A method for isolating large numbers of viable disaggregated cells from various human tissues for cell culture establishment

Summary A method is described for the isolation of large numbers of viable disaggregated cells from human tissues. This method combined the mechanical action of a Stomacher Model 80 Lab Blender, 0.1 mg/ml trypsin or 0.5 mg/ml collagenase, and 0.1 mM [ethylene bis(oxyethylenenitrolo)]-tetraacetic acid (EGTA). Tissue (0.2 to 1.0 g) obtained from human fetal intestine, kidney, liver, lung, and skin were separately minced into approximately 1-mm³ pieces. The pieces were placed in a sterile bag containing 60 ml of calcium- magnesium-free phosphate buffered saline, the appropriate enzyme (0.1 mg/ml trypsin or 0.5 mg/ml collagenase) plus 0.1 mM EGTA, and 0.1% methylcellulose. The bag was then placed into the blender and mixed at a low speed for 3 to 20 min at room temperature. After a single cell suspension was observed by phase contrast microscopy, 10 ml of bovine calf serum was added to the cell suspension to inactivate the proteolytic enzymes. At this time 130 ml of cold Hanks' balanced salts solution containing 5% bovine calf serum was added and the entire cell suspension passed through a tissue sieve (100 mesh, 140 μm) and the cells collected by centrifugation. These cells were then resuspended into the appropriate culture medium. In comparison to other methods for establishment of cell cultures from human tissues, the method described requires shorter incubation times with relatively low concentrations of proteolytic enzymes, and yields two- to three-fold greater number of cells per tissue with 86 to 93% viability. Also, depending on the cell type, 50 to 75% of the isolated cells attached to the culture vessel within 24 h. Variation of the time and concentration of digestive enzymes can be used to select different cell types for culture. This work was supported by research grants from the National Institute of Environmental Health Sciences, Bethesda, MD (ES3101) and the United States Environmental Protection Agency, Washington, D. C. (R810146).     

Isolation of endothelial cells from fresh tissues

Here, we present a protocol for the isolation of endothelial cells (ECs) from tissues. ECs make up a minor population of cells in a tissue, but play a major role in tissue homeostasis, as well as in diverse pathologies. To understand the biology of ECs, characterization of this cell population is highly desirable, but requires the availability of purified cells. For this purpose, tissues are mechanically minced and subsequently digested enzymatically with collagenase and dispase. ECs in the resulting single-cell suspension are labeled with Abs against EC surface antigens and separated from the remainder of the cells and debris by capture with magnetic beads or by high-speed cell sorting. Purified ECs are viable and suitable for characterization of diverse cellular properties. This protocol is optimized for human tissues but can also be adapted for use with other species. Depending on the tissue, the procedure can be completed in approximately 6 h.     

Methods for microcarrier culture of bovine pulmonary artery endothelial cells avoiding the use of enzymes

Enzymes situated along the luminal surface of pulmonary endothelial cells interact with circulating solutes, notably with vasoactive substances, to regulate the hormonal composition of systemic arterial blood. However, it is becoming clear that the range and complexity of reactions occurring at or near the surface of endothelial cells are greater than previously recognized. In addition, evidence indicates that the quality of cell cultures used to define specific endothelial functions must be carefully controlled, together with development of improved understanding of the effects of long-term culture on pulmonary endothelial cells. We have developed new techniques for the culture of pulmonary endothelial cells which avoid exposure to proteolytic enzymes at both the isolation step and during subculture. A combination of mechanical harvest and culture on microcarrier beads has provided a system for the long-term, large-scale culture of pulmonary endothelial cells, features which to a large extent determine the scope of biochemical studies which can be undertaken.     

Heterogeneity of microvascular endothelial cells isolated from human term placenta and macrovascular umbilical vein endothelial cells

The present study compares some phenotypic and physiologic characteristics of microvascular and macrovascular endothelial cells from within one human organ. To this end microvascular endothelial cells from human full-term placenta (PLEC) were isolated using a new method and compared with macrovascular human umbilical vein endothelial cells (HUVEC) and an SV40-transformed placental venous endothelial cell line (HPEC-A2). PLEC were isolated by enzymatic perfusion of small placental vessels, purified on a density gradient and cultured subsequently. Histological sections of the enzyme-treated vessels showed a selective removal of the endothelial lining in the perfused placental cotyledons. The endothelial identity of the cells was confirmed by staining with the endothelial markers anti-von Willebrand factor, Ulex europaeus lectin and anti-QBEND10. The cells internalized acetylated low-density lipoprotein and did not show immunoreactivity with markers for macrophages, smooth muscle cells and fibroblasts. The spindle-shaped PLEC grew in swirling patterns similar to that described for venous placental endothelial cells. However, scanning electron microscopic examination clearly showed that PLEC remained elongated at the confluent state, in contrast to the more polygonal phenotype of HPEC-A2 and HUVEC that were studied in parallel. The amount of vasoactive substances (endothelin-1,2, thromboxane, angiotensin II, prostacyclin) released into the culture medium and the proliferative response to cytokines was more similar to human dermal microvessels (MIEC) derived from non-fetal tissue than to HUVEC. Potent mitogens such as vascular endothelial growth factors (VEGF121, VEGF165) and basic fibroblast growth factor (FGF-2) induced proliferation of all endothelial cell types. Placental growth factors PIGF-1 and PIGF-2 effectively stimulated cell proliferation on PLEC (142 +/- 7% and 173 +/- 10%) and MIEC (160 +/- 20% and 143 +/- 28%) in contrast to HUVEC (9 +/- 8% and 15 +/- 20%) and HPEC-A2 (15 +/- 7% and 24 +/- 6%) after 48 h incubation time under serum-free conditions. These data support evidence for (1) the microvascular identity of the isolated PLEC described in this study, and (2) the phenotypic and physiologic heterogeneity of micro- and macrovascular endothelial cells within one human organ.     

Primary culture of microvascular endothelial cells from bovine retina

Summary To provide an in vitro system for studying retinal capillary function we have developed methods for isolation and culture of microvascular endothelial cells from retina. Retinal microvessels were isolated by homogenization of the retina and collection of the microvessels onto nylon mesh. Treatment of the isolated microvessels with collagenase and dispase followed by Percoll gradient centrifugation yielded endothelial cells that were largely free of pericytes. A homogeneous population of endothelial cells that were capable of at least six population doublings was obtained by plating onto a fibronectin coated substrate in plasma derived serum. The endothelial origin of these cells was confirmed by the presence of Factor VIII antigen, angiotensin converting enzyme activity, numerous tight junctions, and a cell surface that did not bind platelets. A second cell type, which did not exhibit these cell markers and which is presumably the intramural pericyte, was obtained when the isolated microvessels were plated on tissue culture grade plastic in fetal bovine serum. Supported by Research Grants 5R01-EY03772 and 5R01-ES02380 from the U.S. Public Health Service (G. W. G.) and Established Investigator Award 31-107 from the American Heart Association (A. L. B.).     

Isolation and characterization of microvessel endothelial cells from human mammary adipose tissue

Summary A method for the isolation and long-term culture of human microvessel endothelial cells from mammary adipose tissue (HuMMEC) obtained at breast reduction surgery has been developed. Pure cultures of HuMMEC were isolated by sequential digestion of the fat with collagenase and trypsin followed by specific selection of microvessel fragments withUlex europaeus agglutinin-1 coated magnetic beads (Dynabeads). The resulting cells formed contact-inhibited monolayers on gelatin and fibronectin substrates and capillary-like “tubes” on Matrigel; they also expressed von Willebrand factor, angiotensin-converting enzyme, and accumulated acetylated low density lipoprotein. Further immunofluorescence characterization revealed the presence of antigens for the endothelial cell specific monoclonal antibodies EN4 and H4-7/33. In addition, the origin of these cells was confirmed by the demonstration of the cell adhesion molecules, platelet endothelial cell adhesion molecule-1 (CD31), and endothelial leukocyte adhesion molecule-1 (ELAM-1/E-selectin) upon stimulation with tumor necrosis factor (TNF)α. HuMMEC were found to express-1 ELAM-1 at lower levels of TNFα (<10 ng/ml) than required by human umbilical vein endothelial cells. These cells should provide a useful in vitro model for studying various aspects of microvascular biology and pathology.     

Proteolytic activity of first trimester human placenta: localization of interstitial collagenase in villous and extravillous trophoblast

Summary In human placentation, events of implantation and early blastocyst development are mediated by fetal trophoblastic cells which penetrate into the maternal endometrium and myometrium. Although highly regulated in its biological behavior, trophoblast simulates a malignant neoplasm by virtue of invading the uterine wall and uterine spiral arteries and by embolizing throughout the systemic circulation. This process is at least in part dependant on the regulated production of proteolytic enzymes to degrade extracellular matrix. The most abundant extracellular protein is connective tissue type (interstitial) collagen. The uterine remodeling during the establishment of the embryo requires collagenase which catalyzes the intial step in the breakdown of collagen. This study demonstrates the presence of interstitial collagenase in villous and extravillous trophoblast of first trimester placenta using immunocytochemical methods on light microscopic and ultrastructural levels. Intracytoplasmic staining for interstitial collagenase was present in cyto- and syncytiotrophoblast covering the chorionic villi as well as in extravillous intermediate trophoblast invading spiral arteries in the placental bed. Furthermore, outgrowth cultures of chorionic villi were studied with the immunogold method. Gold labelling was associated with the cell surface of trophoblastic cells as well as with fibrillary collagen like proteins of newly synthesized extracellular matrix. We speculate that interstitial collagenase plays a role in the degradation of uterine collagen within the developing human placenta.     

Proteolytic activity of first trimester human placenta: localization of interstitial collagenase in villous and extravillous trophoblast

In human placentation, events of implantation and early blastocyst development are mediated by fetal trophoblastic cells which penetrate into the maternal endometrium and myometrium. Although highly regulated in its biological behavior, trophoblast simulates a malignant neoplasm by virtue of invading the uterine wall and uterine spiral arteries and by embolizing throughout the systemic circulation. This process is at least in part dependant on the regulated production of proteolytic enzymes to degrade extracellular matrix. The most abundant extracellular protein is connective tissue type (interstitial) collagen. The uterine remodeling during the establishment of the embryo requires collagenase which catalyzes the initial step in the breakdown of collagen. This study demonstrates the presence of interstitial collagenase in villous and extravillous trophoblast of first trimester placenta using immunocytochemical methods on light microscopic and ultrastructural levels. Intracytoplasmic staining for interstitial collagenase was present in cyto- and syncytiotrophoblast covering the chorionic villi as well as in extravillous intermediate trophoblast invading spiral arteries in the placental bed. Furthermore, outgrowth cultures of chorionic villi were studied with the immunogold method. Gold labelling was associated with the cell surface of trophoblastic cells as well as with fibrillary collagen like proteins of newly synthesized extracellular matrix. We speculate that interstitial collagenase plays a role in the degradation of uterine collagen within the developing human placenta.     

Use of collagenase from the hepatopancreas of the Kamchatka crab for isolating and culturing endothelial cells of the large vessels in man

The application of hepatopancreas collagenase from crab Paralithodes camtschatica for the isolation and cultivation of the endothelial cells was studied in human umbilical vein endothelium. The comparison of the enzyme from crab hepatopancreas with collagenase from Clostridium histoliticum has shown that the number of viable cells isolated from human umbilical vein by the crab enzyme was lower than in the case of microbial collagenase. However, this difference was not significant for subsequent cultivation of cells. Harvesting of the endothelial cells from the substrate during cultivation was more effective in the case when collagenase from crab hepatopancreas was used. It was shown that crab collagenase, in contrast with microbiological collagenase, was not a metal-dependent enzyme.     

Subcellular location of a soluble factor that stimulates DNA replication in permeable animal cells

The enzymatic isolation of cells with bacterial collagenase has proved to be a powerful technique for the study of a wide variety of tissues. Unfortunately, for some applications such as the isolation of cells from membranous bone, the cellular damage that results from the exposure of the cells to cytotoxic contaminants of bacterial collagenase has limited the usefulness of this approach. The use of chromatographically purified collagenase alone is often ineffective or very slow to release cells from tissue. We have found that two enzymes are necessary and sufficient to isolate cells from neonatal mouse calvaria: purified collagenase and neutral protease. These two enzymes can be chromatographically purified on a preparative scale to yield 100 mg amounts of each enzyme. The purified enzymes can be recombined in amounts which will digest calvaria at the same rate as the crude bacterial collagenase from which they were derived. The cells that are isolated using the purified enzymes are undamaged, as indicated by the measurement of their equilibrium density on gradients of Ficoll and sodium metrizoate. Cells isolated with crude collagenase never reach an equilibrium density upon isopyknic centrifugation, whereas cells isolated with the purified enzymes reach an equilibrium density of 1.074 g/ml in 90 min.     

Isolation and characterization of Kupffer and endothelial cells from the rat liver

Non-parenchymal cell suspensions were prepared from rat livers by three different methods based on a collagenase, a pronase and a combined collagenase-pronase treatment. The highest yield of Kupffer and endothelial cells was obtained with the pronase treatment. Attempts were made for a further purification of these cells by Metrizamide density gradient centrifugation after preferentially loading lysosomal structures in Kupffer cells with Triton WR 1339, Jectofer^®, Neosilvol^®, Zymosan or colloidal carbon. After loading with Triton WR 1339 or Jectofer^®, highly purified endothelial cell suspensions were obtained, but the final Kupffer cell preparations were contaminated with about 20% of endothelial cells. Kupffer and endothelial cells purified in this way showed an altered ultrastructure and contained increased activities of the lysosomal enzymes acid phosphatase, arylsulphatase B and cathepsin D. As an alternative procedure for the purification of Kupffer and endothelial cells, a method based on centrifugal elutriation was employed. With this procedure, highly purified preparations of Kupffer or endothelial cells with a well preserved ultrastructure were obtained. Compared with endothelial cells, purified Kupffer cells had a three times higher cathepsin D activity, whereas the arylsulphatase B activity was three times higher in endothelial cells. The high cathepsin D activity in Kupffer cells could be nearly completely inhibited by the specific cathepsin D inhibitor pepstatin, which excludes a possible contribution to this activity by proteases endocytosed during the isolation of the cells.     

Actin cytoskeletal isoforms in human endothelial cellsin vitro: Alteration with cell passage

Summary The microfilamentous actin component of the cytoskeleton is crucial to endothelial angiogenesis and vascular permeability. Differences in actin cytoskeletal profiles in cultured human endothelial cells were explored: when first isolated, both primary human umbilical vein endothelial cells (HUVEC) and primary human placental microvascular endothelial cells (HPMEC) expressed F-actin, but notβ-actin orα-smooth muscle actin. A similar endothelial actin profile was observed in cryo-sections of freshly delivered term umbilical cord and placenta. In subsequent cell culture, although the actin cytoskeleton of HUVEC remained unchanged, the actin profiles of HPMEC altered after the second passage with the induction ofα-smooth muscle actin expression, which was intercellularly heterogeneous and increased to 20% at P4. This behavior occurred in HPMEC monolayers cultured on a variety of extracellular matrices. Comparisons with a spontaneously immortalized human microvascular cell-line, HGTEN 21, revealed that inprolonged passage, bothα-smooth muscle actin andβ-actin were expressed, whereas HPMEC at P4 showed a lower level ofβ-actin expression. Therefore, in comparison with large vessels, microvascular cells are more likely to dedifferentiate. This may reflect the ability of microvascular cells to remodel according to changing requirement for new vessel formation. In conclusion, passage of human microvascular endothelial cells, but not of larger vessel endothelial cells, alters the expression of actin isoforms. This may be important in relation to comparisons ofin vitro andin vivo vascular permeability; higher passage microvascular endothelial cells should thus be used with caution in such studies.     

Isolation and expansion of high yield of pure mesenchymal stromal cells from fresh and cryopreserved placental tissues

The injection of placental stromal cells isolated from fetal human tissues (f-hPSC) was reported to indirectly induce tissue regeneration in different animal models. A procedure of f-hPSC isolation from fragments of both selected fresh or cryopreserved bulk placental neonate tissues is proposed, based on their high migratory potential,. The fragments of the desired fetal placental tissues are adhered to a culture dish by traces of diluted fibrin and covered with culture medium. Spontaneous migration of pure f-hPSC from the tissue fragments to the cell culture dishes is followed by their rapid expansion by numerous passages. The isolated f-hPSC express typical mesenchymal surface antigens, including CD29, CD105, CD166 and CD146, with negative expression of white blood cell lineage and endothelial cells markers. Optimal yields of f-hPSC cultures can also be obtained from tissue samples cryopreserved in medium composed of 10% dimethyl sulfoxide (M₂SO) and 50% fetal calf serum. Slightly better yields are obtained with media supplemented with 1% human albumin. Medium with 5% M₂SO and/or 0.25 mg/ml PEG yielded inferior results. The f-hPSC from fresh or cryopreserved tissues express similar cell markers and growth kinetics. The proposed isolation protocol may also be applied for high yield isolation of stromal cells from fresh and cryopreserved tissue of other organs.     

Proteinases from invasive larvae of the trematode parasite Schistosoma mansoni degrade connective-tissue and basement-membrane macromolecules.

Larvae of the human parasite Schistosoma mansoni, which invade the vascular system through the skin, secrete proteinases that degrade radioactively labeled extracellular matrices produced by smooth-muscle cells, dermal fibroblasts and endothelial cells. The proteinase purified from one larval form, the cercaria, degrades fibronectin and laminin and is a type-specific collagenase with activity against basement-membrane collagens IV and VIII, but not interstitial collagens I, III and V. The substrate specificity of this enzyme resembles that of the proteolytic enzymes which facilitate tissue invasion by inflammatory cells and tumour cells.     

Isolation and properties in culture of human adrenal capillary endothelial cells

The isolation of human adrenal capillary endothelial (HACE) cells without resort to fluorescence activated cell sorting is described, together with their properties in culture. HACE cells were isolated by plating collagenase digests at high dilution in the presence of endothelial cell growth supplement, followed by clonal selection of endothelial colonies. HACE cells exhibit a typical endothelial 'cobblestone' morphology at confluence and formed 'tubes' when seeded onto 'Matrigel'. They are positive for human MHC1, and the endothelial markers ENDOCAM (CD31) and weakly CD34, they also take up dil-acetyl low density lipoprotein but are negative for Factor VIII. Their growth is strongly stimulated by FGF and inhibited by TGF-beta I. Like their much studied bovine counterparts they are robust in culture, retaining the properties described up to senescence. HACE cells provide a readily available alternative to human umbilical vein endothelial cells in that they are easily isolated pure and in quantity. They should be particularly useful in studies where human capillary, as opposed to large vessel endothelium, is required.     

Preparation of isolated liver endothelial cells and Kupffer cells in high yield by means of an enterotoxin

A new method for preparing non-parenchymal rat liver cells (NPC) is described. The liver cell suspension, prepared by perfusing the liver with collagenase, was treated with enterotoxin from Clostridium perfringens for 15 min. The enterotoxin made the parenchymal cells leaky, and these cells could be separated from the NPC by centrifugation in a solution containing Nycodenz (20%, w/v). During the centrifugation, the NPC floated, while the parenchymal cells sedimented. The yield of NPC per liver (200 g rat) was about 250 X 10(6) cells. The NPC were further separated into endothelial cells, Kupffer cells and stellate cells by centrifugal elutriation. This method was particularly useful for preparing endothelial cells in high yield (100 X 10(6) cells per liver). Intravenously injected formaldehyde-treated albumin was selectively taken up by the endothelial cells. Isolated endothelial cells in suspension as well as in surface culture maintained their ability to endocytose this ligand.     

Simultaneous isolation of vascular endothelial cells and mesenchymal stem cells from the human umbilical cord

The umbilical cord represents the link between mother and fetus during pregnancy. This cord is usually discarded as a biological waste after the child’s birth; however, its importance as a “store house” of stem cells has been explored recently. We developed a method of simultaneous isolation of endothelial cells (ECs) from the vein and mesenchymal stem cells from umbilical cord Wharton’s jelly of the same cord. The isolation protocol has been simplified, modified, and improvised with respect to choice of enzyme and enzyme mixture, digestion time, cell yield, cell growth, and culture medium. Isolated human umbilical vascular ECs (hUVECs) were positive for von-Willibrand factor, a classical endothelial marker, and could form capillary-like structures when seeded on Matrigel, thus proving their functionality. The isolated human umbilical cord mesenchymal stem cells (hUCMSCs) were found positive for CD44, CD90, CD 73, and CD117 and were found negative for CD33, CD34, CD45, and CD105 surface markers; they were also positive for cytoskeleton markers of smooth muscle actin and vimentin. The hUCMSCs showed multilineage differentiation potential and differentiated into adipogenic, chondrogenic, osteogenic, and neuronal lineages under influence of lineage specific differentiation medium. Thus, isolating endothelial cells as well as mesenchymal cells from the same umbilical cord could lead to complete utilization of the available tissue for the tissue engineering and cell therapy.     

Three specific antigens to isolate endothelial progenitor cells from human liposuction material

Background aimsHuman endothelial progenitor cells (EPC) play an important role in regenerative medicine and contribute to neovascularization on vessel injury. They are usually enriched from peripheral blood, cord blood and bone marrow. In human fat tissue, EPC are rare and their isolation remains a challenge.MethodsFat tissue was prepared by collagenase digestion, and the expression of specific marker proteins was evaluated by flow cytometry in the stromal vascular fraction (SVF). For enrichment, magnetic cell sorting was performed with the use of CD133 microbeads and EPC were cultured until colonies appeared. A second purification was performed with CD34; additional isolation steps were performed with the use of a combination of CD34 and CD31 microbeads. Enriched cells were investigated by flow cytometry for the expression of endothelial specific markers, by Matrigel assay and by the uptake of acetylated low-density lipoprotein.ResultsThe expression pattern confirmed the heterogeneous nature of the SVF, with rare numbers of CD133+ detectable. EPC gained from the SVF by magnetic enrichment showed cobblestone morphology of outgrowth endothelial cells and expressed the specific markers CD31, CD144, vascular endothelial growth factor (VEGF)R2, CD146, CD73 and CD105. Functional integrity was confirmed by uptake of acetylated low-density lipoprotein and the formation of tube-like structures on Matrigel.ConclusionsRare EPC can be enriched from human fat tissue by magnetic cell sorting with the use of a combination of microbeads directed against CD133, an early EPC marker, CD34, a stem cell marker, and CD31, a typical marker for endothelial cells. In culture, they differentiate into EC and hence could have the potential to contribute to neovascularization in regenerative medicine.