Efficient uptake and retention of iron oxide-based nanoparticles in HeLa cells leads to an effective intracellular delivery of doxorubicin.

The purpose of this study was to construct and characterize iron oxide nanoparticles (IONPCO) for intracellular delivery of the anthracycline doxorubicin (DOX; IONPDOX) in order to induce tumor cell inactivation. More than 80% of the loaded drug was released from IONPDOX within 24 h (100% at 70 h). Efficient internalization of IONPDOX and IONPCO in HeLa cells occurred through pino- and endocytosis, with both IONP accumulating in a perinuclear pattern. IONPCO were biocompatible with maximum 27.9% ± 6.1% reduction in proliferation 96 h after treatment with up to 200 µg/mL IONPCO. Treatment with IONPDOX resulted in a concentration- and time-dependent decrease in cell proliferation (IC50 = 27.5 ± 12.0 µg/mL after 96 h) and a reduced clonogenic survival (surviving fraction, SF = 0.56 ± 0.14; versus IONPCO (SF = 1.07 ± 0.38)). Both IONP constructs were efficiently internalized and retained in the cells, and IONPDOX efficiently delivered DOX resulting in increased cell death vs IONPCO.

Podocyte injury underlies the progression of focal segmental glomerulosclerosis in the fa/fa Zucker rat.

BACKGROUND: The progression of diabetic nephropathy to chronic renal failure is based on the progressive loss of viable nephrons. The manner in which nephrons degenerate in diabetic nephropathy and whether the injury could be transferred from nephron to nephron are insufficiently understood. We studied nephron degeneration in the fa/fa Zucker rat, which is considered to be a model for non-insulin-dependent diabetes mellitus. METHODS: Kidneys of fa/fa rats with an established decline of renal function and of fa/+ controls were structurally analyzed by advanced morphological techniques, including serial sectioning, high-resolution light microscopy, transmission electron microscopy, cytochemistry, and immunohistochemistry. In addition, tracer studies with ferritin were performed. RESULTS: The degenerative process started in the glomerulus with damage to podocytes, including foot process effacement, pseudocyst formation, and cytoplasmic accumulation of lysosomal granules and lipid droplets. The degeneration of the nephron followed the tuft adhesion-mediated pathway with misdirected filtration from capillaries included in the adhesion toward the interstitium. This was followed by the formation of paraglomerular spaces that extended around the entire glomerulus, as well as via the glomerulotubular junction, to the corresponding tubulointerstitium. This mechanism appeared to play a major role in the progression of the segmental glomerular injury to global sclerosis as well as to the degeneration of the corresponding tubule. CONCLUSIONS: The way a nephron undergoes degeneration in this process assures that the destructive effects remain confined to the initially affected nephron. No evidence for a transfer of the disease from nephron to nephron at the level of the tubulointerstitium was found. Thus, each nephron entering this pathway to degeneration appears to start separately with the same initial injuries at the glomerulus.

How does podocyte damage result in tubular damage?

Severe podocyte damage including detachment from the GBM leads to adhesion of the glomerular tuft to Bowman's capsule, thus to a local loss of the separation of the tuft from the interstitium. Perfused capillaries contained in the tuft adhesion deliver their filtrate no longer into Bowman's space but into the interstitium. In response, interstitial fibroblasts create a cellular cover around the focus of misdirected filtration, interpreted teleologically, aiming at preventing the entry of this fluid into the interstitium. This results in the formation of a crescent-shaped, fluid-filled paraglomerular space overarching the segmental glomerular lesion. Extension of this space over the entire glomerulus leads to global sclerosis; extension of this space via the urinary pole onto the outer aspect of the corresponding tubule leads to the degeneration of the tubule. Since, as we postulate, such misdirected filtration and filtrate spreading is the crucial mechanism of damage progression in 'classic' focal segmental glomerulosclerosis (FSGS), the most characteristic structural injury of FSGS is the merger of the tuft with the interstitium, represented by a tuft adhesion, later a synechia. Therefore, histopathologically, 'classic' FSGS is best defined by an adhesion/synechia of the tuft to Bowman's capsule.

From segmental glomerulosclerosis to total nephron degeneration and interstitial fibrosis: a histopathological study in rat models and human glomerulopathies.

BACKGROUND: Focal segmental glomerulosclerosis (FSGS) is consistently associated with tubular degeneration and interstitial fibrosis, altogether, accounting for the progressive decline in renal function. The mechanisms which link glomerular injury to tubulo-interstitial fibrosis are controversial. The present study describes the step-by-step sequence of histopathological events, i.e. the evolution of the injury from the initial lesion in the glomerulus to total nephron destruction. METHODS: The investigation was performed in male hypertensive Fawn-hooded rats (6-, 9-, and 12-month-old) and 14-month-old Milan normotensive rats. The kidneys were fixed by in vivo perfusion and processed for structural investigation. Autopsy materials from human cases of focal segmental glomerulosclerosis and diabetic nephropathy were also examined. RESULTS: FSGS as seen in rat models consists of collapsed and hyalinized capillaries and mesangial portions which are included within a synechia between the glomerular tuft and Bowman's capsule. In addition, a synechia generally contains glomerular capillaries which are perfused and continue to filter with the filtrate being delivered into the interstitium rather than into Bowman's capsular space. Such filtration creates a paraglomerular space on the outer aspect of the parietal epithelium. This space becomes separated from the interstitium by a dense layer of sheet-like fibroblast processes. Associated with the progression to global sclerosis, this space spreads around the entire circumference of a glomerulus; all 'sclerotic' tuft portions are eventually contained in this space. Starting from the urinary pole this process also involves the proximal tubule, initially by expanding the tubular basement membrane (TBM) and later, by separating the TBM from its epithelium, thus creating a peritubular space by misdirected filtrate spreading. Similar to the situation observed at the glomerulus this space becomes separated from the interstitium by a layer of fibroblast processes. The final degeneration of the nephron occurs via two pathways. Pathway I whereby development to global sclerosis is dominant or develops concurrently with tubular degeneration, eventually terminating in global and cylindrical remnants of extracellular matrix surrounded by abundant fibrous tissue. Pathway II where the degeneration of the tubule is ahead of damage progression in the glomerulus leading to atubular glomerular cysts. CONCLUSION: The present study suggests that severely injured glomeruli may continue to filter with the filtrate spreading along interstitial routes. Fluid added locally to the interstitium from such 'extraterritorial' glomerular capillaries probably is quite different in quantity and composition compared to that from interstitial capillaries. We propose that this kind of abnormal addition of fluid to the interstitium is the essential mechanism accounting for interstitial progression of the disease. Similar histopathological phenomena in human kidneys with focal segmental glomerulosclerosis suggest that the pathogenetic pathways defined in the rat models operate in human disease as well.

Characterizing titin's I-band Ig domain region as an entropic spring.

The poly-immunoglobulin domain region of titin, located within the elastic section of this giant muscle protein, determines the extensibility of relaxed myofibrils mainly at shorter physiological lengths. To elucidate this region's contribution to titin elasticity, we measured the elastic properties of the N-terminal I-band Ig region by using immunofluorescence/immunoelectron microscopy and myofibril mechanics and tried to simulate the results with a model of entropic polymer elasticity. Rat psoas myofibrils were stained with titin-specific antibodies flanking the Ig region at the N terminus and C terminus, respectively, to record the extension behaviour of that titin segment. The segment's end-to-end length increased mainly at small stretch, reaching approximately 90% of the native contour length of the Ig region at a sarcomere length of 2.8 microm. At this extension, the average force per single titin molecule, deduced from the steady-state passive length-tension relation of myofibrils, was approximately 5 or 2.5 pN, depending on whether we assumed a number of 3 or 6 titins per half thick filament. When the force-extension curve constructed for the Ig region was simulated by the wormlike chain model, best fits were obtained for a persistence length, a measure of the chain's bending rigidity, of 21 or 42 nm (for 3 or 6 titins/half thick filament), which correctly reproduced the curve for sarcomere lengths up to 3.4 microm. Systematic deviations between data and fits above that length indicated that forces of >30 pN per titin strand may induce unfolding of Ig modules. We conclude that stretches of at least 5-6 Ig domains, perhaps coinciding with known super repeat patterns of these titin modules in the I-band, may represent the unitary lengths of the wormlike chain. The poly-Ig regions might thus act as compliant entropic springs that determine the minute levels of passive tension at low extensions of a muscle fiber.

Development of vascular pole-associated glomerulosclerosis in the Fawn-hooded rat.

Fawn-hooded hypertensive (FHH) rats constitute a spontaneous model of chronic renal failure with early systemic and glomerular hypertension, proteinuria, and development of focal and segmental glomerulosclerosis. The goal of the present study was to elucidate a step-by-step sequence of histopathologic events leading from an initial glomerular injury to segmental sclerosis. Segmental sclerosis in the FHH rat is consistently associated with the glomerular vascular pole. The initial injury involves the expansion of primary branches of the afferent arteriole. Apposition of those capillaries to Bowman's capsule, together with the degeneration and detachment of corresponding podocytes, allows parietal cells to attach to the naked glomerular basement membrane of this capillary, i.e., allows the formation of a tuft adhesion to Bowman's capsule. The adhesion enlarges to a broad synechia by encroaching to neighboring capillaries, apparently based on progressive podocyte degeneration at the flanks of the adhesion. Capillaries inside the adhesion--before undergoing collapse or hyalinization--appear to stay perfused for some time and to maintain some kind of filtration misdirected toward the cortical interstitium. Thereby, a prominent paraglomerular space comes into existence, enlarging in parallel with the adhesion. Toward the cortical interstitium this space is delimited by a layer of sheetlike fibroblast processes, which has obviously been assembled in response to the formation of this space. Toward the urinary space, the paraglomerular space is demarcated by the parietal epithelium and by the interface between the adhesion and the "intact" tuft remnant. Thus, the sclerotic tuft portions all become enclosed within the paraglomerular space.

The development of focal segmental glomerulosclerosis in masugi nephritis is based on progressive podocyte damage.

We analysed the sequence of structural changes leading to focal segmental glomerulosclerosis (FSGS) in chronic Masugi nephritis. The protocol resulted in an immediate onset of the disease and the development of segmental sclerosis in a considerable proportion of glomeruli within 28 days of serum injection. Throughout the study, the degree of structural damage was significantly correlated with protein excretion. Even 1 day after injection of the serum, the whole spectrum of early lesions was encountered involving all three cell types. Endothelial detachments, mesangiolysis and podocyte foot process effacement were most prominent. There was focal persistence of capillary microthrombosis but, generally, mesangial and endothelial injuries recovered. The development of podocyte lesions was different: on one hand recovery was seen leading to the re-establishment of an interdigitating foot process pattern, and on the other persistent podocyte detachments from peripheral capillaries allowed the attachment of parietal epithelial cells to "naked" portions of the glomerular basement membrane (GBM), and thus to the formation of a tuft adhesion to Bowman's capsule. Progressive podocyte degeneration at the flanks of an adhesion permitted expansion of the adhesion by encroachment of parietal cells onto the tuft along the denuded GBM. Inside an adhesion, capillaries and mesangial areas either collapse or become obstructed by hyalinosis or thrombosis. Resident cells disappear progressively from inside an adhesion; macrophages may invade. Segmental sclerosis in this model consists of collapsed tuft structures adhering broadly to the cortical interstitium. Proliferation of mesangial cells did not contribute to this development. Recovery of endothelial and mesangial lesions was associated with cell proliferation in early stages of the disease; podocyte proliferation was not encountered at any stage. We conclude that the inability to replace an outmatched podocyte crucially underlies the development of sclerosis. Severe podocyte damage cannot be repaired but leads to tuft adhesions to Bowman's capsule followed by progressive collapse of tuft structures inside an adhesion, resulting in segmental glomerulosclerosis.

Heterogeneity of the podocyte membrane in rat kidney as revealed by ethanol dehydration of unosmicated specimens.

The ultrastructure of the podocyte membrane was studied by means of transmission electron microscopy of unosmicated tissue samples after acetone or ethanol dehydration and subsequent embedding in a polyester resin. The podocyte membrane in glutaraldehyde (GA)-fixed, acetone-dehydrated samples consisted of a relatively thick, clear layer (about 6 nm) abutted by the dark staining cytoplasm and a dark surface layer. In GA-fixed, ethanol-dehydrated samples a striking intramembranous pattern was observed in the podocyte cell membrane. The luminal podocyte membrane was regularly perforated by gaps about 25 nm wide. In grazing sections these gaps appeared round and were separated by a honeycomb pattern of intact membrane. The abluminal membrane, in contrast, generally maintained its continuity. The clear layer of the podocyte membrane was thinner in ethanol-dehydrated samples than in acetone-dehydrated ones. In tissue samples fixed with GA supplemented by ruthenium red, ethanol dehydration was not associated with cell-membrane perforations. Based on these observations as well as on biochemical data from the literature we suggest that in GA-fixed, unosmicated, acetone-dehydrated samples the structural integrity of the podocyte membrane is well preserved, while ethanol dehydration extracts some specific material from regularly distributed domains in the podocyte cell membrane.