Isoelectric focusing nonporous silica reversed-phase high-performance liquid chromatography/electrospray ionization time-of-flight mass spectrometry: a three-dimensional liquid-phase protein separation method as applied to the human erythroleukemia cell-line.

A liquid-phase three-dimensional protein separation method has been developed that is used to separate the cytosolic fraction of a HEL cell lysate via isoelectric focusing (IEF), nonporous silica (NPS) reversed-phase high-performance liquid chromatography (RP-HPLC) and electrospray ionization time-of-flight mass spectrometry (ESI-TOFMS), respectively. Several hundred unique protein molecular weights were observed in a pI range from 4.8 to 8.5 and a mass range from 5 to 85 kDa. Proteins were positively identified by analysis of the pI (+/-0.5 pI units), an intact protein molecular weight (+/-150 ppm), and peptide mass mapping results. Using the molecular weight (MW) and peptide mapping results of identified proteins it was possible to characterize their posttranslational (PTMs) and/or sequence modifications. PTMs were detected on both forms of cytosolic actin, heat shock 90 beta, HINT and alpha-enolase. Sequence modifications or conflicts were observed for beta-and gamma-actin, ATP beta-synthase and heat shock 90 beta. IEF-NPS-RP-HPLC/ESI-TOFMS was used to determine experimental pI, MW and relative hydrophobicity values for each protein detected. This data was used to generate a 2-D pI-MS protein map, where proteins are displayed according to their pI and molecular weight. Protein molecular weight peaks are represented as bands in the 2-D pI-MS image where the gray scale of each band is proportional to the intensity of the protein molecular weight peak. In addition, a third hydrophobicity dimension (%B) was added as the % acetonitrile elution to generate a 3-D pI-MS-%B plot where each protein can be tagged according to three parameters.

Inverse regulation of cyclin B1 by c-Myc and p53 and induction of tetraploidy by cyclin B1 overexpression.

We have shown previously that mitotic spindle inhibitors allow the c-Myconcoprotein to uncouple mitosis from DNA synthesis, resulting in the acquisition of tetraploidy. This can also occur in the absence of spindle inhibition if c-Myc deregulation is combined with inactivation of the p53 tumor suppressor. Under these conditions, cyclin B1 protein is induced but retains its normal cell cycle regulation. We now show that the cyclin B1 promoter is directly but oppositely regulated by c-Myc and p53. Enforced expression of cyclin B1 also induces tetraploidy, either after mitotic spindle inhibition or in the absence of such inhibition if cyclin B1 is coexpressed with c-Myc. Cyclin B1 represents a new class of c-Myc target genes that is also regulated by p53. It is also the first identified downstream effector of c-Myc able to produce the chromosomal instability that characterizes virtually all tumor cells.

Osteogenesis and bone-marrow-derived cells.

This paper addresses some of the important aspects of stem cell commitment to the bone cell lineage examining the various types of precursor cells, their responses to cytokines and other extracellular influences, and recent observations on the biochemical and molecular control of lineage-specific gene expression. The process of osteopoiesis involves the proliferation and maturation of primitive precursor cells into functional osteoblasts. The bone cells purportedly originate from mesenchymal stem cells that commit to the osteogenic cell lineage becoming osteoprogenitor cells, preosteoblasts, osteoblasts, and osteocytes. Further understanding of this developmental process requires that lineage-specific markers be identified for the various populations of bone cells and their precursors, that cell separation techniques be established so that cells of the osteogenic lineage can be purified at different stages of differentiation, and that these isolated cells are studied under serum-free, chemically defined conditions.

Three-dimensional cellular development is essential for ex vivo formation of human bone.

Tissue engineering of human bone is a complex process, as the functional development of bone cells requires that regulatory signals be temporally and spatially ordered. The role of three-dimensional cellular interactions is well understood in embryonic osteogenesis, but in vitro correlates are lacking. Here we report that in vitro serum-free transforming growth factor (TGF)-beta1 stimulation of osteogenic cells immediately after passage results in the formation of three-dimensional cellular condensations (bone cell spheroids) within 24 to 48 hours. In turn, bone cell spheroid formation results in the up-regulation of several bone-related proteins (e.g., alkaline phosphatase, type I collagen, osteonectin) during days 3-7, and the concomitant formation of micro-crystalline bone. This system of ex vivo bone formation should provide important information on the physiological, biological and molecular basis of osteogenesis.

Bone marrow accessory cells regulate human bone precursor cell development.

OBJECTIVE: Much remains to be learned about the intimate relationship between bone marrow and its surrounding tissue: the bone. We hypothesized that bone marrow accessory cell populations might regulate the development of human bone precursor cells. MATERIALS AND METHODS: We used immunologic phenotyping, and isolation methods to fractionate subpopulations of nonadherent, low-density (NALD) human bone marrow cells. These cells were examined for their ability to support the serum-free survival, proliferation, and expression of bone proteins by highly purified populations of human bone precursor cells. Quantitative assessment of the accessory cell populations as well as human bone precursor cells phenotype was performed using multiparameter flow cytometry. Bone protein expression was evaluated by immunocytochemistry, Western analysis, and enzymatic analysis (for alkaline phosphatase activity). RESULTS: Human bone marrow contains a cell population that stimulates the development of purified bone precursor cells. Feeder-layer studies demonstrate that these osteopoietic accessory cells (OACs) do not require cell-cell interaction to promote bone precursor cell development but, rather, produce soluble molecules responsible for their effects. Flow cytometric analyses reveal that bone marrow derived B cells, T cells, macrophages, natural killer cells, and endothelial cells do not produce this stimulatory factor. The (growth) factor cannot be replaced by addition of exogenous cytokines. The isolation of human transforming growth factor beta receptor type II (TGF-betaRII)-positive cells increases OAC-specific activity in bone cell ex vivo expansion cultures. Moreover, isolation of OAC bone marrow cells characterized by high TGF-betaRII expression, relatively low cellular complexity, and small size yields a population that is highly enriched for OACs. CONCLUSION: We conclude that human bone marrow contains a population of OACs that are an obligate requirement for the early phases of bone cell development ex vivo.

Bone marrow cell trafficking following intravenous administration.

To address trafficking of transplanted marrow cells immediately after intravenous infusion, we examined the early fate of infused non-adherent, low-density donor bone marrow cells in a syngeneic mouse model. The presence of infused donor cells, marked with indium-111 oxine (111In), with the fluorescent dye PKH26, or by a detectable transgene marker, was evaluated at 3-48 h in a variety of tissues, including peripheral blood. All three cell-marking methods indicated a rapid (< 4 h) influx of cells into the bone marrow, liver, spleen, muscle and other tissues. Moreover, these tissues remained positive for the 48 h observation period. Interestingly, analysis of PKH26-positive cells in non-myeloablated animals demonstrated that approximately 17% of infused donor marrow cells localized to the marrow space within 15 h, whereas a smaller proportion of donor cells (approximately 1-2%) localized to the marrow in recipients preconditioned by irradiation. In an effort to enrich for cells that specifically home to the bone marrow, PKH26-labelled donor marrow cells were recovered from the first host and infused into a secondary recipient. Although this was a phenotypically undefined population of cells, no increase was observed in the relative fraction of PKH26-labelled cells returning or 'homing' to the marrow of the second recipient. Taken together, these data suggest both that marrow engraftment may be mediated by non-specific 'seeding' rather than a specific homing signal, and that efficient targeting of transplanted cells to the marrow is a complex multifaceted process.

Thrombopoietin stimulation of hematopoietic stem/progenitor cells.

The recent cloning of the thrombopoietin gene, and the production of recombinant protein, have allowed studies on both its biological actions and clinical utility. Thrombopoietin not only affects the cells of the megakaryocytic lineage, but has a diverse set of cellular targets. In particular, it stimulates the ex vivo expansion of hematopoietic stem/progenitor cells suggesting that it may play a role in transplantation studies. Pre-clinical but limited clinical studies indicate that under defined conditions, thrombopoietin may accelerate white blood cell count and platelet recoveries following myelosuppression or radiotherapy.

Age-related phenotypic alterations in populations of purified human bone precursor cells.

The ability to purify and characterize phenotypic markers of human bone precursor cells provides an important means to study the basis of age- or disease-related changes in osteogenesis. Utilizing immunologically purified and characterized populations of human bone preosteoblast-like cells, we demonstrate that distinct age-related alterations occur in bone cell phenotypic markers, and additionally document the presence of a subpopulation of elderly individuals who express markedly reduced amounts of bone proteins. These findings provide insights into the early phases of bone cell development, and provide a means for evaluating age- and/or disease-mediated changes in bone cell development.

C-myc overexpression and p53 loss cooperate to promote genomic instability.

p53 monitors genomic integrity at the G1 and G2/M cell cycle checkpoints. Cells lacking p53 may show gene amplification as well as the polyploidy or aneuploidy typical of many tumors. The pathways through which this develops, however, are not well defined. We demonstrate here that the combination of p53 inactivation and c-myc overexpression in diploid cells markedly accelerates the spontaneous development of tetraploidy. This is not seen with either N-myc or L-myc. Tetraploidy is accompanied by significantly higher levels of cyclin B and its associated cdc2 kinase activity. Mitotic spindle poisons accelerate the appearance of tetraploidy in cells either lacking functional p53 or overexpressing c-myc whereas the combination is additive. Restoration of p53 function in cells overexpressing c-myc causing rapid apoptosis, indicating that cells yet to become tetraploid have nonetheless suffered irreversible genomic and/or mitotic spindle damage. In the face of normal p53 function, such damage would either be repaired or trigger apoptotis. We propose that loss of p53 and overexpression of c-myc permits the emergence and survival of cells with increasingly severe damage and the eventual development of tetraploidy.

Differential modulation of G1-S-phase cyclin-dependent kinase 2/cyclin complexes occurs during the acquisition of a polyploid DNA content.

Despite a growing understanding of the biochemical mechanisms controlling the cell cycle, information regarding the temporal ordering of S phase and M phase remains scarce. Polyploid cells represent a useful model for examining S- and M-phase control, because their cell cycle machinery must be modulated to retain high levels of DNA content (ploidy) within a single nucleus. To evaluate the mechanisms of S-phase control during the process of polyploidization, we investigated the modulations that occur in cyclin-dependent kinase (CDK) complexes during the induction of megakaryocyte differentiation in human erythroleukemia cells. We report that during polyploidization, megakaryocytic human erythroleukemia cells undergo a dramatic modulation in the subunit composition of G1-associated and S phase-associated CDK complexes and a marked increase in their specific activities. This, in turn, is facilitated by a differential loss of the p21 or p27 CDK-inhibitory protein/kinase-inhibitory proteins (CIP/KIP) bound to specific cyclin/CDK complexes. The data show that the loss of S- and M-phase control in polyploid cells occurs within the context of an up-regulated function in those CDK complexes associated with both G1-S-phase transit and S-phase progression. Additional studies regarding the regulation of these complex CDK interactions will be important to understand cell cycle control in such diverse processes as megakaryocyte differentiation or the types of genomic instability that occur in cancer cells.

Megakaryocyte differentiation events.

The events underlying the commitment and differentiation of megakaryocytes are poorly understood, particularly with respect to understanding the biochemical and molecular mechanisms regulating this process. These regulatory events begin with the interaction of multiple microenvironmental signals (eg, cytokines, extracellular matrix) with specific cell surface receptors, extend through a signal transduction cascade, and end with transcriptional activation of megakaryocyte-specific genes. This article focuses on the cellular, biochemical, and molecular control of megakaryocyte differentiation events, whereas data on the ligands, receptors, and signal transduction are found elsewhere in this issue. The first area discussed is the classification of functional categories of the cells of the megakaryocyte lineage: identifying those cells which respond to proliferative signals, those which mark the transition from the proliferating cell compartment to mature cells, and the mature, post-mitotic platelet-shedding cells. The transitional cells, the pro-megakaryoblasts, are covered in some detail as these cells are physiologically important both in their early response to thrombopoietic stress, and for their unique capacity to continue to synthesize DNA during their differentiation. Finally, recent data on the control of the process of megakaryocyte polyploidization, as well as the molecular control of megakaryocyte commitment are discussed.

Thrombopoietin requires additional megakaryocyte-active cytokines for optimal ex vivo expansion of megakaryocyte precursor cells.

Little is known concerning the interaction of thrombopoietin (TPO) with other megakaryocyte-active cytokines in directing the early events of megakaryocyte development. Culture of CD34(+) cells in interleukins (IL) -1, -6, -11, plus stem cell factor (SCF; S) results in a 10- to 12-fold expansion in total cell numbers, whereas total CD41(+) megakaryocytes are expanded approximately 120-fold over input levels. Addition of TPO to IL-1, -6, -11, S generates a biphasic proliferation of CD41(+) cells, accelerates their rate of production, and results in an ex vivo expansion of more than 200-fold. The addition of Flt-3 ligand (FL) increases CD41+ cell expansion to approximately 380-fold over input levels. In the absence of TPO, approximately 95% of the expanded cells show the phenotype of promegakaryoblasts; TPO and/or FL addition increases CD41 antigen density and ploidy in a subpopulation of promegakaryoblasts. A moderate (approximately sevenfold) expansion of megakaryocyte progenitor cells (colony-forming unit-megakaryocyte) occurs in the presence of IL-1, -6, -11, S, and the addition of TPO to this cocktail yields an approximately 17-fold expansion. We conclude that early proliferative events in megakaryocyte development in vitro are regulated by multiple cytokines, and that TPO markedly affects these early developmental steps. However, by itself, TPO is neither necessary nor sufficient to generate a full proliferative/maturational in vitro response within the megakaryocyte compartment. TPO clearly affects terminal differentiation and the development of (some) high-ploidy human megakaryocytes. However, its limited in vitro actions on human cell polyploidization suggest that additional megakaryocyte-active cytokines or other signals are essential for the maximal development of human megakaryocytes.

Human hematopoietic progenitor cell isolation based on galactose-specific cell surface binding.

The ability to isolate functional populations of hematopoietic progenitor cells is important to the process of hematopoietic cell transplantation and to the understanding of hematopoietic cell biology in health and disease. We show that a subpopulation of human bone marrow hematopoietic cells bearing the pan-hematopoietic antigen CD34 also binds galactose-conjugated proteins. This lectin-positive sub-population represents approximately 0.1 to 0.5% of the total bone marrow cells, and contains 100% of the hematopoietic progenitor cells. The galactose-binding lectin on these cells is specific for this sugar. Additionally, highly proliferative hematopoietic progenitor cells with very primitive phenotypes, including a newly identified progenitor cell that produces multiple lineages, express this lectin.

Novel alterations in CDK1/cyclin B1 kinase complex formation occur during the acquisition of a polyploid DNA content.

The pathways that regulate the S-phase events associated with the control of DNA replication are poorly understood. The bone marrow megakaryocytes are unique in that they leave the diploid (2C) state to differentiate, synthesizing 4 to 64 times the normal DNA content within a single nucleus, a process known as endomitosis. Human erythroleukemia (HEL) cells model this process, becoming polyploid during phorbol diester-induced megakaryocyte differentiation. The mitotic arrest occurring in these polyploid cells involves novel alterations in the cdk1/cyclin B1 complex: a marked reduction in cdk1 protein levels, and an elevated and sustained expression of cyclin B1. Endomitotic cells thus lack cdk1/cyclin B1-associated H1-histone kinase activity. Constitutive over-expression of cdk1 in endomitotic cells failed to re-initiate normal mitotic events even though cdk1 was present in a 10-fold excess. This was due to an inability of cyclin-B1 to physically associate with cdk1. Nonetheless, endomitotic cyclin B1 possesses immunoprecipitable H1-histone kinase activity, and specifically translocates to the nucleus. We conclude that mitosis is abrogated during endomitosis due to the absence of cdk1 and the failure to form M-phase promoting factor, resulting in a disassociation of mitosis from the completion of S-phase. Further studies on cyclin and its interacting proteins should be informative in understanding endomitosis and cell cycle control.

Marrow-derived heparan sulfate proteoglycan mediates the adhesion of hematopoietic progenitor cells to cytokines.

Heparan sulfate proteoglycan (HS-PG), an important component of the human bone marrow extracellular matrix (ECM), is believed to influence hematopoietic progenitor cell development by binding and localizing growth factors to specific niches within the hematopoietic microenvironment. We utilized a model ECM system, which uses immobilized ECM proteins and/or cytokines and bone marrow populations enriched for human hematopoietic stem cell (HSC), to assess the effects of HS-PG on the development of primitive hematopoietic progenitor cells. HS-PG alone failed to bind hematopoietic progenitor cells cloned from bone marrow CD34+CD15-HLA-DR- cells, which are enriched for HSC. HS-PG alone failed to function as a mitogen. In sharp contrast, the interaction of HS-PG with either growth factors (interleukin-3 [IL-3] or stem cell factor/Kit ligand [KL] or an ECM protein (thrombospondin [TSP]) markedly influenced progenitor cell adherence. The binding of either IL-3 or KL to HS-PG resulted in a two-fold increase in attachment of the colony-forming unit-granulocyte/macrophage (CFU-GM), a 1.5-fold increase in attachment of the burst-forming unit-erythroid (BFU-E) and the high-proliferative-potential colony-forming cell (HPP-CFC), and a two- to three-fold increase in attachment of the colony-forming unit-granulocyte/erythroid/macrophage/megakaryocyte (CFU-GEMM) compared to localized growth factor alone. Attachment of the BFU-megakaryocyte (BFU-MK), however, was slightly reduced by the interaction of either IL-3 or KL with HS-PG. The interaction of HS-PG with TSP resulted in a two-fold increase in CFU-GM and CFU-GEMM attachment, while the attachment of BFU-E, HPP-CFC, and BFU-MK was unaltered. We conclude that HS-PG cooperatively interacts with both growth factors and ECM proteins to augment progenitor cell localization within the hematopoietic microenvironment.

Murine granulocytic cell adhesion to bone marrow hemonectin is mediated by mannose and galactose.

Hemonectin (HN) is a bone marrow (BM) protein that promotes specific attachment of immature granulocytes and their precursors within the BM. We report that HN is a glycoprotein containing both mannose and galactose residues, and provide evidence that these carbohydrates mediate granulocytic cell adhesion to HN. Carbohydrate structure was determined by digoxigenin-conjugated lectin binding to HN and indicated the presence of mannose, galactose, sialic acid, and the absence of fucose-linked oligosaccharides. The role of carbohydrates in mediating cell adhesion was examined by chemical and enzymatic deglycosylation. Deglycosylation of HN with trifluoromethanesulfonic acid, which cleaves N- and O-linked oligosaccharides, inhibits 66% of cell attachment to HN, and results in an apparent decrease in molecular weight from 60 to 50 kD. Enzymatic deglycosylation with endo-B-N-acetylglucosaminidase H, which hydrolyzes specific N-linked mannose residues, inhibits 30% of cell adhesion to HN. Finally, the role of these specific sugars in hemonectin-mediated cell adhesion was confirmed with neoglycoprotein blocking. Preincubation of BM cells with mannosyl- and galactosyl-BSA probes produces a dose-dependent inhibition of cell attachment to HN, whereas fucosyl-BSA does not inhibit cell adhesion to HN. These results show that mannose and galactose partially mediate adhesion of BM granulocytes to HN.

Cyclins and cell division kinases in megakaryocytic endomitosis.

Little is known concerning the mechanism by which megakaryocytes achieve their high levels of DNA content. Mature megakaryocytes show multiple 2-fold increases in DNA content, but the various levels of polyploidization exist within each of the morphologically recognizable classes. A number of studies have documented that the stimulatory actions of partially purified thrombopoietin or other cytokines on megakaryocyte DNA content both in vivo and in vitro. It is thus hypothesized that polyploidization is a crucial first step in megakaryocyte differentiation that is necessary for eventual cytoplasmic maturation and platelet production. Biochemically, there are 2 cell cycle regulatory points (either permissive or restrictive) which lead to polyploid DNA content in megakaryocytes; one regulatory point controls the increased DNA synthesis (presumably at the G1/S cell cycle boundary) and the other controls mitotic events, resulting in a single nucleus and an acytokinetic cell (the control point for this latter switch would be in early M-phase). Alterations in the biochemical control of these check points in other systems suggests that alterations in mitosis are among the first steps in endomitosis.

Regulation of human bone marrow-derived osteoprogenitor cells by osteogenic growth factors.

Human bone marrow contains a distinct cell population that expresses bone proteins and responds to transforming growth factor beta 1 (TGF-beta), but not to hematopoietic growth factors (Long, M. W., J. L. Williams, and K. G. Mann. 1990. J. Clin. Invest. 86:1387-1395). We now report the isolation, characterization, and growth factor responsiveness of these precursors to human osteoblasts and the identification of a human osteoprogenitor cell. Immunological separation of human bone marrow nonadherent low-density (NALD) cells results in a marked enrichment of cells that express osteocalcin, osteonectin, and bone alkaline phosphatase. Flow cytometric analyses show that distinct cell subpopulations exist among these isolated cells. The majority of the bone antigen-positive cells are approximately the size of a lymphocyte, whereas other, less frequent antibody-separated subpopulations consist of osteoblast-like cells and osteoprogenitor cells. In serum-free cultures, TGF-beta stimulates the small, antigen-positive cells to become osteoblast-like, as these cells both increase in size, and express increased levels of osteocalcin and alkaline phosphatase. Antibody-separated cells also contain a separate population of clonal progenitor cells that form colonies of osteoblast-like cells when cultured in serum-free, semi-solid media. Two types of human osteoprogenitor cells are observed: a colony-forming cell (CFC) that generates several hundred bone antigen-positive cells, and a more mature cluster-forming cell that has a lesser proliferative potential and thus generates clusters of 20-50 antigen-positive cells. Osteopoietic colony-forming cells and cluster-forming cells have an obligate but differential requirement for osteogenic growth factors. The CFCs respond to TGF-beta, basic fibroblast growth factor (bFGF), bone morphogenic protein-2 (BMP-2), and 1, 25-dihydroxy vitamin D3 (1,25-OH D3). In contrast to the colony-forming cells, cluster-forming cells are regulated predominantly by 1,25-OH D3 and TGF-beta, but fail to respond to bFGF. We conclude that human bone marrow contains a nonhematogenous, heterogeneous population of bone precursor cells among which exists a population of proliferating osteoprogenitor cells. Further characterization of these bone precursor cell populations should yield important information on their role in osteogenesis in both health and disease.

Population heterogeneity among cells of the megakaryocyte lineage.

Understanding the developmental steps in megakaryocyte differentiation requires information regarding the microenvironmental influences which direct or permit the growth and differentiation of these cells. The megakaryocyte microenvironment, like other lineages, is a complex structure comprised of the various megakaryocytic cells, the extracellular matrix (ECM) surrounding them, and the hematopoietic stromal cells which elaborate both growth factors and ECM. As a result, definition of the minimal essential requirements for megakaryocyte development is difficult. The intricacies of megakaryocyte development are further complicated by the cellular heterogeneity of both mature megakaryocytes and their precursors, as well as a differential responsiveness of these cells to hematopoietic growth factors. This review focuses on defining the various subpopulations of megakaryocytic cells and examining their functional distinctions and in vitro responsiveness to various stimuli.