Contractile proteins in podocytes: immunocytochemical localization of actin and alpha-actinin in normal and nephrotic rat kidneys

Actin and alpha-actinin immunoreactive sites have been localized at the electron microscope level by the protein A-gold immunocytochemical technique in podocytes of normal and nephrotic rat renal tissues. In normal renal glomeruli, fibrillar networks located in the core of foot processes or bundles of micro filaments interconnecting them were found to be labelled for these two cytoskeletal proteins. On the other hand, in nephrotic renal glomeruli, concomitant with the loss of podocytic foot processes a reorganization of the podocytic cytoskeleton and a concentration of some of its elements into thick uniform bands was observed. Actin and alpha-actinin were revealed in these bands. Control experiments confirmed the specificity of the labelling obtained. Our results suggest that normal podocytes contain an actin-based contractile system that might contribute to the maintenance of the particular cell shape of these cells and that the rearrangement of the podocytic cyto-skeleton occurring in the nephrotic syndrome might account for the changes in the foot processes and contribute to the alteration in glomerular function. This work was supported by grants from the Medical Research Council of Canada     

Actin up: regulation of podocyte structure and function by components of the actin cytoskeleton

Podocytes of the renal glomerulus are unique cells with a complex cellular organization consisting of a cell body, major processes and foot processes. Podocyte foot processes form a characteristic interdigitating pattern with foot processes of neighboring podocytes, leaving in between the filtration slits that are bridged by the glomerular slit diaphragm. The highly dynamic foot processes contain an actin-based contractile apparatus comparable to that of smooth muscle cells or pericytes. Mutations affecting several podocyte proteins lead to rearrangement of the actin cytoskeleton, disruption of the filtration barrier and subsequent renal disease. The fact that the dynamic regulation of the podocyte cytoskeleton is vital to kidney function has led to podocytes emerging as an excellent model system for studying actin cytoskeleton dynamics in a physiological context.     

Immunocytochemistry of cytoskeletal proteins in adult Schistosoma mansoni

Antisera to vertebrate actin and actin-binding proteins were used to characterize the cytoskeleton of adult Schistosoma mansoni. Actin, alpha-actinin and tropomyosin immunoreactivities were detected in the cytoplasm of the apical tegument. Antiserum to alpha-actinin bound to the tegumental spines and this protein may be involved in cross-linking of spine actin filaments. Actin, alpha-actinin and tropomyosin antisera bound to the musculature. Strongest immunoreactivity was seen in the parenchyma. Antisera to actin, alpha-actinin, tropomyosin and spectrin bound to parenchyma cells including those of the tubercles, suggesting that these proteins are located in muscle cell bodies. The distribution of cytoskeletal proteins is discussed in relation to tegumental repair processes.     

Actin filament organization of foot processes in rat podocytes.

The foot processes of podocytes possess abundant microfilaments and modulate glomerular filtration. We investigated the actin filament organization of foot processes in adult rat podocytes and the formation of the actin cytoskeletal system of immature podocytes during glomerulogenesis. Electron microscopy revealed two populations of actin cytoskeletons in foot processes of adult podocytes. One is the actin bundle running above the level of slit diaphragms and the other is the cortical actin network located beneath the plasmalemma. Immunogold labeling for actin-binding proteins demonstrated that alpha-actinin and synaptopodin were localized in the actin bundle, whereas cortactin was in the cortical actin network. Immunofluorescence labeling for actin-binding proteins in immature podocyte showed that alpha-actinin was localized at the level of the junctional complex, whereas cortactin was distributed beneath the entire plasmalemma. Synaptopodin was first observed along the basal plasmalemma from the advanced S-shaped body to the capillary loop stage. We conclude that foot processes have specialized actin filamentous organization and that its establishment is associated with the expression and redistribution of actin-binding proteins during development.     

Morphological changes in the rat kidney following long-term diabetes

The morphological basis of diabetic nephropathy has been studied using light and electron microscopy. Kidneys of streptozotocin-induced diabetic rats were examined on the light microscope at 4 weeks and 8 months after induction of diabetes mellitus. In addition, the 8-month diabetic kidneys were examined with the electron microscope. Renal hypertrophy was evidenced by the increase in the weight of kidneys of diabetic rats. Whilst the diabetic kidneys were approximately twice as large after 4 weeks they were only 30% larger compared to age-matched controls after 8 months of induction of diabetes. After 4 weeks, light microscopy revealed dilated tubules within the cortex of the diabetic kidneys. Light microscopy showed a significant amount of destruction of the distal convoluted tubules while electron microscopy revealed a spectrum of damage that included basement membrane thickening, loss of podocytic foot processes, disruption of tubular basal infoldings and their related mitochondria and fibrosis of the tubules 8 months after induction of diabetes. It is concluded that renal hypertrophy persists after a prolonged occurrence of diabetes but the extensive damage and loss of renal tissue including the loss of the foot processes of podocytes might be partly responsible for the clinical presentation of diabetic nephropathy.     

Actin filament organization of foot processes in vertebrate glomerular podocytes

We investigated the actin filament organization and immunolocalization of actin-binding proteins (α-actinin and cortactin) in the podocyte foot processes of eight vertebrate species (lamprey, carp, newt, frog, gecko, turtle, quail, and rat). Three types of actin cytoskeleton were found in these foot processes. (1) A cortical actin network with cortactin filling the space between the plasma membrane and the other actin cytoskeletons described below was found in all of the species examined here. The data indicated that the cortical actin network was the minimal essential actin cytoskeleton for the formation and maintenance of the foot processes in vertebrate podocytes. (2) An actin bundle with α-actinin existing along the longitudinal axis of foot process above the level of slit diaphragms was only observed in quail and rat. (3) An actin fascicle consisting of much fewer numbers of actin filaments than that of the actin bundle was observed in the species other than quail and rat, but at various frequencies. These findings suggest that the actin bundle is an additional actin cytoskeleton reflecting a functional state peculiar to quail and rat glomeruli. Considering the higher intraglomerular pressure and the extremely thin filtration barrier in birds and mammals, the foot processes probably mainly protect the thinner filtration barrier from the higher internal pressure occurring in quail and rat glomeruli. Therefore, we consider that the actin bundle plays a crucial role in the mechanical protection of the filtration barrier. Moreover, the actin fascicle may be a potential precursor of the actin bundle.     

Novel expression of claudin-5 in glomerular podocytes

Tight junctions are the main intercellular junctions of podocytes of the renal glomerulus under nephrotic conditions. Their requisite components, claudins, still remain to be identified. We have measured the mRNA levels of claudin subtypes by quantitative real-time PCR using isolated rat glomeruli. Claudin-5 was found to be expressed most abundantly in glomeruli. Mass spectrometric analysis of membrane preparation from isolated glomeruli also confirmed only claudin-5 expression without any detection of other claudin subtypes. In situ hybridization and immunolocalization studies revealed that claudin-5 was localized mainly in glomeruli where podocytes were the only cells expressing claudin-5. Claudin-5 protein was observed on the entire surface of podocytes including apical and basal domains of the plasma membrane in the normal condition and was inclined to be concentrated on tight junctions in puromycin aminonucleoside nephrosis. Total protein levels of claudin-5 in isolated glomeruli were not significantly upregulated in the nephrosis. These findings suggest that claudin-5 is a main claudin expressed in podocytes and that the formation of tight junctions in the nephrosis may be due to local recruitment of claudin-5 rather than due to total upregulation of the claudin protein levels.     

Actin-associated Proteins in the Pathogenesis of Podocyte Injury

Podocytes have a complex cellular architecture with interdigitating processes maintained by a precise organization of actin filaments. The actin-based foot processes of podocytes and the interposed slit diaphragm form the final barrier to proteinuria. The function of podocytes is largely based on the maintenance of the normal foot process structure with actin cytoskeleton. Cytoskeletal dynamics play important roles during normal podocyte development, in maintenance of the healthy glomerular filtration barrier, and in the pathogenesis of glomerular diseases. In this review, we focused on recent findings on the mechanisms of organization and reorganization of these actin-related molecules in the pathogenesis of podocyte injury and potential therapeutics targeting the regulation of actin cytoskeleton in podocytopathies.     

Podocytes in metanephric organ culture express characteristic in vivo phenotypes

 Podocytes outgrown from isolated glomeruli in vitro have failed to express fully differentiated in vivo phenotypes. In an attempt to determine whether podocytes in metanephric culture accomplish terminal differentiation, as observed in vivo, we investigated expression of their characteristic phenotypic features in rat metanephric organ cultures using immunohistochemistry and electron microscopy. Rat metanephroi were harvested on embryonic day 12.5 and cultured on transmembrane filters for 9 days. Morphological examination revealed two maturation stages when the podocytes resembled those of the S-shaped body stage and maturational stages of glomeruli in vivo. Electron microscopy revealed that, firstly podocytes lost their intercellular contacts and, simultaneously, the tight junctions shifted into close proximity to cell bases, followed by foot process development. Immunohistochemistry demonstrated that the tight junction protein, ZO-1, and specific podocytic markers, pp44, 5-1–6, podocalyxin and vimentin were expressed in a cell maturity-dependent manner, as observed in newborn rat kidneys. Furthermore, glomerular basement membrane components, collagen type IV and laminin, were expressed in the glomerular center. Our findings that cell maturity-dependent expression of structural and functional phenotypes in podocytes in metanephric culture was the same as that observed in developing kidneys in vivo indicate that podocyte differentiation during glomerulogenesis may be operated by an intrinsic property, such as programmed cell fate. Furthermore, these highly differentiated podocytes in vitro may provide clues that will help to establish a podocyte culture system. Accepted: 26 February 1997     

Podocytes in glomerulus of rat kidney express a characteristic 44 KD protein

We describe a new monoclonal antibody (MAb) directed against glomerular visceral epithelial cells (podocytes), generated by immunization with isolated rat kidney glomeruli. In immunoblotting experiments this MAb (IgG1 subclass) reacted with a 44 KD protein. In cryostat sections of normal rat kidney the MAb stained glomerular podocytes; therefore, we called the antigen pp44 (podocyte protein 44 KD). On 0.5-micron cryostat sections the signal could be more precisely ascribed to the podocyte foot processes, whereas the cell bodies appeared virtually unreactive. On ultra-thin frozen sections pp44 was found within the cytoplasm of podocyte foot processes at their origin from their parent processes. The podocyte cell membrane was not labeled. All other parts of the nephron were unreactive. An additional but weaker immunoreaction was found in the arterial endothelium; the endothelia of other vessels (peritubular capillaries, veins) were negative. In human kidney anti-pp44 revealed the same staining pattern as in rat kidney. The expression of pp44 was also studied in newborn rat kidney. The early stages of glomerular development (renal vesicle, S-shaped body) were negative. pp44 first appeared during the capillary loop stage, i.e., when formation of podocyte foot processes commences. In comparing the present results with published data, pp44 is clearly different from other antigens thus far described in podocytes. From the results of this investigation we conclude that pp44 represents a novel cytoplasmic protein of podocytes. Our data suggest a cytoskeletal role for pp44 in preserving the complex architecture of podocytes. This idea is confirmed by the simultaneous appearance of foot processes and anti-pp44 immunoreactivity during glomerular development.     

Stretch, tension and adhesion - adaptive mechanisms of the actin cytoskeleton in podocytes

Podocytes form an epithelial layer on the outer aspect of the basement membrane of glomerular capillaries. The interdigitating pattern of podocyte foot processes (PFPs) generates a unique and extremely long cell-cell contact area - the filtration slit. Thus, the interdigitating PFPs are the morphological basis for the high hydraulic conductivity of the glomerular capillaries. Any disturbance in this interdigitating pattern results in a drop of glomerular filtration rate impairing renal function. PFPs are based on the actin cytoskeleton, consisting of a subplasmalemmal network and a central core of filament bundles. Besides giving PFPs their morphology, the actin cytoskeleton anchors cell-cell contact and cell-matrix proteins in podocytes. Several human genetic diseases as well as transgenic mouse models provide evidence for the crucial role of the actin cytoskeleton in podocytes. Varying flow rates of the filtrate, increased glomerular capillary pressure in glomerular hypertension, and varying activation states of contractile proteins in PFPs impose a mechanical load on the actin cytoskeleton, challenging the intricate arrangement of PFPs and podocyte adhesion. Here we review data about the actin cytoskeleton of podocytes and the response of podocytes to mechanical load. From these data possible mechanisms are emerging how the actin cytoskeleton may allow podocytes to adapt to states of increased mechanical load.     

Requirement for class II phosphoinositide 3-kinase C2alpha in maintenance of glomerular structure and function

An early lesion in many kidney diseases is damage to podocytes, which are critical components of the glomerular filtration barrier. A number of proteins are essential for podocyte filtration function, but the signaling events contributing to development of nephrotic syndrome are not well defined. Here we show that class II phosphoinositide 3-kinase C2α (PI3KC2α) is expressed in podocytes and plays a critical role in maintaining normal renal homeostasis. PI3KC2α-deficient mice developed chronic renal failure and exhibited a range of kidney lesions, including glomerular crescent formation and renal tubule defects in early disease, which progressed to diffuse mesangial sclerosis, with reduced podocytes, widespread effacement of foot processes, and modest proteinuria. These findings were associated with altered expression of nephrin, synaptopodin, WT-1, and desmin, indicating that PI3KC2α deficiency specifically impacts podocyte morphology and function. Deposition of glomerular IgA was observed in knockout mice; importantly, however, the development of severe glomerulonephropathy preceded IgA production, indicating that nephropathy was not directly IgA mediated. PI3KC2α deficiency did not affect immune responses, and bone marrow transplantation studies also indicated that the glomerulonephropathy was not the direct consequence of an immune-mediated disease. Thus, PI3KC2α is critical for maintenance of normal glomerular structure and function by supporting normal podocyte function.     

C3aR过度活化与糖尿病肾病肾组织损伤的关系

C3aR是补体C3裂解产物C3a的受体.最近的一些研究提示C3aR通路可能参与了糖尿病肾病(DN)的病理过程,但有关C3aR通路在DN中的确切病理作用及有关机制远未清楚.需要特别指出的是,现有的有关C3aR参与DN肾组织损伤的证据主要来自一些动物模型的研究,临床上尚缺乏较为系统全面的对DN患者肾组织C3aR通路与肾组织损伤关系的观察分析.为此,本文首次以较大的样本量分析了不同病理时期DN患者肾组织C3aR和C3a的表达变化情况及其与DN患者肾组织损伤的相关性.在此基础上,进而利用体外细胞模型,对高糖环境下C3aR活化致肾小球足细胞损伤的作用及机制进行了探讨.结果显示:a.与正常对照组相比,DN患者肾组织C3a和C3aR的表达水平随DN的进展而升高,C3aR在DN患者肾组织中的表达上调主要见于肾小管上皮细胞和肾小球足细胞;b.DN患者肾组织C3aR和C3a水平与患者肾组织损伤程度,特别是小管和小管间质损伤程度、肾小球足细胞损伤程度具有显著相关性;c.外加C3a激活C3aR可使高糖环境中的足细胞的细胞骨架发生明显改变、足细胞标记分子表达下调、足细胞通透性增加.这些结果说明:a.DN患者肾组织中确实存在C3a/C3aR轴过度活化的现象;b.C3a/C3aR轴的过度活化很可能在DN患者肾组织损伤,特别是小管和小管间质损伤、肾小球足细胞损伤中具有重要作用;c.可能通过破坏成熟足细胞特有的细胞骨架,改变足细胞标记分子表达,增加足细胞的通透性,C3a/C3aR轴过度活化参与DN足细胞损伤过程.本文不仅为C3a/C3aR通路参与DN病理过程提供了新的必不可少的临床证据,也增加了对C3a/C3aR通路过度活化致DN患者肾组织损伤机制,特别是肾小球足细胞损伤机制的了解,这对于拓展对DN病理机制的认识,发展DN防治新思路,无疑都是有益的.     

The Structure of Anuran Podocyte—Determined by Ecology?

Abstract The podocytes of ten frog species with different habitat preference were investigated by scanning electron microscopy. The visceral epithelium within these species shows considerable variation in the branching mode of the cellular processes, in the number of pedicels and in the form of cell bodies. The presence of various podocyte cell forms within anurans of one family (e.g. within Ranidae and Discoglossidae) indicates that podocytic structure is not manifested phylogenetically. The complexity of processes and pedicel numbers are high in glomeruli of terrestrial and semiterrestrial frogs but low in aquatic and semiaquatic animals. Consequently, podocyte structure is (a) correlated with environmental conditions and (b) plays an important role in osmoregulation. Furthermore, since podocytes are suggested to serve as stabilizers of glomerular vessels, the cells of the visceral epithelium provide the structural basis for regulation of glomerular filtration rate, e.g. for glomerular intermittency.     

Cytoskeleton of podocytes in vertebrate animals and human.

Using TEM and immunofluorescence microscope, a study was made on podocytes in vertebrates where an intermediate-sized filament system is replaced by a microtubule system, accompanied by highly developed microfilaments structures. A comparative immunofluorescence study was carried out on cryotome renal sections of plaice (Pleuronectes platessa L.) and rats, using specific antibodies anti-cytokeratins and anti-vimentin. With polyclonal anti-vimentin serum the capillaries of the renal glomeruli showed a bright colour of plaice and only a week one in the rats. Double staining of renal tissue of mongrel rats of different ages (6-7 weeks and 1.8 years old) with antibodies for actin and anti-vimentin polyclonal serum revealed in young rats an intensive fluorescence for actin and a slight fluorescence for the intermediate filaments. Renal glomeruli of old rats demonstrate a strong vimentin-activity and lower actin one. The ultrastructural study of human podocytes showed two different cytoskeleton age-depending types (2, 4, 6, 37 and 65 years old). It is suggested that during individual development and ageing in kidneys of higher animals and human, physiological changes induce morphological cytoskeleton restructuration accompanied by intensive development of intermediate filaments and simultaneous "involution" of microtubules and microfilaments.     

Localization of receptors for atrial natriuretic polypeptide (ANP) in the glomerulus: in vitro electron microscopic autoradiographical investigation using 125I-labeled ANP

The localization of receptors for atrial natriuretic polypeptide (ANP) in the glomerulus of the rat was studied by electron microscopic autoradiography using 125I-labeled ANP. A total of 1,134 silver grains counted in 30 glomeruli were distributed as follows: processes of the podocytes (36.4%), cell bodies of the podocytes (14.8%), basement membrane (12.3%), endothelial cells (6.3%), mesangial cells (7.7%) and others, for example the vascular spaces (22.5%). This finding indicates that ANP binding sites are mainly localized on the foot processes of the podocytes in the glomerulus.     

Transmembrane collagen XVII is a novel component of the glomerular filtration barrier

The kidney filtration barrier consists of the capillary endothelium, the glomerular basement membrane and the slit diaphragm localized between foot processes of neighbouring podocytes. We report that collagen XVII, a transmembrane molecule known to be required for epithelial adhesion, is expressed in podocytes of normal human and mouse kidneys and in endothelial cells of the glomerular filtration barrier. Immunoelectron microscopy has revealed that collagen XVII is localized in foot processes of podocytes and in the glomerular basement membrane. Its role in kidney has been analysed in knockout mice, which survive to birth but have high neonatal mortality and skin blistering and structural abnormalities in their glomeruli. Morphometric analysis has shown increases in glomerular volume fraction and surface densities of knockout kidneys, indicating an increased glomerular amount in the cortex. Collagen XVII deficiency causes effacement of podocyte foot processes; however, major slit diaphragm disruptions have not been detected. The glomerular basement membrane is split in areas in which glomerular and endothelial basement membranes meet. Differences in the expression of collagen IV, integrins α3 or β1, laminin α5 and nephrin have not been observed in mutant mice compared with controls. We propose that collagen XVII has a function in the attachment of podocyte foot processes to the glomerular basement membrane. It probably contributes to podocyte maturation and might have a role in glomerular filtration.