The role of spatial organization of cells in erythropoiesis

Erythropoiesis, the process of red blood cell production, occurs mainly in the bone marrow. The functional unit of mammalian erythropoiesis, the erythroblastic island, consists of a central macrophage surrounded by adherent erythroid progenitor cells (CFU-E/Pro-EBs) and their differentiating progeny, the erythroblasts. Central macrophages display on their surface or secrete various growth or inhibitory factors that influence the fate of the surrounding erythroid cells. CFU-E/Pro-EBs have three possible fates: (a) expansion of their numbers without differentiation, (b) differentiation into reticulocytes that are released into the blood, (c) death by apoptosis. CFU-E/Pro-EB fate is under the control of a complex molecular network, that is highly dependent upon environmental conditions in the erythroblastic island. In order to assess the functional role of space coupled with the complex network behavior in erythroblastic islands, we developed hybrid discrete-continuous models of erythropoiesis. A model was developed in which cells are considered as individual physical objects, intracellular regulatory networks are modeled with ordinary differential equations and extracellular concentrations by partial differential equations. We used the model to investigate the impact of an important difference between humans and mice in which mature late-stage erythroblasts produce the most Fas-ligand in humans, whereas early-stage erythroblasts produce the most Fas-ligand in mice. Although the global behaviors of the erythroblastic islands in both species were similar, differences were found, including a relatively slower response time to acute anemia in humans. Also, our modeling approach was very consistent with in vitro culture data, where the central macrophage in reconstituted erythroblastic islands has a strong impact on the dynamics of red blood cell production. The specific spatial organization of erythroblastic islands is key to the normal, stable functioning of mammalian erythropoiesis, both in vitro and in vivo. Our model of a simplified molecular network controlling cell decision provides a realistic functional unit of mammalian erythropoiesis that integrates multiple microenvironmental influences within the erythroblastic island with those of circulating regulators of erythropoiesis, such as EPO and glucocorticosteroids, that are produced at remote sites.

Chronic myeloid leukemia-associated membranoproliferative glomerulonephritis that responded to imatinib mesylate therapy

There is no known clinical association between chronic myelogenous leukemia (CML) and membranoproliferative glomerulonephritis (MPGN). We present a patient who was followed in the renal clinic for proteinuria of unknown etiology (3.2 g/24 h) and normal renal function who was diagnosed with CML as well as MPGN and acute renal failure at the same time. The patient's renal function and proteinuria improved when his CML was treated with imatinib mesylate, suggesting that CML either caused or exacerbated existing MGPN. To the best of our knowledge, this is the first reported case of MPGN associated with CML that improved with imatinib mesylate therapy.

Plasma S-adenosylhomocysteine is a more sensitive indicator of cardiovascular disease than plasma homocysteine

BACKGROUND

Although plasma total homocysteine has been identified as an independent risk factor for vascular disease in a multitude of studies, there is a considerable overlap in values between patients at risk and control subjects. The difference in values can be used to distinguish statistically between the 2 groups, provided each group is large enough; however, discriminating between individual patients at risk and control subjects is difficult.

OBJECTIVE

We investigated whether the precursor of homocysteine, S-adenosylhomocysteine, is a more sensitive indicator of risk.

DESIGN

We measured plasma total homocysteine, S-adenosylhomocysteine, S-adenosylmethionine, creatinine, folate, and vitamin B-12 in 30 patients with proven cardiovascular disease and 29 age- and sex-matched control subjects.

RESULTS

The homocysteine values (+/-SD) were 12.8 +/- 4.9 (95% CI: 11.0, 14.7) micromol/L for patients and 11.0 +/- 3.2 (9.8, 12.2) micromol/L for control subjects. The S-adenosylhomocysteine values were 40.0 +/- 20.6 (32.3, 47.7) nmol/L for patients and 27.0 +/- 6.7 (24.5, 30.0) nmol/L for control subjects (P = 0.0021). The S-adenosylmethionine values were 121.8 +/- 42.9 (105.8, 137.8) nmol/L for patients and 103.9 +/- 21.8 (95.6, 112.2) nmol/L for control subjects (P = 0.0493). The creatinine values were 110 +/- 27 (97, 120) micromol/L for patients and 97 +/- 9 (80, 100) micromol/L for control subjects (P = 0.0025). Values for folate and vitamin B-12 did not differ significantly between groups.

CONCLUSIONS

Plasma S-adenosylhomocysteine appears to be a much more sensitive indicator of the difference between patients with cardiovascular disease and control subjects than is homocysteine. Both plasma total homocysteine and S-adenosylhomocysteine are significantly correlated with plasma creatinine in patients.

Apoptosis in megaloblastic anemia occurs during DNA synthesis by a p53-independent, nucleoside-reversible mechanism

Deficiency of folate or vitamin B(12) (cobalamin) causes megaloblastic anemia, a disease characterized by pancytopenia due to the excessive apoptosis of hematopoietic progenitor cells. Clinical and experimental studies of megaloblastic anemia have demonstrated an impairment of DNA synthesis and repair in hematopoietic cells that is manifested by an increased percentage of cells in the DNA synthesis phase (S phase) of the cell cycle, compared with normal hematopoietic cells. Both folate and cobalamin are required for normal de novo synthesis of thymidylate and purines. However, previous studies of impaired DNA synthesis and repair in megaloblastic anemia have concerned mainly the decreased intracellular levels of thymidylate and its effects on nucleotide pools and misincorporation of uracil into DNA. An in vitro model of folate-deficient erythropoiesis was used to study the relationship between the S-phase accumulation and apoptosis in megaloblastic anemia. The results indicate that folate-deficient erythroblasts accumulate in and undergo apoptosis in the S phase when compared with control erythroblasts. Both the S-phase accumulation and the apoptosis were induced by folate deficiency in erythroblasts from p53 null mice. The complete reversal of the S-phase accumulation and apoptosis in folate-deficient erythroblasts required the exogenous provision of specific purines or purine nucleosides as well as thymidine. These results indicate that decreased de novo synthesis of purines plays as important a role as decreased de novo synthesis of thymidylate in the pathogenesis of megaloblastic anemia.

Fus deficiency in mice results in defective B-lymphocyte development and activation, high levels of chromosomal instability and perinatal death

The gene FUS (also known as TLS (for translocated in liposarcoma) and hnRNP P2) is translocated with the gene encoding the transcription factor ERG-1 in human myeloid leukaemias. Although the functions of wild-type FUS are unknown, the protein contains an RNA-recognition motif and is a component of nuclear riboprotein complexes. FUS resembles a transcription factor in that it binds DNA, contributes a transcriptional activation domain to the FUS-ERG oncoprotein and interacts with several transcription factors in vitro. To better understand FUS function in vivo, we examined the consequences of disrupting Fus in mice. Our results indicate that Fus is essential for viability of neonatal animals, influences lymphocyte development in a non-cell-intrinsic manner, has an intrinsic role in the proliferative responses of B cells to specific mitogenic stimuli and is required for the maintenance of genomic stability. The involvement of a nuclear riboprotein in these processes in vivo indicates that Fus is important in genome maintenance.

Mitogen-activated protein kinase mediates erythropoietin-induced phosphorylation of the TAL1/SCL transcription factor in murine proerythroblasts

Ectopic expression of the basic helix-loop-helix transcription factor TAL1 (or SCL) is the most frequent gain-of-function mutation in T-cell acute lymphoblastic leukaemia. Gene-knockout studies in mice have demonstrated that TAL1 is required for embryonic and adult haematopoiesis, and considerable evidence suggests it also has important functions in terminal erythroid differentiation. We reported previously that TAL1 phosphorylation is stimulated by erythropoietin in splenic proerythroblasts isolated from mice infected with the anaemia-inducing strain of Friend virus and show here the signalling pathway responsible. Erythropoietin was found to stimulate nuclear mitogen-activated protein kinase activity in addition to TAL1 protein phosphorylation, both of which were quantitatively inhibited by the mitogen-activated protein kinase kinase inhibitor PD 098059 and the phosphatidylinositol 3-kinase inhibitor wortmannin. Tryptic phosphopeptide analysis of radiolabelled TAL1 immunoprecipitated from nuclear extracts of Friend virus-induced proerythroblasts revealed that phosphorylation of Ser(122), shown previously to be a substrate for the mitogen-activated protein kinase ERK1 (extracellular signal-regulated protein kinase) in vitro, was specifically, although not exclusively, increased by erythropoietin and inhibited by wortmannin and PD 098059. These results are consistent with an erythropoietin-stimulated signalling pathway in which there is direct activation of a mitogen-activated protein kinase kinase by phosphatidylinositol 3-kinase and identify TAL1 as one of its nuclear targets. These data suggest, in addition, a specific mechanism by which the principal regulator of erythroid differentiation could enhance TAL1 function, in addition to increasing its expression.

Comparative analysis of different methodological approaches to the in vitro study of drug-induced apoptosis

Apoptosis is a dynamic process in which a characteristic morphological or biochemical event used in an assay as a specific marker of apoptosis may be observed over a limited period of time. Asynchronous involvement of cells in apoptosis results in different proportions of apoptotic cells with blebbed membrane, broken nuclei, modified mitochondrial units or fragmented DNA coexisting in the culture at any single moment. Thus, depending on the method used, the extent of apoptosis determined in the same cell population may vary. In the present study, a microculture kinetic (MiCK) assay was used to monitor apoptosis in HL-60 cells exposed to 1, 2.5, 5, 10, and 20 micromol/L etoposide and cisplatin. Both the extent and timing of apoptotic responses were dependent on the drug and drug concentration. Time-lapse video microscopy (TLVM), flow cytometry analysis of the light scattering properties of cells, morphological studies of Giemsa-stained cells, annexin V binding, and DNA fragmentation assays were performed at multiple times of cell exposure to 10 micromol/L etoposide and 5 micromol/L cisplatin. Steep linear increases in optical density, indicating apoptosis in the MiCK assay, correlated with both linear increases in the proportion of cells with plasma membrane blebbing in TLVM and with increased side scattering properties of apoptotic cells in flow cytometry. During a 24-hour culture period, the MiCK assay and TLVM provided multiple consecutive appraisals of nondisturbed cell microcultures at intervals of 5 and 2.5 minutes, respectively, and thus could be considered as real time kinetic assays. With the three endpoint assays, each of which was applied 12 times at 2-hour intervals, maximum apoptotic responses varied from 22.5 to 72% in etoposide-treated cells and from 30 to 57% in cisplatin-treated cells. With the annexin V binding assay, maximum apoptosis could always be detected 4 to 5 hours earlier than it was seen in Giemsa-stained preparations and 8 hours earlier than it was detected by measuring of DNA fragmentation. Values of the maximum extent of apoptosis varied, being the lowest with annexin V and the greatest with DNA fragmentation assays. The best correlations of both extent and timing of apoptosis were observed between the MiCK, TLVM, and morphological assays. In conclusion, both a maximum apoptotic response and the time at which it was achieved are the obligatory requirements for determining the apoptosis-inducing potency of an agent and for comparing results of studies performed in different laboratories.

Increased expression of the distal, but not of the proximal, Gata1 transcripts during differentiation of primary erythroid cells

Gata1 is expressed from either one of two alternative promoters, the erythroid (proximal to the AUG) and the testis (distal to the AUG) promoter, both used by hemopoietic cells. To clarify the role of the distal and proximal Gata1 transcripts in erythroid differentiation, we determined by specific reverse transcriptase-polymerase chain reactions their relative levels of expression during the differentiation of erythroid precursors purified from the spleen of mice treated with phenylhydrazine (PHZ) or infected with the anemia-inducing strain of the Friend virus (FVA cells). PHZ cells are erythroid precursors that progress in vivo to erythroblasts in 3 days. Both PHZ and FVA cells synchronously proliferate and differentiate in vitro in the presence of erythropoietin (EPO). The levels of total and of distal, but not of proximal, Gata1 transcripts increased by five- to eightfold during in vivo and in vitro differentiation of FVA and PHZ cells. The increase in expression was temporally associated with an increase in the expression of Eklf, Scl, and Nfe2, three genes required for erythroid differentiation, and preceded by 24 h the repression of Gata2 and Myb expression. The day 1 PHZ cells that survived 18 h in the absence of EPO do not express globin genes and express detectable levels of distal but not of proximal Gata1 transcripts. These cells activate the expression of the globin genes within 2 h when exposed to EPO. Therefore, during erythroid differentiation of primary cells, increased expression of distal Gata1 transcripts underlies the increase in the expression of total Gata1 associated with the establishment of the erythroid differentiation program.

Detection of mutations by automated fluorescence/RNA-based dideoxy fingerprinting (ARddF)

Dideoxy fingerprinting (ddF) is a hybrid technique which combines aspects of single strand conformational polymorphism (SSCP) and dideoxy sequencing to detect the presence of single base changes in a defined fragment of nucleic acid. ddF is no more technically demanding than SSCP, yet it is more sensitive in detecting point mutations. We describe here the adaptation of conventional ddF to an automated sequencing system using fluorescent Cy5 labeled primers. We show that automated RNA-based ddF (ARddF) has several advantages over conventional radioisotope-based ddF, including: (1) analysis of larger nucleic acid fragments (up to 10(3) bp), due to the ability to continuously analyse and compile sequencing information; (2) greater reliability for distinguishing mutant sequences from wild type sequences (particularly when the mutation leads to gain or loss of a dideoxy termination segment); (3) the use of fluorescent labeled primers, making ARddF less hazardous than methods requiring radionucleotides. The use of ARddF in conjunction with new methods for isolating RNA from a [corrected] small number of cells facilitates mutational analysis of small tissue biopsies and other limited samples, and will allow more widespread application of mutational screening in the setting of clinical diagnostic laboratories.

Use of the microculture kinetic assay of apoptosis to determine chemosensitivities of leukemias

Chemotherapeutic agents exert their antitumor effects by inducing apoptosis. The microculture kinetic (MiCK) assay provides an automated, continuous means of monitoring apoptosis in a cell population. We used the MiCK assay to determine the chemosensitivities of the human promyelocytic HL-60 and lymphoblastic CEM cell lines and leukemia cells freshly isolated from patients with acute nonlymphocytic (ANLL) or acute lymphocytic (ALL) leukemias. Continuous monitoring of apoptosis in the MiCK assay permits determination of the time to the maximum apoptosis (Tm) and its two components which are initiation time (Ti) and development time (Td). Duration of the three timing components of apoptosis varies from hours to days depending on the drug, drug concentration, and type of target cells. In the MiCK assay, the extent of apoptosis is reported in kinetic units of apoptosis. Kinetic units are determined by the slope of the curve created when optical density caused by cell blebbing is plotted as a function of time. Using the leukemia cell lines, we define the relationship between kinetic units determined by the MiCK assay and the percentage of morphologically apoptotic cells in the culture. Flow cytometry analysis of apoptosis in Annexin-V-fluorescein isothiocyanate-labeled preparations of HL-60 and CEM cells was also used to compare with data obtained by the MiCK assay. The feasibility of the MiCK assay of apoptosis as a chemosensitivity test was confirmed by its comparison with a 3H-thymidine incorporation assay. We show that samples from 10 ANLL and ALL patients patients tested for sensitivity to various doses of idarubicin (IDR), daunorubicin (DNR), or mitoxantrone (MTA) gave the same percentages of apoptotic cells when calculated by the MiCK assay as when determined by morphological analysis. The MiCK assay was used for dose-response analyses of the sensitivities to IDR, DNR, and MTA of leukemia cells from 4 other patients (2 ANLL and 2 ALL). The results from both cell lines and patient samples indicate that ANLL cells are more sensitive than ALL cells to all three of these chemotherapeutic agents. However, for individual patients the chemosensitivities varied significantly among the three chemotherapeutic agents. These varying responses to IDR, DNR, and MTA indicate that the MiCK assay results can be of potential use in designing a treatment regimen for a specific patient with acute leukemia. Among several drugs of presumed similar efficacy, the MiCK assay can permit the selection of the specific chemotherapeutic agent that causes the most apoptosis in the patient's leukemic cells.

Constitutive and inducible expression of megakaryocyte-specific genes in Friend erythroleukaemia cells

Friend murine erythroleukaemia cells (MELC) were analysed by semiquantitative RT-PCR for the constitutive and inducible expression of megakaryocyte-specific genes. Uninduced MELC expressed detectable levels of mRNAs for acethylcholinesterase (AChE), platelet factor-4 (PF4), glycoprotein IIb (GPIIb) and von Willebrand factor (VWF), whereas the erythroid alpha- and beta-globin genes were not transcribed appreciably. However, MELC exposed to 5 mM hexamethylene bisacetamide (HMBA) or 1.5% dimethyl sulphoxide (DMSO) seemed to be channelled towards a mixed erythroid/megakaryocytic phenotype characterized by unaltered levels of VWF mRNA, increased levels of AChE, GPIIb and PF4 mRNA. and simultaneous induction of the globin genes. Megakaryocyte-related genes were expressed. in the absence of globin gene transcription, by MELC treated with either phorbol-12-myristate acetate (PMA; 100 ng/ml) or colcemid (40 nM), an antimicrotubule agent capable of promoting polyploidization in this model. Moreover, PMA and colcemid induced also de novo expression of the thrombopoietin receptor c-mpl. PMA and colcemid did not affect high basal c-myb mRNA levels which, in turn, were down-regulated upon HMBA or DMSO induction. Additionally, both uninduced and induced MELC exhibited significant levels of Epo-R and IL-3R mRNAs, whereas no expression of granulocyte/macrophage-related genes was detected. Megakaryocyte gene expression of MELC was also compared to that of other haemopoietic cell populations from normal mice and mice infected with the anaemic strain of the Friend virus. According to our results, MELC should be seen as an unique erythro-megakaryocytic model of differentiation, potentially useful for studying molecular events governing lineage commitment as well as some steps of megakaryocytopoiesis.

Folate deficiency delays the onset but increases the incidence of leukemia in Friend virus-infected mice

Clinical studies have indicated that folate deficiency may enhance the development of various malignancies. In animal studies that examined the effect of folate deficiency on malignancies, conflicting results have been reported. In some studies, folate deficiency increased the development and growth of malignant tumors; in others, it decreased the development and growth of malignancies. We examined the effect of transient folate deficiency on the development of leukemia in mice infected with the anemia-inducing strain of Friend leukemia virus. Friend virus disease can be considered as a model for human acute leukemias that are preceded by a preleukemic period. These include leukemias that develop in patients who received previous chemotherapy and/or radiation therapy, as well as patients with chronic granulocytic leukemia or myelodysplasia. Folate deficiency around the time of Friend virus-infection delayed the onset but increased the incidence of leukemia. The rates of rearrangement of the Spi-1 (PU.1 ) oncogene by provirus integration and alteration of the p53 tumor-suppressor gene were the same in leukemia cell lines derived from folate-deficient mice as they were in cell lines from control mice. These results indicate that folate deficiency did not exert its enhancement of leukemogenesis through changes in either Spi-1 or p53, even though these two genes have been found to be the most frequently altered ones in Friend virus-induced leukemias. Our results suggest that folate deficiency may enhance the development of acute leukemia in patients who are at high risk for this disease.

Apoptosis of late-stage erythroblasts in megaloblastic anemia: association with DNA damage and macrocyte production

An in vitro model of folate-deficient erythropoiesis has been developed using proerythroblasts isolated from the spleens of Friend virus-infected mice fed an amino acid-based, folate-free diet. Control proerythroblasts were obtained from Friend virus-infected mice fed the same diet plus 2 mg folic acid/kg diet. Our previous studies showed that, after 20 to 32 hours of culture in folate-deficient medium with 4 U/mL of erythropoietin, the folate-deficient proerythroblasts underwent apoptosis, whereas control erythroblasts survived and differentiated into reticulocytes over a period of 48 hours. The addition of folic acid or thymidine to the folate-deficient medium prevented the apoptosis of the folate-deficient erythroblasts, thereby implicating decreased thymidylate synthesis as the main cause of apoptosis in the folate-deficient erythroblasts. In the study reported here, we examined intracellular folate levels, uracil misincorporation into DNA, p53 and p21 proteins, and reticulocyte formation in erythroblasts cultured in folate-deficient or control medium. In all experiments, the folate-deficient erythroblasts cultured in folate-deficient medium gave results that varied significantly from folate-deficient erythroblasts cultured in control medium or control erythroblasts cultured in either folate-deficient or control media. Folate-deficient erythroblasts cultured in folate-deficient medium had marked decreases in all coenzyme forms of folate that persisted throughout culture, increased uracil misincorporation into DNA, persistent accumulations of p53 and p21, and decreased reticulocyte production but increased size of individual reticulocytes. A model of folate-deficient erythropoiesis based on apoptosis of late stage erythroblasts is presented. This model provides explanations for the clinical findings in megaloblastic anemia.

Needle aspiration and biopsy in the diagnosis and monitoring of bone marrow diseases

OBJECTIVE

To review the procedures required to perform and evaluate needle aspiration and biopsy of bone marrow.

DATA SOURCES

Journal articles, monographs and authors' experience.

DATA SYNTHESIS

The performance of bone marrow needle aspiration and biopsy requires close cooperation between the physician and the clinical laboratory scientist (CLS). Several tests require special handling when obtaining and processing bone marrow samples. Serial bone marrow aspiration and biopsy studies can help in the management of some bone marrow diseases. This article reviews the procedures required to obtain and to process bone marrow aspirates and biopsies. It also reviews the interpretation of light microscopic studies of bone marrow samples.

CONCLUSION

Current procedures for obtaining and procuring bone marrow needle aspirates and biopsies require close interaction between the CLS and the physician. Multiple specialized assays require special handling at the time marrow samples are obtained. Serial bone marrow needle aspirates and biopsies can be very useful in guiding the clinical care of certain patients.

C-myc expression affects proliferation but not terminal differentiation or survival of explanted erythroid progenitor cells

The expression of c-myc was analyzed in murine and human erythroblasts throughout their differentiation in vitro into reticulocytes. The murine cells were splenic erythroblasts from animals infected with the anemia strain of Friend virus (FVA cells). In FVA cells cultured without EPO, the c-myc mRNA and protein levels decrease sharply within 3 to 4 h, showing that continual EPO stimulation is required to maintain c-myc expression. When cultured with EPO, the c-myc mRNA level of FVA cells is raised within 30 min of exposure. The c-myc mRNA and protein reach maxima at 1 to 3 h, then decline slowly to very low levels by 18 h. In contrast, c-fos and c-jun mRNA levels are not regulated by EPO in FVA cells. The human cells analyzed were colony-forming units-erythroid, CFU-E, derived in vitro by the culture of peripheral blood burst-forming units-erythroid (BFU-E). When grown in EPO and insulin-like growth factor 1 (IGF-1) these cells differentiate into reticulocytes over 6 days rather than the 2 days required for murine cells, but the c-myc mRNA kinetics and response to EPO parallel those of mouse cells at similar stages of differentiation. Both IGF-1 and c-kit ligand (SCF) cause an additive increase in c-myc mRNA in human CFU-E in conjunction with EPO. These additive effects suggest that EPO, IGF-1, and SCF affect c-myc mRNA accumulation by distinct mechanisms. Addition of an antisense oligonucleotide to c-myc in cultures of human CFU-E specifically inhibited cell proliferation but did not affect erythroid cell differentiation or apoptosis. When human cells were grown in high SCF concentrations, an environment which enhances proliferation and retards differentiation, antisense oligonucleotide to c-myc strongly inhibited proliferation, but such inhibition did not induce differentiation. This latter result indicates that differentiation requires signals other than depression of c-Myc and resultant depression of proliferation.

Erythropoietin stimulates transcription of the TAL1/SCL gene and phosphorylation of its protein products

Activation of the TAL1 (or SCL) gene, originally identified through its involvement by a recurrent chromosomal translocation, is the most frequent molecular lesion recognized in T-cell acute lymphoblastic leukemia. The protein products of this gene contain the basic-helix-loop-helix motif characteristic of a large family of transcription factors that bind to the canonical DNA sequence CANNTG as protein heterodimers. TAL1 expression by erythroid cells in vivo and in chemical-induced erythroleukemia cell lines in vivo suggested the gene might regulate aspects of erythroid differentiation. Since the terminal events of erythropoiesis are controlled by the glycoprotein hormone erythropoietin (Epo), we investigated whether the expression or activity of the TAL1 gene and its protein products were affected by Epo in splenic erythroblasts from mice infected with an anemia-inducing strain of Friend virus (FVA cells). Epo elicited a rapid, dose-related increase in TAL1 mRNA by increasing transcription of the gene and stabilizing one of its mRNAs. An Epo-inducible TAL1 DNA binding activity was identified in FVA cell nuclear extracts that subsequently decayed despite accumulating mRNA and protein. Induction of DNA binding activity was associated temporally with Epo-induced phosphorylation of nuclear TAL1 protein. These results indicate that Epo acts at both transcriptional and posttranscriptional levels on the TAL1 locus in Friend virus-induced erythroblasts and establish a link between Epo signaling mechanisms and a member of a family of transcription factors involved in the differentiation of diverse cell lineages.

Apoptosis in erythroid progenitors deprived of erythropoietin occurs during the G1 and S phases of the cell cycle without growth arrest or stabilization of wild-type p53

Erythropoietin (Epo) inhibits apoptosis in murine proerythroblasts infected with the anemia-inducing strain of Friend virus (FVA cells). We have shown that the apoptotic process in FVA cell populations deprived of Epo is asynchronous as a result of a heterogeneity in Epo dependence among individual cells. Here we investigated whether apoptosis in FVA cells correlated with cell cycle phase or stabilization of p53 tumor suppressor protein. DNA analysis in nonapoptotic FVA cell subpopulations cultured without Epo demonstrated little change in the percentages of cells in G1,S, and G2/M phases over time. Analysis of the apoptotic subpopulation revealed high percentages of cells in G1 and S, with few cells in G2/M at any time. When cells were sorted from G1 and S phases prior to culture without Epo, apoptotic cells appeared at the same rate in both populations, indicating that no prior commitment step had occurred in either G1 or S phase. Steady-state wild-type p53 protein levels were very low in FVA cells compared with control cell lines and did not accumulate in Epo-deprived cultures; however, p53 protein did accumulate when FVA cells were treated with the DNA-damaging agent actinomycin D. These data indicate that erythroblast apoptosis caused by Epo deprivation (i) occurs throughout G1 and S phases and does not require cell cycle arrest, (ii) does not have a commitment event related to cell cycle phase, and (iii) is not associated with conformational changes or stabilization of wild-type p53 protein.

A manual therapy approach to evaluation and treatment of a patient with a chronic lumbar nerve root irritation

The purpose of this case report is to familiarize the reader with the basic principles of the approach to manual therapy evaluation and treatment pioneered by Maitland, an Australian physical therapist. This approach involves a complete subjective examination to determine the severity, irritability, nature, and stage of the patient's complaints. In this way, the therapist may reach conclusions as to the amount and vigor of the physical examination and proceed with treatment in an analytical manner. Methodical reassessment is used to justify treatment progression. Comprehensive treatment and the rationale for this approach are discussed. Though most physical therapists are familiar with the straight-leg-raising test as a means of assessing low back pain and chronic lumbar nerve root irritation, they are often not familiar with other tests that examine neural tissues, such as the slump test. The proposed anatomical and biomechanical bases for these tests are discussed. The patient in this case study was a 50-year-old man with a physician's diagnosis of a chronic lumbar nerve root irritation. The patient was evaluated and treated in eight visits using techniques designed to evaluate neural tissues. Reassessment indicated significant symptom reduction, and the treatment was modified accordingly. Patient management, including home exercises, is discussed.

Apoptosis mediates and thymidine prevents erythroblast destruction in folate deficiency anemia

Deficiency of the vitamin folic acid causes pancytopenia by decreasing the production of new blood cells. Although impaired DNA synthesis and destruction of hematopoietic cells have been implicated, the mechanism by which folate deficiency decreases blood cell production is uncertain. An in vitro model of folate-deficient erythropoiesis was developed by using proerythroblasts isolated from folate-deficient mice that were infected with Friend leukemia virus. Proerythroblasts from folate-deficient mice had one-tenth the total folate as did proerythroblasts from control mice. The folate-deficient proerythroblasts underwent apoptosis, a form of programmed cell death, after 20-32 h in culture in folate-deficient medium. At the time of apoptosis the cells had differentiated into the later erythroblast stages and some had begun hemoglobin synthesis. Addition of either folic acid or thymidine, but not deoxycytidine or inosine, to the folate-deficient medium prevented the apoptosis and permitted proliferation and differentiation of the proerythroblasts into reticulocytes. The prevention of apoptosis by thymidine indicates (i) that decreased thymidylate synthesis plays a role in erythroblast apoptosis and the anemia of folate deficiency and (ii) that DNA cleavage is likely to be a primary event in the apoptosis of folate-deficient erythroblasts. Apoptosis of erythroblasts in the late stages of differentiation leads to decreased erythrocyte production and to anemia. The increased erythropoietin produced in response to the anemia increases the number of erythroid progenitor cells in the differentiation stages preceding those in which the cells undergo apoptosis. This population shift to earlier stage erythroblasts and proerythroblasts is characteristic of bone marrows of individuals with folate deficiency anemia.

Survival or death of individual proerythroblasts results from differing erythropoietin sensitivities: a mechanism for controlled rates of erythrocyte production

Murine erythroid progenitors infected with the anemia-inducing strain of Friend virus (FVA cells) undergo apoptosis when deprived of erythropoietin (EPO). When cultured with EPO, they survive and complete terminal differentiation. Although cell volume is decreased and nuclear chromatin is condensed during both apoptosis and terminal differentiation, morphologic and biochemical distinctions between these two processes were observed. In apoptosis, homogeneous nuclear condensation with nuclear envelope loss occurred in cells that had not reached the stage of hemoglobin synthesis. In terminal erythroid differentiation, nuclear condensation with heterochromatin, euchromatin, and nuclear envelope preservation occurred simultaneously with hemoglobin synthesis. Cells with apoptotic morphology appeared asynchronously in EPO-deprived cultures, indicating that only a portion of the cells were undergoing apoptosis at any given time. The percentages of apoptotic cells and cleaved DNA increased with time in EPO-deprived cultures. Inhibition of DNA cleavage was directly proportional to EPO concentration over a wide physiologic range, demonstrating a heterogeneity in susceptibility to apoptosis based on variability in the EPO sensitivity of individual cells. A subpopulation of FVA cells with increased EPO sensitivity (decreased EPO requirement) was isolated from EPO-deprived cultures. This increased EPO sensitivity did not result from differences in EPO receptor number, affinity, or structure, suggesting that the differences are in the signal transduction pathway. These results indicate that control of red blood cell production involves both prevention of apoptosis by EPO and heterogeneity in the EPO requirement of individual progenitor cells.

Prevention of Programmed Death in Hematopoietic Progenitor Cells by Hematopoietic Growth Factors

Hematopoietic growth factors have been thought to control blood cell production by stimulating proliferation and differentiation of hematopoietic progenitor cells. However, recent studies show that these growth factors prevent programmed death in progenitor cells. A model of hematopoiesis based on prevention of this death by hematopoietic growth factors is presented.

The use of in situ hybridization to study erythropoietin gene expression in murine kidney and liver

In situ hybridization has been used to localize erythropoietin (EPO)-producing cells in murine kidney and liver. Peritubular interstitial cells were the only cell type that produced EPO in the kidney. The EPO-producing cells were primarily concentrated in the inner cortex but were also seen in the outer medulla and outer cortex. EPO-producing cells represented less than 10% of the total interstitial cell population. The number of EPO-producing cells per square centimeter of cortex directly correlated with the amount of renal EPO mRNA and varied in an inverse exponential manner with hematocrit. These results suggest that EPO is expressed in an all-or-none fashion in peritubular interstitial cells and that the oxygen carrying capacity of blood is the major regulator of renal EPO production. Peritubular interstitial cells were also identified as the renal source of human EPO in transgenic mice that expressed human EPO mRNA is a regulated fashion in the kidney. Transgenic mice exhibiting inducible supranormal liver expression of human EPO were used to identify EPO-producing cells in the liver. Hepatocytes surrounding central veins produced human EPO in these mice. Individual hepatocytes were able to modulate their production of human EPO depending upon the severity of anemia to which they were subjected. Two types of widely scattered cells produced EPO in severely anemic nontransgenic mice. Eighty percent of EPO-producing cells were hepatocytes and 20% were classified as being nonepithelial based on their nuclear morphology and location in venous sinusoids.

Regulation of programmed death in erythroid progenitor cells by erythropoietin: effects of calcium and of protein and RNA syntheses

Erythropoietin (EPO) retards DNA breakdown characteristic of programmed cell death (apoptosis) and promotes survival in erythroid progenitor cells. The mechanism by which EPO inhibits programmed death is unknown. In the well-characterized model of glucocorticoid-treated thymocytes, activation of a Ca2+/Mg(2+)-sensitive endonuclease and new protein and RNA syntheses have been found necessary for apoptosis. We examined the effects of EPO on the free intracellular calcium ion concentration ([Ca2+]i), and the roles of Ca2+ and RNA and protein syntheses on DNA cleavage in erythroid progenitor cells. The murine model of erythroid differentiation using Friend leukemia virus-infected proerythroblasts (FVA cells) was used. EPO did not affect the [Ca2+]i in FVA cells. Decreasing [Ca2+]i by extracellular Ca2+ chelation with EGTA facilitated DNA breakdown. Increasing [Ca2+]i with the calcium ionophore 4-bromo-A23187 increased DNA cleavage; however, DNA fragments generated by high [Ca2+]i were much larger than those seen in the absence of EPO or presence of EGTA. Increased [Ca2+]i also inhibited DNA breakdown to small oligonucleosomal fragments characteristic of cells cultured without EPO. However, no concentration of ionophore protected the high molecular weight DNA as did EPO. Cycloheximide inhibited DNA breakdown in a dose dependent manner in cultures lacking EPO, but two other protein synthesis inhibitors, pactamycin and puromycin, did not prevent DNA breakdown. Inhibition of RNA synthesis with actinomycin D did not prevent DNA breakdown. Cells with morphological characteristics similar to those reported in other cells undergoing programmed death accumulated in EPO-derived cultures. These studies demonstrate that although DNA cleavage and morphological changes are common to apoptotic cells, the roles for Ca2+ and protein and RNA syntheses are not universal and suggest that apoptosis can be regulated by different biochemical mechanisms in different cell types.

Ineffective hematopoiesis in folate-deficient mice

A folate-free amino acid-based diet provided an opportunity to characterize the effects of folate depletion on growth, tissue folate levels, and hematopoiesis of mice under well-standardized conditions. Weanling mice were fed a folate-free, amino acid-based diet supplemented with either 0 or 2 mg folic acid/kg diet for 35 to 48 days. Folate concentrations were decreased in liver, kidney, serum, and erythrocytes in mice fed the folate-free diet. The folate-deficient mice had anemia, reticulocytopenia, thrombocytopenia, and leukopenia, all of which reverted to normal after folic acid was reintroduced to the diet. Hematopoietic organs of folate-deficient mice had alterations that were similar to those seen in folate-deficient humans except that in mice, the hyperplasia of hematopoietic tissue occurred in the spleen rather than in the marrow. Ferrokinetic studies showed a normal 59Fe-transferrin half-life, but the percentage of 59Fe-incorporation into red blood cells at 48 hours was markedly subnormal. The number of committed hematopoietic progenitors at the stages of erythroid colony-forming units (CFUs), megakaryocyte CFUs, and granulocyte-macrophage CFUs were all increased in folate-deficient mice. However, the progeny of these progenitors was markedly decreased in folate-deficient mice. Thus, the folate-deficient mice had "ineffective hematopoiesis" leading to pancytopenia, and they therefore provide a murine model of megaloblastic anemia.

The mechanism of erythropoietin action

Erythropoietin (Epo) is a glycoprotein hormone produced in the kidney that acts on erythroid progenitor cells in the bone marrow. A negative feedback system, in which tissue oxygenation controls Epo production and Epo controls red blood cell (RBC) production, provides homeostasis in oxygen delivery to body tissues. The target cells for the action of Epo are committed erythroid progenitor cells, which have specific receptors for the hormone. The Epo receptor is a member of a larger family of hematopoietic growth factor receptors. No known second messenger system has been implicated in signal transduction from the Epo receptor. Although Epo may have some effect on mitosis in early erythroid progenitor cells, its control of RBC production appears to occur in later stages of erythroid cell development, where it prevents programmed cell death.

Localization of cells producing erythropoietin in murine liver by in situ hybridization

In situ hybridization using antisense RNA probes was used to localize cells that produce erythropoietin (EPO) in the livers of anemic transgenic mice expressing the human EPO gene and in livers of anemic nontransgenic mice. In transgenic mice bled from a hematocrit of 55% to one of 10%, hepatocytes surrounding central veins synthesized large amounts of human EPO mRNA. EPO-producing cells were very rare in the area of portal triads. In transgenic mice bled to a hematocrit of 20%, a similar number and distribution of cells contained human EPO mRNA as was found with a 10% hematocrit, but the cells were less heavily labeled, indicating increased EPO production per cell at 10% hematocrit as compared with 20% hematocrit. No human EPO mRNA was detected in the kidneys of anemic transgenic mice, although endogenous murine EPO mRNA was strongly expressed in cortical interstitial cells. In sections of livers from nontransgenic mice bled from a hematocrit of 45% to one of 10%, only isolated cells produced EPO. When the types of cells could clearly be identified, approximately 80% of these cells were hepatocytes, while 20% had a nonepithelial morphology and were located in or adjacent to the sinusoidal spaces. When the sense strand was used as the RNA probe for in situ hybridization, no labeled cells were seen in normal or anemic livers. These results demonstrate that hepatocytes are responsible for production of EPO in both transgenic and nontransgenic mice and that a second cell type that is similar in morphology to EPO-producing interstitial cells in the kidney also produces EPO in the livers of nontransgenic mice.

Metabolic adaptation during erythropoietin-mediated terminal differentiation of mouse erythroid cells

Metabolic development was examined in erythroid precursor cells, which were isolated from the spleens of mice infected with the anemia-inducing strain of Friend virus (FVA cells). FVA cells undergo differentiation in vitro from the proerythroblast stage through the reticulocyte stage over a 48-hour period in the presence of erythropoietin. Concomitant with marked decreases in cellular size and energy demand, metabolic capacities of both glycolysis and oxygen consumption diminish after 48 hours in culture by 7- and 18-fold, respectively. Because the oxidative capacity decreases more than glycolytic ability does, the metabolic machinery increasingly shifts toward anaerobic metabolism. During the 48-hour period of differentiation, the 2,3-diphosphoglyceric acid (DPG) content per cell and 2,3-DPG mutase activity per cell increased eightfold and threefold, respectively. Freshly harvested FVA cells have adenosine triphosphate (ATP) levels of 7.23 +/- 2.52 mumol/10(10) cells or 3.76 +/- 1.31 mumol/mL cell water which are 12- or 2.3-fold higher, respectively, than the ATP levels of mature red blood cells. In the course of FVA cell differentiation, ATP content per cell decreases by fourfold, but ATP concentration in cell water remains unchanged because of a corresponding decrease in cellular size and water content during differentiation. These studies show that in the face of dramatic decreases in cell size and cellular energy demand, terminally differentiating erythroid cells maintain a constant ATP level by undergoing an involution of their glycolytic machinery as well as by losing their aerobic metabolic capacity.

Thrombocytopenic purpura in HIV-seronegative users of intravenous cocaine

Severe thrombocytopenic purpura occurred in seven patients who had histories of recent or current intravenous cocaine use. All of the patients denied heroin use and all were seronegative for antibodies to the human immunodeficiency virus (HIV). The seven patients had normal or increased numbers of megakaryocytes in their bone marrows. While receiving corticosteroid therapy their platelet counts rose to 10(11)/L over periods ranging from 5 to 11 days. In view of the widespread use of cocaine, severe thrombocytopenia in the HIV-seronegative patient should suggest the possibility of current or recent intravenous use of cocaine.

Erythropoietin retards DNA breakdown and prevents programmed death in erythroid progenitor cells

The mechanism by which erythropoietin controls mammalian erythrocyte production is unknown. Labeling experiments in vitro with [3H]thymidine demonstrated DNA cleavage in erythroid progenitor cells that was accompanied by DNA repair and synthesis. Erythropoietin reduced DNA cleavage by a factor of 2.6. In the absence of erythropoietin, erythroid progenitor cells accumulated DNA cleavage fragments characteristic of those found in programmed cell death (apoptosis) by 2 to 4 hours and began dying by 16 hours. In the presence of erythropoietin, the progenitor cells survived and differentiated into reticulocytes. Thus, apoptosis is a major component of normal erythropoiesis, and erythropoietin controls erythrocyte production by retarding DNA breakdown and preventing apoptosis in erythroid progenitor cells.

Cytoskeletal distribution and function during the maturation and enucleation of mammalian erythroblasts

We have used murine splenic erythrolasts infected with the anemia-inducing strain of Friend virus (FVA cells), as an in vitro model to study cytoskeletal elements during erythroid maturation and enucleation. FVA cells are capable of enucleating in suspension culture in vitro, indicating that associations with an extracellular matrix or accessory cells are not required for enucleation to occur. The morphology of FVA cells undergoing enucleation is nearly identical to erythroblasts enucleating in vivo. The nucleus is segregated to one side of the cell and then appears to be pinched off resulting in an extruded nucleus and reticulocyte. The extruded nucleus is surrounded by an intact plasma membrane and has little cytoplasm associated with it. Newly formed reticulocytes have an irregular shape, are vacuolated and contain all cytoplasmic organelles. The spatial distribution of several cytoskeletal proteins was examined during the maturation process. Spectrin was found associated with the plasma membrane of FVA cells at all stages of maturation but was segregated entirely to the incipient reticulocyte during enucleation. Microtubules formed cages around nuclei in immature FVA cells and were found primarily in the incipient reticulocyte in cells undergoing enucleation. Reticulocytes occasionally contained microtubules, but a generalized diffuse distribution of tubulin was more common. Vimentin could not be detected at any time in FVA cell maturation. Filamentous actin (F-actin) had a patchy distribution at the cell surface in the most immature erythroblasts, but F-actin bundles could be detected as the cells matured. F-actin was found concentrated between the extruding nucleus and incipient reticulocyte in enucleating erythroblasts. Newly formed reticulocytes exhibited punctate actin fluorescence whereas extruded nuclei lacked F-actin. Addition of colchicine, vinblastine, or taxol to cultures of FVA cells did not affect enucleation. In contrast, cytochalasin D caused a complete inhibition of enucleation that could be reversed by washing out the cytochalasin D. These results demonstrate that F-actin plays a role in enucleation while the complete absence of microtubules or excessive numbers of polymerized microtubules do not affect enucleation.

Quantitation of erythropoietin-producing cells in kidneys of mice by in situ hybridization: correlation with hematocrit, renal erythropoietin mRNA, and serum erythropoietin concentration

In situ hybridization was used to quantitate the cells that produce erythropoietin (EP) in the renal cortices of mice with varying severities of acute anemia and of mice recovering from severe, acute anemia. The number of EP-producing cells in the renal cortex increased in an exponential manner as hematocrit was decreased. Individual EP-producing cells had very similar densities of silver grains in autoradiograms regardless of whether they were from normal mice or from slightly, moderately or severely anemic animals. With increasingly severe anemia, total renal EP mRNA levels and serum EP concentrations showed increases that correlated with the number of renal EP-producing cells. These results indicate that as mice become more anemic, additional cells are recruited to produce EP rather than the cells already producing EP being stimulated to increase their individual production. In mildly and moderately anemic animals, small clusters of EP-producing cells were found in the inner cortex with large areas of cortex containing no EP-producing cells. In severely anemic mice, EP-producing cells were found throughout the inner cortex with only a very few found scattered in the outer cortex and outer medulla. The data indicate that only a subset of total renal interstitial cells produce EP. During recovery from severe, acute anemia, the numbers of EP-producing cells decreased exponentially as hematocrits rose and correlated with decreases in total renal EP mRNA and serum EP concentrations. These results suggest that following an acute blood loss and during the recovery from a blood loss, the capacity to deliver oxygen, as represented by hematocrit, is the major regulator of EP production.

Maintenance by erythropoietin of viability and maturation of murine erythroid precursor cells

Erythroblasts isolated from the spleens of mice infected with the anemia-inducing strain of Friend virus (FVA cells)-are erythropoietin (EP)-sensitive cells at the late colony forming unit-erythroid (CFU-E) and cluster forming unit stages of differentiation (Koury et al., J. Cell. Physiol. 121:526-532, 1984). We investigate here the EP requirements of FVA cells in vitro for viability, proliferation, and maturation. By delaying the addition of EP to FVA cell cultures or by withdrawing EP at early times of culture, the subsequent viability, cell numbers, and maturation were diminished. The longer the delay in EP addition or the earlier the EP withdrawal, the more diminished these parameters were when compared to cultures which contained EP throughout the 48 h of differentiation. FVA cells had a period of EP requirement in vitro that lasted for only 24 h or less after the initiation of culture. During these crucial first 24 h, EP induced an increase in the synthesis of all size classes of RNA. Protein synthesis was maintained at a stable level in cells cultured with EP, but it declined in cells cultured without it. In contrast, the synthesis rate of DNA and the content of DNA per cell were not affected by the presence of EP in the culture. However, FVA cells cultured without EP had progressive accumulation of small sized DNA due to breakage of higher molecular weight DNA. The rate of DNA breakdown was sufficient to prevent DNA accumulation and thus it probably plays a role in the abortion of cell proliferation. No such breakage was found in cells cultured with EP. Our results indicate that EP exerts an effect on FVA cells in culture which is reflected in their viability, cell number, and maturation. This effect is not mediated by a stimulation of the rate of DNA synthesis, but is accompanied by stimulation of overall RNA synthesis and maintenance of protein synthesis.

Morphological changes in erythroblasts during erythropoietin-induced terminal differentiation in vitro

Immature murine erythroblasts infected with the anemia-inducing strain of Friend virus (FVA cells) differentiate in vitro under the influence of erythropoietin (EP). These cells were used as a model for the examination of morphological changes occurring during terminal erythroid differentiation. FVA cells differentiate more completely in vitro in response to EP than continuous erythroleukemia cell lines do in response to chemical induction. Because they can be isolated in much greater numbers and in much higher purity than bone marrow or spleen cells explanted from anemic mice, FVA cells are an attractive alternative for studies of mammalian terminal erythroid differentiation. FVA cells cultured with EP followed a sequence of differentiation events that included a progressive decrease in cell size, disappearance of nucleoli, condensation of nuclei, and accumulation of hemoglobin. After 45 h of culture most FVA cells enucleated, giving rise to vacuolated reticulocytes and free nuclei that were surrounded by a thin layer of cytoplasm and a plasma membrane. The ratio of nuclear to cytoplasmic volumes increased significantly by 24 h of culture but did not change significantly from 24 through 36 h of culture. Variation in the morphology of enucleating FVA cells indicated that not all cells proceeded through a rigorously defined series of morphological stages prior to enucleation. These results are discussed in terms of previous studies of erythroblast maturation.

Erythropoietin messenger RNA levels in developing mice and transfer of 125I-erythropoietin by the placenta

Erythropoietin (EP) mRNA was measured in normal and anemic mice during fetal and postnatal development. Normal fetal livers at 14 d of gestation contained a low level of EP mRNA. By day 19 of gestation, no EP mRNA was detected in normal or anemic fetal livers or normal fetal kidneys, but anemic fetal kidneys had low levels of EP mRNA. Newborn through adult stage mice responded to anemia by accumulating renal and hepatic EP mRNA. However, total liver EP mRNA was considerably less than that of the kidneys. Juvenile animals, 1-4 wk old, were hyperresponsive to anemia in that they produced more EP mRNA than adults. Moreover, nonanemic juveniles had readily measured renal EP mRNA, whereas the adult level was at the lower limit of detection. Because of the very low level of fetal EP mRNA, placental transfer of EP was evaluated. When administered to the pregnant mouse, 125I-EP was transferred in significant amounts to the fetuses. These results indicate that in mice the kidney is the main organ of EP production at all stages of postnatal development and that adult kidney may also play some role in providing EP for fetal erythropoiesis via placental transfer of maternal hormone.

Localization of erythropoietin synthesizing cells in murine kidneys by in situ hybridization

In situ hybridization was used to localize the cells that produce erythropoietin (EP) in anemic murine kidneys. Kidneys from anemic and nonanemic mice were fixed and processed for paraffin embedding. Sections were hybridized with a 35S-labeled RNA probe complementary to mRNA coding for EP. An uncommon, but specific type of cell was intensely labeled in the cortices of anemic kidneys. The labeled cells were clearly nonglomerular and nontubular. Their location outside of the tubular basement membrane was consistent with that of a subset of interstitial cells or capillary endothelial cells.

Changes in erythroid membrane proteins during erythropoietin-mediated terminal differentiation

Membrane and membrane skeleton proteins were examined in erythroid progenitor cells during terminal differentiation. The employed model system of erythroid differentiation was that in which proerythroblasts from mice infected with the anemia-inducing strain of Friend virus differentiate in vitro in response to erythropoietin (EP). With this system, developmentally homogeneous populations of cells can be examined morphologically and biochemically as they progress from proerythroblasts through enucleated reticulocytes. alpha and beta spectrins, the major proteins of the erythrocyte membrane skeleton, are synthesized in the erythroblasts both before and after EP exposure. At all times large portions of the newly synthesized spectrins exist in and are turned over in the cytoplasm. The remaining newly synthesized spectrin is found in a cellular fraction containing total membranes. Pulse-chase experiments show that little of the cytoplasmic spectrins become membrane associated, but that the proportion of newly synthesized spectrin which is membrane associated increases as maturation proceeds. A membrane fraction enriched in plasma membranes has significant differences in the stoichiometry of spectrin accumulation as compared to total cellular membranes. Synthesis of band 3 protein, the anion transporter, is induced only after EP addition to the erythroblasts. All of the newly synthesized band 3 is membrane associated. A two-dimensional gel survey was conducted of newly synthesized proteins in the plasma membrane enriched fraction of the erythroblasts as differentiation proceeded. A majority of the newly synthesized proteins remain in the same proportion to each other during maturation; however, a few newly synthesized proteins greatly increase following EP induction while others decrease markedly. Of the radiolabeled proteins observed in two dimensional gels, only the spectrins, band 3 and actin become major proteins of the mature erythrocyte membrane. Examination of total proteins of the plasma membrane enriched fractions of EP-treated erythroblasts using silver staining and 32P autoradiography show that many proteins and phosphoproteins are selectively eliminated from this fraction late in the course of differentiation during the reticulocyte stage. The selective removal of many proteins at the reticulocyte stage of development combined with previous selective synthesis and accumulation of some specific proteins such as alpha and beta spectrin and band 3 in the differentiating erythroblasts lead to the final mammalian erythrocyte membrane structure.

Induction of megakaryocytic colony-stimulating activity in mouse skin by inflammatory agents and tumor promoters

The production of megakaryocytic colony-stimulating activity (MEG-CSA) was assayed in acetic acid extracts of skin from mice topically treated with inflammatory and tumor-promoting agents. A rapid induction of MEG-CSA was found in skin treated both with phorbol 12-myristate 13-acetate (PMA), a strong tumor promoter, and with mezerein, a weak tumor promoter, but no induction was found in untreated skin. The time course of induction of MEG-CSA following treatment of skin with PMA or mezerein was very similar to that previously demonstrated for the induction of granulocyte-macrophage colony-stimulating activity in mouse skin by these agents. The induced MEG-CSA was found in both the epidermis and the dermis. Pretreatment of the skin with beta-methasone abrogated the MEG-CSA induction. The cell number response curve suggests that the MEG-CSA acts directly on the progenitor cells of the megakaryocyte colonies. That topical administration of diterpene esters results in the rapid, local induction of MEG-CSA which can be blocked by beta-methasone pretreatment suggests a mechanism for the thrombocytosis associated with some inflammatory states. The indirect action in which diterpene esters induce in certain cells the production or release of growth regulatory factors for other cell types may also aid in understanding their carcinogenic properties.

Anemia induces accumulation of erythropoietin mRNA in the kidney and liver

Regulation of the production of erythropoietin occurs in the kidney and liver largely through control of accumulation of erythropoietin mRNA. Erythropoietin mRNA was first detected in kidneys at 1.5 h postanemia and reached a plateau value at least 200-fold above the control value by 4 to 8 h. A 20-base sequence immediately upstream from the reported erythropoietin mRNA initiation site is complementary to a hypervariable sequence in 18S rRNA.

The role of erythropoietin in the production of principal erythrocyte proteins other than hemoglobin during terminal erythroid differentiation

Erythropoietin (EP) controls the terminal phase of differentiation in which proerythroblasts and their precursors, the colony forming units-erythroid (CFU-e), develop into erythrocytes. Biochemical studies of this hormone-directed terminal differentiation have been hindered by the lack of a homogeneous population of erythroid cells at the developmental stages of CFU-e and proerythroblasts that will synchronously differentiate in response to EP. Such a population of cells can be prepared from the spleens of mice with the acute erythroblastosis resulting from infection with anemia-inducing Friend virus (FVA). Using these FVA-infected erythroid cells, which were induced to differentiate with EP, four proteins other than hemoglobin that have key functions in mature erythrocytes were monitored during the 48-hour period of terminal differentiation. Synthesis of spectrin and membrane band 3 proteins were determined by immunoprecipitation and SDS-polyacrylamide gel electrophoresis; accumulation of the cytoskeletal protein band 4.1 was monitored by immunoblotting; carbonic anhydrase activity was measured electrometrically. Band 3 synthesis and band 4.1 accumulation could be detected only after exposure of the cells to EP. Spectrin synthesis was ongoing prior to culture with EP, but it did increase after exposure to the hormone. Carbonic anhydrase-specific activity changed very little throughout the terminal differentiation process. These results reveal at least three patterns of production of principal erythrocyte proteins during EP-mediated terminal differentiation of FVA-infected erythroid cells. Depending on the specific protein examined, de novo synthesis can be induced by EP, an ongoing production can be enhanced by EP, or the production of a protein can be completed at a developmental stage prior to EP-mediated differentiation in these cells.

Control of globin gene transcription by erythropoietin in erythroblasts from friend virus-infected mice

Splenic erythroblasts of mice infected with the anemia-inducing strain of Friend virus can be isolated in large numbers with less than 5% contamination with other cell types. In short-term culture, the isolated cells will initiate globin synthesis and undergo other aspects of terminal differentiation only if erythropoietin (EP) is added to the medium. An early effect of the hormone on these cells is stimulation of total RNA synthesis. EP also causes initiation of transcription of the beta-globin genes after a lag period of 4 to 6 h. By 6 h, the transcription rate of beta-globin RNA is enhanced threefold, and by 12 h, it is nearly maximal at ca. 20 times the level of control cells which received no EP. Transcription rates of alpha and beta-globin genes are approximately equal to each other throughout the period of terminal differentiation. In the splenic erythroblasts, the chromatin structure in the vicinity of the beta-major globin gene was analyzed with two nucleases during these transcription rate changes. No S1 nuclease-hypersensitive site is detectable near the gene. The beta-major gene is quite sensitive to DNase I in comparison with the albumin gene; however, the level of sensitivity is the same before EP addition as it is during maximal gene transcription after EP addition. Also, a hypersensitive site near the 5' cap site of the beta-major gene is quantitatively equivalent both before and after EP addition. Analysis of cytosine methylation at two sites upstream from the gene showed no changes upon induction of beta-globin gene transcription by EP. Thus, the initiation of beta-globin transcription by EP appears to be at some step after chromatin structural alteration such as synthesis, release, or activation of a specific transcription initiation factor.

The Fv-2 gene controls induction of erythroid burst formation by Friend virus infection in vitro: studies of growth regulators and viral replication

When infected in vitro with Friend virus complex, the bone marrow cells of susceptible mice form large colonies (bursts) of erythroblasts after 5 days of culture in semi-solid medium. This virus-induced burst growth occurs without the addition of erythropoietin (EP) which is normally required for erythroid progenitor growth in vitro. Erythroid progenitor cells from C57BL/6 mice infected in vitro with Friend virus are resistant to virus-induced burst growth, while cells from the B6.S mouse strain, which is congenic with C57BL/6 but possesses the 'Friend virus sensitivity' alleles at the Fv-2 locus, are susceptible. This susceptibility of the B6.S cells demonstrates that virus-induced burst growth is regulated by the Fv-2 gene. Two mechanisms by which the Fv-2 locus could control virus resistance were analysed. The possible modulation of the erythroproliferative effect of the virus by soluble substances which either promote burst growth in the sensitive strains or inhibit growth in the resistant strain was examined. Also, the possible restriction of virus infection or replication in resistant (Fv-2rr) haemopoietic cells was investigated. In a variety of experimental conditions designed to test the effects of soluble growth promoters on bone marrow cells infected in vitro, the resistance of C57BL/6 cells to erythroid burst formation could not be overcome. Neither could resistance be transferred to co-cultured sensitive cells by any soluble substances produced in culture by C57BL/6 cells. Use of haemopoietic cells from C57BL/6 animals in various physiological states of haemopoiesis also did not overcome the resistance to virus-induced burst growth. Quantification of several parameters of viral replication in whole marrow cultures or in erythroblasts from bursts of the Fv-2 sensitive and Fv-2 resistant congenic mouse strains showed that haemopoietic cells of both strains support virus growth equally well. These data suggest that Fv-2rr-mediated resistance to the erythroproliferative effect of Friend virus infection in vitro is an inherent property of an erythroid progenitor target cell and is not determined by external factors. The resistance is also not due to restriction of virus replication.