Method for kinetic analysis of drug-induced cell cycle perturbations.

A method is described for quantitative study of the flux of cells through the cell cycle phases in in vitro systems perturbed by chemicals, such as chemotherapeutic agents. The method utilizes cell count and the flow cytometric technique of bromodeoxyuridine (BrdUrd) labeling, according to an optimized strategy. Cells are exposed to BrdUrd during the last minutes of drug treatment and fixed for analysis at 0, 1/3Ts, 2/3Ts, Ts, and Tc + TG1 recovery times, where Ts, TG1, Tc are the mean durations of phases S and G1 and of the whole cycle of control cells. As an example of application of the proposed procedure, a kinetic study of the effect of 1-(2-chloroethyl)-1-nitrosourea (CNU) on the L1210 cell cycle is described. Simple data analysis, requiring only a pocket calculator, showed that cells in phases G1 and G2M at the end of a 1 h treatment with 1 microgram/ml CNU were fully able to leave these phases but were destined to remain blocked in the following G2M phase (G1 for a minority of them). We also found that cells initially in S phase were slightly delayed in completing their S phase and that 50% of them remained temporarily blocked in the subsequent G2M phase, irrespective of their position in the S phase.     

A new method to discriminate G1, S, G2, M, and G1 postmitotic cells

A new flow cytometric method combining light scattering measurements, detection of bromodeoxyuridine (BrdU) incorporation via fluorescent antibody, and quantitation of cellular DNA content by propidium iodide (PI) allows identification of additional compartments in the cell cycle. Thus, while cell staining with BrdU-antibodies and PI reveals the G1, S, and G2 + M phases of the cell cycle, differences in light scattering allow separation of G2 phase cells from M phase cells and subdivision of G1 phase into two compartments, i.e., G1A representing postmitotic cells which mature to G1B cells ready to initiate DNA synthesis. The method involves fixation of cells in 70% ethanol, extraction of histones with HC1, and thermal denaturation of DNA. This treatment appears to enhance the differences in chromatin structure of cells in the various phases of the cell cycle to the extent that cells could be separated on the basis of the 90 degrees scatter. Mitotic cells show much lower scatter than G2 phase cells, and G1 postmitotic cells (G1A) show lower scatter than G1 cells about to enter the S phase (G1B). Light scattering is correlated with chromatin condensation, as judged by microscopic evaluation of cells sorted on the basis of light scatter. The method has the advantage over the parental BrdU/DNA bivariate analysis in allowing the G2 and M phases of the cell cycle to be separated and the G1 phase to be analyzed in more detail. The method may also allow separation of unlabeled S phase cells from mitotic cells and distinguish between labeled and unlabeled mitotic cells.     

Analysis of cell kinetics using BrdU monoclonal antibody on cultured tumor cells after irradiation and treatment with anti-cancer drugs

Flow cytometry (FCM) permits instantaneous determination of the percentages of cells in various phases of cell cycle using BrdU-PI double staining method, and allowing rapid evaluation of the effects of irradiation and anti-cancer drugs (ACNU, ADR, BLM) on the cell kinetics. In this study, the growth inhibition and changes in the cell kinetics after irradiation and chemotherapy were examined according to the growth curve analysis and BrdU-PI method to evaluate the usefulness of BrdU-PI method for assessment of the effect of the treatments. By the conventional method based on the DNA histogram, accurate determination of S cell fraction was difficult due to overlapping of the DNA contents of G1 cells and early S cells and those of late S cells and G2 cells. BrdU-PI double staining allowed direct differentiation of G1, S, and G2 + M cells, especially between G1-S and S-G2 + M cells. The analysis of cell kinetics using BrdU is advantageous in comparison to the conventional autoradiographic methods because it allows more rapid assay with very high sensitivity. By the present BrdU method, rapid transition to the G1-S phase was observed within 4 hours after exposure to radiation and anti-cancer drugs. This initial G1 arrest induced by irradiation was confirmed for the first time by the present BrdU-PI double staining. The present method is considered to be indispensable for evaluation of the percentage of S cells in the tumor tissue and analysis of cell kinetics after irradiation and chemotherapy against cancer.     

Measurement of c-myc protein content and cell cycle kinetics of normal and spontaneously transformed murine mastocytes by bivariate flow cytometry

Progressive in vitro culturing of interleukin-3 (IL-3) dependent normal murine mastocytes (PB-3) resulted in a variant cell line (PB-1) able to grow without exogenous IL-3 and which was tumorogenic in syngenic mice. Bivariate flow cytometry was used to evaluate the c-myc protein and DNA content of PB-3 and PB-1 cells. The c-myc protein was detected by specific monoclonal antibodies. Kinetic characteristics of PB-3 and PB-1 cell lines, namely, the duration of the G1, S and G2 + M cell cycle phases were also evaluated using the bromodeoxyuridine (BrdU) pulse-chase method and BrdU/DNA flow cytometry. Levels of c-myc protein in PB-1 cells were about two-fold higher than those of PB-3 cells in all cell cycle phases. Mean duration of the cell cycle (Tc) was 15.3 h for PB-3 cells and 12.4 h for PB-1 cells. Shortening in Tc for the transformed cells was due to a decrease of nearly 30% in mean duration of the G1 phase (from 8 h to 5.7 h). No significant differences were found in the duration of the S and G2 + M phases. These results indicate that acquired IL-3 independency in vitro and tumorogenicity of PB-1 cells were accompanied by a doubling of c-myc protein level and by a parallel shortening, or bypass, of the regulatory events within the G1 phase of the cell cycle.     

RNA dependence in the cell cycle of V79 cells

The cell cycle of V79 Chinese hamster lung cells synchronized by hydroxyurea was investigated by flow cytometry. The metachromatic fluorochrome acridine orange was used to differentially stain DNA and RNA of V79 cells. Green and red fluorescence from individual cells, representing cellular DNA and RNA, respectively, was measured by flow cytometry. Periodic changes of cellular DNA and RNA contents were observed over nine cell cycles. The duration of G1, S, and G2 + M phases of synchronized V79 cells whose RNA content was close to that of the cells in balanced growth was 3, 4.5, and 1.5 hours, respectively. The duration of G1 and S phases of cells containing RNA above a certain threshold was inversely proportional to the RNA content. The RNA content of cells containing RNA above the normal level regressed to normal after a few generations. Coefficients of variation for RNA content were significantly larger than those for DNA. An explanation for the decay of synchrony in a synchronized cell population is proposed.     

Cell cycle perturbation of cultured C6 glioma cells following short-term contact with a low dose of ACNU

The purpose of this study was to investigate the cell cycle perturbation of cultured C6 rat glioma cells induced by 1-(4-amino-2-methyl-5-pyrimidyl)methyl-3-(2-chloroethyl)3-nitrosourea hydrochloride (ACNU) using simultaneous flow cytometric measurements of DNA and bromodeoxyuridine (BrdU) content. A new graphic computer program permitted the quantification of cell density in hexagonal subareas and allowed the fraction of BrdU-labeled cells with mid-S phase DNA content (FLS) to be defined in a narrow window. The cell kinetic parameters such as cell cycle time (Tc) and S phase time (Ts) were estimated from a manually plotted FLS curve at 18 and 6 hr, respectively. The major effect of ACNU on the cell cycle was an accumulation of the cells in the G2M phase 12 to 24 hr posttreatment when compared to G2M traverse of untreated cells. For the two-dimensional analysis, cells were labeled with BrdU and then treated with ACNU, or treated with ACNU and then labeled with BrdU. It was concluded that the cells in the S and G2M phases at the time of ACNU administration progressed to mitosis but that the G1 phase cells accumulated in the subsequent G2M phase. Two-dimensional FCM analysis using BrdU provided a useful tool in studying cell cycle perturbation.     

Analysis of simian virus 40 infection of CV-1 cells by quantitative two-color fluorescence with flow cytometry

Quantitative two-color fluorescent analysis of Simian virus (SV40) infection of permissive CV-1 cells was investigated. Analysis included by quantitation of cellular DNA, the early viral tumor (T) antigen with a monoclonal antibody, and late viral (V) antigens with a polyclonal antibody. T antigen was detected in all phases of the cell cycle at 6 and 12 h, after SV40 infection of growth arrested cells. At later time intervals, the percentage of T-antigen-positive cells increased with the induction of the cells into successive rounds of DNA synthesis and an increase in tetraploid-polyploid cells. The amount of T antigen per cell increased as the cells entered the successive stages of the cell cycle (G0/G1----G2 + M----tetraploid S and G2 + M). The V antigen from adsorbed virus was detected immediately after infection. Synthesis of V antigen began in late S and G2 + M phases of the cell cycle. This quantitative analysis allows a definitive determination of antigen per cell in a population correlated with the cell cycle and may be useful in correlating viral and cellular events with transformation.     

Self-renewal of human embryonic stem cells is supported by a shortened G1 cell cycle phase

Competency for self-renewal of human embryonic stem (ES) cells is linked to pluripotency. However, there is a critical paucity of fundamental parameters of human ES cell division. In this study we show that human ES cells (H1 and H9; NIH-designated WA01 and WA09) rapidly proliferate due to a very short overall cell cycle (15-16 h) compared to somatic cells (e.g., normal diploid IMR90 fibroblasts and NT-2 teratocarcinoma cells). The human ES cell cycle maintains the four canonical cell cycle stages G1, S, G2, and M, but the duration of G1 is dramatically shortened. Bromodeoxyuridine (BrdU) incorporation and FACS analysis demonstrated that 65% of asynchronously growing human ES cells are in S phase. Immunofluorescence microscopy studies detecting BrdU labeled mitotic chromosomes, Ki67 domains, and p220(NPAT) containing Cajal bodies revealed that the durations of the S ( approximately 8 h), G2 ( approximately 4 h), and M phases ( approximately 1 h) are similar in ES and somatic cells. We determined that human ES cells remain viable after synchronization with either nocodazole or the anti-tumor drug Paclitaxel (taxol) and have an abbreviated G1 phase of only 2.5-3 h that is significantly shorter than in somatic cells. Molecular analyses using quantitative RT-PCR demonstrate that human ES cells and somatic cells express similar cell cycle markers. However, among cyclins and cyclin-dependent kinases (CDKs), we observed high mRNA levels for the G1-related CDK4 and cyclin D2 genes. We conclude that human ES cells exhibit unique G1 cell cycle kinetics and use CDK4/cyclin D2 related mechanisms to attain competency for DNA replication.     

Measurement of c-myc protein content and cell cycle kinetics of normal and spontaneously transformed murine mastocytes by bivariate flow cytometry

Abstract. Progressive in vitro culturing of interleukin-3 (IL-3) dependent normal murine mastocytes (PB-3) resulted in a variant cell line (PB-1) able to grow without exogenous IL-3 and which was tumorogenic in syngenic mice. Bivariate flow cytometry was used to evaluate the c-myc protein and DNA content of PB-3 and PB-1 cells. The c-myc protein was detected by specific monoclonal antibodies. Kinetic characteristics of PB-3 and PB-1 cell lines, namely, the duration of the G¹, S and G₂+ M cell cycle phases were also evaluated using the bromodeoxyuridine (BrdU) pulse-chase method and BrdU/DNA flow cytometry. Levels of c-myc protein in PB-1 cells were about twofold higher than those of PB-3 cells in all cell cycle phases. Mean duration of the cell cycle ( T _c) was 15-3 h for PB-3 cells and 12-4 h for PB-1 cells. Shortening in T _c for the transformed cells was due to a decrease of nearly 30% in mean duration of the G ₁ phase (from 8 h to 5.7 h). No significant differences were found in the duration of the S and G₂+ M phases. These results indicate that acquired IL-3 independency in vitro and tumorogenicity of PB-1 cells were accompanied by a doubling of c-myc protein level and by a parallel shortening, or bypass, of the regulatory events within the G¹ phase of the cell cycle.     

cAMP-mediated growth inhibition of a B-lymphoid precursor cell line Reh is associated with an early transient delay in G2/M, followed by an accumulation of cells in G1

This study was undertaken to gain more insight into the effects of cyclic adenosine monophosphate (cAMP) on cell-cycle progression in the B-lymphoid precursor cell line Reh. The adenylate cyclase activator forskolin reduced the proliferation of asynchronously growing Reh cells by 50% after 72 hr culture. Growth inhibition was associated with an accumulation of cells in G1. Furthermore, we demonstrated that forskolin provoked a delay of cells for approximately 10 hr in G2/M prior to the G1 arrest. Two different methods were applied to elucidate how cells in different phases of the cell cycle were affected by an elevated cAMP level. One method was based on centrifugal elutriation, whereby synchronous cell populations from the different phases of the cell cycle were isolated. By the other method, S-phase cells were selectively stained by pulsing asynchronously growing cells with bromo-deoxyuridine (BrdU). The data demonstrate that the position of a cell in the cell cycle is critical in determining how the cell will respond to an elevated cAMP level. Thus cells in G1 at the time forskolin is added are not delayed in G2/M, but they will subsequently accumulate in G1 after 48 hr. Cells given forskolin in G2/m, however, are delayed for 10 hr in G2/M, but they do not accumulate in G1. Cells given forskolin in the S phase are delayed in G2/M as well as arrested in G1. The results suggest that cAMP inhibits growth of the Reh cells by preventing the cells from passing important restriction points located in the G1 and G2 phases of the cell cycle.     

Flow cytometry after bromodeoxyuridine labeling to measure S and G2+M phase durations plus doubling times in vitro and in vivo

This protocol describes methods for calculating the proliferative parameters of cell populations. The basis of the technique is to label cells, either in vitro or in vivo, with halogenated thymidine analogs, such as bromodeoxyuridine (BrdU). Bivariate DNA-BrdU flow cytometry is used to analyze the BrdU-labeled and unlabeled cells. The enumeration of specific cohorts of cells that either have or have not divided in the interval between labeling and cell/tissue sampling permits the calculation of the potential doubling time (T(pot)) of the population, plus the durations of DNA synthesis (T(S)) and the G2+M phase (T(G2+M)) of the cell cycle. The method provides information that is not otherwise available, namely inhibition of DNA synthesis and the separate evaluation of cell-cycle effects in BrdU-labeled and unlabeled subpopulations. Ethanol-fixed samples take 1 d to prepare and stain, and reliable parameter estimates might be obtained from measurements made at a single time point after labeling.     

Differences in the Detection of BrdU/EdU Incorporation Assays Alter the Calculation for G1, S,and G2 Phases of the Cell Cycle in Trypanosomatids

Trypanosomatids are the etiologic agents of various infectious diseases in humans. They diverged early during eukaryotic evolution and have attracted attention as peculiar models for evolutionary and comparative studies. Here, we show a meticulous study comparing the incorporation and detection of the thymidine analogs BrdU and EdU in Leishmania amazonensis, Trypanosoma brucei, and Trypanosoma cruzi to monitor their DNA replication. We used BrdU‐ and EdU‐incorporated parasites with the respective standard detection approaches: indirect immunofluorescence to detect BrdU after standard denaturation (2 M HCl) and “click” chemistry to detect EdU. We found a discrepancy between these two thymidine analogs due to the poor detection of BrdU, which is reflected on the estimative of the duration of the cell cycle phases G1, S, and G2. To solve this discrepancy, we increase the exposure of incorporated BrdU using different concentrations of HCl. Using a new value for HCl concentration, we re‐estimated the phases G1, S, G2 + M, and cytokinesis durations, confirming the values found by this approach using EdU. In conclusion, we suggest that the studies using BrdU with standard detection approach, not only in trypanosomatids but also in others cell types, should be reviewed to ensure an accurate estimation of DNA replication monitoring.     

Characteristics of the cell cycle of matrix cells in the mouse embryo during histogenesis of telencephalon

The cell cycle of matrix cells in the telencephalon of the mouse embryo at different stages at day 10, 13, and 17 of gestation was investigated by means of ³H-thymidine autoradiography.The cell cycle time of matrix cells in the day 10 group was found to be 7.0 h, and lengthened linearly with embryonic age. The cell cycle times of day 13 and 17 groups were 15.5 and 26.0 h, respectively.The duration of G1 and S phases also lengthened linearly with embryonic age. The durations of G1 phase were 0.1, 6.8, and 13.8 h, for day 10, 13, and 17 groups, respectively, and those of S phase were 5.1, 6.9, and 10.4 h, for day 10, 13, and 17 groups, respectively. On the other hand, the durations of both G2 and M phases remained unchanged and these were 1.0 and 0.8 h, respectively, throughout the embryonic stages.It was a characteristic of the alteration of the cell cycle of the telencephalon during mouse embryonic life that not only G1 but also S phases lengthened linearly with embryonic age and both G2 and M phases remained constant.     

Cell Cycle Kinetics of Aerated, Hypoxic and Re-Aerated Cells In Vitro Using Flow Cytometric Determination of Cellular Dna and Incorporated Bromodeoxyuridine

Abstract. The effects of extreme hypoxia on cell cycle progression were studied by simultaneous determination of DNA and bromodeoxyuridine (BrdU) contents of individual cells. V79-379A cells were pulse-labelled with BrdU (1 μM, 20 min, 37°C) and then incubated for up to 12 hr in BrdU-free medium under either aerated or extremely hypoxic conditions. After the incubation interval (0-12 hr), the cells were trypsinized and fixed in 50% EtOH. Propidium iodide and a fluorescein-labelled monoclonal antibody to BrdU were then used to quantify DNA content and incorporated BrdU, respectively. Measurements in individual cells were made by simultaneous detection of green and red fluorescence upon excitation at 488 nm using flow cytometry. Bivariate analysis revealed progression of BrdU-labelled cells in aerated cultures out of S phase, into G₂ and cell division, with halving of mean fluorescence, and back into S phase by approximately 9 hr after the BrdU pulse. Hypoxia immediately arrested cells in all phases of the cell cycle. Both the DNA distribution and the bivariate profile of cells that were fixed from 2 to 12 hr after induction of hypoxia were identical to the 0 hr controls. the percent of cells with green fluorescence in a mid-S phase window remained 100% and the mean fluorescence of these cells remained at control (0 hr) levels. This indicates that, under hypoxic conditions, cells were moving neither into nor out of S phase. Cultures that had been hypoxic for 12 hr exhibited an increasing rate of BrdU uptake with time after re-aeration. Re-aerated cells were able to complete or initiate DNA synthesis, but their rates of progression through the cell cycle were markedly reduced. A large fraction of cells appeared unable to divide up to 12 hr following release from hypoxia.     

Spontaneous apoptosis of melanotic and amelanotic melanoma cells in different phases of cell cycle: relation to tumor growth

Since the spontaneous alteration of native melanotic (Ma) into amelanotic (Ab) transplantable melanoma line it has been observed that this alteration is accompanied by the acceleration of growth of Ab line. The aim of the present study was to check and estimate spontaneous apoptosis of cells from cell cycle phases. Cytometric cell cycle analysis was performed by staining cells with propidium iodide (PI). Apoptosis estimated by the TUNEL method, alterations in the plasma membrane structure (annexin V staining), changes in the mitochondrial transmembrane potential--delta psi m (JC-1 staining) showed that amelanotic melanoma cells have decreased ability to undergo spontaneous apoptosis. The obtained results showing that in the native melanotic line about 30% of cells are in S+G2/M phases and that 33% of these cells undergo apoptosis could lead to the conclusion that the slower growth of this melanoma line is the result of lower proliferation activity and higher rate of apoptosis of these tumor cells. The number of cells in S+G2/M phases in amelanotic melanoma line increases up to 40% and only 7% of them undergo apoptosis. This observation seems to suggest that the expansive growth of this melanoma line depends mainly on the decreased ability to undergo spontaneous apoptosis, especially in case of cells from S+G2/M phases. Moreover, the obtained results indicate that alteration of melanotic line into amelanotic one, accompanied by differences in many biological features also concerns basic cell processes such as cell cycle and cell death.     

Differential cell cycle-specificity for chromosomal damage induced by merbarone and etoposide in V79 cells

Merbarone, a topoisomerase II (topo II) inhibitor which, in contrast to etoposide, does not stabilize topo II-DNA cleavable complexes, was previously shown to be a potent clastogen in vitro and in vivo. To investigate the possible mechanisms, we compared the cell cycle-specificity of the clastogenic effects of merbarone and etoposide in V79 cells. Using flow cytometry and BrdU labeling techniques, etoposide was shown to cause a rapid and persistent G2 delay while merbarone was shown to cause a prolonged S-phase followed by a G2 delay. To identify the stages which are susceptible to DNA damage, we performed the micronucleus (MN) assay with synchronized cells or utilized a combination of BrdU pulse labeling and the cytokinesis-blocked MN assay with non-synchronized cells. Treatment of M phase cells with either agent did not result in increased MN formation. Etoposide but not merbarone caused a significant increase in MN when cells were treated during G2 phase. When treated during S-phase, both chemicals induced highly significant increases in MN. However, the relative proportion of MN induced by merbarone was substantially higher than that induced by etoposide. Both chemicals also caused significant increases in MN in cells that were treated during G1 phase. To confirm the observations in the MN assay, first division metaphases were evaluated in the chromosome aberration assay. The chromosomes of cells treated with merbarone and etoposide showed increased frequencies of both chromatid- and chromosome-type of aberrations. Our findings indicate that while etoposide causes DNA damage more evenly throughout the G1, S and G2 phases of the cell cycle, an outcome which may be closely associated with topo II-mediated DNA strand cleavage, merbarone induces DNA breakage primarily during S-phase, an effect which is likely due to the stalling of replication forks by inhibition of topo II activity.     

Cell cycle kinetics of aerated, hypoxic and re-aerated cells in vitro using flow cytometric determination of cellular DNA and incorporated bromodeoxyuridine

The effects of extreme hypoxia on cell cycle progression were studied by simultaneous determination of DNA and bromodeoxyuridine (BrdU) contents of individual cells. V79-379A cells were pulse-labelled with BrdU (1 microM, 20 min, 37 degrees C) and then incubated for up to 12 hr in BrdU-free medium under either aerated or extremely hypoxic conditions. After the incubation interval (0-12 hr), the cells were trypsinized and fixed in 50% EtOH. Propidium iodide and a fluorescein-labelled monoclonal antibody to BrdU were then used to quantify DNA content and incorporated BrdU, respectively. Measurements in individual cells were made by simultaneous detection of green and red fluorescence upon excitation at 488 nm using flow cytometry. Bivariate analysis revealed progression of BrdU-labelled cells in aerated cultures out of S phase, into G2 and cell division, with halving of mean fluorescence, and back into S phase by approximately 9 hr after the BrdU pulse. Hypoxia immediately arrested cells in all phases of the cell cycle. Both the DNA distribution and the bivariate profile of cells that were fixed from 2 to 12 hr after induction of hypoxia were identical to the 0 hr controls. The percent of cells with green fluorescence in a mid-S phase window remained 100% and the mean fluorescence of these cells remained at control (0 hr) levels. This indicates that, under hypoxic conditions, cells were moving neither into nor out of S phase. Cultures that had been hypoxic for 12 hr exhibited an increasing rate of BrdU uptake with time after re-aeration. Re-aerated cells were able to complete or initiate DNA synthesis, but their rates of progression through the cell cycle were markedly reduced. A large fraction of cells appeared unable to divide up to 12 hr following release from hypoxia.     

Cell cycle distributions, growth characteristics, and variation in prolactin and growth hormone production in cultured rat pituitary cells.

Clonal strains of rat pituitary tumour cells (GH3 cells) spontaneously produce and secrete prolactin and growth hormone. Chromosome analysis and DNA ploidy measurements revealed that the GH3 cells in the present study were triploid and had a decreased chromosome number compared to the parent strain. Monolayer cultures of these cells grow exponentially for 6-7 days with a mean doubling time of 54 h. Cell cycle distributions and phase durations were determined by micro-flow fluorometric measurements of cellular DNA content combined with computer calculations. During exponential growth the cell cycle distribution did not change (65.4% cells with a G1 phase DNA content, 24.9% with an S phase DNA content, and 9.7% with a (G2 + M) phase DNA content). Counting of mitoses gave 1.4% cells in M phase. The 3H-Tdr labeling indices were determined by autoradiography, and the results were in good agreement with the number of cells in S phase as calculated by micro-flow fluorometry. The phase durations were: Ts=15.9 h, TG2=6.2 h, TM=1.1 h, and TG1=30.9 h. TS and TM calculated from 3H-Tdr labeled and Colcemid treated cultures gave corresponding results. In plateau phase cultures the number of cells with a G1 DNA content increased to 80% and the number of cells with an S phase DNA content decreased to between 5% and 10%. The specific production of prolactin and growth hormone determined by radioimmunoassay showed two and four-fold increases respectively, during exponential growth. The hormone values decreased to initial or subinitial values (day 2 values) when approaching plateau phase. We conclude: that changes in the cell cycle distribution of the cell population cannot be responsible for the spontaneous alterations in hormone production during growth and that most of the hormone-producing cells must be in the G1 phase.     

Systemic Inflammation Impairs Proliferation of Hippocampal Type 2 Intermediate Precursor Cells

Neurogenesis is a plastic event modulated by external cues. Systemic inflammation decreases neurogenesis in the dentate gyrus (DG) in part through the proliferative restrain of neural precursor cells (NPCs). To evaluate if inflammation affects the cell cycle progression of particular populations of NPCs, we treated young-adult mice with a single i.p. injection of saline or 1 mg/kg LPS. After 7 days, we analysed proliferation of new BrdU+/DCX+ cells through immunohistochemistry. We extracted the hippocampus and performed a neurosphere assay and a flow cytometric analysis to evaluate proliferation and to identify the phase of the cell cycle in specific populations of DG-derived NPCs. We show that the number of BrdU+/DCX+ cells diminishes in the LPS-treated group and that the number of primary neurospheres derived from LPS-injected animals is significantly reduced compared to the saline-injected group. Flow cytometry revealed that inflammation does not affect the total number of Type 1 BLBP+/TBR2? cells, while the total number of Type 2 intermediate precursor cells (IPCs) (TBR2+) from the LPS-treated group was increased. Cell cycle analysis shows a decrease in the total rate of NPCs in phases S, G2 and M in the LPS-treated group. The percentage of Type 1 BLBP+/TBR2? cells in each cell cycle phase was not different between groups, while there was a fewer number of Type 2 TBR2+ cells in S/G2/M phase. These results show that inflammation alters the appropriate cell cycle progression of Type 2 IPCs, which may contribute to the decrease in the birth rate of DG neurons.