Dissecção e cultura do rim embrionário do rato
Summary
Este protocolo descreve um método para isolar e cultivar rudimentos metanefricos de embriões de ratinho.
Abstract
O objetivo deste protocolo é descrever um método para a dissecção, isolamento e cultura de rastreios metanefric do rato.
Durante o desenvolvimento do rim mamífero, os dois tecidos progenitorais, o broto ureterico e o mesênquima metanéfrico, comunicam-se e induzem reciprocamente mecanismos celulares para formar eventualmente o sistema colector e os nefrões do rim. À medida que os embriões de mamíferos crescem intra-uterinos e, portanto, são inacessíveis ao observador, desenvolveu-se uma cultura de órgãos. Com este método, é possível estudar interações epitélio-mesenquimais e comportamento celular durante a organogênese do rim. Além disso, a origem das malformações congênitas do rim e do trato urogenital pode ser investigada. Após dissecção cuidadosa, os rudimentos metanéfricos são transferidos para um filtro que flutua no meio de cultura e podem ser mantidos numa incubadora de cultura de células durante vários dias. Contudo, deve ter-se em conta que as condiçõesArtificial e poderia influenciar o metabolismo no tecido. Além disso, a penetração das substâncias de teste poderia ser limitada devido à matriz extracelular e à membrana basal presentes no explante.
Uma vantagem principal da cultura do órgão é que o experimentador pode ganhar o acesso direto ao órgão. Esta tecnologia é barata, simples e permite um grande número de modificações, como a adição de substâncias biologicamente ativas, o estudo de variantes genéticas e a aplicação de técnicas de imagem avançadas.
Introduction
The mammalian kidney is derived from two primordial structures with mesodermal origin: the tubular epithelial ureteric bud and the metanephric mesenchyme. During nephrogenesis, the ureteric bud invades the metanephric mesenchyme and branches to form the collecting system. The metanephric mesenchyme gives rise to the epithelial elements of the nephrons. These processes occur in a precisely timed and spatially coordinated manner and are initiated by reciprocal inductive mechanisms. Both tissue components communicate and affect the other’s cell morphogenesis.
In the 1920s, it was Boyden who performed the in vivo obstruction of the mesonephric duct in chicken, providing the first indication of inductive interactions as separated nephric blastema fail to differentiate1. At about the same time, the first successful attempts to culture chicken nephric rudiments in a hanging drop were published. Subsequently, the organ culture was developed to study tissue interactions in mammalian organogenesis. In the 1950s, Grobstein developed a technique in which metanephric rudiments could be cultured on a filter. This technique was modified by Saxén, who placed the filter on a Trowell-type screen in a culture dish1. Over the years, many modifications and applications for organ culture have emerged. The method described here is based on Saxén’s technique but is simplified, as the filters float free on the medium and the diameter of the culture well only slightly exceeds the diameter of the filter, limiting unwanted movement of the filter.
Whole-organ culture is a classical, cheap, and simple but powerful tool to investigate cellular processes and intercellular communication during organogenesis. Organ culture allows for treatment with biological agents, such as growth factors, antibodies, antisense oligonucleotides, viruses, and peptides, as well as with pharmaceutical compounds and other chemicals. Also, gene function may be studied using explants derived from genetically modified mice or using inducible gene inactivation technology, such as the Cre-loxP system. This allows for the study of genetic mutations that cause embryonic lethality prior to the development of the kidney. Organ culture can also be combined with fluorescent tagging for gene function or lineage tracing and modern imaging techniques, which enable real-time monitoring of cell behavior2.
In the specific example provided here, the effect of EphrinB2-activated Eph-receptor signaling on the branching morphology of the ureteric bud was investigated. The morphology of the EphA4/EphB2 double-knockout mice suggested several severe defects in kidney development, which were detectable as early as embryonic day 11 (E11) and involved the ureteric bud, the ureter, and the common nephric duct3. Signaling via Eph receptors requires the clustering of the ligand-receptor dimer4. To over-activate Eph signaling, the kidney rudiments from E11.5 mouse embryos were cultured in the presence of clustered recombinant EphrinB2-Fc. EphrinB2 is a known ligand for the EphA4 receptor, which is expressed in the ureteric bud tips3.
Protocol
Representative Results
Discussion
Este manuscrito descreve um método para isolar o desenvolvimento de metanéfric anlagen do embrião de rato e para cultivar os rudimentos de órgãos. Este método é uma técnica padrão, como desenvolvido por Grobstein 8 e Saxen 9 , 10 , e foi adaptado e modificado por muitos outros 11 , 12 . O sucesso do método depende principalmente da duração da dissecção, como sobreviv…
Declarações
The authors have nothing to disclose.
Acknowledgements
Os autores agradecem a Leif Oxburgh e Derek Adams por compartilhar generosamente seus conhecimentos, Leif Oxburgh pelos comentários úteis sobre o manuscrito, e Stefan Wölfl e Ulrike Müller pelo seu apoio técnico e Saskia Schmitteckert, Julia Gobbert, Sascha Weyer e Viola Mayer pela ajuda na Laboratório Este trabalho foi apoiado por Desenvolvimento, A Empresa de Biólogos (a CP).
Materials
| DMEM/F-12 | Thermo Fisher Scientific | 21331020 | |
| Penicillin-Streptomycin (10,000 U/mL) | Thermo Fisher Scientific | 15140148 | |
| GlutaMAX Supplement | Thermo Fisher Scientific | 35050061 | |
| DPBS, calcium, magnesium | Thermo Fisher Scientific | 14040117 | use for dissection |
| holo-Transferrin human | Sigma-Aldrich | T0665 | |
| Insulin-Transferrin-Selenium (ITS -G) (100X) | Thermo Fisher Scientific | 41400045 | |
| Paraformaldehyde | Sigma-Aldrich | 158127 | |
| Amphotericin B solution | Sigma-Aldrich | A2942 | |
| Triton X-100 | Sigma-Aldrich | X100 | |
| Sodium azide | Sigma-Aldrich | S8032 | |
| Thimerosal | Sigma-Aldrich | T5125 | |
| Propyl gallate | Sigma-Aldrich | 2370 | |
| Mowiol 4-88 | Sigma-Aldrich | 81381 | |
| Glycerol | Sigma-Aldrich | G5516 | |
| Biotinylated Dolichorus Biflorus Agglutinin | Vector Laboratories | B-1035 | |
| Alexa488 conjugated Streptavidin | Jackson Immuno Research | 016-540-084 | |
| Recombinant Mouse Ephrin-B2 Fc Chimera Protein, CF | R&D Systems | 496-EB | |
| Recombinant Human IgG1 Fc, CF | R&D Systems | 110-HG-100 | |
| Goat Anti-Human IgG Fc Antibody | R&D Systems | G-102-C | |
| Phosphate buffered saline tablets | Sigma-Aldrich | P4417 | use for fixation and immunostaining |
| Dumont #5, biologie tips, INOX, 11cm |
agnthos.se | 0208-5-PS | 2 pairs of forceps are needed |
| Iris scissors, straight, 12cm | agnthos.se | 03-320-120 | |
| Dressing Forceps, straight, delicate, 13cm |
agnthos.se | 08-032-130 | |
| Petri dishes Nunclo Delta treated | Thermo Fisher Scientific | 150679 | |
| TMTP01300 Isopore Membrane Filter, polycarbonate, Hydrophilic, 5.0 µm, 13 mm, white, plain | MerckMillipore | TMTP01300 | |
| Nunclon Multidishes 4 wells, flat bottom |
Sigma-Aldrich | D6789-1CS | |
| Microscope cover glass24x50mm thickn. No.1.5H 0.17+/-0.005mm | nordicbiolabs | 107222 | |
| Cover glasses No.1.5, 18x18mm | nordicbiolabs | 102032 | |
| Slides ~76x26x1, 1/2-w. ground plain | nordicbiolabs | 1030418 | |
| VWR Razor Blades | VWR | 55411-055 | |
| 50 mL centrifuge tubes | Sigma-Aldrich | CLS430828 | |
| 15 mL centrifuge tubes | Sigma-Aldrich | CLS430055 | |
| Whatman prepleated qualitative filter paper, Grade 113V, creped | Sigma-Aldrich | WHA1213125 | |
| Fixed stage research mircoscope | Olympus | BX61WI | |
| Black 6 inbred mice, male, C57BL/6NTac | Taconic | B6-M | |
| Black 6 inbred mice,female, C57BL/6NTac | Taconic | B6-F | |
| Greenough Stereo Microscope | Leica | Leica S6 E |
Referências
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