Analysis Of Cell Cycle Status Research Articles

Immunophenotypic analysis of cell cycle status in acute myeloid leukaemia: relationship to cytogenetics, genotype and clinical outcome.

Cell cycle status may play an important role in directing patient therapy. We therefore determined the cell cycle status of leukaemic cells by immunophenotypic analysis of bone marrow trephine biopsies from 181 patients with acute myeloid leukaemia (AML) and correlated the results with biological features and clinical outcome. There was considerable heterogeneity between patients. The presenting white cell count significantly correlated with the proportion of non-quiescent cells (P<0·0001), of cycling cells beyond G1 (P<0·0001) and the speed of cycling (P<0·0001). Profiles in acute promyelocytic leukaemia (APL) differed from non-APL and were consistent with more differentiated cells with reduced proliferative potential, but no significant differences were observed between non-APL cytogenetic risk groups. NPM1 mutations but not FLT3 internal tandem duplication (FLT3ITD ) were significantly associated with a higher proportion of cells beyond G1 (P=0·002) and faster speed of cycling (P=0·003). Resistance to standard cytosine arabinoside and daunorubicin induction chemotherapy was significantly related to a slower speed of cycling (P=0·0002), as was a higher relapse rate (P=0·05), but not with the proportion of non-quiescent cells or actively cycling cells. These results show a link between the cycling speed of AML cells and the response to chemotherapy, and help to identify a group with a very poor prognosis.

Abstract 1670: Radiosensitization of glioma cells by the ketone body β-hydroxybutyrate is associated with enhanced cell cycle arrest in the G2/M phase

Abstract Glioblastoma multiforme (GBM) is an aggressive primary brain tumor with a 5 year survival rate of 25% in children and less than 10% in adults. Improvement in the prognosis of GBM patients requires the development of new therapeutic approaches. One emerging strategy is to target aberrant cell metabolism, a trait shared by virtually all tumor cells. The ketogenic diet (KD), a high fat, low carbohydrate and protein metabolic therapy has been shown to prolong survival in animal glioma models, and when used in conjunction with radiation cured 9 of 11 mice of their implanted tumors. We have also shown that the KD alters hypoxia, angiogenesis, and other hallmarks of glioma progression. To elucidate the underlying mechanisms through which ketones exert their effects on glioma, we are doing analyses of the effect of β-hydroxybutyrate (βHB), the most prevalent ketone body synthesized during ketosis, on glioma cells in vitro. We found that βHB both alone and in conjunction with radiation significantly inhibits proliferation of human and mouse glioma cells and human glioma stem cells (GSC). Alterations in passage through the cell cycle may affect proliferation, and cells are also more sensitive to radiation in the G2/M cell cycle phase. We therefore analyzed the effect of βHB on cell cycle distribution of cells treated with βHB and/or radiation. An analysis of cell cycle status by flow cytometry demonstrated that treating the GSC line L0 with 5mM βHB in combination with 4 Gy of radiation significantly increased the number of cells in G2/M cell cycle arrest. In GL261-Luc2 mouse glioma cells, 5mM βHB alone significantly enhanced G2/M cell cycle arrest, which could lead to radiosensitization. Currently we are analyzing proteins involved in cell cycle progression and apoptosis to better understand βHB mediated changes in growth and radioresistance. In summary, these data provide insight to the radiosensitization and anti-proliferative mechanisms of βHB and may hold implications for the use of the KD in the treatment of GBM. Citation Format: Helena B. Silva-Nichols, Alex P. Rossi, Eric C. Woolf, Marshall J. Fairres, Loic P. Deleyrolle, Brent A. Reynolds, Adrienne C. Scheck. Radiosensitization of glioma cells by the ketone body β-hydroxybutyrate is associated with enhanced cell cycle arrest in the G2/M phase. [abstract]. In: Proceedings of the 107th Annual Meeting of the American Association for Cancer Research; 2016 Apr 16-20; New Orleans, LA. Philadelphia (PA): AACR; Cancer Res 2016;76(14 Suppl):Abstract nr 1670.

Assaying Cell Cycle Status Using Flow Cytometry.

In this unit, two protocols are described for analyzing cell cycle status using flow cytometry. The first is based on the simultaneous analysis of proliferation-specific marker (Ki-67) and cellular DNA content, which discriminate resting/quiescent cell populations (G0 cell) and quantify cell cycle distribution (G1, S, or G2/M), respectively. The second is based on differential staining of DNA and RNA through co-staining of Hoechst 33342 and Pyronin Y, which is also useful to identify G0 cells from G1 cells. Along with these methods for analyzing cell cycle status, two additional methods for cell proliferation assays with recent updates of newly developed fluorophores, which allow multiplex analysis of cell cycle status, cell proliferation, and a gene of interest using flow cytometry, are outlined.

Cytometry in stem cell research and therapy

recent Nobel Prize in medicine was awarded to two stemcell researchers, John Gurdon and Shinya Yamanaka, for theirachievements in stem cell research and reprogramming ofsomatic cells. Flow cytometry is by nature the ideal tool toidentify, characterize, and isolate stem and progenitor cells forresearch and potential clinical use (1). The major strength offlow cytometry is its ability to rapidly perform highlymultiplexed quantitative measurements on single cells withina heterogeneous cell population. However, when the cell typeof interest is extremely rare, as most stem and progenitor cellsare, several sources of artifact must be addressed. The impor-tance of flow cytometry as a driving force for stem cellresearch was demonstrated in a focused issue of the journalexactly three years ago (1). This current focus issue of Cytome-try A is devoted to the topic of stem cells due to numerouscurrent innovations and discoveries.Applications of stem cells include several disciplines,from embryogenesis, adult tissue maintenance, and repair,and more recently, cancer as well as for toxicity screening anddisease modeling. All of these topics are represented in thisissue, with special emphasis on the role of analytic and pre-parative flow cytometry in the elucidation of stem cell pheno-type and function, and best laboratory practices as they applyto flow cytometry. Image and flow cytometry together withcell sorting have revolutionized the study of stem cell biologyand the implications of these cells and their progeny indevelopmental biology, tissue engineering, and cellulartherapy. The number of parameters and the speed of theirsimultaneous measurements in single cells has continued toincrease with advances in hardware, reagents, and analyticalsoftware (2).

Plerixafor (AMD3100) induces prolonged mobilization of acute lymphoblastic leukemia cells and increases the proportion of cycling cells in the blood in mice

The CXCR4 antagonist Plerixafor (AMD3100) induces the rapid mobilization of hematopoietic stem and progenitor cells into the blood in mice and humans. AMD3100 similarly induces the mobilization of human acute lymphoblastic leukemia (ALL) cells into the blood in mice. In this study, the temporal response of pre-B ALL cells to AMD3100 was compared with that of normal hematopoietic progenitor cells (HPC) using an NOD/SCID xenograft model of ALL and BALB/c mice, respectively. ALL cells remained in the circulation up to 6 hours after AMD3100 administration, by which time normal HPCs were no longer detectable. AMD3100 also increased the proportion of actively cycling ALL cells in the peripheral blood. Together, these data suggest that ALL cells are more sensitive to the effects of bone marrow disruption than normal progenitors. Using the NOD/SCID xenograft model, we demonstrated that AMD3100 increased the efficacy of the cell cycle specific drug vincristine, resulting in reduced disease levels in the blood and spleens of animals over 3 weeks and extended the survival of NOD/SCID mice with ALL. These data demonstrate that mobilizing agents can increase the therapeutic effect of cell cycle dependent chemotherapeutic agents.

Flow cytometry analysis of murine hematopoietic stem cells

Hematopoietic stem cells (HSCs) remain the most well-characterized adult stem cell population both in terms of markers for purification and assays to assess functional potential. However, despite over 40 years of research, working with HSCs in the mouse remains challenging because of the relative abundance (or lack thereof) of these cells in the bone marrow. The frequency of HSCs in murine bone marrow is about 0.01% of total nucleated cells and ∼5,000 can be isolated from an individual mouse depending on the age, sex, and strain of mice as well as purification scheme utilized. Adding to the challenge is the continual reporting of new markers for HSC purification, which makes it difficult for the uninitiated in the field to know which purification strategies yield the highest proportion of long-term, multilineage HSCs. In this updated version of our review from 2009, we review different strategies for hematopoietic stem and progenitor cell identification and purification. We will also discuss methods for rapid flow cytometric analysis of peripheral blood cell types, and novel strategies for working with rare cell populations such as HSCs in the analysis of cell cycle status by BrdU, Ki-67, and Pyronin Y staining. The purpose of updating this review is to provide insight into some of the recent experimental and technical advances in mouse hematopoietic stem cell biology.

The Role of Nucleophosmin In Hematopoietic Stem Cells and the Pathogenesis of Myelodysplastic Syndrome

AbstractAbstract 95Myelodysplastic syndrome (MDS) is an incurable stem cell disorder characterized by ineffective hematopoiesis and an increased risk of leukemia transformation. Nucleophosmin (NPM) is directly implicated in primitive hematopoiesis, the pathogenesis of hematopoietic malignancies and more recently of MDS. However, little is known regarding the molecular role and function of NPM in MDS pathogenesis and in stem cell biology. Here we present data demonstrating that NPM plays a critical role in the maintenance of hematopoietic stem cells (HSCs) and the transformation of MDS into leukemia.NPM is located on chromosome 5q and is frequently lost in therapy-related and de novo MDS. We have previously shown that Npm1 acts as a haploinsufficient tumor suppressor in the hematopoietic compartment and Npm1+/− mice develop a hematologic syndrome with features of human MDS, including increased susceptibility to leukemogenesis. As HSCs have been demonstrated to be the target of the primary neoplastic event in MDS, a functional analysis of the HSC compartment is essential to understand the molecular mechanisms in MDS pathogenesis. However, the role of NPM in adult hematopoiesis remains largely unknown as Npm1-deficiency leads to embryonic lethality.To investigate NPM function in adult hematopoiesis, we have generated conditional knockout mice of Npm1, using the Cre-loxP system. Analysis of Npm1 conditional mutants crossed with Mx1-Cre transgenic mice reveals that Npm1 plays a crucial role in adult hematopoiesis and ablation of Npm1 in adult HSCs leads to aberrant cycling and followed by apoptosis. Analysis of cell cycle status revealed that HSCs are impaired in their ability to maintain quiescence after Npm1-deletion and are rapidly depleted in vivo as well as in vitro. Competitive reconstitution assay revealed that Npm1 acts cell-autonomously to maintain HSCs. Conditional inactivation of Npm1 leads to an MDS phenotype including a profoundly impaired ability to differentiate into cells of the erythroid lineage, megakaryocyte dyspoiesis and centrosome amplification. Furthermore, Npm1 loss evokes a p53-dependent response and Npm1-deleted HSCs undergo apoptosis in vivo and in vitro. Strikingly, transfer of the Npm1 mutation into a p53-null background rescued the apoptosis of Npm1-ablated HSCs and resulted in accelerated transformation to an aggressive and lethal form of acute myeloid leukemia. Our findings highlight the crucial role of NPM in stem cell biology and identify a new mechanism by which MDS can progress to leukemia. This has important therapeutic implications for de novo MDS as well as therapy-related MDS, which is known to rapidly evolve to leukemia with frequent loss or mutation of TRP53. Disclosures:No relevant conflicts of interest to declare.

Mouse hematopoietic stem cell identification and analysis

Hematopoietic stem cells (HSCs) remain by far the most well-characterized adult stem cell population both in terms of markers for purification and assays to assess functional potential. However, despite over 40 years of research, working with HSCs in the mouse remains difficult because of the relative abundance (or lack thereof) of these cells in the bone marrow. The frequency of HSCs in bone marrow is about 0.01% of total nucleated cells and approximately 5,000 can be isolated from an individual mouse depending on the age, sex, and strain of mice as well as purification scheme utilized. This prohibits the study of processes in HSCs, which require large amounts of starting material. Adding to the challenge is the continual reporting of new markers for HSC purification, which makes it difficult for the uninitiated in the field to know which purification strategies yield the highest proportion of long-term, multilineage HSCs. This report will review different hematopoietic stem and progenitor purification strategies and compare flow cytometry profiles for HSC sorting and analysis on different instruments. We will also discuss methods for rapid flow cytometric analysis of peripheral blood cell types, and novel strategies for working with rare cell populations such as HSCs in the analysis of cell cycle status by BrdU, Ki-67, and Pyronin Y staining. The purpose of this review is to provide insight into some of the recent experimental and technical advances in mouse hematopoietic stem cell biology.

Immunomodulatory properties of Ascaris suum glycosphingolipids - phosphorylcholine and non-phosphorylcholine-dependent effects.

Immunomodulatory properties of phosphorylcholine (PC)-containing glycosphingolipids from Ascaris suum were investigated utilizing immune cells from BALB/c mice. Proliferation of splenic B cells induced either via F(ab')2 fragments of anti-murine Ig (anti-Ig) or LPS was significantly reduced when the glycosphingolipids were present in the culture medium. However whereas the LPS-mediated effect was dependent on the PC moiety of the glycosphingolipids, the result generated when using anti-Ig was not. Analysis of cell cycle status and mitochondrial potential indicated that the combination of the glycosphingolipids and anti-Ig reduced B cell proliferation, at least in part, by inducing apoptosis. Consistent with the observed suppression of B cell activation/cell cycle progression, investigation of the effect of glycosphingolipid pre-exposure on mitogenic B cell signal transduction pathways activated by anti-Ig, revealed a PC-independent inhibitory effect on dual (thr/tyr) phosphorylation and activation of ErkMAPKinase. The glycosphingolipids were also investigated for their inhibitory effect on LPS/IFN-gamma induced Th1/pro-inflammatory cytokine production by peritoneal macrophages. It was found that IL-12 p40 production was inhibited and in an apparently PC-dependent manner. Overall these data indicate that PC-containing glycosphingolipids of A. suum appear to have at least two immunomodulatory constituents - PC and an as yet unknown component.

Homing of primitive hematopoietic cells in non-myeloablated murine recipients

Investigations into the homing of hematopoietic stem cells (HSC) following transplantation have most commonly been performed in myeloablated recipients. Recent success of bone marrow (BM) transplantation in non- or minimally-myeloablated recipients has increased interest in examining homing patterns of HSC in non/myeloablated hosts. To this end, low-density murine BM cells were stained with PKH2 and transplanted into lethally-irradiated (18 hr post-irradiation) or non-irradiated syngeneic recipients, which were sacrificed at various time points post-transplantation (PT). Cells harvested from the peripheral blood (PB), BM, and spleen were analyzed for recovery of donor cells, adhesion molecule profile, cell cycle status, and proliferation history. Despite relative enrichment of donor cells in myeloablated tissues, recovery from all 3 tissues of donor cells up to 24 hr PT was similar between myeloablated and non-ablated recipients. Recovery ranged from 6 to 10% of the original graft, with 60–90% of the recovered cells homing to BM. Recovery of donor Sca-1+ lin− cells from BM was up to 8-fold higher than recovery total donor cells in both transplant settings, suggesting specific homing of primitive phenotypes. Interestingly, recovery of Sca-1+ lin− cells was greater in non-myeloablated recipients compared to irradiated recipients. Analysis of cell cycle status of donor cells recovered from BM, spleen, or PB revealed a high degree of quiescence, while BRD-U incorporation indicated that 10 to 30% of these cells had cycled in vivo by 24 hr PT. Examination of adhesion molecule expression of BM-homed Sca-1+ cells revealed that phenotypes enriched for long-term engraftment potential, such as Sca-1+ lin− CD43+ cells, homed preferentially to the marrow of non-irradiated recipients compared to that of irradiated hosts. These data suggest that while homing in myeloablated recipients may represent a random process due to radiation damage of stroma and/or endothelial cells, homing in non-myeloablated recipients may better portray natural trafficking patterns of HSC in vivo.

Oncostatin M induces the differentiation of breast cancer cells

We have recently described the action of Oncostatin M (OSM) to inhibit the proliferation of breast cancer cells. In this study we examined the action of OSM on 2 breast cancer cell lines to further characterize the nature of OSM inhibition of cellular proliferation. Treatment with OSM for 6 days resulted in an approximately 2- to 5-fold decrease in cell number, which was independent of estrogen receptor status. Consistent with this, colony formation was reduced to approximately 50% when cells were exposed to OSM in primary agar cultures. Clonogenicity was further inhibited following 7 days treatment with OSM in monolayer cultures: the total number of clonogenic cells was suppressed approximately 10-fold. Analysis of cell cycle status in OSM-treated cells demonstrated a 40% reduction in the proportion of cells in S phase within 12 hr, with an increase in cells in G0/G1. After 6 days, there was a 10-fold reduction in the absolute number of cells in S phase in OSM-treated cultures. These changes were associated with striking changes in cellular morphology, including disruption of intercellular junctions and the production of lipid droplets. There was a 5-fold increase of c-fos and c-myc mRNA within 30 min of commencing treatment with OSM. In addition, in the ER positive cells there was a decrease in ER mRNA (evident within approximately 2 hr) and ER protein expression following treatment with OSM. Conversely, there was a 5-fold increase in epidermal growth factor receptor (EGFR) mRNA within 4 hr, and a 2.5-fold rise in mRNA for transforming growth factor alpha (TGF alpha). Thus, the inhibition of breast cancer cells by OSM was associated with decreased clonogenicity, a decrease in S phase cells and a variety of phenotypic changes, all consistent with the induction of differentiation.