Ultrastructural analyses of control and enzyme-treated isolated renal basement membranes

New developments in corneal endothelial cell replacement

Corneal transplantation is currently the most effective treatment to restore corneal clarity in patients with endothelial disorders. Endothelial transplantation, either by Descemet membrane endothelial keratoplasty (DMEK) or by Descemet stripping (automated) endothelial keratoplasty (DS(A)EK), is a surgical approach that replaces diseased Descemet membrane and endothelium with tissue from a healthy donor eye. Its application, however, is limited by the availability of healthy donor tissue. To increase the pool of endothelial grafts, research has focused on developing new treatment options as alternatives to conventional corneal transplantation. These treatment options can be considered as either 'surgery-based', that is tissue-efficient modifications of the current techniques (e.g. Descemet stripping only (DSO)/Descemetorhexis without endothelial keratoplasty (DWEK) and Quarter-DMEK), or 'cell-based' approaches, which rely on in vitro expansion of human corneal endothelial cells (hCEC) (i.e. cultured corneal endothelial cell sheet transplantation and cell injection). In this review, we will focus on the most recent developments in the field of the 'cell-based' approaches. Starting with the description of aspects involved in the isolation of hCEC from donor tissue, we then describe the different natural and bioengineered carriers currently used in endothelial cell sheet transplantation, and finally, we discuss the current 'state of the art' in novel therapeutic approaches such as endothelial cell injection.

Basement membranes in the cornea and other organs that commonly develop fibrosis

Basement membranes are thin connective tissue structures composed of organ-specific assemblages of collagens, laminins, proteoglycan-like perlecan, nidogens, and other components. Traditionally, basement membranes are thought of as structures which primarily function to anchor epithelial, endothelial, or parenchymal cells to underlying connective tissues. While this role is important, other functions such as the modulation of growth factors and cytokines that regulate cell proliferation, migration, differentiation, and fibrosis are equally important. An example of this is the critical role of both the epithelial basement membrane and Descemet's basement membrane in the cornea in modulating myofibroblast development and fibrosis, as well as myofibroblast apoptosis and the resolution of fibrosis. This article compares the ultrastructure and functions of key basement membranes in several organs to illustrate the variability and importance of these structures in organs that commonly develop fibrosis.

The ultrastructural organization and architecture of basement membranes

Basement membranes are ubiquitous complex, multicomponent structures having diverse functions. They are morphologically distinct and exhibit specific structural details including the lamina rara and lamina densa. In addition, the interstitial stroma abutting the lamina densa has a unique organization. While the composition of basement membranes is still incompletely known, several components have been identified, including collagen types IV and V, laminin and heparan sulphate proteoglycan. High resolution immunoelectron microscopic studies have allowed the development of various models of the organization and architecture of the basement membrane, suggesting specific localizations of the various collagen types and specific domains of the collagen molecules, laminin and other components. In addition, high resolution metal shadow casting techniques have allowed the development of molecular models of specific components of the basement membrane and methods of studying the domain structure and interactions of these components.

Development of late-stage diabetic nephropathy in OVE26 diabetic mice

OVE26 mice are a transgenic model of severe early-onset type 1 diabetes. These mice develop diabetes within the first weeks of life and can survive well over a year with no insulin treatment, and they maintain near normal body weight. To determine whether OVE26 mice provide a valuable model of chronic diabetic nephropathy (DN), OVE26 diabetic mice were compared with their nondiabetic littermates for functional and structural characteristics of DN. OVE26 mice exhibited pronounced polyuria and significant albuminuria by 2 months of age (305 microg/24 h in OVE26 vs. 20 microg/24 h in controls). Albumin excretion rate increased progressively with age and exceeded 15,000 microg/24 h at 9 months of age. The profound loss of albumin led to hypoalbuminemia in some diabetic animals. Albuminuria coincided with an elevation in blood pressure as measured by tail cuff. The glomerular filtration rate (GFR) in OVE26 mice measured using fluorescein isothiocynate inulin clearance demonstrated that GFR increased significantly from 2 to 3 months of age and then decreased significantly from 5 to 9 months. GFR in 9-month-old diabetic mice was significantly lower than that of 9-month-old control mice. The decline in GFR coincided with a significant increase in renal vascular resistance. Structural studies showed an almost twofold increase in kidney weight between 2 and 5 months. Diabetic mice also showed progressively enlarged glomeruli and expanded mesangium with diffuse and nodular expansion of mesangial matrix. Tubulointerstitial fibrosis was also observed in these mice. Glomerular basement membrane was thickened in OVE26 mice. In summary, OVE26 mice demonstrate that most of the characteristics of human DN can be produced by chronic hyperglycemia in a murine model. This model will be useful for improved understanding and treatment of DN.

Scanning and transmission electron microscopic studies of normal and diabetic acellular glomerular and retinal microvessel basement membranes

Basement membranes (BMs) were first described in the mid-19th century, but they were not isolated and prepared for compositional studies until nearly 100 years later. Early methods of isolation were carried out on renal glomeruli, which were first sub-fractionated from kidney tissues by sieving. BMs were then isolated from the glomeruli by ultrasonic disruption, which, following low speed centrifugation, yielded "purified" but highly fragmented BM material. In an effort to obviate the mechanical damage to BMs produced by ultrasound, a sequential detergent solubilization technique was introduced that resulted in morphologically intact BMs from a variety of tissue sub-fractions. This was highly advantageous because "acellular" BMs produced by the procedure could be examined critically by light and electron microscopic methods. Subsequently, this procedure has been utilized to demonstrate the substructural heterogeneity of vascular and non-vascular BMs from a wide variety of animal species. The current review describes the results of scanning and transmission electron microscopic studies of acellular BMs prepared from renal glomeruli and from the retinal microvessels of the eye. These BMs are of particular interest to basic scientists and clinicians because they are altered in several disease states, most notably diabetes mellitus. An effort is made to point out the implications of glomerular and retinal vessel BM changes to the pathogenesis of diabetic kidney and retinal vessel BM disease.

Quick-freeze, deep-etch studies of renal basement membranes

The fine structure of the renal (i.e., glomerular, tubular, and capillary) basement membranes was re-evaluated with the aid of a deep-etch replica method. The structure of the laminae rarae interna and externa of the rat glomerular basement membrane (GBM) and laminae lucida of other basement membranes were basically identical in that 6 to 8 nm fibrils were interconnected to form a three-dimensional, polygonal network. By contrast, all of the laminae densa examined were composed of closely packed granules, and a filamentous substructure was identified only in a limited area. These granular components were demonstrated to be an integral component of the lamina densa. From additional observations on the trypsinized bovine GBM, it appeared that the basic structure of renal basement membranes was almost identical, namely, that a three-dimensional fibrillar meshwork existed throughout the individual layers to form a structural framework upon which fine particles were variably attached. In addition, we observed some of the fine structure of the pars fibroreticularis; the laminae densa of the tubular and capillary basement membranes continued to the fibrillar meshwork resembling the structural backbone of the glomerular basement membrane. The network was sometimes directly connected to the extracellular matrix, but more often changed into a rough fibrillar framework and connected to the extracellular matrix.

Nonenzymatic glycosylation-induced modifications of intact bovine kidney tubular basement membrane

We examined structural changes in bovine kidney tubular basement membrane (TBM) following in vitro nonenzymatic glycosylation (NEG). Isolated TBM was incubated for 2 wk at 37 degrees C in the absence of sugar or in the presence of either glucose or ribitol under conditions that minimized degradation and oxidative damage. NEG and crosslink formation in glycated TBM were confirmed by decreased solubility, increased amounts of low mobility material by SDS-PAGE, and increased specific fluorescence compared to controls. Morphological analysis using high resolution, low voltage scanning electron microscopy (LV-SEM) revealed a complex three-dimensional meshwork of interconnecting strands with intervening openings. Glycated TBM underwent distinct morphological changes, including a 58% increase in the amount of image surface area occupied by openings. This was due to an apparent increase in the number of large openings (diameters > 12.5 nm), whereas the number of small openings (diameters < 12.5 nm) remained unchanged. These findings corroborate earlier physiological studies, which established that the loss of glomerular permselectivity seen in patients with diabetic nephropathy is due to the formation of large pores in the kidney filtration barrier of which the BM is a major component. We conclude that NEG and crosslink formation among BM components lead to modifications of BM ultrastructure, which could play a role in loss of barrier function in diabetic microangiopathy and nephropathy.

Lectin-binding sites during postnatal differentiation of normal and cystic rabbit renal corpuscles

Fluorochrome-labeled lectins were used to study the expression of glycoconjugates during the postnatal differentiation of normal and cystic rabbit renal corpuscles. Glomerular cysts (GC) are induced in the rabbit by a single injection of corticoids. The Bowman's capsule of these cysts is exclusively formed of podocytes (parietal podocytes). During normal development, the cell coat of the podocytes is intensely positive for wheat germ agglutinin (WGA) and Maclura pomifera agglutinin (MPA). This reaction decreases considerably during maturation, in parallel with an increase in the number of binding sites masked by terminal sialylation. Throughout the stages studied, the podocyte coat is peanut agglutinin (PNA)-negative, but it becomes intensely positive after neuraminidase treatment. Visceral and parietal podocytes in the glomerular cysts show the same pattern of glycosylation as the normal podocytes. In contrast, normal parietal cells only transiently expressed a weak reactivity to WGA and MPA during the first stages of differentiation, and did not express cryptic binding sites at any stage. The glomerular basement membrane (GBM) is positive to WGA, to succinylated WGA, and to MPA, in all the stages studied. Maturation of the GBM is characterized by expression of cryptic MPA-binding sites, and by a considerable increase in the number of cryptic PNA-binding sites. The basement membrane of the parietal layer of the cystic Bowman's capsule shows the same pattern of glycosylation, despite the fact that this epithelial layer is solely formed of podocytes and lacks endothelial cells. In contrast, the normal parietal basement membrane does not express PNA or MPA cryptic sites at any stage.(ABSTRACT TRUNCATED AT 250 WORDS)

Renal basement membranes by ultrahigh resolution scanning electron microscopy

Three-dimensional ultrastructures of basement membranes of the rat kidney were investigated with an ultrahigh resolution scanning electron microscope (HSEM) equipped with a resolving power of 0.5 nm. All cellular components were extracted from renal cortical tissues by sequential-detergent treatment. Four types of acellular basement membranes were observed after tannin-osmium conductive staining: the glomerular basement membrane (GBM) associated with the mesangial matrix, the tubular basement membrane (TBM), the Bowman's capsule basement membrane (BCBM), and the peritubular capillary basement membrane (PTCBM). We could demonstrate the polygonal meshwork structures composed of strands in the respective basement membranes. The strands averaged 6 to 7 nm wide, whereas the pore sizes within the meshworks were variable and differed according to the basement membrane type. Moreover, we confirmed the presence of the heterogeneity of the GBM suggested by several approaches. Present data support the proposition that a polygonal meshwork structure may represent the basic structure of basement membrane. Some of the observed architectural dissimilarities in basement membrane types may reflect their different functional properties, which in turn may reflect the heterogeneous distribution of major basement membrane components as demonstrated by immunohistochemical and biochemical studies.

SEM and TEM analyses of isolated human retinal microvessel basement membranes in diabetic retinopathy

Human retinas from persons with diabetic retinopathy and age-matched controls were rendered acellular by sequential detergent treatment. The resulting network of microvascular extracellular matrix (ECM) materials, including basement membranes (BMs), was compared by TEM and, following cryofracture, by SEM. Our study demonstrates that in diabetics, retinal capillary BM complexes are generally thickened and that their ECM subcomponents, including BM leaflets and BM-like pericytic matrix (PCM), are differentially altered. Two diabetic microvessel types were identified. In type A vessels, ECM expansion is manifested by loosely arranged combinations of concentric PCM layers and collagen fibrils with thickened subendothelial (EBM) and pericyte (PBM) BM leaflets. Type B vessels show densely compact central PCM masses and poorly recognizable EBMs and PBMs. In both types, Müller cell BMs (MBMs) are relatively unaffected. High-resolution SEM shows tissue-specific features in normal EBM and MBM surfaces, but disease-related topographic changes are not evident. It is possible that the ECM arrangements identified in our study relate to different microvessel domains and that their specific morphological features may play important roles in the pathogenesis of diabetic retinopathy including capillary closure and neovascularization.

Characterization of the collagen in the hexagonal lattice of Descemet's membrane: its relation to type VIII collagen

To investigate the nature of the hexagonal lattice structure in Descemet's membrane, monoclonal antibodies were raised against a homogenate of bovine Descemet's membranes. They were screened by immunofluorescence microscopy to obtain antibodies that label Descement's membrane. Some monoclonal antibodies labeled both Descemet's membrane and fine filaments within the stroma. In electron microscopy, with immunogold labeling on a critical point dried specimen, the antibodies labeled the hexagonal lattices and long-spacing structures produced by the bovine corneal endothelial cells in culture; 6A2 antibodies labeled the nodes of the lattice and 9H3 antibodies labeled the sides of the lattice. These antibodies also labeled the hexagonal lattice of Descemet's membrane in situ in ultrathin frozen sectioning. In immunofluorescence, these antibodies stained the sclera, choroid, and optic nerve sheath and its septum. They also labeled the dura mater of the spinal cord, and the perichondrium of the tracheal cartilage. In immunoblotting, the antibodies recognized 64-kD collagenous peptides both in tissue culture and in Descemet's membrane in vivo. They also recognized 50-kD pepsin-resistant fragments from Descemet's membranes that are related to type VIII collagen. However, they did not react either in immunoblotting or in immunoprecipitation with medium of subconfluent cultures from which type VIII collagen had been obtained. The results are discussed with reference to the nature of type VIII collagen, which is currently under dispute. This lattice collagen may be a member of a novel class of long-spacing fibrils.

Human retinal capillary basement membrane leaflets are morphologically distinct: a correlated TEM and SEM analysis

Because retinal capillaries and their associated basement membranes (BMs) are significantly altered in a number of diseases (most notably diabetic retinopathy), the human retinal microvasculature is of interest to both basic scientists and clinicians. Consequently, numerous TEM studies centered primarily on cellular elements of retinal microvessels have been carried out. Ultrastructural studies emphasizing retinal capillary extracellular matrix (ECM) materials including BMs however, are nearly non-existent. Accordingly, the current correlated TEM/SEM investigation was undertaken. The study shows that retinal capillary walls are comprised of a continuous layer of endothelial cells and a discontinuous layer of intramural pericytes which are in frequent contact. These are underlain and/or surrounded by a retinal capillary BM complex which includes pericytic matrix, fibrillar collagen, and subendothelial, pericytic and Müller cell BM leaflets. Following sequential detergent treatment, all retinal cells are solubilized. Vessel ECM components, however, maintain their in vivo histoarchitectural relationships. Moreover, on the basis of substructure, susceptibility to non-specific proteases and anionic site density, BM leaflets are morphologically distinct. In addition, high-resolution SEM studies show that BM surface characteristics are tissue specific. It is concluded that retinal capillary BM complexes are comprised of structurally unique subcomponents the characteristics of which should be considered in future studies of retinal capillary BM structure, composition and function and particularly in investigations in which retinal capillaries are pathologically altered.

Ultrastructural evidence for morphological specificity in isolated bovine retinal capillary basement membranes

Because of its relative availability, large size, and presumed similarity to human, the bovine retina has been used by numerous investigators as a source of vessels, cells, and basement membranes (BMs) for biochemical analyses and in vitro studies of cells and extracellular matrix. Careful morphological studies of these vessels and their associated BMs, however, have not been done. Accordingly, we carried out experimental ultrastructural studies in an effort to show their cellular composition, their histoarchitectural relationships within retinal capillary walls, and the disposition and features of their isolated BMs. Our study shows that these vessels are complex, multicomponent structures composed of endothelial cells and intramural pericytes, which frequently communicate via direct cell/cell contacts, and a system of BMs. The latter includes continuous Muller cell BMs, interrupted subendothelial BMs, and pericytic BMs with masses of pericytic matrix (PCM) intervening. Isolated subendothelial BMs are remarkable for fenestrations, selective susceptibility to nonspecific proteases, and high density of ruthenium red (RR)-positive anionic sites. On the contrary, Muller cell BMs are continuous (completely surrounding retinal capillaries), relatively refractory to proteases, and show significantly fewer anionic sites by RR. Acellular capillary BMs frequently show ghost-like "pockets" previously occupied by pericytes. These are surrounded by pericytic BMs and interstitial spaces are "filled-in" by a BM-like material (PCM) which frequently contains striated collagen fibrils and is positionally and morphologically homologous to glomerular mesangial matrix. These data indicate that tissue specificity of BMs may be far more precise than previously thought and that each capillary BM leaflet may possess a peculiar macromolecular architecture commensurate with its specific function.

Localization of newly synthesized protein precursors of basement membrane in the embryonic central nervous system as revealed by radioautography

Using light- and electron microscope radioautography, the dynamics of newly synthesized protein precursors taking part in elaboration of brain basement membrane have been examined. The data presented give evidence that all cell types (endothelial, pericytal, and astroglial cells) surrounding the brain basement membrane contribute to its composition. A quantitative uptake analysis of 3H-proline indicates a progressive decline in the amount of labeled precursor in the examined cell types with a corresponding increase in deposition of the label at the presumptive basement membrane. The endothelial cells plays the main role in the membrane elaboration followed by pericyte and astrocyte which participate at lesser but equal degree in this synthesis.

SEM studies of acellular glomerular basement membrane in human diabetic glomerulopathy

Previous transmission electron microscopic studies have demonstrated glomerular basement membrane (GBM) thickening and mesangial matrix (MM) expansion in chronic stages of diabetes. It is difficult, however, to achieve an appreciation of GBM surface features and distribution of MM in planar views. In the current study, autopsy human renal cortical tissue from patients with end-stage diabetic nephropathy were minced and rendered acellular with detergents prior to fixation, cryofracture, and preparation for light microscopic (LM), transmission electron microscopic (TEM), and scanning electron microscopic (SEM) observation in an effort to visualize extracellular materials in three dimensions. Our studies demonstrated that although diabetic glomerular changes vary widely within and between individuals, most showed alterations primarily affecting peripheral (epithelial) GBM (with MM increased but diffusely distributed), or they exhibited similar GBM changes but with variable nodular MM expansion leading ultimately to capillary occlusion. Both types showed peripheral GBM thickening and demonstrated external surface irregularities that by SEM appeared as "cauliflower-like" lobulations. In these glomeruli, GBM lamellation or reduplication was common with internal layers frequently thrown into lumenward projections. Glomeruli with diffusely distributed MM generally showed patent capillary channels with little evidence of occlusion. By TEM, highly compact, epithelial GBMs were clearly distinguishable from the electron-lucent MM. In these preparations the matrix was concentrated in relatively small discrete masses sometimes covered by a finely fibrillar material, which extended intermittently onto lumenal surfaces of epithelial GBMs. In more advanced stages of MM involvement, glomeruli typically exhibited smooth-surfaced nodules that were increased at the expense of capillary surface area. By TEM, MM nodules were comprised of a meshwork of very fine (20-A) fibrils surrounding a variety of detergent-resistant structures including collagenous fibrils and non-collagenous 30-nm circular fibrils with 16-nm subunits. By SEM, GBM and MM nodules were not distinguishable and merged to form substantial barriers to capillary blood flow. In those capillary channels remaining patent, inwardly projecting folds and ridges were common GBM features, and frequently thin fenestrated layers, distinctly separate from epithelial GBMs, formed sieve-like linings for the channels. These three-dimensional observations provide unique views of the processes leading to diabetic glomerular occlusion and suggest a potential for this technique in the study of renal BM disease.

Type VI collagen in extracellular, 100-nm periodic filaments and fibrils: identification by immunoelectron microscopy

Filaments and fibrils that exhibit a 100-nm axial periodicity and occur in the medium and in the deposited extracellular matrix of chicken embryo and human fibroblast cultures have been tentatively identified with type VI collagen on the basis of their similar structural characteristics (Bruns, R. R., 1984, J. Ultrastruct. Res., 89:136-145). Using indirect immunoelectron microscopy and specific monoclonal and polyclonal antibodies, we now report their positive identification with collagen VI and their distribution in fibroblast cultures and in tendon. Primary human foreskin fibroblast cultures, labeled with anti-type VI antibody and studied by fluorescence microscopy, showed a progressive increase in labeling and changes in distribution with time up to 8 d in culture. With immunoelectron microscopy and monoclonal antibodies to human type VI collagen followed by goat anti-mouse IgG coupled to colloidal gold, they showed in thin sections specific 100-nm periodic labeling on extracellular filaments and fibrils: one monoclonal antibody (3C4) attached to the band region and another (4B10) to the interband region of the filaments and fibrils. Rabbit antiserum to type VI collagen also localized on the band region, but the staining was less well defined. Control experiments with antibodies to fibronectin and to procollagen types I and III labeled other filaments and fibrils, but not those with a 100-nm period. Heavy metal-stained fibrils with the same periodic and structural characteristics also have been found in both adult rat tail tendon and embryonic chicken tendon subjected to prolonged incubation in culture medium or treatment with adenosine 5'-triphosphate at pH 4.6. We conclude that the 100-nm periodic filaments and fibrils represent the native aggregate form of type VI collagen. It is likely that banded fibrils of the same periodicity and appearance, reported by many observers over the years in a wide range of normal and pathological tissues, are at least in part, type VI collagen.

Ultrastructural organization of the glomerular basement membrane as revealed by a deep-etch replica method

The fine structure of the glomerular basement membrane was re-evaluated by using a deep-etch replica method. The structure of the laminae rarae interna and externa of the rat glomerular basement membrane was basically identical in that 6 to 8 nm fibrils were interconnected to form a three-dimensional, polygonal network. The size of the mesh was quite variable but most often ranged from 20 to 25 nm in width. In addition, a zipper-like substructure of the epithelial slit diaphragm was observed. By contrast, the lamina densa was composed of closely packed particles. After exposure of the bovine glomerular basement membrane to ultrasonic waves or trypsin, the particles of the lamina densa were effectively removed. The underlying structure showed the fibrillar network closely resembled that seen in the laminae rarae of the rat glomerular basement membrane. The glomerular basement membrane thus revealed was as principally composed of a fibrillar network, which might be regularly arranged units of type-IV collagen. Numerous fine particles, most likely proper components of the glomerular basement membrane, were attached onto this basic fibrillar structure, giving rise to a morphologic appearance different from that of the laminae rarae.

Evidence for collagen molecular orientation in basement membranes

The following basement membranes (BMs) from representative species of the main vertebrate classes were studied by the Picrosirius-polarization method: lens capsule, Reichert's membrane and glomerular BMs. A distinct birefringence was consistently observed in all BMs from all species studied by this method. The results reported provide a strong evidence for collagen macromolecular orientation in BMs. Heparitin sulphate was the only glycosaminoglycan detected in dogs lens capsules.

A topographical (SEM) analysis of acellular glomerular mesangial matrix in situ

Normal kidneys from human and New Zealand white rabbits were made acellular by vascular perfusion with detergents. Cortical regions were dissociated from the central renal mass and further minced to 2 mm3 and fixed for TEM and SEM analyses. In an effort to visualize the internal histoarchitecture of glomerular basement membranes (GBM) and associated mesangial matrix (MM), some of the fixed samples were cryofractured prior to preparation for SEM observations. By this technique, the in situ MM exhibits a lacy network of fenestrated plates (septa) that separate and support peripheral glomerular channels. It seems possible that these structures may be intrinsically rigid and that their shape-preserving properties may be transmitted to the entire GBM. The matrix is not restricted to centrolobular zones, but extends throughout the glomerulus via a loose inner (endothelial-mesangial) layer of GBM. This filamentous layer is similar to MM in texture and surface characteristics and is often thrown into folds or trabeculae. In contrast, the outer (epithelial) surface of GBMs is more compact and smoothly contoured. Our SEM and correlative TEM studies indicate that the inner layer is continuous with MM septa distally and extends proximally to the glomerular vascular pole via arteriolar BMs where it reaches the extraglomerular interstitium. This establishes an extracellular morphological pathway from centrolobular zones to the polar cushion.

The water permeability of basement membrane under increasing pressure: evidence for a new theory of permeability

The water permeability and physical characteristics of the basement membrane (lens capsule) of the crystalline lens of the adult rat have been investigated. The hydraulic conductivity of the basement membrane at low pressure is 50 +/- 9.5 X 10(-12) m s-1 Pa-1 and at high pressure 17 +/- 7.5 X 10(-12) m s-1 Pa-1. This decrease in permeability occurs despite a 75% increase in area of the membrane and a 65% reduction in its thickness. Conventional theories of a membrane possessing pores or of a fibre matrix of filaments of a constant diameter fail to explain the decreasing permeability of the membrane with increasing hydrostatic pressure. The present data suggest that the structure of the membrane is changed by pressure and the coiled filaments of which it is composed are extended as stress is applied to the membrane. If allowance is made both for thinning and for compaction of the membrane and the extension of its area the permeability of the membrane can be predicted satisfactorily at varying pressures. Thus the hydraulic conductivity of basement membrane at a given pressure can be adequately described by the product of a constant and a dimensionless 'deformation coefficient'. This deformation coefficient is equal to the square of the product of the thickness ratio and elongation ratio of the membrane at the given filtration pressure.