phosphoproteins of 42,000 Mr depending on whether a continuous sucrose gradient (27.6-54.1%, g/ml) or a discontinuous sucrose gradient (16, 35 and 48%, g/ml) was used. Phosphoproteins of 42,000 Mr were located in the mitochondrial and membrane fractions collected by discontinuous sucrose gradient separation, whereas a phosphoprotein of 42,000 Mr was found primarily in the mitochondrial fraction after continuous sucrose gradient separation. By 5'-nucleotidase activity measurements, the latter approach appears to result in the isolation of a heavy fragment of the plasma membrane with the mitochondrial light fraction which is 42,000 in Mr and labeled. Finally, comparison of the autoradiographs of two-dimensional (2D) gels (isoelectric focusing followed by 10% SDS-PAGE) show different isoelectric points for 42,000 Mr components in [gamma-32P]ATP- and 32Pi-labeled cells.(ABSTRACT TRUNCATED AT 400 WORDS)     

Phospholipid synthesis in the squid giant axon: incorporation of lipid precursors

The squid giant axon and extruded axoplasm from the giant axon were used to study the capacity of axoplasm for phospholipid synthesis. Extruded axoplasm, suspended in chemically defined media, catalyzed the synthesis of phospholipids from all of the precursors tested. 32P-Labeled inorganic phosphate and gamma-labeled ATP were actively incorporated into phosphatidylinositol phosphate, while [2-3H]myo-inositol and L-[3H(G)]serine were actively incorporated into phosphatidylinositol and phosphatidylserine, respectively. Though less well utilized. [2-3H]glycerol was incorporated into phosphatidic acid, phosphatidylinositol, and triglyceride, and methyl-3H]choline and [1-3H]ethanolamine were incorporated into phosphatidylcholine and phosphatidylethanolamine, respectively. Isolated squid giant axons were incubated in artificial seawater containing the above precursors. The axoplasm was extruded following the incubations. Although most of the product lipids were recovered in the sheath (composed of cortical axoplasm, axolemma, and surrounding satellite cells), significant amounts (4-20%) were present in the extruded axoplasm. With tritiated choline and myo-inositol, the major labeled phospholipids found in both the extruded axoplasm and the sheath were phosphatidylcholine and phosphatidylinositol, respectively. With both glycerol and phosphate, phosphatidylethanolamine was a major labeled lipid in both axoplasm and sheath. These findings demonstrate that all classes of phospholipids are formed by endogenous synthetic enzymes in axoplasm. In addition, we feel that the different patterns of incorporation by intact axons and extruded axoplasm indicate that surrounding sheath cells contribute lipids to axoplasm. A comprehensive picture of axonal lipid metabolism should include axoplasmic synthesis and glial-axon transfer as pathways complementing the axonal transport of perikaryally formed lipids.     

Schistosoma mansoni adult microsomal antigens, a serologic reagent. I. Systematic fractionation, quantitation, and characterization of antigenic components

A systematic and quantitative search was conducted to identify and isolate a serologically pertinent antigen with high specific activity and low cross-reactivity from adult worms of Schistosoma mansoni. Adult worms of S. mansoni quickly thawed from liquid N2 temperatures were disrupted by controlled homogenization in isotonic buffered sucrose. Differential centrifugation of the homogenate yielded three particulate and one soluble fractions: the 480 x G pellet (nuclear), the 7650 x G pellet (mitochondrial), the 360,000 x G pellet (microsomal), and the 360,000 x G supernatant (cytosol). Quantitative analysis indicated a major concentration of specific antigenic activities in the microsomal fraction. Further purifications of the urea-solubilized, n-butanol-treated microsomal particles by gel filtration and ionic-exchange chromatography resulted in a microsomal antigen (MAMA) possessing high specific activity and low cross-reactivity. The final purification post-ionic exchange chromatograph showed a 30-fold increase of specific antigen activity over that of the cytosol fraction. Sodium dodecyl sulfate/polyacrylamide gel electrophoresis (SDS-PAGE) and enzyme-linked immunotransfer blot by the "Western blot" technique (EITB) indicated specific antigenic activities in association with several different m.w. bands (heterogeneous m.w. by extrapolation = 4.3 to 11.9 x 10(6), 2.0 x 10(5), and 2.0 x 10(4) daltons) of the MAMA fraction. When compared with other reported serologic antigens, MAMA showed substantially higher specific activity and lower cross-reactivity.