High Molecular Mass Protein Research Articles

Influence of running different distances on renal glomerular and tubular impairment in humans.

Strenuous exercise has been claimed to modify renal glomerular and tubular function, the relative involvement of the two sites being unknown. These changes may be assessed by the determination of plasma high and low molecular mass proteins. A group of 13 man performed five runs (100, 400, 800, 1,500, 3,000 m) at maximal speed. The excretion rates and renal clearances of creatinine, albumin (Alb), beta 2-microglobulin (beta 2-m) and retinol-binding protein (RBP) were determined before and after each run. The glomerular filtration rate remained stable during the shorter runs and declined by about 40% during the longer runs. The excretion rate for Alb rose from 10-fold above the basal value (6 micrograms.min-1) for the 100 m to 49-fold for the 800 m and then declined for distances up to 3,000 m. The beta 2-m and RBP had a lesser initial increase, 3.5-(rest 55 ng.min-1) and 7.6-(rest 116 ng.min-1) fold, respectively, for the 100 m run and thereafter showed a higher excretion rate than Alb for the 400 m and 800 m runs. The renal clearances of these high (Alb) and low molecular mass (beta 2-m and RBP) proteins followed the changes observed for excretion rates. There was a linear relationship (r2 = 0.996) between plasma lactate concentration and total protein excretion in the postexercise period when taking all five runs into consideration. Glomerular permeability was primarily affected by the 100-m run while the longer runs modified both the glomerular and the tubular sites. To conclude, the present study demonstrated a differential response of the kidney to strenuous exercise with respect to the intensity and duration of the events.

Early steps in the biosynthesis of MUC2 epithelial mucin in colon cancer cells.

Expression of the MUC2 mucin has been demonstrated in normal gastrointestinal and respiratory epithelium and in carcinomas of the gastrointestinal and respiratory tracts, breast, ovary, and bladder using RNA probes and (or) monoclonal antibodies reactive with peptide epitopes on the 23 amino acid tandem repeat. Mouse monoclonal antibodies 4F1 and 3A2 were previously obtained by immunization with mucin derived from the LS174T colon cancer cell line and a KLH conjugate of a synthetic MUC2 VNTR peptide. These antibodies react with distinct epitopes on synthetic VNTR peptides and with normal and malignant epithelial tissues. In the present study, we examined the biosynthesis of MUC2 in LS174T colon cancer cells, using these antibodies to immunoprecipitate labelled mucin. A very high molecular mass protein was immunoprecipitated following 1 min pulse labelling with [3H]threonine and [3H]proline. A slight increase in molecular mass was observed over the next 16 min; however, unlike the MUC1 mucin, there was no large difference in apparent molecular mass between the MUC2 protein precursor and fully processed mucin using separation by SDS-PAGE. O-Glycosylation began within 1 h of synthesis of the protein core. Mucin secretion into the culture medium was detected in the 2nd hour following synthesis and was largely completed within 4 h of synthesis. Secreted mucin was far less reactive with these monoclonal antibodies than the precursor protein.

Flavocetin-A and -B, two high molecular mass glycoprotein Ib binding proteins with high affinity purified from Trimeresurus flavoviridis venom, inhibit platelet aggregation at high shear stress

Two high molecular mass proteins, flavocetin-A and flavocetin-B, were purified from Trimeresurus flavoviridis venom. On polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulfate, the apparent molecular mass of flavocetin-A and -B were 149 and 139 kDa, respectively, under nonreducing conditions. On reduction, flavocetin-A showed two distinct subunits (17 and 14 kDa), and flavocetin-B three distinct subunits (17, 15 and 14 kDa). At 1 μg/ml, flavocetin-A and -B (flavocetins) inhibited the von Willebrand factor (vWF)-dependent aggregation of fixed human platelets. However, flavocetins (10 μg/ml) had no effect on ADP- and collagen-induced platelet aggregation in PRP. Flavocetins (3 μg/ml) also inhibited shear-induced platelet aggregation at high shear stress. Furthermore, flavocetin-A completely inhibited the aggregation of and ATP release from washed platelets stimulated with a low concentration of thrombin. Flavocetin-A specifically bound to platelet with high affinity ( K d = 0.35 ± 0.13nM) at 21 500 ± 1760 binding sites per platelet. The N-terminal amino acid sequences of the subunits of flavocetin-A show a high degree of homology with those of echicetin, botrocetin, alboaggregin-B and factor IX/factor X-binding protein. These results suggest that flavocetins may be a useful tool for further investigation of the GPIb-vWF interaction.

In vitro effects of sodium selenite on nuclear 3,5,3’-triiodothyronine (T3) receptor gene expression in rat pituitary GH4C1 cells

The present study was undertaken in order to investigate the effects of sodium selenite on: 1. The growth of rat pituitary GH4C1 cells; 2. The nuclear T3 receptor gene expression; 3. The cytoplasmic protein phosphorylation; and 4. The prolactin secretion in rat pituitary GH4C1 cell line. Sodium selenite (up to 2.5 microM) has no inhibitory effect on GH4C1 cell proliferation as well as the prolactin secretion. On the other hand, 0.5 microM sodium selenite significantly decreases the rate of mRNA synthesis and/or degradation of both, the alpha 1 form of the T3 receptor (TR alpha 1) and the alpha 2 isoform of the T3 receptor. At 1 microM of sodium selenite, significant changes in the electrophoretic profile of low molecular mass cytoplasmic proteins were found, moreover, sodium selenite (1 microM) also considerably affects phosphorylation of a higher molecular mass proteins. The results based on the in vitro experiments suggest that sodium selenite may affect specific processes at the pretranslational level as well as it may also take part in processes of posttranslational modification of protein(s), the cell vitality and the cell growth remaining unchanged.

Variation in the size of the repeat region of the fibrinogen receptor (clumping factor) of Staphylococcus aureus strains.

The ability of Staphylococcus aureus to bind to fibrinogen and fibrin is believed to be an important factor in the initiation of foreign body and wound infections. Recently, the gene encoding the fibrinogen receptor (clumping factor, ClfA) of S. aureus strain Newman was cloned and sequenced. The ClfA protein possesses a highly unusual 308 residue dipeptide repeat region composed predominantly of Asp and Ser. Polymerase chain reaction analysis of seven different strains showed that the size of the clfA repeat coding region varies from 580 bp to 1320 bp. In contrast, the clfA region A is the same size in each strain. The size of the clfA repeat region did not correlate with the ability of these strains to form clumps in a solution of fibrinogen. Indeed, the strain with the smallest repeat size of 580 bp clumped almost as well as strain Newman. Each strain of S. aureus examined contained several high molecular mass proteins that reacted with anti-ClfA region A antibody. In some cases the molecular mass of the major protein varied in accordance with the length of the coding sequence for the repeat region R.

Characterization of native pathogenic antigens of Onchocerca volvulus: Identification of high molecular mass protein antigens eliciting interstitial keratitis in a guinea pig model

Sclerosing keratitis is the predominant cause of blindness due to onchocerciasis which is a major human parasitic disease caused by the filarial parasite Onchocerca volvulus. In the present investigation, native pathogenic antigens of O. volvulus which are particularly potent in causing interstitial keratitis were characterized utilizing a guinea pig model. Following demonstration of the protein nature of these antigens using pronase digestion, the crude O. volvulus antigen extract was subjected to stepwise procedures of protein purification. At each stage of purification, pooled antigen fractions were injected into one cornea of presensitized guinea pigs followed by clinical evaluation of stromal inflammation and vascularization at different intervals of time after intrastromal challenge. Initial purification of the pathogenic antigens was carried out in the following order: molecular sieve chromatography on Bio-gel A-5m. anion exchange chromatography on Mono Q followed by DEAE-Sepharose CL-6B and cation exchange chromatography on Mono S. Two out of six different pools from the Mono S column (pool a eluted unbound at 10 mM-NaCl and pool e eluted between 130 mM and 475 mM-NaCl) were found to be most pathogenic. Further purification of Mono S pool a and pool e separately by gel filtration chromatography using Superose 12 demonstrated that the fractions which were most potent in inducing interstitial keratitis contained proteins with approximate molecular masses between 100 and 200 kDa. These results show that minor subfractions of total crude antigens of O. volvulus are largely responsible for induction of experimental interstitial keratitis. We have demonstrated the presence of these antigens in O. volvulus microfilariae by their cross-reactivities with anti-microfilarial antibodies, and hence the relevance of the purified antigens to ocular onchocerciasis in man since sclerosing keratitis is associated with invasion of the cornea by O. volvulus microfilariae. Isolation of these two pathogenic antigen pools represents the practical limits of purification and subsequent animal experiments possible with the available amounts of native parasite material obtained from infected human individuals in the absence of a suitable non-human host or of an in vitro culture system for O. volvulus.

Interaction of cadmium and oestradiol-17β on metallothionein and vitellogenin synthesis in rainbow trout (Oncorhynchus mykiss)

The induction of metallothionein and vitellogenin synthesis in rainbow trout liver was studied after injection of oestradiol-17 beta alone or in combination with cadmium or zinc. Intraperitoneal injection of oestradiol-17 beta increased the liver somatic index, with subsequent induction of vitellogenin synthesis. Oestradiol-17 beta did not induce metallothionein synthesis. Injection of cadmium induced the synthesis of metallothionein mRNA and metallothionein. Injection of oestradiol-17 beta in combination with cadmium resulted in inhibition of transcription and translation of both vitellogenin and metallothionein. Chromatography of liver cytosols revealed that cadmium, when co-injected with oestradiol-17 beta, did not bind to metallothionein but would initially bind to high-molecular-mass (HMr) cytosolic proteins. In fish injected with cadmium in combination with oestradiol-17 beta, cadmium was gradually redistributed from HMr proteins to metallothionein. This resulted in induction of metallothionein synthesis and in binding of most of the cadmium to metallothionein. Induction of vitellogenin mRNA was observed 15 days after injection, as cadmium was being redistributed to newly synthesized metallothionein. These findings indicate that cadmium inhibits the transcription of vitellogenin. The binding of cadmium to these non-metallothionein proteins represses the induction of metallothionein and results in increased toxicity of the metal. Preinduction of metallothionein by zinc injections resulted in decreased cadmium sensitivity of the fish and a decrease in the repression of vitellogenin mRNA. Furthermore, a role for metallothionein in the detoxification of cadmium is indicated by the induction of vitellogenin synthesis that occurs once metallothionein has begun sequestering cadmium.

A high molecular mass protein isolated from chicken gizzard: its localization at the dense plaques and dense bodies of smooth muscle and the Z-disks of skeletal muscle.

We purified a 450 kDa protein from a low-salt alkaline extract of chicken gizzard smooth muscle. This high molecular mass protein could be extracted with the low-salt alkaline solution at 37 degrees C but not at 4 degrees C. The 450 kDa protein was isolated from the extract by ammonium sulfate fractionation and following sequential column chromatography using hydroxylapatite, DEAE-Cellulofine A-800m and phenyl-Sepharose CL-4B resins. The partially purified protein molecule resembled a flexible rod with a globular head and an irregular-shaped tail. Its length was approximately 300 nm. The nucleotide sequence of the partial cDNA encoding this protein was determined and analyzed with a data base. The analysis showed that the protein revealed significant homology with the rod region of chicken filamin (57% homology in amino acid sequence). Immunoblot analysis showed that an affinity-purified antibody reacted exclusively with the 450 kDa protein band of smooth, skeletal and cardiac muscle tissues. By indirect immunofluorescence microscopy, we examined the localization of the 450 kDa protein in smooth and skeletal muscle cells. The affinity-purified antibody against the 450 kDa protein stained the dense plaques and dense bodies of smooth muscle, the peripheral region of Z-disks and the subsarcolemmal region of skeletal muscle. Immunoelectron microscopy confirmed the localization of the 450 kDa protein at the peripheral regions of the actin anchoring structures mentioned above. Judging from its amino acid sequence, molecular size, molecular shape, immunological reactivity and localization in muscle cells, the 450 kDa protein seemed to be a new component associated with the actin-anchoring structures of muscle tissues.(ABSTRACT TRUNCATED AT 250 WORDS)

Anti-peptide Sera Against Cell-CAM 105 Determine High Molecular-mass Variants of the Long Isoform in Rat Hepatocytes

The glycoprotein cell-CAM 105 is a member of the carcinoembryonic-antigen-(CEA)-gene family, involved in cell-cell adhesion of rat hepatocytes and expressed on the cell surface as a long (L) and a short (S) isoform with slightly differing molecular masses and isoelectric points. The cDNA of the L-isoform has been isolated and sequenced, as confirmed by the preparation of specific anti-peptide sera [Lin, S.-H., Culic, O., Flanagan, D. & Hixson, D. C. (1991) Biochem. J. 278, 155-161]. Recently, two additional cDNAs have been sequenced, which possess identical deduced primary structures, including short intracellular domains 10 amino acids in length, which differ from the cytoplasmic domain of the L-isoform specifically in the last four C-terminal amino acids. Here, we report on the production of the polyclonal antiserum [anti-(peptide 2)] by immunization with a synthetic hexapeptide (GGSGSF) corresponding to the unique intracellular C-terminal domain of these short cell-CAM 105 cDNA isoforms. This antiserum was specific in ELISA, immunoblot and immunoprecipitation assays for a protein with the same biochemical properties as the S-isoform of cell-CAM 105 expressed in rat liver. In addition, CNBr peptide maps of the S-isoform and the protein immunoprecipitated with anti-(peptide 2) serum were identical. Together, these results provide strong evidence that anti-(peptide 2) serum is specific for the S-isoform of rat liver cell-CAM 105. In immunoblot analysis on liver plasma membrane extracts prepared without collagenase perfusion, at least seven high molecular-mass proteins were observed which showed strong reactivity with mAbs against extracellular epitopes and L-isoform-specific antibodies but no reactivity with anti-(peptide 2) serum. Like the L-isoform, these proteins are expressed on the cell surface and might represent structural variants of cell-CAM 105.

The Thermosome of Thermoplasma acidophilum and Its Relationship to the Eukaryotic Chaperonin TRiC

A high molecular-mass protein complex from the archaebacterium Thermoplasma acidophilum, referred to here as the 'thermosome', is built from two subunits (M(r) 58 and 60). The thermosome has been purified to homogeneity. The molecular mass of the native complex was determined to be 1061 +/- 30 Da by scanning transmission electron microscopy. It shows a weak ATPase activity and is able to bind denatured polypeptides. Averages obtained from electron micrographs of negatively stained molecules in the end-on and side-on orientations, respectively, were compared with those of the t-complex polypeptide 1 ring complex (TRiC), isolated from bovine testes. Both molecules consist of two stacked pseudo eightfold symmetric rings which build up a cylindrical particle with a large cavity in the center. Sequence alignments of peptides generated from both subunits of the thermosome and different subunits of TRiC reveal a high partial similarity to each other and to the archaebacterial chaperonin thermophilic factor 55 from Sulfolobus shibatae as well as to eukaryotic TCP1 proteins. These striking structural similarities confirm the proposition that all these molecules belong to a single protein family which is structurally and functionally related to the GroEL class of molecular chaperones.

Isolation of a Protein Target of the FKBP12-Rapamycin Complex in Mammalian Cells

The immunosuppressive drug, rapamycin, interferes with an undefined signaling pathway required for the progression of G1-phase T-cells into S phase. Genetic analyses in yeast indicate that binding of rapamycin to its intracellular receptor, FKBP12, generates a toxic complex that inhibits cell growth in G1 phase. These analyses implicated two related proteins, TOR1 and TOR2, as targets of the FKBP12-rapamycin complex in yeast. In this study, we have used a glutathione S-transferase (GST)-FKBP12-rapamycin affinity matrix to isolate putative mammalian targets of rapamycin (mTOR) from tissue extracts. In the presence of rapamycin, immobilized GST-FKBP12 specifically precipitates similar high molecular mass proteins from both rat brain and murine T-lymphoma cell extracts. Binding experiments performed with rapamycin-sensitive and -resistant mutant clones derived from the YAC-1 T-lymphoma cell line demonstrate that the GST-FKBP12-rapamycin complex recovers significantly lower amounts of the candidate mTOR from rapamycin-resistant cell lines. The latter results suggest that mTOR is a relevant target of rapamycin in these cells. Finally, we report the isolation of a full-length mTOR cDNA that encodes a direct ligand for the FKBP12-rapamycin complex. The deduced amino acid sequence of mTOR displays 42 and 45% identity to those of yeast TOR1 and TOR2, respectively. These results strongly suggest that the FKBP12-rapamycin complex interacts with homologous ligands in yeast and mammalian cells and that the loss of mTOR function is directly related to the inhibitory effect of rapamycin on G1- to S-phase progression in T-lymphocytes and other sensitive cell types.

Molecular cloning and identification of a novel porcine cathelin-like antibacterial peptide precursor.

A novel clone (C6) encoding the precursor of a 79-residue proline/arginine-rich antibacterial peptide prophenin was isolated from a porcine bone marrow cDNA library. Its deduced N-terminal propart shows 84% identity with cathelin. Additionally, two cathelin isoforms were isolated from peripheral porcine blood and their N-termini sequenced. The sequence of one isoform corresponds to the cathelin sequence, whereas that of the other protein is identical to the propeptide of C6 clone. Western blot analysis of total proteins from porcine and human bone marrow using polyclonal antibodies against cathelin revealed the presence of immunochemically related high molecular mass proteins of about 30 kDa in both samples, whereas low molecular mass proteins of approximately 12 kDa, corresponding to isolated cathelin, were not detected in human bone marrow.

Beta-Amyloid precursor protein isoforms show correlations with neurones but not with glia of demented subjects.

Post-mortem cerebral cortex from 15 demented patients was specially collected to minimise autolysis and two membrane fractions and one soluble fraction were quantitatively examined for the major species of beta-amyloid precursor protein (APP) of high apparent molecular mass (> or = 80 kDa) together with the major mRNA species encoding APP isoforms. The number of pyramidal neurones and astrocytes, putative biochemical indices of interneurones and pyramidal neurones, and choline acetyl transferase activity were also determined. Multiple regression analysis has been used to investigate intercorrelations of APP species with biochemical and morphometric measures, free of any effects of confounding demographic variables. Subjects with Alzheimer's disease showed a loss of cholinergic activity and D-aspartate uptake compared with patients with other causes of dementia. The major finding of the study is that measures of neurones rather than astrocytes most closely correlate with the concentration of APP. Pyramidal cell numbers were positively correlated with mRNA for APP695. APP in the soluble fraction showed a negative correlation with pyramidal cell numbers and cholinergic activity. These results indicate that neurones within the cerebral cortex are the major source of APP, and that secretion of APP is dependent upon cortical pyramidal neuronal activity and cholinergic activity.

Characterization of a novel, high-molecular weight, acidic, endothelin-1 inactivating metalloendopeptidase from the rat kidney

To characterize endothelin-1 inactivating peptidase (ET-1 peptidase) recently isolated from rat kidney. ET-1 peptidase was purified from the membranes of whole Wistar-Kyoto (WKY) rat kidneys using differential centrifugation, detergent solubilization, ion-exchange chromatography, ultrafiltration and preparative electrophoresis. The enzyme activity in the presence of increasing concentrations of unlabelled peptides, inhibitors and other substances was determined at pH 5.5 and 37 degrees C using fixed amounts of [125I]-ET-1 as the substrate. On non-denaturing gels, the purified enzyme migrated in the form of a compact, low-mobility (Rf 0.07), high relative molecular mass (approximately 250,000) protein band. During denaturing polyacrylamide gel electrophoresis this protein separated into three fractions with apparent relative molecular masses 158,000, 110,000 and 61,000. Using different buffers, the optimum pH for this enzyme was found to be 5.5. Zinc (3.7 mmol/l), nickel (4.0 mmol/l), citrate (0.6 mmol/l), phosphate (1.3 mmol/l) and barbital ions (2.5 mmol/l) inhibited ET-1 peptidase activity by 50%, whereas magnesium, calcium, cobalt, manganous, sodium and borate ions were without effect. The most powerful inhibitors of the enzyme included: phenanthroline [median inhibitory concentration (IC50) 28 mumol/l], phosphoramidon (IC50 8.0 nmol/l), thiorphan (IC50 32 nmol/l) and N-carboxymethyl-Phe-Leu (IC50 12 mumol/l). Also, bacitracin (25 mumol/l), cyclosporine A (20 mumol/l) and sodium dodecyl sulphate (0.5%) inhibited enzyme activity by 50%, whereas bestatin, puromycin, aprotinin, phenylmethylsulphonyl fluoride, amanitin (50-100 mumol/l) and cardiotoxin (25 micrograms/assay) had no effect. The Michaelis constant (Km) values of 70 and 66 nmol/l were found towards ET-1 and the ET(16-21) fragment, respectively, whereas the Km values in respect to big-ET-1, sarafotoxin S6b, sulphated cholecystokin octapeptide, gastrin, glucagon, insulin, gastric inhibitory peptide and growth hormone ranged from 1.5 to approximately 50 mumol/l. The enzyme showed no apparent affinity for enkephalins, bradykinin, angiotensins, cholecystokinin tetrapeptides and kyotorphin. The present data suggest that the ET-1 peptidase that we isolated from rat kidney displays inhibitory characteristics similar to that of other known metalloendopeptidases. However, this enzyme exhibits several unique properties such as high molecular mass, an apparent complex subunits structure, pH optimum at 5.5, and very high substrate specificity towards ET-1 and the ET(16-21) fragment compared with other peptides either related or unrelated to endothelin.

A brain-specific activator of cyclin-dependent kinase 5.

Phosphorylation of the neurofilament proteins of high and medium relative molecular mass, as well as of the Alzheimer's tau protein, is thought to be catalysed by a protein kinase with Cdc2-like substrate specificity. We have purified a novel Cdc2-like kinase from bovine brain capable of phosphorylating both the neurofilament proteins and tau. The purified enzyme is a heterodimer of cyclin-dependent kinase 5 (Cdk5) and a novel regulatory subunit, p25 (ref. 8). When overexpressed and purified from Escherichia coli, p25 can activate Cdk5 in vitro. Unlike Cdk5, which is ubiquitously expressed in human tissue, the p25 transcript is expressed only in brain. A full-length complementary DNA clone showed that p25 is a truncated form of a larger protein precursor, p35, which seems to be the predominant form of the protein in crude brain extract. Cdk5/p35 is the first example of a Cdc2-like kinase with neuronal function.

Cell surface protein receptors in oral streptococci

Streptococci have a vast repertoire of adherence properties which include binding to human tissue components, epithelial cells and to other bacterial cells. These interactions are determined by the expression of cell-surface receptors some of which are species-specific. In the oral streptococci, two families of surface protein receptors with highly conserved amino acid sequences have been identified. The antigen I/II family of polypeptides are wall-associated high molecular mass proteins (158–166 kDa) with several binding functions that may be attributed to different domains of the receptor molecules. The LraI family of polypeptides are surface-associated lipoproteins (32–33 kDa) involved in adherence of streptococci to salivary glycoprotein pellicle and to oral Actinomyces. A region of amino acid sequence similarity is evident amongst members of the two protein families in Streptococcus gordonii. Ligand-binding specificities of these receptor polypeptides may account for species-specific adherence and site-directed colonization of streptococci within the human oral cavity.

Cell surface protein receptors in oral streptococci.

Streptococci have a vast repertoire of adherence properties which include binding to human tissue components, epithelial cells and to other bacterial cells. These interactions are determined by the expression of cell-surface receptors some of which are species-specific. In the oral streptococci, two families of surface protein receptors with highly conserved amino acid sequences have been identified. The antigen I/II family of polypeptides are wall-associated high molecular mass proteins (158-166 kDa) with several binding functions that may be attributed to different domains of the receptor molecules. The LraI family of polypeptides are surface-associated lipoproteins (32-33 kDa) involved in adherence of streptococci to salivary glycoprotein pellicle and to oral Actinomyces. A region of amino acid sequence similarity is evident amongst members of the two protein families in Streptococcus gordonii. Ligand-binding specificities of these receptor polypeptides may account for species-specific adherence and site-directed colonization of streptococci within the human oral cavity.

A Novel Very High Molecular Mass Protein Located in the Membrane Skeleton

A monoclonal antibody generated from a mouse immunized with L6 rat myoblast cells was found to react with a major 700-kDa band and a minor 500-kDa band in immunoblots. Immunofluorescence microscopy demonstrated a submembranous location in tissue sections and an exclusion from stress fiber regions in cultured cells. Further, permeabilization of cultured cells with nonionic detergent prior to fixation changed the diffuse pattern of fluorescence to a web. These findings are characteristic of membrane skeletal proteins. In muscle tissue, the protein was much more abundant in fast twitch fibers and was found in internal locations as well as at the membrane. The protein could be solubilized in the absence of detergents and, hence, is not transmembrane. Although initially discovered in myoblast cells, the protein is present in a variety of tissue types, including brain, kidney, heart, liver, and lung. Pulse-chase labeling of the two bands suggested that the 500-kDa band was not a breakdown product of the 700-kDa protein. The protein appears to be a previously undiscovered membrane skeletal constituent for which the name "endossin" is proposed.

Characterization of a novel high molecular mass protein with peptidase activity purified from the human erythrocyte membrane by calmodulin affinity chromatography

A previously undescribed high molecular mass protein (HMP) from human erythrocyte membranes was solubilized by Triton X-100 and purified on a calmodulin-agarose column in the presence of Ca2+. It was shown to have a native molecular mass of 522-560 kDa, comprised of a single subunit of a molecular mass of 28 kDa (p28). The protein is associated with the lipid bilayer rather than with the cytoskeletal component of the membrane. The purified HMP showed peptidase-hydrolyzing activity toward substrates containing hydrophobic amino acids at the P1 position of the P2-P1 cleavage site. The activity was inhibited by serine proteinase inhibitors (leupeptin, phenylmethansulfonyl fluoride) and chymotrypsin inhibitors in particular (chymostatin, N-tosyl-L-phenylalanine chloromethyl ketone). The enzyme exhibited maximal activity at slightly alkaline pH (7.5-8.5) and at 37 degrees C and was stimulated over a narrow range of SDS concentrations (maximal at 0.05%). HMP was found to cross-react in Western blots with an antibody raised against the rabbit multicatalytic proteinase. The single subunit of HMP therefore contains both the catalytic activity and a sequence necessary for its association into a multimeric complex. The properties of the human erythrocyte membrane HMP described indicate that it is a novel peptidase related to the ubiquitous multicatalytic proteinase.

Covalent modificaition of juvenile hormone binding proteins by photoaffinity labeling: An unexpected gel shift effect

The 32 kD juvenile hormone binding protein (JHBP) and two 80 kD proteins in larval Manduca sexta hemolymph were labeled with [3H]FDK, a photoaffinity analog of methyl farnesoate (MF). The labeling could be completely displaced by a 30-fold excess of either MF or JH II, demonstrating that [3H]FDK binds specifically to the JH binding sites of the 32 kD JHBP and the 80 kD proteins. In addition, a high molecular-mass protein was labeled with [3H]FDK; labeling could be displaced by excess MF but not by JH II, demonstrating the selectivity in binding MF. The 32 kD JHBP also appeared to weakly bind the potent juvenoid, methoprene, at the JH binding site. Covalent modification by [3H]FDK induced a change in the apparent size and the isoelectric point of the JHBP. These changes were not induced by substrate alone, nor by UV irradiation alone. The same effect was also observed during labeling with [3H]MDK, an analog of methoprene. These data provide an important caveat for anticipating artifactual changes of protein properties during chemical or photochemical affinity labeling experiments. The molecular dimensions of [3H]FDK more closely resemble those of JH II than those of [3H]EHDA, a photoactivatable analog of JH II. We suggest that covalent modification by a diazoketone photolabel involves a hydrophilic amino acid important in the recognition of the ester group of JH. © 1994 Wiley-Liss, Inc.