Renal pathology in hemizygous sickle cell mice.

Transgenic mice have been developed that express exclusively human sickle cell beta hemoglobin and have major pathological features found in humans with sickle cell disease. These mice provide a unique opportunity to investigate the fundamental mechanisms of this disease and to design new strategies to correct the associated genetic defect(s). We found that in breeding males expressing only adult human alpha-globin and sickle beta-globin (homozygous SS mice) with females containing these transgenes plus one copy of the mouse beta-globin gene (hemizygous SS mice) greater than expected numbers of hemizygous offspring were produced than homozygous mice (carrying no mouse beta-globin gene). These hemizygous mice, expressing the human alpha and sickle beta(s) transgenes in combination with mouse beta+/-, were used for our preliminary studies of their renal pathology. No kidney lesions were found in the control (129/Sv) mice, whereas about 50% of the hemizygous SS mice showed mild-to-severe kidney lesions, including glomerulonephritis, cystic atypical hyperplastic tubules, and general nephropathy. Kidneys of some hemizygous mice were normal or showed minimal nephropathy, yet those of the susceptible phenotype developed a mild-to-more-severe form of renal lesions. The tubular epithelium of kidneys of hemizygous mice of the more affected phenotype exhibited increased expression of inducible nitric oxide synthase with an increased 3-nitrotyrosine in close proximity. There was also a stronger immunostaining for vascular cell adhesion molecule-1 in the interstitial capillary cells as well as the tubular epithelial cells of the renal cortex, compared with normal control mice. The occurrence of a high incidence of renal abnormalities in our hemizygous SS mice suggests that these mice may provide a suitable model to study the pathogenesis of nephropathy resulting from altered blood flow and/or insufficient oxygen delivery.

Molecular analysis of transferrin receptor mRNA expression in acute myeloid leukaemia.

Transferrin receptor (TfR, CD71) is an integral membrane glycoprotein that mediates cellular uptake of iron. In most tissues, TfR expression is correlated positively with proliferation and regulated at the post-transcriptional level. The available data regarding the pattern of TfR gene expression in haematological malignancies are very limited. In the present study, we evaluated TfR gene expression at the molecular level in bone marrow (BM) samples of 44 patients with de novo acute myeloid leukaemia (AML) at diagnosis with BM blasts > 85%. TfR mRNA levels were determined by densitometric analysis of quantitative reverse transcription polymerase chain reaction products corresponding to TfR exons 15-17. Each sample was tested in at least two independent experiments. In 13/44 patients, TfR messages were not detected (this is probably an underestimate as some positive results may be attributed to residual normal erythroid cells present in the samples). In 17/44, TfR mRNA levels were low-intermediate, and were high in the remaining patients (14/44). TfR mRNA positivity was significantly associated with older age. No statistically significant correlations were found either with specific French-American-British (FAB) subtypes or attainment of complete remission, incidence of relapse and survival (after adjusting accordingly for age and FAB subtype). The absence of TfR mRNA transcripts in a significant minority of cases suggests that alternative mechanisms of iron uptake may function in AML blast cells.

Nitric oxide transport on sickle cell hemoglobin: where does it bind?

We have recently reported that nitric oxide inhalation in individuals with sickle cell anemia increases the level of NO bound to hemoglobin, with the development of an arterial-venous gradient, suggesting delivery to the tissues. A recent model suggests that nitric oxide, in addition to its well-known reaction with heme groups, reacts with the beta-globin chain cysteine 93 to form S-nitrosohemoglobin (SNO-Hb) and that SNO-Hb would preferentially release nitric oxide in the tissues and thus modulate blood flow. However, we have also recently determined that the primary NO hemoglobin adduct formed during NO breathing in normal (hemoglobin A) individuals is nitrosyl (heme)hemoglobin (HbFeIINO), with only a small amount of SNO-Hb formation. To determine whether the NO is transported as HbFeIINO or SNO-Hb in sickle cell individuals, which would have very different effects on sickle hemoglobin polymerization, we measured these two hemoglobin species in three sickle cell volunteers before and during a dose escalation of inhaled NO (40, 60, and 80 ppm). Similar to our previous observations in normal individuals, the predominant species formed was HbFeIINO, with a significant arterial-venous gradient. Minimal SNO-Hb was formed during NO breathing, a finding inconsistent with significant transport of NO using this pathway, but suggesting that this pathway exists. These results suggest that NO binding to heme groups is physiologically a rapidly reversible process, supporting a revised model of hemoglobin delivery of NO in the peripheral circulation and consistent with the possibility that NO delivery by hemoglobin may be therapeutically useful in sickle cell disease.

The human erythropoietin receptor gene rescues erythropoiesis and developmental defects in the erythropoietin receptor null mouse.

Erythropoietin and its receptor are required for definitive erythropoiesis and maturation of erythroid progenitor cells. Mice lacking the erythropoietin receptor exhibit severe anemia and die at about embryonic day 13.5. This phenotype can be rescued by the human erythropoietin receptor transgene. Animals expressing only the human erythropoietin receptor survived through adulthood with normal hematologic parameters and appeared to respond appropriately to induced anemic stress. In addition to restoration of erythropoiesis during development, the cardiac defect associated with embryos lacking the erythropoietin receptor was corrected and the increased apoptosis in fetal liver, heart, and brain in the erythropoietin receptor null phenotype was markedly reduced. These studies indicate that no species barrier exists between mouse and human erythropoietin receptor and that the human erythropoietin receptor transgene is able to provide specific expression in hematopoietic and other selected tissues to rescue erythropoiesis and other organ defects observed in the erythropoietin receptor null mouse.

Pathophysiology of a sickle cell trait mouse model: human alpha(beta)(S) transgenes with one mouse beta-globin allele.

As a potential model for sickle cell trait (AS), we examined mice containing one normal mouse beta-globin allele in combination with a human hemoglobin S (h(alpha)beta(S)) transgene (m(beta)/hS). The mice segregated into two subpopulations containing low and high proportions of hemoglobin S (m(beta)/hS1 and m(beta)/hS2, respectively) that was associated with one or two human h(alpha)beta(S) transgenes. We noted striking kidney pathology (cortical cysts, hyperplastic tubules, and glomerulonephritis), increasing with age and with greater severity in m(beta)/hS1. mBeta/hS2 animals were largely tolerant to 5% O(2) for 1 h, whereas 80% of m(beta)/hS1 mice died, exhibiting acute sequestration of erythrocytes in spleen, liver, and heart. These pathologies appear to result from a decreased oxygen affinity of the hybrid (human alpha/mouse beta) hemoglobins with a mild beta-thalassemia phenotype. Thus, these mouse models of sickle trait seem to manifest their renal pathology and sensitivity to hypoxia by mechanisms related to low tissue oxygen delivery and are different from the human syndrome. Analyses of parameters such as P(50), red cell indices, and genetic background are necessary in establishing potential relevance of any mouse model of the sickle cell syndromes.

A negative cis-element regulates the level of enhancement by hypersensitive site 2 of the beta-globin locus control region.

The core of DNase hypersensitive site (HS) 2 from the beta-globin locus control region is a potent enhancer of globin gene expression. Although it has been considered to contain only positive cis-regulatory sequences, our study of the enhancement conferred by segments of HS2 in erythroid cells reveals a novel negative element. Individual cis-regulatory elements from HS2 such as E boxes or Maf-response elements produced as great or greater enhancement than the intact core in mouse erythroleukemia (MEL) cells, indicating the presence of negative elements within HS2. A deletion series through HS2 revealed negative elements at the 5' and 3' ends of the core. Analysis of constructs with and without the 5' negative element showed that the effect is exerted on the promoters of globin genes expressed at embryonic, fetal, or adult stages. The negative effect was observed in bipotential human cells (K562 and human erythroleukemia (HEL) cells), proerythroblastic mouse (MEL) cells, and normal adult human erythroid cells. The novel negative element also functions after stable integration into MEL chromosomes. Smaller deletions at the 5' end of the HS2 core map the negative element within a 20-base pair region containing two conserved sequences.

Production and processing of erythropoietin receptor transcripts in brain.

The expression of erythropoietin receptor (EpoR) in brain and neuronal cells, and hypoxia-responsive production of erythropoietin (Epo) in the brain suggests that the function of Epo as a survival or viability factor may extend beyond hematopoietic tissue and erythroid progenitor cells. Epo, produced by astrocytes and neurons, can be induced by hypoxia by severalfold, and in animal models Epo administration is neuroprotective to ischemic challenge. We characterized the human EpoR transcript in brain and neuronal cells to determine its contribution in regulating the Epo response in brain. Screening of a human brain cDNA library and quantitative analysis of EpoR transcripts indicate that the EpoR gene locus is transcriptionally active in brain. In addition to the proximal promoter that is active in hematopoietic cells, a significant proportion of transcripts originates far upstream from the EpoR coding region. Unlike erythroid cells with efficient splicing of EpoR transcripts to its mature form, brain EpoR transcripts are inefficiently or alternately processed with a bias towards the 3' coding region. In human EpoR transgenic mice, anemic stress induces expression of the transgene and endogenous EpoR gene in hematopoietic tissue and brain. In culture of neuronal cells, hypoxia induces EpoR expression and increases sensitivity to Epo. Induction of EpoR expression appears to be a consequence of increased transcription from the upstream region and proximal promoter, and a shift towards increased processing efficiency. These data suggest that in contrast to erythropoiesis where erythroid progenitor cells express high levels of EpoR and are directly responsive to Epo stimulation, the neuroprotective effect of Epo and its receptor may require two molecular events: the induction of Epo production by hypoxia and an increase in EpoR expression in neuronal cells resulting in increased sensitivity to Epo.

Erythropoietin stimulates proliferation and interferes with differentiation of myoblasts.

Erythropoietin (Epo) is required for the production of mature red blood cells. The requirement for Epo and its receptor (EpoR) for normal heart development and the response of vascular endothelium and cells of neural origin to Epo provide evidence that the function of Epo as a growth factor or cytokine to protect cells from apoptosis extends beyond the hematopoietic lineage. We now report that the EpoR is expressed on myoblasts and can mediate a biological response of these cells to treatment with Epo. Primary murine satellite cells and myoblast C2C12 cells, both of which express endogenous EpoR, exhibit a proliferative response to Epo and a marked decrease in terminal differentiation to form myotubes. We also observed that Epo stimulation activates Jak2/Stat5 signal transduction and increases cytoplasmic calcium, which is dependent on tyrosine phosphorylation. In erythroid progenitor cells, Epo stimulates induction of transcription factor GATA-1 and EpoR; in C2C12 cells, GATA-3 and EpoR expression are induced. The decrease in differentiation of C2C12 cells is concomitant with an increase in Myf-5 and MyoD expression and inhibition of myogenin induction during differentiation, altering the pattern of expression of the MyoD family of transcription factors during muscle differentiation. These data suggest that, rather than acting in an instructive or specific mode for differentiation, Epo can stimulate proliferation of myoblasts to expand the progenitor population during differentiation and may have a potential role in muscle development or repair.

Quantitative PCR analysis of HbF inducers in primary human adult erythroid cells.

The development and evaluation of drugs to elevate fetal hemoglobin in the treatment of the genetic diseases of hemoglobin would be facilitated by the availability of reliable cell assays. We have used real-time, quantitative polymerase chain reaction (PCR) analyses of globin messenger RNA (mRNA) levels in a biphasic, erythropoietin-dependent primary culture system for human adult erythroid cells in order to assay compounds for their ability to modulate levels of adult (beta) and fetal (gamma) globin mRNA. Complementary DNA synthesized from total RNA extracted at timed intervals from aliquots of cells were assayed throughout the period that the culture was studied. gamma-globin mRNA levels were found to be much lower (less than 1%) than beta-globin mRNA levels. At concentrations of agents chosen for minimal effect on cell division, we find that the 3 drugs studied, 5-azacytidine (5 micromol/L), hydroxyurea (40 micromol/L), and butyric acid (0.5 mmol/L), significantly increase gamma-globin mRNA levels. Interestingly, hydroxyurea also had a small stimulatory effect on beta-globin mRNA levels, while butyric acid caused a twofold inhibition of beta-globin mRNA levels, and 5-azacytidine had little effect on beta-globin mRNA levels. The net result of all 3 drugs was to increase the gamma/(gamma + beta) mRNA ratios by threefold to fivefold. These data suggest that the mechanism is distinct for each drug. The profile of butyric-acid-induced changes on globin gene expression is also quite distinct from changes produced by trichostatin A, a known histone deacetylase inhibitor. Quantitative PCR analyses of human erythroid cells should prove useful for studying the mechanism(s) of action of known inducers of gamma-globin and identifying new drug candidates.

Levels of GATA-1/GATA-2 transcription factors modulate expression of embryonic and fetal hemoglobins.

GATA transcription factors bind the consensus sequence WGATAR, present in the flanking regions of most erythroid specific genes. GATA-1 and GATA-2, coexpressed in erythroid cells, are important for expression of erythroid genes. To elucidate the role of specific GATA transcription factors on globin gene expression, we examined the human alpha- and beta-globin gene clusters for all GATA sites. Conserved GATA sites were found in each of the hypersensitive sites in both beta-and alpha clusters and in proximal regulatory regions of the zeta-, epsilon- and gamma-globin but not the alpha, delta or beta-globin genes. We then tested the effect of increasing levels of GATA-1 and GATA-2 on the expression of endogenous globin genes in human erythroid cells. Increasing GATA-1 levels in K562 cells decreased the levels of epsilon-globin mRNA but had no effect on the levels of expression of gamma, zeta or alpha-globin genes. Increasing GATA-2 levels increased epsilon-globin and gamma-globin transcripts. Increasing levels of GATA-1 also caused a decrease in the expression of endogenous GATA-2, while increased levels of GATA-2 had no effect on GATA-1 mRNA. Our results indicate a differential role of GATA-1 and -2 transcription factors on globin transcripts and suggest a correlation between the conservation of GATA sites in the regulatory regions and the ability of endogenous globin genes to respond to GATA transcription factors. They also suggest that quantitative changes in the levels of GATA-1 or GATA-2 can result in alterations of globin target gene expression and may participate in the ontogenic control of the globin genes.

Overexpression of GATA-2 inhibits erythroid and promotes megakaryocyte differentiation.

GATA-1 and GATA-2 transcription factors are required for effective hematopoiesis. These regulatory proteins present overlapping yet distinct patterns of expression in hematopoietic cells. Absence of GATA-2 leads to defective hematopoiesis and an embryonic lethal phenotype. Disruption of GATA-1 results in a compensatory increase in GATA-2 in early erythroid cells and incomplete erythropoiesis with embryos dying at 11.5 days. We examine the specific role of GATA-2 later in hematopoiesis, during erythroid differentiation. Stable K562 cell lines expressing various levels of GATA-2 were generated using a GATA-2 expression plasmid. Overexpression of GATA-2 transcripts was determined by quantitative polymerase chain reaction (PCR). Cytospin smears, growth curve analysis, PCR, and flow cytometry were used to examine the effects of increased levels of GATA-2 in altering cell phenotype and activation of megakaryocytic markers. Human progenitor erythroid cells also were transfected with a GATA-2 expression vector. Growth curve analysis, benzidine staining, and high-performance liquid chromatographic analysis were used to study the effects of GATA-2 on erythroid maturation and proliferation.K562/GATA-2 cell lines expressing high levels of GATA-2 mRNA showed a marked decrease in proliferation and a shift in phenotype toward the megakaryocyte lineage. Ploidy analyses showed that these cell lines developed a multinuclear phenotype, including tetraploids and octaploids. PCR analysis showed activation of megakaryocyte-specific genes including thrombopoietin receptor (c-mpl). Surface expression of platelet glycoprotein receptors Ib/IX (CD42b/CD42a) and IIb/IIIa (CD41/CD61) also was demonstrated by flow cytometry. In primary human adult erythroid cultures transfected with a GATA-2 expression vector, production of total hemoglobin and cell proliferation decreased in a dose-dependent manner.GATA-2 plays an important role in deciding cell lineage throughout hematopoiesis, and increased expression of GATA-2 determines megakaryocytic differentiation. Downregulation of GATA-2 is required for erythroid differentiation.

A minimal cytoplasmic subdomain of the erythropoietin receptor mediates erythroid and megakaryocytic cell development.

Signals provided by the erythropoietin (Epo) receptor are essential for the development of red blood cells, and at least 15 distinct signaling factors are now known to assemble within activated Epo receptor complexes. Despite this intriguing complexity, recent investigations in cell lines and retrovirally transduced murine fetal liver cells suggest that most of these factors and signals may be functionally nonessential. To test this hypothesis in erythroid progenitor cells derived from adult tissues, a truncated Epo receptor chimera (EE372) was expressed in transgenic mice using a GATA-1 gene-derived vector, and its capacity to support colony-forming unit-erythroid proliferation and development was analyzed. Expression at physiological levels was confirmed in erythroid progenitor cells expanded ex vivo, and this EE372 chimera was observed to support mitogenesis and red blood cell development at wild-type efficiencies both independently and in synergy with c-Kit. In addition, the activity of this minimal chimera in supporting megakaryocyte development was tested and, remarkably, was observed to approximate that of the endogenous receptor for thrombopoietin. Thus, the box 1 and 2 cytoplasmic subdomains of the Epo receptor, together with a tyrosine 343 site (each retained within EE372), appear to provide all of the signals necessary for the development of committed progenitor cells within both the erythroid and megakaryocytic lineages.

Inhaled nitric oxide augments nitric oxide transport on sickle cell hemoglobin without affecting oxygen affinity.

Nitric oxide (NO) inhalation has been reported to increase the oxygen affinity of sickle cell erythrocytes. Also, proposed allosteric mechanisms for hemoglobin, based on S-nitrosation of beta-chain cysteine 93, raise the possibility of altering the pathophysiology of sickle cell disease by inhibiting polymerization or by increasing NO delivery to the tissue. We studied the effects of a 2-hour treatment, using varying concentrations of inhaled NO. Oxygen affinity, as measured by P(50), did not respond to inhaled NO, either in controls or in individuals with sickle cell disease. At baseline, the arterial and venous levels of nitrosylated hemoglobin were not significantly different, but NO inhalation led to a dose-dependent increase in mean nitrosylated hemoglobin, and at the highest dosage, a significant arterial-venous difference emerged. The levels of nitrosylated hemoglobin are too low to affect overall hemoglobin oxygen affinity, but augmented NO transport to the microvasculature seems a promising strategy for improving microvascular perfusion.

Protein kinase calpha is an effector of hexamethylene bisacetamide-induced differentiation of Friend erythroleukemia cells.

The program of biochemical and molecular events necessary for commitment to erythroid cell differentiation is particularly well characterized in murine Friend erythroleukemia cell lines. Commitment to hemoglobin synthesis in response to a variety of chemical inducers, including hexamethylene bisacetamide and dimethyl sulfoxide is completed by 24 h and proceeds to terminal differentiation by 96 h. Phorbol 12-myristate 13-acetate, a classical tumor promoter phorbol ester that binds to protein kinase C, blocks differentiation in a reversible manner, suggesting an important role for protein kinase C signaling pathways. The classical protein kinase C isoforms alpha, betaI, and betaII, play distinct roles in the transduction of proliferative and differentiative signals in human, as well as in murine, erythroleukemia cells. Protein kinase Calpha has been implicated in differentiation of human erythroleukemia cells although its translocation to the nucleus has not been observed. Taking advantage of the ability of phorbol 12-myristate 13-acetate to block differentiation in Friend erythroleukemia cells, we determined the localization of the predominant protein kinase C isoforms alpha and betaI during differentiation and in response to their blockade. The ability of phorbol myristate acetate to preferentially diminish protein kinase Calpha-protein localization to the nucleus by 24 h and thereby block differentiation induced by hexamethylene bisacetamide was paralleled by the ability of protein kinase Calpha antisense transfection to block differentiation. In addition, beta-globin transcription, assessed by polymerase chain reaction, was significantly decreased in protein kinase Calpha antisense-transfected cells compared to that seen in vector transfected ones. Taken together, these data suggest an important temporal role for nuclear protein kinase Calpha localization in Friend erythroleukemia cell differentiation.

Multi-ribozyme targeting of human alpha-globin gene expression.

One approach to gene therapy for the treatment of hemoglobinopathies has been focused on increasing normal globin gene expression. However, because of the high concentration of hemoglobin in the red blood cell (32-34 g/dl), merely introducing the normal globin gene may not be enough to counteract the effect of an abnormal globin. We propose that in addition to strategies to add normal beta- or gamma-globin production to sickle erythrocytes, a decrease in overall hemoglobin concentration would further decrease the polymerization potential and should be considered with other gene therapy approaches. Ribozymes offer the potential to target a selected gene product. A model system has been set up using the human alpha-globin gene for specific gene suppression by ribozymes by cleaving alpha-globin mRNA transcripts. Ribozymes, specifically targeted to five different sites in the 5' portion of human alpha-globin mRNA, have been designed and tested in vitro. Cleavage of 32P-labeled alpha-globin mRNA by these ribozymes has been observed in vitro and the highest level of activity has been found for a multi-ribozyme combining all five ribozymes. The multi-ribozyme gene along with promoters with varying activities in erythroid cells was transfected into human erythroleukemia K562 cells. The multi-ribozyme gene, under the control of human alpha-2-globin promoter alone and combined with the locus control region enhancer, caused a decrease in the level of alpha-globin mRNA of 50-75% compared to the control, determined by RNase protection and by real-time quantitative PCR. The decrease in alpha-globin transcripts has been found to be correlated with expression of the multi-ribozyme in a dose-dependent manner and does not appear to be mediated by an antisense effect. These results suggest that the multi-ribozyme may be useful in gene therapy as an effective suppressor of a specific globin gene.

Multiple regulatory elements in the 5'-flanking sequence of the human epsilon-globin gene.

We have previously reported, on the basis of transfection experiments, the existence of a silencer element in the 5'-flanking region of the human embryonic (epsilon) globin gene, located at -270 base pairs 5' to the cap site, which provides negative regulation for this gene. Experiments in transgenic mice suggest the physiological importance of this epsilon-globin silencer, but also suggest that down-regulation of epsilon-globin gene expression may involve other negative elements flanking the epsilon-globin gene. We have now extended the analysis of epsilon-globin gene regulation to include the flanking region spanning up to 6 kilobase pairs 5' to the locus control region using reporter gene constructs with deletion mutations and transient transfection assays. We have identified and characterized other strong negative regulatory regions, as well as several positive regions that affect transcription activation. The negative regulatory regions at -3 kilobase pairs (epsilonNRA-I and epsilonNRA-II), flanked by a positive control element, has a strong effect on the epsilon-globin promoter both in erythroid K562 and nonerythroid HeLa cells and contains several binding sites for transcription factor GATA-1, as evidenced from DNA-protein binding assays. The GATA-1 sites within epsilonNRA-II are directly needed for negative control. Both epsilonNRA-I and epsilonNRA-II are active on a heterologous promoter and hence appear to act as transcription silencers. Another negative control region located at -1.7 kilobase pairs (epsilonNRB) does not exhibit general silencer activity as epsilonNRB does not affect transcription activity when used in conjunction with an epsilon-globin minimal promoter. The negative effect of epsilonNRB is erythroid specific, but not stage-specific as it can repress transcription activity in both K562 erythroid cells as well as in primary cultures of adult erythroid cells. Phylogenetic DNA sequence comparisons with other primate and other mammalian species show unusual degree of flanking sequence homology for the epsilon-globin gene, including in several of the regions identified in these functional and DNA-protein binding analyses, providing alternate evidence for their potential importance. We suggest that the down-regulation of epsilon-globin gene expression as development progresses involves complex, cooperative interactions of these negative regulatory elements, epsilonNRA-I/epsilonNRA-II, epsilonNRB, the epsilon-globin silencer and probably other negative and positive elements in the 5'-flanking region of the epsilon-globin gene.

Sickling of nucleated erythroid precursors from patients with sickle cell anemia.

The pathophysiology of sickle cell anemia is primarily explained in terms of the oxygen-dependent polymerization of sickle hemoglobin (HbS) followed by sickling of erythrocytes. Since the rate and extent of HbS polymerization depend on its intracellular concentration, it has been generally assumed that sickling occurs primarily in mature erythrocytes with their high intracellular hemoglobin concentration. In the present study, we investigated the propensity of nucleated erythroid precursors to undergo sickling; both cultured and fresh marrow-derived erythroid precursors from patients with homozygous sickle cell anemia were studied. The results revealed that upon deoxygenation cultured erythroblasts underwent characteristic morphological deformation in the form of fine, fragile, elongated spicules. Ultrastructural analysis demonstrated highly organized and tightly aligned hemoglobin fibers in the protruded regions. Bone marrow cells examined under partial or complete deoxygenated conditions displayed similar morphological changes. When cultured SS erythroid precursors were exposed to hydroxyurea or butyrate, drugs that may increase fetal hemoglobin (HbF) and inhibit intracellular polymerization, a significant decrease was observed in the propensity of these precursors to undergo sickling, accompanied by a three- to fivefold increase in HbF. These results suggest that, in addition to mature erythrocytes, nucleated erythroid precursors in the bone marrow have the capacity to undergo characteristic sickling as a result of HbS polymerization and may be involved in several aspects of the pathophysiology of sickle cell anemia. Treatment with HbF-stimulating drugs may benefit patients with this disease by inhibiting polymerization-induced sickling of erythroid precursors in the marrow as well as mature erythrocytes in the peripheral blood.

Localization and characterization of curved DNA in the human erythropoietin receptor gene by experimental and theoretical approaches.

We report here the locations of curved DNA in the human erythropoietin receptor gene. A total of 13 DNA bend sites were mapped by circular permutation assays, appearing at an average interval of 651.2+/-214.6 (S.D.) in the 8-kb region. The bend centers in these 13 bend sites were confirmed by oligonucleotide-based assays where most of these centers had bend angles higher than that shown by (AAACCGGGCC) x (A)20 and lower than that shown by (AAACCGGGCC)2 x (A)10. DNA curvature mapping by TRIF software, which is based on the distribution of dinucleotides, primarily AA and TT, provided a highly accurate prediction for the locations of the bend sites. They showed approximately 20 degrees to 40 degrees of bend angles demonstrated by the oligonucleotide assays and by computer analysis.

Modulation of globin gene expression in cultured erythroid precursors derived from normal individuals: transcriptional and posttranscriptional regulation by hemin.

We are interested in the genetic mechanisms whereby several classes of drugs increase fetal hemoglobin (HbF) in patients with sickle-cell anemia or beta-thalassemia. Recently, we have shown (Kollia et al., Proc. Natl. Acad. Sci. U.S.A. 93: 5693, 1996) that cultured primary human adult erythroid cells (hAEC) offer a useful model for the study of transcriptional and posttranscriptional regulation of globin gene expression. We have found also that hemin markedly increases HbF levels in these cells. We report here the effect of hemin on globin gene transcription and RNA processing in hAEC. Quantitative reverse transcriptase-polymerase chain reaction analysis showed that the gamma-globin message levels in the cytoplasm and nucleus were increased two-fold by hemin. In the untreated cells, only spliced gamma-transcripts were detected in the cytoplasm, indicating that only completely processed gamma-RNA is transported to the cytoplasm, whereas approximately half of the nuclear gamma-globin RNA transcripts were unspliced. After treatment with hemin, correctly spliced gamma-transcripts increased in the cytoplasm and nucleus, while the unprocessed gamma-transcripts decreased in number in the nucleus. We also studied epsilon-globin RNA transcripts; in the cytoplasm of untreated cells, only correctly processed transcripts were present, whereas the nuclear epsilon-globin RNA transcripts were unspliced. In hemin-induced cells, unspliced nuclear epsilon-transcripts decreased in number. In contrast to the gamma- and epsilon-globin genes, the levels of full-length, correctly spliced beta-globin message are not affected by hemin. Nuclear run-on transcription assays confirmed the increase in the rate of transcription of gamma- and epsilon-globin genes in hemin-treated versus untreated hAEC. These results indicate that hemin affects the expression of embryonic and fetal globin genes by acting both at the transcriptional and posttranscriptional levels. These results may be relevant to the action of other agents that affect the hemoglobin phenotype of human erythroid cells.