Mouse Pancreas Tissue Slice Culture Facilitates Long-Term Studies of Exocrine and Endocrine Cell Physiology in situ

Speier, Stephan, Marciniak, Anja, Selck, Claudia, Friedrich, Betty

02 December 2015

Studies on pancreatic cell physiology rely on the investigation of exocrine and endocrine cells in vitro. Particularly, in the case of the exocrine tissue these studies have suffered from a reduced functional viability of acinar cells in culture. As a result not only investigations on dispersed acinar cells and isolated acini were limited in their potential, but also prolonged studies on pancreatic exocrine and endocrine cells in an intact pancreatic tissue environment were unfeasible. To overcome these limitations, we aimed to establish a pancreas tissue slice culture platform to allow long-term studies on exocrine and endocrine cells in the intact pancreatic environment. Mouse pancreas tissue slice morphology was assessed to determine optimal long-term culture settings for intact pancreatic tissue. Utilizing optimized culture conditions, cell specificity and function of exocrine acinar cells and endocrine beta cells were characterized over a culture period of 7 days. We found pancreas tissue slices cultured under optimized conditions to have intact tissue specific morphology for the entire culture period. Amylase positive intact acini were present at all time points of culture and acinar cells displayed a typical strong cell polarity. Amylase release from pancreas tissue slices decreased during culture, but maintained the characteristic bell-shaped dose-response curve to increasing caerulein concentrations and a ca. 4-fold maximal over basal release. Additionally, endocrine beta cell viability and function was well preserved until the end of the observation period. Our results show that the tissue slice culture platform provides unprecedented maintenance of pancreatic tissue specific morphology and function over a culture period for at least 4 days and in part even up to 1 week. This analytical advancement now allows mid -to long-term studies on the cell biology of pancreatic disorder pathogenesis and therapy in an intact surrounding in situ.

Pankreas

regenertative Therapie

Diabetes

Pancreas

Insulin

Cell physiology

Endocrine cells

Glucose

Endocrine physiology

Secretion

Cell staining

ddc:610

rvk:XA 10000

Mouse Pancreas Tissue Slice Culture Facilitates Long-Term Studies of Exocrine and Endocrine Cell Physiology in situ

Speier, Stephan, Marciniak, Anja, Selck, Claudia, Friedrich, Betty

02 December 2015

Studies on pancreatic cell physiology rely on the investigation of exocrine and endocrine cells in vitro. Particularly, in the case of the exocrine tissue these studies have suffered from a reduced functional viability of acinar cells in culture. As a result not only investigations on dispersed acinar cells and isolated acini were limited in their potential, but also prolonged studies on pancreatic exocrine and endocrine cells in an intact pancreatic tissue environment were unfeasible. To overcome these limitations, we aimed to establish a pancreas tissue slice culture platform to allow long-term studies on exocrine and endocrine cells in the intact pancreatic environment. Mouse pancreas tissue slice morphology was assessed to determine optimal long-term culture settings for intact pancreatic tissue. Utilizing optimized culture conditions, cell specificity and function of exocrine acinar cells and endocrine beta cells were characterized over a culture period of 7 days. We found pancreas tissue slices cultured under optimized conditions to have intact tissue specific morphology for the entire culture period. Amylase positive intact acini were present at all time points of culture and acinar cells displayed a typical strong cell polarity. Amylase release from pancreas tissue slices decreased during culture, but maintained the characteristic bell-shaped dose-response curve to increasing caerulein concentrations and a ca. 4-fold maximal over basal release. Additionally, endocrine beta cell viability and function was well preserved until the end of the observation period. Our results show that the tissue slice culture platform provides unprecedented maintenance of pancreatic tissue specific morphology and function over a culture period for at least 4 days and in part even up to 1 week. This analytical advancement now allows mid -to long-term studies on the cell biology of pancreatic disorder pathogenesis and therapy in an intact surrounding in situ.

info:eu-repo/classification/ddc/610

ddc:610

Effects on immune cell viability, morphology and proliferation in a sub-microliter cell sampler system

Wiklund, Sofia

January 2013

Today,   most traditional method used in the research of immune cells, such as flow   cytometry and microscopy, are based on average values of cell responses.   However, immune cells are heterogeneous and respond differently to a given   stimuli. There is also a risk that important, but rare, behaviors of   individual cells are missed when a larger population of immune cells is   analyzed. Also, flow cytometry and microscopy do not allow long-term survival   of cells; these methods lack the ability to do dynamic long-term analysis of   motile immune cells, i.e. studies of cell-cell interactions, morphology and proliferation.   In a   patient who is affected by cancer, the cell heterogeneity contributes to the   ability to battle various types of cancer or virus infections. In an   outbreak, immune cells recognize and kill tumor cells. However, the number of   specific immune cells is sometimes too few to kill all the tumor cells in a   successful way. One way to help these patients is to isolate, select out and   cultivate the active immune cells with capacity to kill tumor cells.   The   Cell Physic Laboratory (a part of the department of Applied Physics) at the   Royal Institute of Technology (KTH) has developed a method for single-cell   analysis where the immune cells are trapped in microwells in a silicon chip.   The immune cells are then studied by using fluorescence microscopy in an   inverted setup. The method enables high-throughput experiments due to the   parallelization. Furthermore, since the immune cells survive long periods in   the chip, the cells can be analyzed over several days up to weeks. The   research group has also developed a semi-automatic ‘cell-picker’. The   cell-picker will be used in combination with the developed method for   single-cell analysis, which enables picking of cells of interest. In this report, experiments for the characterization and evaluation of the biocompatibility of two generations of the cell-picker will be presented. The experiments include development of a protocol for the cell-picking process, studies of the survival time of transferred cells for both generation of the cell-picker and studies of surface coating in the chip in order to increase the biocompatibility. The preliminary results indicate that the cell-picker has potential to be used as a selection tool for immune cells of interest.

Cell-picker

sub-microliter cell sampler system

immune cells

T cells

NK cells

B cells

cell viability

morphology

proliferation

surface coating

microchip

wells

silicon chip

single-cell analysis

flow system

fluorescence microscopy

cell staining

characterization

Dendritic Cell Podosome Dynamics Does Not Depend on the F-actin Regulator SWAP-70

Götz, Anne, Jessberger, Rolf

22 January 2014

In addition to classical adhesion structures like filopodia or focal adhesions, dendritic cells similar to macrophages and osteoclasts assemble highly dynamic F-actin structures called podosomes. They are involved in cellular processes such as extracellular matrix degradation, bone resorption by osteoclasts, and trans-cellular diapedesis of lymphocytes. Besides adhesion and migration, podosomes enable dendritic cells to degrade connective tissue by matrix metalloproteinases. SWAP-70 interacts with RhoGTPases and F-actin and regulates migration of dendritic cells. SWAP-70 deficient osteoclasts are impaired in F-actin-ring formation and bone resorption. In the present study, we demonstrate that SWAP-70 is not required for podosome formation and F-actin turnover in dendritic cells. Furthermore, we found that toll-like receptor 4 ligand induced podosome disassembly and podosome-mediated matrix degradation is not affected by SWAP-70 in dendritic cells. Thus, podosome formation and function in dendritic cells is independent of SWAP-70.

F-Aktin

Podosome

Immunsystem

TU Dresden

Publikationsfonds

F-actin

podosomes

immune system

Actins

Bone resorption

Cell migration

Cell staining

Dendritic cells

Extracellular matrix

Fluorescence recovery

after photobleaching

Technical University Dresden

Publication funds

ddc:610

rvk:XA 10000

Dendritic Cell Podosome Dynamics Does Not Depend on the F-actin Regulator SWAP-70

Götz, Anne, Jessberger, Rolf

22 January 2014

In addition to classical adhesion structures like filopodia or focal adhesions, dendritic cells similar to macrophages and osteoclasts assemble highly dynamic F-actin structures called podosomes. They are involved in cellular processes such as extracellular matrix degradation, bone resorption by osteoclasts, and trans-cellular diapedesis of lymphocytes. Besides adhesion and migration, podosomes enable dendritic cells to degrade connective tissue by matrix metalloproteinases. SWAP-70 interacts with RhoGTPases and F-actin and regulates migration of dendritic cells. SWAP-70 deficient osteoclasts are impaired in F-actin-ring formation and bone resorption. In the present study, we demonstrate that SWAP-70 is not required for podosome formation and F-actin turnover in dendritic cells. Furthermore, we found that toll-like receptor 4 ligand induced podosome disassembly and podosome-mediated matrix degradation is not affected by SWAP-70 in dendritic cells. Thus, podosome formation and function in dendritic cells is independent of SWAP-70.

info:eu-repo/classification/ddc/610

ddc:610