Showing papers on "Proteolytic enzymes published in 1988"

Proteolytic activation of latent transforming growth factor-beta from fibroblast-conditioned medium.

Abstract: Transforming growth factor-beta (TGF beta) is produced by most cultured cells in an inactive form. Potential activation mechanisms of latent TGF beta were studied using fibroblastic (NRK-49F and AKR-MCA) cell-conditioned medium as a model. Active TGF beta was monitored by radioreceptor and soft agar assays as well as by antibody inhibition and immunoprecipitation. Little or no TGF beta was detected in untreated conditioned medium. Treatment of the medium with extremes of pH (1.5 or 12) resulted in significant activation of TGF beta as shown by radioreceptor assays, while mild acid treatment (pH 4.5) yielded only 20-30% of the competition achieved by pH 1.5. In an effort to define more physiological means of TGF beta activation, the effects of some proteases were tested. Plasmin and cathepsin D were found to generate 25-kD bands corresponding to the active form of TGF beta as shown by immunoprecipitation analysis of radiolabeled cell-conditioned medium. Plasmin treatment of the medium resulted in activity that was quantitatively similar to that of mild acid treatment as measured by radioreceptor and soft agar assays. In addition, the plasmin-generated activity was inhibited by anti-TGF beta antibodies. Sequential treatments of AKR-MCA cell-conditioned medium with mild acid followed by plasmin or plasmin followed by mild acid gave activation comparable to either treatment alone. The data suggest that conditioned medium may contain at least two different pools of latent TGF beta. One pool is resistant to mild acid and/or plasmin and requires strong acid or alkali treatment for activation. A second pool is activated by mild pH change and/or plasmin. Activation of this form of latent TGF beta may take place by dissociation or proteolytic digestion from a precursor molecule or hypothetical TGF beta-binding protein complex.

Activation of programmed cell death in the rat ventral prostate after castration.

Abstract: The rapid involution of the rat ventral prostate after castration is an active process initiated by removal of the inhibitory effects of androgen on prostatic cell death. The present studies demonstrate that after castration-induced androgen deprivation a series of temporally discrete biochemical events are activated which result in the rapid programmed death of the subset of androgen-dependent cells within the rat ventral prostate. These biochemical steps involve 1) rapid loss of nuclear androgen receptor retention; by 12 h after castration, androgen receptors are no longer detectable in ventral prostatic nuclei; 2) an initial fragmentation of nuclear DNA into low mol wt (less than 1000 basepairs) nucleosomal oligomers which lack intranucleosomal break points; and 3) eventual complete digestion of these nucleosomal oligomers into component nucleotides. Additional studies demonstrate that activation of a Ca2+-Mg2+-dependent endonuclease is associated with this DNA fragmentation. By 4 days after castration, maximal DNA fragmentation is obtained, with 15% of the total nuclear DNA extractable as low mol wt fragments. Proteolytic enzymes are apparently not involved initially in this process, suggesting that DNA fragmentation is a discrete event in, rather than a result of, cell death. Flow cytometric analysis of nuclear DNA content demonstrated that each day after castration, a subpopulation of androgen-dependent cells in rat ventral prostate fragmented all of their genomic DNA, as opposed to the whole population of cells fragmenting an increasing portion of their DNA daily.

Purification, characterization and antimicrobial spectrum of a bacteriocin produced by Pediococcus acidilactici.

Abstract: An antimicrobial peptide designated pediocin AcH was isolated from Pediococcus acidilactici strain H. The pediocin AcH was purified by ion exchange chromatography. The molecular weight of pediocin AcH was determined by SDS-PAGE to be about 2700 daltons. Pediocin AcH was sensitive to proteolytic enzymes resistant to heat and organic solvents, and active over a wide range of pH. Pediocin AcH exhibited inhibition against several food spoilage bacteria and foodborne pathogens including Staphylococcus aureus, Clostridium perfringens and Listeria monocytogenes. It was bactericidal to sensitive cells and acted very rapidly. The bactericidal effect was not produced by either cell lysis or apparent loss of membrane permeability.

Mapping antigenic domains expressed by Chlamydia trachomatis major outer membrane protein genes.

Abstract: Chlamydia trachomatis is an obligate prokaryotic intracellular pathogen of humans that infects mucosal epithelial cells. Exposed domains of its major outer membrane protein (MOMP) are both serotyping and protective antigenic determinants. To identify these domains, we have cloned and epitope-mapped the genes of serovars A, C (C serogroup) and L2, B (B serogroup) with a panel of monoclonal antibodies (mAbs). Predominantly conserved regions of the genes of both serogroups are interspersed with four short variable domains (I-IV). Recombinant phage clones expressing specific MOMP antigenic determinants revealed that protective serotype-specific recognized epitopes in variable domains I and II. Protective subspecies and serogroup-specific mAbs recognized overlapping determinants in variable domain IV near the C terminus. A nonprotective species-specific mAb mapped to an invariant peptide of nine residues contained within variable domain IV. In the intact chlamydial organism of serovar B, variable domains II and IV were susceptible to proteolytic digestion, whereas both N and C termini were protected. These results suggest an arrangement of MOMP in the outer membrane in which three of the four variable domains are exposed to the outside and in which both N and C termini are presumably oriented toward the periplasmic space. This molecular analysis of MOMP antigenic determinants and their surface topology on intact chlamydiae will be useful toward the development of a recombinant subunit or synthetic chlamydial vaccine.

Insulin degradation: mechanisms, products and significance

Abstract: EIGHT YEARS have passed since our previous review of insulin degradation in this journal (1). Much information has been obtained during this period, but the opening statement in that review remains true: Insulin degradation is a complex and incompletely understood process at present. The subcellular site, the cellular and enzymatic mechanisms, and especially the biological functions of insulin degradation all continue to be active and important areas of research. Although significant progress has been made, definitive conclusions are scarce. The purpose of this review is to examine the progress, draw some tentative conclusions, and advance some speculations. Work performed before 1980 will be discussed only briefly, and questions posed in the previous review will be answered, if possible, from the new information now available. New questions will be posed for future consideration. I. Insulin Degrading Enzymes A. Insulin protease-insulin degrading enzyme The primary insulin degrading enzyme in tissues is a...

Protein L. A novel bacterial cell wall protein with affinity for Ig L chains.

Abstract: A novel Ig-binding protein has been isolated from the surface of bacteria belonging to the anaerobic species Peptococcus magnus. To solubilize the protein, peptococci were treated with different proteolytic enzymes (papain, pepsin, and trypsin) or with mutanolysin, a bacteriolytic agent known to digest the cell walls of streptococci. Papain, trypsin, and mutanolysin all solubilized peptides showing affinity for radiolabeled human IgG in Western blot analysis. Compared with papain and trypsin, mutanolysin liberated a more homogeneous material, which also had a higher m.w. This mutanolysin-solubilized protein (Mr 95 kDa) was obtained highly purified by a single isolation step on IgG-Sepharose, and the molecule was found to exhibit unique Ig-binding properties. Thus, in dot blots and in Western blots, human IgG, F(ab')2 and Fab fragments of IgG, and human kappa and lambda L chains all showed affinity for the protein. Moreover, the molecule also bound human IgM and IgA, whereas no binding was recorded for IgG-Fc fragments or IgG H chains. Finally, the protein bound to human polyclonal Ig L chains immobilized on polyacrylamide beads. These different data demonstrate that the isolated peptococcal protein binds Ig through L chain interaction. The name protein L is therefore suggested for this novel Ig-binding bacterial cell wall protein.

Isolation and characterization of the Streptococcus mutans gtfC gene, coding for synthesis of both soluble and insoluble glucans.

Abstract: The intact gtfC gene from Streptococcus mutans GS-5 was isolated in Escherichia coli in plasmid vector pUC18. The glucosyltransferase activity expressed by the gene synthesized both low-molecular-weight water-soluble glucan and insoluble glucan in a primer-independent manner. Purification of the enzyme by procedures that minimize proteolytic digestion yielded a purified preparation with a molecular weight of 140,000. Insertional inactivation of the gtfC gene with a streptococcal erythromycin resistance gene fragment followed by transformation of strain GS-5 suggested that the gtfC gene product was required for sucrose-dependent colonization in vitro. In addition, evidence for the presence of a third gtf gene coding for soluble glucan synthesis was obtained following the construction of mutants containing deletions of both the gtfB and gtfC genes. Images

Protein modification in aging.

Abstract: The age-related accumulation of abnormal forms of enzymes is attributable to posttranslational modification of protein structure and to a progressive loss with age of proteases that preferentially degrade the modified forms. The protein modifications include, but are not limited to: the oxidation of amino acid side chains (especially, side chains of prolyl, arginyl, lysyl and histidinyl residues) by mixed-function oxidation systems; the deamidation of asparaginyl and glutaminyl residues; the racemization and isomerization of aspartyl and asparaginyl residues; the isomerization of prolyl residues; the oxidation of cysteine sulfhydryl groups; and spontaneous changes in protein conformation that are apparently unlinked to changes in amino acid composition. Evidence supporting the roles of these protein modifications and of the proteases that degrade abnormal enzymes during aging is discussed, as well as a consideration of some technical limitations of the methods used in their study.

Pericellular proteolysis by neutrophils in the presence of proteinase inhibitors: effects of substrate opsonization.

Abstract: Inflammatory cells are capable of degrading extracellular matrix macromolecules in vivo in the presence of proteinase inhibitors. We and others have hypothesized that such proteolysis is permitted in large part by mechanisms operative in the immediate pericellular environment, especially at zones of contact between inflammatory cells and insoluble matrix components. To further test this hypothesis in vitro, we have used a model system in which viable polymorphonuclear neutrophils (PMN) are allowed to contact a surface coated with proteinase-sensitive substrate, and in which PMN interaction with the surface can be modulated. We have evaluated proteolysis of the surface-bound protein in the presence and absence of proteinase inhibitors. Our results were: (a) In the presence (but not in the absence) of proteinase inhibitors, proteolysis was confined to sharply marginated zones subjacent to the cells; (b) opsonization of the surface enhanced spreading of the PMN, (c) opsonization diminished the effectiveness of alpha-1-proteinase inhibitor (alpha-1-PI) and alpha-2-macroglobulin as inhibitors of proteolysis of surface-bound protein; (d) anti-oxidants did not alter the effectiveness of alpha-1-PI in inhibiting proteolysis of opsonized substrate by PMN; and (e) PMN could restrict entry of alpha-1-PI into zones of contact with opsonized surfaces. We conclude that: (a) In the presence of proteinase inhibitors, PMN can express sharply marginated and exclusively pericellular proteolytic activity; (b) locally high proteinase concentrations and/or exclusion of proteinase inhibitors from pericellular microenvironments may be important mechanisms for pericellular matrix degradation by PMN; and (c) these observations may have general relevance to extracellular matrix remodeling by a variety of inflammatory and other cell types.

Estrogens and growth factors induce the mRNA of the 52K-pro-cathepsin-D secreted by breast cancer cells.

Abstract: The estrogen-induced 52K protein secreted by human breast cancer cells is a lysosomal protease recently identified as a pro-cathepsin D by sequencing several cDNA clones isolated from MCF7 cells (Augereau et al., Mol. Endocr.). Using one of these clones, we detected, in MCF7 cells, a 2.2 kb mRNA whose level was rapidly increased 4- to 10-fold by estradiol, but not by other classes of steroids. Other mitogens, such as epidermal growth factor and insulin, also induced the 2.2 kb mRNA in a dose-dependent manner. Induction with epidermal growth factor was as rapid but was 2- to 3-fold lower than with estradiol. Antiestrogens had no effect on the 52K-cathepsin-D mRNA in MCF7 cells, but became estrogen agonists in two antiestrogen-resistant sublines R27 and LY2. The use of transcription and translation inhibitors and nuclear run-on experiments indicate that estradiol enhances transcription of the 52K-cathepsin-D gene in MCF7 cells.

Mitochondria contain a proteolytic system which can recognize and degrade oxidatively-denatured proteins.

Abstract: When incubated with mitochondria in an air atmosphere, menadione and doxorubicin (which redox cycle with the respiratory chain to produce oxygen radicals), as well as xanthine oxidase plus xanthine (which generate superoxide and H2O2), stimulated the degradation of newly-synthesized [( 3H]leucine-labelled) mitochondrial polypeptides. No stimulation was observed in an N2 atmosphere, ATP was not required, and xanthine oxidase was not effective without xanthine. Various forms of oxidative stress induced varying degrees of protein cross-linking, protein fragmentation and proteolysis, as judged by gel electrophoresis and amino acid analysis. To learn more about the proteolytic enzymes involved in degradation, we undertook studies with purified protein substrates which had been exposed to oxidative stress (OH or H2O2) in vitro. Despite mitochondrial contamination with acid proteases of lysosomal (and other) origin, pH profiles revealed distinct proteolytic activities at both pH 4 and pH 8. The pH 8 activity preferentially degraded the oxidatively-denatured forms of haemoglobin, albumin and superoxide dismutase; was unaffected by digitonin; and exhibited a several-fold increase in activity upon mitochondrial disruption (highest activity being found in the matrix). In contrast, the pH 4 activity was dramatically decreased by digitonin treatment (to reduce lysosomal contamination); was unaffected by mitochondrial disruption; and showed no preference for oxidatively-denatured proteins. The pH 8 activity was not stimulated by ATP, but was inhibited by EDTA, haemin and phenylmethylsulphonyl fluoride. In contrast, the contaminating pH 4 activity was only inhibited by pepstatin and leupeptin. Thus, our experiments reveal a distinct mitochondrial (matrix) proteolytic pathway which can preferentially degrade oxidatively-denatured proteins.

Dimerization of the tat protein from human immunodeficiency virus: a cysteine-rich peptide mimics the normal metal-linked dimer interface.

Abstract: We have synthesized an 18-amino acid peptide that contains the cysteine-rich region of the tat protein from human immunodeficiency virus. Previous experiments in vitro with the intact tat protein have shown that these cysteines serve as metal ligands, causing tat to form metal-linked dimers. Ultraviolet absorption spectra show that the synthetic peptide (tat21-38) binds two Cd2+ or two Zn2+ ions per peptide monomer, and some changes in the circular dichroism spectra are seen as the metals bind. The peptide-metal complexes are completely resistant to proteolytic digestion, and mass spectrometry demonstrates that this peptide forms metal-linked dimers. The peptide can also combine with the intact tat protein to form metal-linked heterodimers. If these heterodimers are unable to trans-activate viral transcription, tat21-38 could be a lead compound for designing drugs to treat acquired immunodeficiency syndrome.

Accelerated cheese ripening with heat treated cells of Lactobacillus helveticus and a commercial proteolytic enzyme

Abstract: Synergic effects of proteolytic enzymes from two different microbial sources on the ripening of Swedish hard cheese were studied. When extracellular proteolytic enzymes from Bacillus subtilis (Neutrase) and/or heat treated cells of Lactobacillus helveticus (now L. delbrueckii subsp. helveticus ) were added to the cheese milk, cheese ripening was accelerated; Neutrase effectively hydrolysed casein to give a softer body. Addition of heat treated lactobacilli did not accelerate hydrolysis of casein, but accelerated the breakdown of peptides which increased the amount of amino acid N in the cheese and also enhanced the intensity of cheese flavour. A bitter taste which developed in cheeses with added Neutrase could be eliminated by the simultaneous addition of heat treated lactobacilli.

Long-term stability of electroenzymatic glucose sensors implanted in mice. An update.

Abstract: Protection of the enzyme layer of glutaraldehyde vapor-stabilized glucose oxidase-based glucose sensors from attack by proteolytic enzymes and peritoneal macrophages can be accomplished by covering with a regenerated cellulose (viscose) membrane, as commonly used for laboratory dialysis. These implanted sensors are not externally polarized, but continuously consume oxygen and glucose and generate gluconic acid and hydrogen peroxide. On the average (sensors in 45 mice) the activity declines with time, almost vanishing by 600 days. However, the fact that some sensors retain nearly all of their activity for over 500 days indicates that glucose sensors can be made with a life span compatible with the requirements for an artificial pancreas (glucose sensor/insulin pump). Limited observation with similar implanted lactate sensors indicates their life span to be shorter.

Protein stabilization via hydrophilization

Abstract: This paper experimentally verifies the idea presented earlier that the contact of nonpolar clusters located on the surface of protein molecules with water destabilizes proteins It is demonstrated that protein stabilization can be achieved by artificial hydrophilization of the surface area of protein globules by chemical modification Two experimental systems are studied for the verification of the hydrophilization approach The surface tyrosine residues of trypsin are transformed to aminotyrosines using a two-step modification procedure: nitration by tetranitromethane followed by reduction with sodium dithionite The modified enzyme is much more stable against irreversible thermoinactivation: the stabilizing effect increases with the number of aminotyrosine residues in trypsin and the modified enzyme can become even 100 times more stable than the native one Alpha-chymotrypsin is covalently modified by treatment with anhydrides or chloroanhydrides of aromatic carboxylic acids As a result, different numbers of additional carboxylic groups (up to five depending on the structure of the modifying reagent) are introduced into each Lys residue modified Acylation of all available amino groups of alpha-chymotrypsin by cyclic anhydrides of pyromellitic and mellitic acids results in a substantial hydrophilization of the protein as estimated by partitioning in an aqueous Ficoll-400/Dextran-70 biphasic system These modified enzyme preparations are extremely stable against irreversible thermal inactivation at elevated temperatures (65-98 degrees C); their thermostability is practically equal to the stability of proteolytic enzymes from extremely thermophilic bacteria, the most stable proteinases known to date

Protein antigen-monoclonal antibody contact sites investigated by limited proteolysis of monoclonal antibody-bound antigen: protein "footprinting"

Abstract: This study describes the use of limited proteolysis of monoclonal antibody (mAb)-bound antigens in the analysis of the two measles virus surface glycoproteins. This approach is dubbed protein "footprinting" in analogy with DNA "footprinting." Protein footprinting was superior to competitive-binding assays and as good as in vitro mAb-selected variant analysis in differentiating among mAbs with various specificities to a given protein. Proteolytic digestion of the antigen prior to mAb binding drastically reduced mAb binding resulting in poor differentiation among mAbs. In contrast, protein footprinting showed that some mAbs retained the ability to immunoprecipitate such fragments. Thus footprinting could be used for localization of mAb epitopes on a protein and proved also to be an effective means of distinguishing among mAb-selected variants differing in single epitopes. Conformational changes caused by heat-denaturation or the binding of anti-antibody to an antigen-antibody complex could also be detected by footprinting.

Two viral proteins involved in the proteolytic processing of the cowpea mosaic virus polyproteins.

Abstract: A series of specific deletion mutants derived from a full-length cDNA clone of cowpea mosaic virus (CPMV) B RNA was constructed with the aim to study the role of viral proteins in the proteolytic processing of the primary translation products. For the same purpose cDNA clones were constructed having sequences derived from both M and B RNA of CPMV. In vitro transcripts prepared from these clones with T7 RNA polymerase, were efficiently translated in rabbit reticulocyte lysates. The translation products obtained were processed in the lysate by specific proteolytic cleavages into smaller products, which made it possible to study subsequently the effect of the various mutations on this process. The results obtained indicate that the B RNA-encoded 24K polypeptide represents a protease responsible for all cleavages in the polyproteins produced by both CPMV B and M RNA. For efficient cleavage of the glutamine-methionine site in the M RNA encoded polyprotein the presence of a second B RNA encoded protein, the 32K polypeptide, is essential, although the 32K polypeptide itself does not have proteolytic activity. A number of cleavage-site mutants were constructed in which the coding sequence for the glutamine-glycine cleavage site between the two capsid proteins was changed. Subsequent in vitro transcription and translation of these cleavage site mutants show that a correct dipeptide sequence is a prerequisite for efficient cleavage but that the folding of the polypeptide chain also plays an important role in the formation of a cleavage site.

Folding of collagen IV.

Abstract: Collagen IV dimers of two collagen IV molecules connected by their C-terminal globular NC1 domains were isolated by limited digestion with bacterial collagenase from mouse Engelbreth-Holm-Swarm (EHS) sarcoma tissue. The collagenous domains were only 300 nm long as compared to 400 nm of intact collagen IV but the disulfide bonds in the N-terminal region of the major triple helix were retained. Unfolding of the collagenous domains as monitored by circular dichroism occurred in a temperature range of 30 to 44°C with a midpoint at 37°C. The transition is significantly broader than that of the continuous triple helices in collagens I, II and III, a feature which can be explained by the frequent non-collagenous interruptions in the triple-helical domain of collagen IV. Refolding at 25°C following complete unfolding at 50°C was monitored by circular dichroism, selective proteolytic digestion of non-refolded segments and by a newly developed method in which the recovered triple-helical segments were visualized by electron microscopy. Triple-helix formation was found to proceed in a zipper-like fashion from the C-terminal NC1 domains towards the N-terminus, indicating that this domain is essential for nucleations. For collagen IV dimers with intact NC1 domains the rate of triple-helix growth was of comparable magnitude to that of collagen III, demonstrating that the non-collagenous interruptions do not slow down the refolding process where the rate-limiting step is the cis-trans isomerization of proline peptide bonds. Refolding was near to 100% and the refolding products were similar to the starting material as judged by thermal stability and electron microscopic appearance. Removal of the NC1 domains by pepsin or dissociation of their hexametric structures by acetic acid led to a loss of the refolding ability. Instead products with randomly dispersed short triple-helical segments were formed in a slow reaction. In no case, even when the disulfide bonds in the N-terminal region of the triple-helical domain were intact, was refolding from the N- towards the C-terminus observed. Taken together with results in other collagens, this suggests that C to N directionality might be an intrinsic property of triple-helix folding.

Functional characterization of macrophage receptors for in vitro phagocytosis of unopsonized Pseudomonas aeruginosa.

Abstract: The phagocytic receptor for unopsonized Pseudomonas aeruginosa was characterized functionally using human monocyte-derived macrophages. Freshly isolated human peripheral blood monocytes were unable to ingest unopsonized P. aeruginosa; ingestion did not occur until the cells had been in culture for 2 d and it became maximal after 4 d. Macrophages plated on coverslips derivatized with anti-BSA IgG or with human gamma-globulin lost the capacity to phagocytose unopsonized P. aeruginosa, unopsonized zymosan, and EIgG but bound C3bi-coated erythrocytes normally. Each of the four human IgG subclasses and Fc fragments of anti-BSA IgG inhibited phagocytosis of both unopsonized P. aeruginosa and EIgG. Phagocytosis of P. aeruginosa and zymosan was markedly impaired and EIgG minimally inhibited if macrophages were plated on coverslips derivatized with mannan or when mannan was added to the phagocytosis buffer. Phagocytosis of P. aeruginosa and zymosan, and binding of EC3bi was dependent on the presence of divalent cations, but phagocytosis of EIgG was not. The macrophage phagocytic receptor for unopsonized P. aeruginosa was inactivated by proteolytic enzymes. Phagocytosis of P. aeruginosa was inhibited by D-mannose, L-fucose, and alpha methyl mannoside, but not by L-mannose, D-fucose, or D-glucose. The same sugars inhibited phagocytosis of unopsonized zymosan. We conclude that phagocytosis of unopsonized P. aeruginosa by human monocyte-derived macrophages is facilitated by mannose receptors.

Molecular cloning and expression of genes encoding proteolytic enzymes

Abstract: Novel methods and novel industrial Bacillus strains are provided for enhanced production of serine protease. Plasmid constructs comprising the serine protease gene are introduced into a compatible host, generally a Bacillus already overproducing serine protease. Preferred host cells are those from Bacillus novo sp. PB92 and the preferred serine protease gene also originates from Bacillus PB92. Integration and maintenance of the plasmid in the host cell chromosome can be achieved by including a temperature sensitive origin of replication in the plasmid construct and growing under selective conditions.

Three-dimensional network of cords: The main component of basement membranes

Abstract: Basement membranes were divided into two types: 1) thin basement membranes, such as those of the epidermis, trachea, jejunum, seminiferous tubule, and vas deferens of the rat, the ciliary process of the mouse, and the seminiferous tubule of the monkey, and 2) thick basement membranes, such as the lens capsule of the mouse and Reichert's membrane of the rat. High-magnification electron microscopy was used to examine both types after fixation either in glutaraldehyde followed by postosmication or in potassium permanganate. The basic structure of thin and thick basement membranes was found to be a three-dimensional network of irregular, fuzzy strands referred to as "cords"; the diameter of these cords was variable, but averaged 4 nm in all cases examined. The spaces separating the cords differed, however. In the lamina densa of thin basement membranes, the diameter of these spaces averaged about 14 nm in every case, whereas in the lamina lucida it ranged up to more than 40 nm. Intermediate values were recorded in thick basement membranes. Finally, the third, inconstant layer of thin basement membranes, pars fibroreticularis, was composed of discontinuous elements bound to the lamina densa: i.e., anchoring fibrils, microfibrils, or collagen fibrils. In particular, collagen fibrils were often surrounded by processes continuous with the lamina densa and likewise composed of a typical cord network. Finally, two features were encountered in every basement membrane: 1) a few cords were in continuity with a 1.4- to 3.2-nm thick filament or showed such a filament within them; the filaments became numerous after treatment of the seminiferous tubule basement membrane with the proteolytic enzyme, plasmin, since cords decreased in thickness and could be reduced to a filament, and 2) at the cord surface, it was occasionally possible to see 4.5-nm-wide sets of two parallel lines, referred to as "double tracks." On the basis of evidence that the filaments are type IV collagen molecules and the double tracks are polymerized heparan sulfate proteoglycan, it is proposed that cords are composed of an axial filament of type IV collagen to which are associated glycoprotein components (laminin, entactin, fibronectin) and the double tracks of the proteoglycan.