Your search keyword '"Kreft,Mateja Erdani"' showing total 8 results

1. Astrocytes in stress accumulate lipid droplets.

Author

Smolič, Tina, Tavčar, Petra, Horvat, Anemari, Černe, Urška, Halužan Vasle, Ana, Tratnjek, Larisa, Kreft, Mateja Erdani, Scholz, Nicole, Matis, Maja, Petan, Toni, Zorec, Robert, and Vardjan, Nina

Published

2021

2. Co‐culturing porcine normal urothelial cells, urinary bladder fibroblasts and smooth muscle cells for tissue engineering research.

Author

Zupančič, Daša, Mrak Poljšak, Katjuša, and Kreft, Mateja Erdani

Subjects

TRANSITIONAL cell carcinoma, BLADDER diseases, MESENCHYMAL stem cells, MULTIPOTENT stem cells, CELL differentiation

Abstract

Abstract: New strategies for culturing and co‐culturing of the main types of urinary bladder cells are essential for successful establishment of biomimetic in vitro models, which could be applied for research into, and management of, diverse urological disorders. Porcine normal urothelial cells are available in nearly unlimited amounts and have many properties equivalent to human urothelial cells. In the present study, we established normal differentiated porcine urothelial cells in co‐cultures with porcine urinary bladder normal fibroblasts and/or smooth muscle cells. The optimal culture medium for establishment of differentiated urothelial cells, demonstrated by positive immunofluorescence of uroplakins, cytokeratins (CK 7, CK 20), zonula occludens 1 (ZO‐1), claudin 4, claudin 8, and E‐cadherin, was the medium composed of equal parts of Advanced Dulbecco's modified Eagle's medium (A‐DMEM) and MCDB 153 medium with physiological calcium concentration of 2.5 mM and without fetal bovine serum, named UroM (+Ca2+ − S). This medium was also proven to be suitable for culturing of bladder fibroblasts and smooth muscle cells and co‐culturing of urothelial cells with these mesenchymal cells. Urothelial cell differentiation was optimal in UroM (+Ca2+ − S) medium in all co‐culture conditions and when compared to all conditioned‐media combinations. To summarize, these strategies for culturing and co‐culturing of urinary bladder urothelial cells with mesenchymal cells could be used as new in vitro models for future basic and applicable research of the urinary bladder and thus potentially also for translational tissue engineering studies. [ABSTRACT FROM AUTHOR]

Published

2018

3. Comparison of pigment cell ultrastructure and organisation in the dermis of marble trout and brown trout, and first description of erythrophore ultrastructure in salmonids.

Author

Djurdjevič, Ida, Kreft, Mateja Erdani, and Sušnik Bajec, Simona

Subjects

*SALMONIDAE, *TROUT, *ANIMAL pigments, *DERMIS, *TRANSMISSION electron microscopy

Abstract

Skin pigmentation in animals is an important trait with many functions. The present study focused on two closely related salmonid species, marble trout ( Salmo marmoratus) and brown trout ( S. trutta), which display an uncommon labyrinthine (marble-like) and spot skin pattern, respectively. To determine the role of chromatophore type in the different formation of skin pigment patterns in the two species, the distribution and ultrastructure of chromatophores was examined with light microscopy and transmission electron microscopy. The presence of three types of chromatophores in trout skin was confirmed: melanophores; xanthophores; and iridophores. In addition, using correlative microscopy, erythrophore ultrastructure in salmonids was described for the first time. Two types of erythrophores are distinguished, both located exclusively in the skin of brown trout: type 1 in black spot skin sections similar to xanthophores; and type 2 with a unique ultrastructure, located only in red spot skin sections. Morphologically, the difference between the light and dark pigmentation of trout skin depends primarily on the position and density of melanophores, in the dark region covering other chromatophores, and in the light region with the iridophores and xanthophores usually exposed. With larger amounts of melanophores, absence of xanthophores and presence of erythrophores type 1 and type L iridophores in the black spot compared with the light regions and the presence of erythrophores type 2 in the red spot, a higher level of pigment cell organisation in the skin of brown trout compared with that of marble trout was demonstrated. Even though the skin regions with chromatophores were well defined, not all the chromatophores were in direct contact, either homophilically or heterophilically, with each other. In addition to short-range interactions, an important role of the cellular environment and long-range interactions between chromatophores in promoting adult pigment pattern formation of trout are proposed. [ABSTRACT FROM AUTHOR]

Published

2015

4. Molecular ultrastructure of the urothelial surface: Insights from a combination of various microscopic techniques.

Author

Zupančič, Daša, Romih, Rok, Robenek, Horst, Žužek Rožman, Kristina, Samardžija, Zoran, Kostanjšek, Rok, and Kreft, Mateja Erdani

Abstract

ABSTRACT The urothelium forms the blood-urine barrier, which depends on the complex organization of transmembrane proteins, uroplakins, in the apical plasma membrane of umbrella cells. Uroplakins compose 16 nm intramembrane particles, which are assembled into urothelial plaques. Here we present an integrated survey on the molecular ultrastructure of urothelial plaques in normal umbrella cells with advanced microscopic techniques. We analyzed the ultrastructure and performed measurements of urothelial plaques in the normal mouse urothelium. We used field emission scanning electron microscopy (FESEM), atomic force microscopy (AFM), transmission electron microscopy (TEM) on immunolabeled ultrathin sections (immuno-TEM), and freeze-fracture replicas (FRIL). We performed immunolabeling of uroplakins for scanning electron microscopy (immuno-FESEM). All microscopic techniques revealed a variability of urothelial plaque diameters ranging from 332 to 1179 nm. All immunolabeling techniques confirmed the presence of uroplakins in urothelial plaques. FRIL showed the association of uroplakins with 16 nm intramembrane particles and their organization into plaques. Using different microscopic techniques and applied qualitative and quantitative evaluation, new insights into the urothelial apical surface molecular ultrastructure have emerged and may hopefully provide a timely impulse for many ongoing studies. The combination of various microscopic techniques used in this study shows how these techniques complement one another. The described advantages and disadvantages of each technique should be considered for future studies of molecular and structural membrane specializations in other cells and tissues. Microsc. Res. Tech. 77:896-901, 2014. © 2014 Wiley Periodicals, Inc. [ABSTRACT FROM AUTHOR]

Published

2014

5. Apical Plasma Membrane Traffic in Superficial Cells of Bladder Urothelium.

Author

Kreft, Mateja Erdani, Jezernik, Kristijan, Kreft, Marko, and Romih, Rok

Subjects

*CELL membranes, *BLADDER, *URINARY organs, *EXOCYTOSIS, *CELL physiology, *ENDOCYTOSIS, *CELLS, *CYTOLOGY, *BIOLOGY

Abstract

Superficial urothelial cells that line the urinary bladder accommodate cyclical changes in organ volume while maintaining a permeability barrier between urine and tissue fluids. The specific apical plasma membrane traffic is necessary for their proper function. The composition of the apical plasma membrane is dramatically modified during differentiation of bladder urothelial cells, most notably by assembly of urothelial plaques containing uroplakins. However, the assembly of uroplakins into plaques, their insertion and removal from the apical surface, and the regulation of these processes are still poorly understood. This review examines the traffic (exocytosis/endocytosis) of the apical plasma membrane during differentiation of urothelial cells and focuses on the physiological and clinical significance of the apical plasma membrane traffic in bladder superficial urothelial cells. [ABSTRACT FROM AUTHOR]

Published

2009

6. Stimulation inhibits the mobility of recycling peptidergic vesicles in astrocytes.

Author

Potokar, Maja, Stenovec, Matjaž, Kreft, Marko, Kreft, Mateja Erdani, and Zorec, Robert

Published

2008

7. ANTIGENIC AND ULTRASTRUCTURAL MARKERS ASSOCIATED WITH UROTHELIAL CYTODIFFERENTIATION IN PRIMARY EXPLANT OUTGROWTHS OF MOUSE BLADDER

Author

Kreft, Mateja Erdani, Romih, Rok, and Sterle, Maksimiljan

Subjects

*CELL culture, *BLADDER, *MORPHOLOGY

Abstract

The purpose of this study was to establish an in vitro culture model that closely resembles whole mouse urothelial tissue. Primary explant cultures of mouse bladder were established on porous membrane supports and explant outgrowths were analysed for morphology and the presence of antigenic and ultrastructural markers associated with urothelial cytodifferentiation. When examined at the ultrastructural level, the cultured urothelium was polarized and organized as a multilayered epithelium. Differentiation was found to increase from the porous membrane towards the surface and from the explant towards the periphery of the culture. Scanning and transmission electron microscopical analysis of the most superficially-located cells revealed four successive differentiation stages: cells with microvilli, cells with ropy microridges, cells with rounded microridges, and highly-differentiated cells with asymmetric unit membrane (AUM) plaques forming rigid microridges and fusiform vesicles. The more highly-differentiated cells were numerous at the periphery of the culture, but rare close to the explant. Epithelial organization was stabilized by well developed cell junctions. Immunolabeling demonstrated that superficial urothelial cells in culture: (1) develop tight junctions, E-cadherin adherens junctions and abundant desmosomes and (2) express uroplakins and cytokeratin 20 (CK 20). Using a culture model of primary explant outgrowth we have shown that non-differentiated mouse urothelial cells growing on a porous membrane show a high level of de novo differentiation. [Copyright &y& Elsevier]

Published

2002

8. Golgi apparatus fragmentation as a mechanism responsible for uniform delivery of uroplakins to the apical plasma membrane of uroepithelial cells.

Author

Kreft ME, Di Giandomenico D, Beznoussenko GV, Resnik N, Mironov AA, and Jezernik K

Subjects

Animals, Cells, Cultured, Fluorescence Recovery After Photobleaching, Golgi Apparatus drug effects, Golgi Apparatus ultrastructure, Hypertrophy, Intermediate Filaments pathology, Keratin-20 metabolism, Keratin-7 metabolism, Microscopy, Electron, Microscopy, Fluorescence, Microtubules metabolism, N-Acetyllactosamine Synthase metabolism, Nocodazole pharmacology, Swine, Uroplakin II, Cell Differentiation physiology, Cell Membrane metabolism, Golgi Apparatus metabolism, Membrane Proteins metabolism, Protein Transport, Urothelium cytology

Abstract

Background Information: The GA (Golgi apparatus) has an essential role in membrane trafficking, determining the assembly and delivery of UPs (uroplakins) to the APM (apical plasma membrane) of superficial UCs (uroepithelial cells) of urinary bladder. UPs are synchronously and uniformly delivered from the GA to the APM by DFVs (discoidal- or fusiform-shaped vesicles); however, the mechanism of UP delivery is not known. We have used the culture model of UCs with the capacity to undergo terminal differentiation to study the process of uniform delivery of DFVs to the APM and to elucidate the mechanisms involved., Results: By three-dimensional localization using confocal microscopy of immunofluorescence-labelled GA-related markers [GM130 (cis-Golgi matrix protein of 130 kDa), GS15 (Golgi Snare 15 kDa), GS28 and giantin], uroepithelial differentiation-related markers (UPs), MTs (microtubules; α-tubulin) and intermediate filaments [CK7 (cytokeratin 7) and CK20], we found that in non-differentiated, UP-negative UCs the GA is mostly organized as a single ribbon-like structure close to the nucleus, whereas in differentiated, UP-positive UCs the GA is fragmented and spread almost through the entire cell. The FRAP (fluorescence recovery after photobleaching) experiments on the UCs transfected with GalT (trans-Golgi/TGN enzyme β1,4-galactosyltransferase) fused to fluorescent protein showed that Golgi-resident enzyme cycles freely within ribbon-like GA but not within fragmented GA. By CLEM (correlative light-electron microscopy), we examined the GA fragments in cells expressing UPs. We found that GA fragments are fully functional and similar to the GA fragments that are formed after nocodazole treatment. Furthermore, we demonstrated that the reorganization of GA into a fragmented form is associated with the impairment of the MT organization in the basal, central and subapical cytoplasm and the accumulation of intermediate filaments in the apical cytoplasm that could affect the kinetics of MT star leading to the peripheral fragmentation of the GA in the differentiated UCs., Conclusions: The fragmentation of the GA and the subsequent spreading of GA to the cell periphery represent one of the key events that promote the uniform delivery of UPs over the entire APM of differentiating UCs and thus are of major importance in the final proper formation and maintenance of the blood-urine barrier.

Published

2010