Cryopreservation of primary cultures of mammalian somatic cells in 96-well plates benefits from control of ice nucleation

Cryopreservation of mammalian cells has to date typically been conducted in cryovials, but there are applications where cryopreservation of primary cells in multiwell plates would be advantageous. However excessive supercooling in the small volumes of liquid in each well of the multiwell plates is inevitable without intervention and tends to result in high and variable cell mortality. Here, we describe a technique for cryopreservation of adhered primary bovine granulosa cells in 96-well plates by controlled rate freezing using controlled ice nucleation. Inducing ice nucleation at warm supercooled temperatures (less than 5 °C below the melting point) during cryopreservation using a manual seeding technique significantly improved post-thaw recovery from 29.6% (SD = 8.3%) where nucleation was left uncontrolled to 57.7% (9.3%) when averaged over 8 replicate cultures (p < 0.001). Detachment of thawed cells was qualitatively observed to be more prevalent in wells which did not have ice nucleation control which suggests cryopreserved cell monolayer detachment may be a consequence of deep supercooling. Using an infra-red thermography technique we showed that many aliquots of cryoprotectant solution in 96-well plates can supercool to temperatures below −20 °C when nucleation is not controlled, and also that the freezing temperatures observed are highly variable despite stringent attempts to remove contaminants acting as nucleation sites. We conclude that successful cryopreservation of cells in 96-well plates, or any small volume format, requires control of ice nucleation.     

Preservation at -195 degrees C of trypsinized organs for primary cultures

Trypsinized cells from rabbit kidney can be kept at -195, 8 degrees C indefinitely. When necessary, propagation in monolayer cultures is readily obtained as primary cultures, provided that some conditions be respected: 1) only glass culture flask must be used. Falcon plastic vessels do not allow cell attachment in this type of primary culture 2) the lag period is particularly long: it taken about 20 days before the beginning of cell multiplication 3) fetal calf serum is toxic for the cells in the 2nd and 3rd change of the culture medium, during the lag period.     

Methods for imaging Shewanella oneidensis MR-1 nanofilaments

Nanofilament production by Shewanella oneidensis MR-1 was evaluated as a function of lifestyle (planktonic vs. sessile) under aerobic and anaerobic conditions using different sample preparation techniques prior to imaging with scanning electron microscopy. Nanofilaments could be imaged on MR-1 cells grown in biofilms or planktonically under both aerobic and anaerobic batch culture conditions after fixation, critical point drying and coating with a conductive metal. Critical point drying was a requirement for imaging nanofilaments attached to planktonically grown MR-1 cells, but not for cells grown in a biofilm. Techniques described in this paper cannot be used to differentiate nanowires from pili or flagella.     

A simple and reliable method for the localization in cell culture of single identifiable cells for ultrastructural analyses

A simple method for relocating single cells in monolayer cultures for subsequent morphological or ultrastructural analysis is reported. This consists of producing, on the culture dish surface, a nontoxic carbon grid that is preserved during processing for either transmission (TEM) or scanning (SEM) electron microscopy. For TEM studies these grids are readily transferred along with the cells into the embedding plastic, and thus individual grid squares containing a cell(s) of interest can be quickly located, remounted, and sectioned. These grids may be useful for ultrastructural analyses of single cells previously studied electrophysiologically or after microinjection of macromolecules.     

Transmission electron microscopy of tissue prepared for scanning electron microscopy by ethanol-cryofracturing.

Tissue processed for scanning electron microscopy by ethanol-cryofracturing combined with critical point drying was embedded and sectioned for transmission electron microscopy. Study of specimens cut in a plane passing through the fracture edge indicated that preservation of cellular fine structure of fractured cells was excellent. Even at the most peripheral edge of the fracture there was no evidence that movement of cytoplasmic components occurred to distort the original structural organization of fractured cells. Lack of cytoplasmic detail in ethanol-cryofractographs has been due more to the nature of the fracturing of the tissue and to the obscuring effects of the metal coating than to structural deformation at the fracture edge or to limitations in resolving power of the scanning electron microscope used.     

Transmission Electron Microscopy of Tissue Prepared for Scanning Electron Microscopy by Ethanol-Cryofracturing

Tissue processed for scanning electron microscopy by ethanol-cryofracturing combined with critical point drying was embedded and sectioned for transmission electron microscopy. Study of sections cut in a plane passing through the fracture edge indicated that preservation of cellular fine structure of fractured cells was excellent. Even at the most peripheral edge of the fracture there was no evidence that movement of cytoplasmic components occurred to distort the original structural organization of fractured cells. Lack of cytoplasmic detail in ethanol-cryofractographs has been due more to the nature of the fracturing of the tissue and to the obscuring effects of the metal coating than to structural deformation at the fracture edge or to limitations in resolving power of the scanning electron microscope used.     

Improved transmission electron microscopy (TEM) of cultured cells through a “floating sheet” method

Cultured cells provide isolated systems for both biochemical and morphological studies. Previous methods of processing cell culture specimens for electron microscopy (EM) have been limited to sectioning either a monolayer or centrifuged cell suspensions which are not morphologically intact. In our improved method, N-butylglycidyl ether is added to cell cultures (2–5 min with agitation) following in situ fixation (3.0% glutaraldehyde in 0.1 M Pipes, pH 7.2, for 20 min, osmium tetraoxide 4% for 20 min). A thin pliable “sheet” of cells floats free from the plastic culture device and can be manipulated (centrifuged or folded) to obtain a vast number of morphologically intact cells for examination. We have examined several cell types (vascular smooth muscle, lung, liver, and endothelial cells) grown in two types of plastic culture flasks (Nunc and Falcon). This new method provides excellent EM morphology, maximizes the number of cells examined, and allows determination of cell orientation since a remnant of the dissolved flask remains loosely bound to the bottom of the cells.     

Cryo-preservation for scanning electron microscopy avoids artefacts induced by conventional methods of specimen preparation

Cryo-preservation of tissues for scanning electron microscopy avoids artefacts associated with critical point drying and freeze-drying (solvent extraction and cell distortion). Motile specimens are arrested immediately, cells remain fully hydrated, delicate structures are undisturbed and conductive coating with metals or carbon is achieved at low temperatures.     

Protein analysis of mammalian cells in monolayer culture using the bicinchoninic assay

We have applied the bicinchoninic acid (BCA) protein assay to rat brain primary astrocyte monolayer cultures growing in multiwell culture plates. The BCA method provides a more rapid and sensitive procedure with greater stability of color than is obtained using the Lowry method. Also, large numbers of samples can be read rapidly at the available wavelengths on an enzyme-linked immunosorbent assay microtiter plate reader. We found, however, artifactually high readings when using isotonic buffered sucrose to wash the cultures followed by sodium hydroxide to solubilize the cell protein. Such a procedure is commonly used for washing monolayer cell cultures in transport and binding studies. This effect was found to be due to hydrolysis of sucrose to the reducing sugar glucose. Use of Triton X-100 eliminated this problem, but this agent only solubilized about 80% of the protein that could be solubilized with sodium hydroxide. Furthermore, the high viscosity of Triton X-100 makes it more difficult to use. We found that washing the cells with isotonic mannitol solution followed by solubilization with sodium hydroxide gave reliable results. The sensitivity and speed of this method makes it suitable for multiple protein determinations in experiments using large numbers of cell culture samples.     

Culture of human main pancreatic duct epithelial cells

Summary Attempts to grow human pancreatic duct epithelial cells in long-term culture have proven difficult. We have developed a system of growing these cells for several passages by adapting methods used to culture dog pancreatic duct cells. Epithelial cells were enzymatically dissociated from the main pancreatic duct and plated onto collagen-coated culture inserts suspended above a human fibroblast feeder layer. After primary culture, the cells were either passaged onto new inserts or plastic tissue culture plates in the absence of collagen. Cells grown on the latter plates were maintained in a serum-free medium. Primary pancreatic duct epithelial cells grow steadily to confluence as a monolayer in the feeder layer system. After primary culture, cells passaged onto new inserts with fresh feeder layer or plastic plates and fed with serum-free medium continued to develop into confluent monolayers for up to four passages. The cells were columnar with prominent apical microvilli, sub-apical secretory vesicles, and lateral intercellular junctions resembling the morphology of normal in vivo epithelial cells. These cells were also positive for cytokeratin 19, 7, and 8 and carbonic anhydrase II, as measured by immunohistochemistry. Metabolically, these cells synthesized and secreted mucin, as measured by incorporation of tritiated N-acetyl-d-glucosamine. In conclusion, we demonstrated that human pancreatic epithelial cells from the main duct can be successfully grown in culture and repeatedly passaged using a feeder layer system, with serum-free medium, and in organotypic cultures.     

Prolonged in vitro cultivation of Ichthyophthirius multifiliis using an EPC cell line as substrate

The ciliate Ichthyophthirius multifiliis, which normally requires a fish host to develop from the theront stage to the trophont stage, was cultivated in vitro for part of its life cycle. Experiments were conducted using a laboratory strain of the parasite originally isolated from rainbow trout Oncorhynchus mykiss in a Danish trout farm. Theronts escaping from tomontocysts were kept in water, cell culture media (E-MEM or L-15), or cultures of EPC (Epithelioma Papulosum Cyprini) cells in plastic tissue culture dishes (Nunc multidish plates). In addition, a 2-compartment system, with water separated from tissue culture media by a monolayer of EPC cells on an Anopore Tissue Culture Insert (mimicking the fish epidermis) was tested as an experimental habitat for the parasite. Theronts transformed into trophonts in all treatments except in water alone. However, development was accelerated in wells containing EPC cells, and survival and growth of trophonts were significantly increased compared to water or tissue culture media alone. Further, the 2-compartment system allowed superior performance of the parasites (attachment of parasites to cells and growth from 36 to 46 microm). In all experiments it was found that the presence of host factors (mucus and serum) stimulated parasite development.     

Freeze-drying from tertiary butanol in the preparation of endocardium for scanning electron microscopy.

The scanning electron microscope appearances and shrinkage of blocks of canine endocardium prepared by freeze-drying directly, by freeze-drying after replacing tissue water with tertiary butanol (2-methyl propan-2-ol) and by critical point drying were compared. All three methods demonstrated endothelial cells which showed nuclear prominences, microvilli and intercellular boundaries. The microvilli varied in size and number from dog to dog but were generally less well defined in specimens freeze-dried from water. Shrinkage due to t-butanol dehydration was significantly less than that which occurred in ethanol in the critical point drying method. Overall the reduction in surface area was significantly less in specimens freeze-dried directly at -65 C (6.8%) than in those dried from t-butanol at -20 C (15.4%) and those prepared bly critical point drying (22.1%). However the amount of shrinkage observed in t-butanol treated tissue was not significantly different from that which was critical point dried. It was not possible to distinguish between comparable samples prepared by these two methods on the basis of their scanning electron microscopic appearances. Thus the relative simplicity and convenience of the t-butanol method, together with its saving of time, its use of standard freeze-drying equipment and the avoidance of ice-crystal artefact justify its consideration as an alternative method of preparing wet biological tissue for scanning electron microscopy.     

Indication of selective growth of human endometrial epithelial cells on extracellular matrix

Summary The culturing of human endometrium in conventional plastic dishes and media is only partially successful, mainly because a growth of a heterogeneous population of cells is achieved. Naturally produced extracellular matrix closely resembles the subepithelial basement membrane and seems to affect both growth and differentiation of cells. These qualities of the extracellular matrix (ECM) were applied for obtaining endometrial epithelial cultures. Endometrial tissue specimens were plated after slicing on ECM-coated dishes and kept for up to 8 d. The growth of a confluent homogeneous tissue composed of polygonal epithelial-like cells was demonstrated. To further characterize these cells, cultures were examined by scanning electron microscopy and transmission electron microscopy. Scanning electron microscopy revealed flattened polygonal cells covered with microvilli, among which ciliated cells were observed. By transmission electron microscopy the cells were seen as a monolayer, with some cells overlapping, closely adherent to the matrix. Microvilli, as well as intracellular vacuoles and glycogen granules were observed. Cell type specific cytoskeletal markers were demonstrated by antibodies to intermediate filament proteins (keratin and epithelial membrane antigen). Taken together, the morphologic and immunohistochemical studies indicate that a selective growth of the epithelial component of endometrial tissue was obtained after plating unprocessed endometrial tissue fragments on ECM-coated culture dishes. This work was supported by PHS grant no. CA 30289 to J.V.     

Freeze-Drying from Tertiary Butanol in the Preparation of Endocardium for Scanning Electron Microscopy

The scanning electron microscope appearances and shrinkage of blocks of canine endocardium prepared by freeze-drying directly, by freeze-drying after replacing tissue water with tertiary butanol (2-methyl propan-2-01) and by critical point drying were compared. All three methods demonstrated endothelial cells which showed nuclear prominences, microvilli and interoellular boundaries. The microvilli varied in six and number from dog to dog hut were generally less well defined in specimens freeze-dried from water. Shrinkage due to t-butanol dehydration was significantly less than that which occurred in ethanol in the critical point drying method. Overall the reduction in surface area was significantly less in specimens freeze-dried directly at -65 C (6.8%) than in those dried from t-butanol at -20 C (15.4%) and those prepared by critical point drying (22.1%). However the amount of shrinkage observed in t-butanol treated tissue was not significantly different from that which was critical point dried. It was not possible to distinguish between comparable samples prepared by these two methods on the basis of their scanning electron microscopic appearances. Thus the relative simplicity and convenience of the t-butanol method, together with its saving of time, its use of standard freeze-drying equipment and the avoidance of ice-crystal artefact justify its consideration as an alternative method of preparing wet biological tissue for scanning electron microscopy.     

Editorial note

Abstract

The histology laboratory can face many challenges when small, often critical, specimens of cultured cells are submitted for specialized immunocytochemical studies or special stains. Although clinical pathology labs often receive cell preparations, these usually contain enough cells so that pellets can be formed by centrifugation, and the pellets directly embedded and sectioned. Research labs, however, often need to submit very small samples of cells for experimental studies. We summarize here a number of techniques that currently are available and methods we have developed and/or adapted and used in our laboratory over the years. We describe the utility of multi-chambered slides for cell culture and histologic studies, multi-well cell culture plates, monolayer cell culture on specialized coated cell wells, cell well inserts, and agarose embedding techniques for small cultures of cells and for cultures that require antigen retrieval or multiple antibody localizations. Traditional double embedding techniques, such as the use of agar, are also cited.     

Porcelain Color Plates for Immunohistochemical Incubation of Free-Floating Tissue Sections

Porcelain color plates are a convenient alternative to multiwell plastic plates for immunohistochemical incubations. The advantage of the plates are that they allow relatively large tissue sections to float freely in small volumes of liquid and allow easy access to the sections.     

Method of preparing suspended cells for scanning electron microscopy]

To preserve the lifetime morphology of the surface of suspended cells, these must be fixed in suspensions. The subsequent stages of cell preparation for scanning electron microscopy (dehydratation, critical point drying, coating) are considerably facilitated if fixed cells are preliminary attached to some substrate surface. An effective substrate should provide a firm rather than selective attachment of the overwhelming majority of fixed cells; the substrate should be also available for a wide application. The trial of different types of substrates showed a sufficient effectivity of plates made of commercial aluminium foil. In tests with murine embryonal and transformed fibroblasts as well as with human blood leukocytes, in average 90 per cent of cells fixed with glutaraldehyde in suspensions got attached to foil substrate surfaces; the fixed cells both settled from suspension and attached were seen distributed evenly on the substrate surface. The use of aluminium foil substrates made it possible to study the surface topography of some types of suspended cells.     

Scanning electron microscopy of hydrated and desiccated mature somatic embryos and zygotic embryos of white spruce (Picea glauca [Moench] Voss.)

Summary Four scanning electron microscope techniques for preparing somatic and zygotic embryos of white spruce (Picea glauca [Moench] Voss.) were compared. Direct sputter coating without critical point drying worked well for desiccated embryos while conventional methods using chemical fixation were appropriate for hydrated somatic embryos. Low temperature scanning electron microscopy and plastic replicas provided excellent specimens of all embryos studied. Plastic replicas were used to document cotyledon formation and growth during maturation of somatic embryos. Apart from some differences in embryo size, orientation of cotyledons and surface wrinkling, the general morphology of mature somatic embryos of white spruce was very similar to zygotic embyros at a similar stage of development.     

Monolayer cell expansion conditions affect the chondrogenic potential of adipose-derived stem cells

Adipose-derived stem cells (ASCs) are an abundant, readily available population of multipotent progenitor cells that reside in adipose tissue. Isolated ASCs are typically expanded in monolayer on standard tissue culture plastic with a basal medium containing 10% fetal bovine serum. However, recent data suggest that altering the monolayer expansion conditions by using suspension culture plastic, adding growth factors to the medium, or adjusting the seeding density may affect the self-renewal rate, multipotency, and lineage-specific differentiation potential of the ASCs. We hypothesized that variation in any of these expansion conditions would influence the chondrogenic potential of ASCs. ASCs were isolated from human liposuction waste tissue and expanded through two passages with different tissue culture plastic, feed medium, and cell seeding densities. Once expanded, the cells were cast in an agarose gel and subjected to identical chondrogenic culture conditions for 7 days, at which point cell viability, radiolabel incorporation, and gene expression were measured. High rates of matrix synthesis upon chondrogenic induction were mostly associated with smaller cells, as indicated by cell width and area on tissue culture plastic, and it appears that expansion in a growth factor supplemented medium is important in maintaining this morphology. All end-point measures were highly dependent on the specific monolayer culture conditions. These results support the hypothesis that monolayer culture conditions may "prime" the cells or predispose them towards a specific phenotype and thus underscore the importance of early culture conditions in determining the growth and differentiation potential of ASCs.