The kinetics of chick cell population aging in vitro.

We have examined the kinetics of chick cell population aging in vitro using the percentage of labeled nuclei, the number of colonies formed from a low density inoculum and the number of cells/colony to monitor culture age. The results from these studies showed a gradual age-associated decline in each of the parameters which was first detected early in the culture lifespan and well in advance of changes in total cell number at confluency. Our results also indicated that each of the above parameters, in addition to the calendar time cells had been in culture, could be used to estimate the percentage of lifespan completed by the culture. A comparison of the methods used to estimate the remaining culture lifespan indicated that the percentage of labeled nuclei was the most accurate in describing cell age.     

Statistical optimization of single-cell production from Taxus cuspidata plant cell aggregates

Flow-cytometric characterization of plant cell culture growth and metabolism at the single-cell level is a method superior to traditional culture average measurements for collecting population information. Investigation of culture heterogeneity and production variability by obtaining information about different culture subpopulations is crucial for optimizing bio-processes for enhanced productivity. Obtaining high yields of intact and viable single cells from aggregated plant cell cultures is an enabling criterion for their analysis and isolation using high-throughput flow cytometric methods. The critical parameters affecting the enzymatic isolation of single cells from aggregated Taxus cuspidata plant cell suspensions were optimized using response-surface methodology and factorial central composite design. Using a design of experiments approach, the output response single-cell yield (SCY, percentage of cell clusters containing only a single cell) was optimized. Optimal conditions were defined for the independent parameters cellulase concentration, pectolyase Y-23 concentration, and centrifugation speed to be 0.045% (w/v), 0.7% (w/v), and 1200?×?g, respectively. At these optimal conditions, the model predicted a maximum SCY of 48%. The experimental data exhibited a 72% increase over previously attained values and additionally validated the model predictions. More than 99% of the isolated cells were viable and suitable for rapid analysis through flow cytometry, thus enabling the collection of population information from cells that accurately represent aggregated suspensions. These isolated cells can be further studied to gain insight into both growth and secondary metabolite production, which can be used for bio-process optimization.     

Image analysis of rat satellite cell proliferation in vitro

Myogenic cells were isolated from adult rat skeletal muscles and cultured in vitro. Cell proliferation was analyzed between days 1 and 14. The cell cycle phases were determined by examining Feulgen-stained cultures with a cell image processor. The nuclei were automatically analyzed by calculating 18 parameters relating to the texture and densitometry of chromatin and the shape of each nucleus. Cell cycle phases were characterized (Moustafa and Brugal, 1984). The recognition methods made it possible to analyse the nuclei of the myogenic cell populations which were either involved in each phase of the mitotic cycle, or left out of the cycle after fusion into myotubes.After 3 hr of culture 10% of the cell population was involved in the cell cycle. In the presence of foetal calf serum, this percentage increased until day 3 after plating. At that time, the DNA content of 28.2% of the cell population was higher than 3C, whereas it is 2C in G1 or G0 nuclei; image analysis showed that 42% of these cells were in S or G2 phase. From day 4, the proliferation rate gradually slowed down until day 8. After day 8, when numerous myotubes differentiated, the percentage of S and G2 phase cells had diminished to between 3 and 8%. The percentage of nuclei in G0 increased when the first myotubes differentiated around day 5. Myotube nuclei were largely in G0. When horse serum was added to the culture medium on day 4 to enhance myotube differentiation, significant cell proliferation was observed before cell fusion.These methods of analysis give the first daily pattern of myogenic cell proliferation and fusion in a cell population isolated from adult muscles.     

Analysis of cell cycle activity and population dynamics in heterogeneous plant cell suspensions using flow cytometry

Flow cytometry was used to measure cell cycle parameters in Solanum aviculare plant cell suspensions. Methods for bromodeoxyuridine (BrdU) labeling of plant nuclei were developed so that cell cycle times and the proportion of cells participating in growth could be determined as a function of culture time and conditions. The percentage of cells active in the cell cycle at 25 degrees C decreased from 52% to 19% within 7.6 d of culture; presence of a relatively large proportion of non-active cells was reflected in the results for culture growth. While the maximum specific growth rate of the suspensions at 25 degrees C was 0.34 d-1 (doubling time: 2.0 d), the specific growth rate of active cells was significantly greater at 0.67 d-1, corresponding to a cell cycle time of 1.0 d. A simple model of culture growth based on exponential and linear growth kinetics and the assumption of constant cell cycle time was found to predict with reasonable accuracy the proportion of active cells in the population as a function of time. Reducing the temperature to 17 degrees C lowered the culture growth rate but prolonged the exponential growth phase compared with 25 degrees C; the percentage of cells participating in the cell cycle was also higher. Exposure of plant cells to different agitation intensities in shake flasks had a pronounced effect on the distribution of cells within the cell cycle. The proportion of cells in S phase was 1.8 times higher at a shaker speed of 160 rpm than at 100 rpm, while the frequency of G0 + G1 cells decreased by up to 27%. Because of the significant levels of intraculture heterogeneity in suspended plant cell systems, flow cytometry is of particular value in characterizing culture properties and behavior.     

兔转基因单细胞克隆株的分离培养及其染色体倍性分析

为检测原代二倍体细胞转基因后单细胞克隆的增殖能力及其染色体倍性稳定性,用脂质体介导的转染方法将质粒DNA pEGFP-C1（带有报告基因GFP和Neo^r）导入体外培养的兔胎儿成纤维细胞中,经G418药物筛选后,分离出73个GFP阳性细胞克隆,最后存活13个（18％）,对其中9个克隆的染色体倍性进行分析,结果只有2个（22％）克隆的染色体倍性正常率在75％以上,分别为80％和75％,其余7个克隆的染色体倍性正常率均在70％以上。这表明,当使用转基因单细胞克隆株作为供核细胞产生克隆动物时,单细胞克隆的增殖代数和染色体倍性的稳定性需要进一步研究提高。     

Kinetic analysis of cell population growth during cultivation in vitro.

XL-2 cells (Xenopus laevis) were used for kinetic analysis of cell population growth. The dependence of the time of cell duplication on the percentage of cells in the G0 phase of the cell cycle was studied and described by a mathematical expression. Possible causes of the changes in the ratio between the percentage of cells in the cell cycle and that in the G0 phase were analyzed. These are the decrease in the percentage of cells in the G0 phase due to the increase in the number of dividing cells, their position in the cell islets, the number of nuclei, the relative position of cells in the G0 phase. It was shown that the loss of the free edge by cells during their transition to the second layer of the cell islets without any changes in spreading led to a significant increase in the percentage of cells in the G0 phase. The percentage of cells in the G0 phase increased about five times for multinuclear cells. Analysis of the position of cells in the G0 phase showed that these cells were mostly in groups of two, three or four. Studies of a real cell culture in the logarithmic phase of growth (48-120 h of cultivation) showed that the percentage of cells in the G0 phase did not virtually change and all processes were equalized by one another. We propose a new method to determine the cell cycle duration under conditions from the time of cell culture duplication and the data on the percentage of cells in the G0 phase. This method can be used when traditional approaches using BrdU or [3H]]thymidine are difficult to implement or are unacceptable.     

A serological assay for the detection of cell surface receptors of nerve growth factor

When single-cell suspensions prepared from embroyonic day 8 (E8) chick sensory ganglia are incubated with nerve growth factor (NGF), anti-NGF antiserum, and complement, an NGF-dependent cytotoxic kill of 20 (±3)% of the ganglia cells is observed. This percentage is increased by a factor of two when only the neuronal cells are tested. No kill is observed on the nonneuronal cell population representing 50% of the ganglia dissociate. When E8 sensory ganglia cells are cultured in the presence of NGF following cytotoxic kill, the large, phase-bright NGF-reponsive neurons are missing from the culture. These results indicate that the cells recognized in the cytotoxicity assay have to carry NGF-binding sites of type I, which is the one with the higher affinity of the two types of NGF-binding sites (I and II) present on sensory ganglia cells. This conclusion is further supported by the following data: (a) half maximal cytotoxicity is reached already at a concentration of NGF which is below the K_D of binding site I; (b) a washing step which removes all NGF bound to type II receptors while leaving a high percentage of type I receptors occupied has no effect on the percentage of ganglia cells killed. Using the cytotoxicity assay the presence of high-affinity binding sites of type I can be demonstrated on sensory ganglia cells from E8 chick embryos but not from E4 embryos and not on liver and heart cells from E8 embryos. Further, type I receptor-bearing cells were detectable in the brain using this assay. At E8, NGF receptors could be detected on cells of the forebrain and the tectum but not on brain stem cells. Cytotoxic kill of forebrain cells was found to be especially high at E8 and E9, and decreased by E10.     

Human nerve stem cells in vitro

The growth characteristics of a fraction of the human embryonic brain Nest-positive cells cultivated in vitro are the subject of the study. Our data demonstrate a probable increase in the content of Nest-positive cells in the cell population from 44.1 to 62.5% as a response to the presence of EGF and bFGF in a growth medium supplemented with heat-inactivated serum. Further differentiation in the cell culture led to a decrease in the number of Nest-positive cells. Retinoic acid-based stimulation of neural induction causes a decrease in the content of these cells in the population by 14.1%. The results of this study will allow for the obtaining of a nerve cell population that could be more effective as a graft material suitable for therapeutic use.     

Isolation of autofluorescent ‘aged’ human fibroblasts by flow sorting : Morphology, enzyme activity and proliferative capacity

In cultures of human fibroblasts the percentage of bright autofluorescent (AF) cells increases with increasing passage number. These autofluorescent cells were isolated using a FACS II cell sorter and compared with sorted non-fluorescent (NF) cells. The AF cells showed an increase in population doubling time (2.3-fold), cell protein (1.9-fold), and in specific activities of the lysosomal enzymes: β-hexosaminidase (4.2-fold), β-galactosidase (3.8-fold) and acid phosphatase (2.5-fold). The specific activities of two non-lysosomal enzymes glucose-6-phosphate dehydrogenase and lactate dehydrogenase had increased only slightly (1.1-fold) respectively (1.5-fold).The autofluorescence in the AF cells was restricted to small round organelles. The distribution and size of these autofluorescence granules were similar to the acid phosphatase-containing granules in the cytochemically stained cells. Electronmicroscopical examination showed that these AF cells contained a large amount of small electron-dense granules containing amorphosmophilic material. These granules which were positive for the acid phosphatase reaction, were classified as secondary lysosomes. The low percentage of the sorted AF cells which incorporate [³H]thymidine during a 24 h test period (19%) as compared with the labelling percentage of sorted NF cells (73%) from the same culture, indicate that the autofluorescent cells in a ‘young’ culture have a very limited remaining proliferative capacity. The results imply, that by flow sorting it is possible to isolate ‘aged’ cells with characteristics of ‘phase III’ cells out of non-aged fibroblast cultures.     

Cell population density and phenotypic expression of tissue culture fibroblasts from heterozygotes of Lesch-Nyhan's disease (inosinate pyrophosphorylase deficiency)

Radioautographic examination of skin fibroblasts grown in tissue culture from normal donors revealed heavy labeling of almost all cells following incubation with tritiated hypoxanthine. Cells from patients with Lesch-Nyhan's disease, lacking inosinate pyrophosphorylase, had only 10 grains or less per cell. When normal and abnormal cells were mixed prior to culture, there was a progressive increase, with culture time, in the percentage of heavily labeled cells so that by 96 hr, when the cells were confluent, over 95% of the cells were heavily labeled. Reduction of cell density by subculture produced a reversion to original values. Cultures from three obligatory heterozygotes revealed the expected mixed population of cells. This appears to be a practical approach to the identification of the heterozygote.Aided by USPHS CA08748 and GM15508, and the Health Research Council of the City of New York.     

Proliferative characteristics and chromosomal stability of bovine donor cells for nuclear transfer

Few studies have characterized donor cell lines in terms of proliferative capacity and chromosomal stability. Abnormal phosphorylation patterns of the histones during metaphase could lead to abnormal chromosome segregation and extensive chromosome loss during mitosis. Suboptimal culture conditions may lead to abnormal histone H3 phosphorylation patterns, ultimately inducing missegregation and loss of chromosomes. The objective of the present study was to determine proliferative characteristics, chromosomal stability, and level of histone phosphorylation in cell lines established by explants and enzymatic dissociation. Proliferative characteristics, percentage of aneuploid cells, and relative levels of phosphorylated histone H3 (ser10) were determined at different population doublings (PD) by cell counting, karyotyping, and flow cytometry, respectively. The level of aneuploidies was high and remained elevated throughout the study independent of the technique used to establish the primary culture. Some cell lines had up to 50% of aneuploid cells during early passages. Multinucleated cells and abnormal spindle configurations were observed after prolonged time in culture (60 and 41%, respectively). An increase in the relative level of phosphorylated histone occurred after extended time in culture (55.7 during early passages vs. 102.6 at late passages). These data demonstrate the importance of determining chromosome content and the selection of healthy cell lines to decrease the percentage of aneuploid reconstructed embryos and increase the efficiency of nuclear transfer (NT).     

Influence of plating density on individual cell growth, cell division and differentiation of neonatal rat heart primary cultures

The influence of plating cell density of an originally enriched myocardial cell population has been studied in neonatal rat heart cells in culture. Low density (LDM) is defined as a density (24 h after plating) of 209 +/- 44 cells/mm2 (mean +/- SEM) and is compared with high density (HDM), 419 +/- 67 cells/mm2. Cell growth is evaluated by the total cell number, the percentage of myocardial cells (M) in culture (PAS method) and the protein content per cell. Some differentiation parameters such as beating rates, glycogen concentration, enzymatic activities (cytochrome C oxidase and glycogen phosphorylase) are studied with time in culture (48, 96 and 192 hr). High density was designed to yield a complete confluency of the cells within 24 hr after plating and to minimize cell division of the non-muscle cells (F). At high density, cell division of F cells is effectively limited, thus leading to a more stable model regarding the cell density per plate and the percentage of M cells: 85.7 +/- 4% and 33.4 +/- 6% in LDM cultures compared with 86.5 +/- 4.7% and 51.7 +/- 9.8% in HDM cultures at 24 and 192 hr (mean +/- SEM). Heart cells increase similarly in size with age in culture in both groups. In HDM cultures the spontaneous contractions begin sooner (24 hr) than in LDM cultures and are more rapidly synchronized. The beating rate is higher in HDM cultures between 48 and 96 hr; however, after this time it falls in HDM and does not fall in LDM. Thus the overgrowth of muscle cells by non-muscle cells is not responsible for loss of beating with time in culture but more likely high density could be a limiting factor for isotonic contraction. There is more glycogen per myocyte in LDM than in HDM cultures. The cell density influences the enzymatic activities of cytochrome C oxidase and glycogen phosphorylase. The cytochrome oxidase activity is higher in HDM cultures than in LDM cultures at 96 hr whereas glycogen phosphorylase activity is higher in LDM cultures at time 96 and 192 hr. In LDM cultures, the ratio cytochrome C oxidase/glycogen phosphorylase decreases with time in culture from 1.685 +/- 0.680 at 48 hr to 0.780 +/- 0.290 at 192 hr but not in HDM cultures (2.13 +/- 0.36 and 1.64 +/- 0.34 respectively). Thus plating density influences properties of heart cell cultures with regard to the overgrowth of the F-cell population and the differentiated state of M cells.     

Recombinant adeno-associated virus mediates a high level of gene transfer but less efficient integration in the K562 human hematopoietic cell line.

We tested the ability of a recombinant adeno-associated virus (rAAV) vector to express and integrate exogenous DNA into human hematopoietic cells in the absence of selection. We developed an rAAV vector, AAV-tNGFR, carrying a truncated rat nerve growth factor receptor (tNGFR) cDNA as a cell surface reporter under the control of the Moloney murine leukemia virus (MoMuLV) long terminal repeat. An analogous MoMuLV-based retroviral vector (L-tNGFR) was used in parallel, and gene transfer and expression in human hematopoietic cells were assessed by flow cytometry and DNA analyses. Following gene transfer into K562 cells with AAV-tNGFR at a multiplicity of infection (MOI) of 13 infectious units (IU), 26 to 38% of cells expressed tNGFR on the surface early after transduction, but the proportion of tNGFR expressing cells steadily declined to 3.0 to 3.5% over 1 month of culture. At an MOI of 130 IU, nearly all cells expressed tNGFR immediately posttransduction, but the proportion of cells expressing tNGFR declined to 62% over 2 months of culture. The decline in the proportion of AAV-tNGFR-expressing cells was associated with ongoing losses of vector genomes. In contrast, K562 cells transduced with the retroviral vector L-tNGFR expressed tNGFR in a constant fraction. Integration analyses on clones showed that integration occurred at different sites. Integration frequencies were estimated at about 49% at an MOI of 130 and 2% at an MOI of 1.3. Transduction of primary human CD34+ progenitor cells by AAV-tNGFR was less efficient than with K562 cells and showed a declining percentage of cells expressing tNGFR over 2 weeks of culture. Thus, purified rAAV caused very high gene transfer and expression in human hematopoietic cells early after transduction, which steadily declined during cell passage in the absence of selection. Although the efficiency of integration was low, overall integration was markedly improved at a high MOI. While prolonged episomal persistence may be adequate for gene therapy of nondividing cells, a very high MOI or improvements in basic aspects of AAV-based vectors may be necessary to improve integration frequency in the rapidly dividing hematopoietic cell population.     

Establishment of pure neuronal and muscle precursor cell cultures fromDrosophila early gastrula stage embryos

Summary Primary cultures ofDrosophila gastrula stage embryonic cells will divide and terminally differentiate into morphologically recognizable neurons and muscles. The phenotypically mixed nature of this primary culture system has made it difficult to effectively analyze various parameters of cell growth and differentiation for individual cell types. We report here a simple and economic method to separate early embryonic precursors for different cell types, using a shallow linear reorienting Ficoll gradient at unit gravity. The separated cells were collected into fractions, cultured, and analyzed for their growth and differentiation patterns. The larger and denser cells of the first fractions differentiated to yield pure neuronal cultures, as judged by morphologic, immunologic, and biochemical criteria. Cells in the last fractions differentiated into a predominantly muscle-enriched cell population, which also contained a very small percentage of neurons morphologically distinct from those in the pure neuronal fractions. Approximately 35% of the early gastrula stage embryonic cells differentiate into neuronal cells, and 65% of the non-neuronal lineage cells later develop into predominantly muscle population. The method is highly reproducible, can process 3×10⁷ cells per procedure, and the recovery is >90% of the input cells. The separated cells are suitable for cell biological analyses as well as for biochemical and molecular studies of neuron and muscle precursors. Deceased.     

Differentiation of neuron-like cells in cultured rat optic nerves: a neuron or common neuron-glia progenitor?

The optic nerve consists of axons, glia, and undifferentiated cells; neuronal cell bodies are absent. To study the developmental potential of glia and precursor cells in vitro, we devised an original, long-term culture system of optic nerve explants, called minisegments, of newborn rats; at this stage the nerves are composed of naked axons, astrocytes, and undifferentiated cells. After about 4-5 weeks in culture, neuron-like cells appeared, which showed morphological, fine structural, and immunocytochemical properties ascribed to neurons. These neuron-like cells may be derived from a common neuron-glia progenitor or from a small population of precursors, which never produce glia in situ.     

Varied persistent life cycles of Borna disease virus in a human oligodendroglioma cell line

Borna disease virus (BDV) establishes a persistent infection in the central nervous system of vertebrate animal species as well as in tissue cultures. In an attempt to characterize the life cycle of BDV in persistently infected cultured cells, we developed 30 clones by single-cell cloning from a human oligodendroglioma (OL) cell line after infection with BDV. According to the percentage of cells expressing the BDV major proteins, p40 (nucleoprotein) and p24 (phosphoprotein), the clones were classified into two types: type I (>20%) and type II (<20%). mRNAs corresponding to both proteins were detected by in situ hybridization (ISH) in a percentage of cells consistent with that for the protein expression in the two types. Surprisingly, ISH for the detection of the genomic RNA, mainly in type II, revealed a significantly larger cell population harboring the genomic RNA than that with the protein as well as the mRNA expression. By recloning from type II primary cell clones, the same phenotype was confirmed in the secondary cell clones obtained: i.e., low percentage of protein-positive cells and higher percentage of cells harboring the genomic RNA. After nerve growth factor treatment, the two types of clones showed increases in the percentage of cells expressing BDV-specific proteins that reached 80% in type II clones, in addition to increased expression levels per cell. Such enhancement might have been mediated by the activation of the mitogen-activated protein kinase in the clones as revealed by the detection of activated ERK1/2. Thus, our findings show that BDV may have established a persistent infection at low levels of viral expression in OL cells with the possibility of a latent infection.     

Development of a bioreactor for evaluating novel nerve conduits

We describe an experimental closed bioreactor device for studying novel tissue engineered peripheral nerve conduits in vitro. The system integrates a closed loop system consisting of one, two, or three experimental nerve conduits connected in series or parallel, with the ability to study novel scaffolds within guidance conduits. The system was established using aligned synthetic microfiber scaffolds of viscose rayon and electrospun polystyrene. Schwann cells were seeded directly into conduits varying from 10 to 80 mm in length and allowed to adhere under 0 flow for 1 h, before being cultured for 4 days under static or continuous flow conditions. In situ viability measurements showed the distribution of live Schwann cells within each conduit and enabled quantification thereafter. Under static culture viable cells only existed in short conduit scaffolds (10 mm) or at the ends of longer conduits (20-80 mm) with a variation in viable cell distribution. Surface modification of scaffold fibers with type-1 collagen or acrylic acid increased cell number by 17% and 30%, respectively. However, a continuous medium flow of 0.8 mL/h was found to increase total cell number by 2.5-fold verses static culture. Importantly, under these conditions parallel viability measurements revealed a ninefold increase compared to static culture. Fluorescence microscopy of scaffolds showed cellular adhesion and alignment on the longitudinal axis. We suggest that such a system will enable a rigorous and controlled approach for evaluating novel conduits for peripheral nerve repair, in particular using hydrolysable materials for the parallel organization of nerve support cells, prior to in vivo study.     

Ultrastructural observations on rapid formation of neuro-muscular junctions in vitro

Summary The development of neuro-muscular junctions (mouse, rat) from the time of first contact between neurons and myotubes in culture and the changes which lead to the formation of functional synaptic contacts have been investigated using light microscopy and ultrastructural techniques.An extensive basal lamina was present when the neuronal cell population was added to the developing myotubes in culture. The nerve cells were initially strongly attracted to each other and nerve cell aggregates formed rapidly. It was only when nerve fibres began to grow out of these aggregates to contact developing myotubes that changes within the cytoplasm of the two adjacent cells were observed. These developments included accumulations of filaments, membrane densities, mitochondria and large clear vesicles within both cells in the region of contact. In addition, collections of glycogen granules and an extensive membrane reticular complex were found within myotubes, and an extensive granular material filled many of the nerve processes. The basal lamina within the intercellular space appeared more electron-dense than elsewhere and was traversed by strands linking the two cell membranes. These features all appeared to be stages in the initial formation of neuro-muscular junctions. It was only after these events had occurred that presynaptic vesicles gradually appeared within the future nerve terminal. The results of this paper therefore support the view that synaptic transmission at developing mammalian neuromuscular junctions is not necessarily dependent on the presence of presynaptic vesicles.     

Suspension culture of myocardial cells from newborn rats.

Myocardial cells from newborn rats were held in a spinner type culture for 2 days and then explanted into culture flasks. Three main cell types were observed: single multipolar cells of embryonic type, cell aggregates containing 10 to 50 connected cells, and bipolar cells retaining some adult characteristics. Except for the latter, up to 95% of intact cells settled and were beating 6 hours after explantation. The percentage of fibroblast-like cells was drastically reduced when compared with conventional cultures. Cell debris could be removed 2 hours after explantation by changing the culture medium, or more effectively by a density step centrifugation using Lymphoprep or Lymphoprep-Ficoll mixtures.     

VARIATIONS IN GROWTH AND CELL CYCLE TIME OF ARTERIAL SMOOTH MUSCLE CELLS CULTURED AT LOW DENSITY

The population kinetics of cultured rat arterial smooth muscle cells replated at various low densities were studied by direct counting and observation of the cells. Population doubling time decreases with increasing initial density of the culture. These variations in population doubling times depend on both the variation in the percentage of quiescent cells and on the variation of the mean cell cycle time of non-quiescent cells.