A microcytofluorometric method for quantitative and qualitative evaluation of CFU-E and BFU-E colonies.

A new method has been developed for the precise identification of human bone marrow colony forming unit erythroid (CFU-E) and burst forming unit erythroid (BFU-E) colonies, and for determination of the hemoglobin contents using microcytofluorometry. The method relies on a photochemical reaction in which intracellular hemoglobin is converted into fluorescent porphyrin under violet light (lambda = 405 nm) in the presence of an SH-donor (mercaptoethylamine hydrochloride). The CFU-E and BFU-E colonies showed red fluorescence with two spectrum peaks at 600 and 650 nm when illuminated by violet light. These two peaks are consistent with those of porphyrin fluorescence. The porphyrin fluorescence was not inducible in colony forming unit granulocyte-macrophage (CFU-GM) colonies, while 20% of the CFU-GM colonies were false positive with respect to the conventional benzidine reaction. The photochemically inducible fluorescence began to appear in BFU-E colonies on the 4th day of culture, while the same colonies started to be positive for the benzidine reaction on the 9th day. Therefore, the photochemical reaction was more specific and sensitive than the benzidine reaction for the identification of CFU-E and BFU-E colonies. In addition, this method enabled us to measure the hemoglobin level in the cells forming the colonies because the intensity of the fluorescence was proportional to the amount of hemoglobin when the photochemical reaction was carried out for 50 min.(ABSTRACT TRUNCATED AT 250 WORDS)     

A microcytofluorometric method for quantitative and qualitative evaluation of CFU-E and BFU-E colonies

Summary A new method has been developed for the precise identification of human bone marrow colony forming unit erythroid (CFU-E) and burst forming unit erythroid (BFU-E) colonies, and for determination of the hemoglobin contents using microcytofluorometry. The method relies on a photochemical reaction in which intracellular hemoglobin is converted into fluorescent porphyrin under violet light (=405 nm) in the presence of an SH-donor (mercaptoethylamine hydrochloride). The CFU-E and BFU-E colonies showed red fluorescence with two spectrum peaks at 600 and 650 nm when illuminated by violet light. These two peaks are consistent with those of porphyrin fluorescence. The porphyrin fluorescence was not inducible in colony forming unit granulocyte-macrophage (CFU-GM) colonies, while 20% of the CFU-GM colonies were false positive with respect to the conventional benzidine reaction. The photochemically inducible fluorescence began to appear in BFU-E colonies on the 4th day of culture, while the same colonies started to be positive for the benzidine reaction on the 9th day. Therefore, the photochemical reaction was more specific and sensitive than the benzidine reaction for the identification of CFU-E and BFU-E colonies. In addition, this method enabled us to measure the hemoglobin level in the cells forming the colonies because the intensity of the fluorescence was proportional to the amount of hemoglobin when the photochemical reaction was carried out for 50 min. As a result of qualitative and quantitative analysis of CFU-E colonies by this method, it was possible to detect the hemoglobin levels in the colonies from 1 of 4 cases of untreated acute nonlymphocytic leukemia and from 2 of 4 cases of myelodysplastic syndrome in which the hemoglobin levels were too low to be detected by the benzidine reaction. These cases, where the CFU-E colonies showed very low levels of hemoglobin, were associated with poor prognosis. Thus, our method is useful for identifying CFU-E colonies, determining their hemoglobin synthesis, and as a cue to predict the clinical course of the patients.     

Primitive erythropoiesis of mouse teratocarcinoma stem cells PCC3/A/1 in serum-free medium

Mouse teratocarcinoma stem cells PCC3/A/1 differentiated into various types of cells, such as red cells, when they were grown in serum-free medium containing transferrin and bovine serum albumin on a KCF cell feeder layer. These red cells were stained well with 2,7-diaminofluorene (DAF), and therefore were erythroid cells. They were nucleated and contained embryonic globin chains, immunologically identified with antiembryonic hemoglobin antisera after acid urea Triton X-100 polyacrylamide gel electrophoresis (UT-PAGE). The addition of erythropoietin to the culture medium enhanced the production of both embryonic and adult globin chains. The addition of interleukin-3 also enhanced the production of embryonic globin chains, but not the production of adult globin chains. These results indicated that primitive erythropoiesis of PCC3/A/1 teratocarcinoma cells did not require exogenous addition of any hematopoietic factor such as erythropoietin or interleukin-3. This culture system will be a new model system for investigating the factors regulating the primitive erythropoiesis in yolk sac blood islands.     

X-linked control of hemoglobin production in somatic hybrids of mouse erythroleukemic cells and mouse lymphoma or bone marrow cells

Somatic cell hybrids were generated by fusion of mouse erythroleukemic cells (clone 745) to mouse lymphoma cells or mouse bone marrow cells. The erythroleukemic cells have been shown previously to have a low basal level of erythroid differentiation which is markedly amplified when the cells are grown in medium containing dimethylsulfoxide (DMSO). Hybrid cells were examined for hemoglobin production by benzidine staining. Many hybrid clones were found in which hemoglobin production in response to DMSO was either abolished or greatly reduced. From these hybrids, subclones were isolated in which hemoglobin production was restored. Karyological and enzyme analysis showed that the restoration of hemoglobin production was associated with the loss of an X chromosome contributed by the nonerythroleukemic parent. Other subclones which retained an X chromosome continued to be inhibited for hemoglobin production. Analysis of other hybrid lines capable of a limited degree of erythroid differentiation indicated a quantitative inverse correlation between the proportion of cells bearing an X chromosome and the proportion of cells able to form hemoglobin. Finally, four hybrid lines having many cells without an X chromosome were grown in medium containing DMSO. This procedure led to the selection of hybrid sublines having a nondifferentiating phenotype and concomitantly having a greatly increased proportion of cells bearing an X chromosome. Thus three lines of evidence suggest that a locus (loci) on the X chromosome is capable of inhibiting the DMSO-inducible hemoglobin production of the erythroleukemic cells.     

Annexin1 regulates the erythroid differentiation through ERK signaling pathway

K562 cells can be used as a model of erythroid differentiation on being induced by hemin. We found that the level of annexin1 gene expression was notably increased during this indicated process. To test the hypothesis that annexin1 can regulate erythropoiesis, K562 cell clones in which annexin1 was stably increased and was knocked down by RNAi were established, respectively. With analysis by hemoglobin quantification, benzidine staining, and marker gene expression profile determination, we confirmed that hemin-induced erythroid differentiation of K562 cells was modestly stimulated by overexpression of annexin1 while it was significantly blocked by knock down of annexin1. Further studies revealed that the mechanisms of annexin1 regulation of the erythroid differentiation was partially related to the increased ERK phosphorylation and expression of p21(cip/waf), since specific inhibitor of MEK blocked the function of annexin1 in erythroid differentiation. We concluded that annexin1 exerted its erythropoiesis regulating effect by ERK pathway.     

Separation and trace estimation of benzidine and its macromolecular adducts using supercritical fluid chromatography

A sensitive, rapid, selective and reproducible method has been developed to measure blood plasma levels of benzidine (BZ) and its acetylated metabolite, N-OH-N,N'-diacetylbenzidine (N-OH-DABZ), using supercritical fluid chromatography (SFC) for the first time. Benzidine and N-OH-N,N'-diacetylbenzidine were extracted from the plasma using ether. Separation was done on a Nucleosil (250 mm x 4.6 mm) 10 microm, Nucleosil-RP-C18 column with 7.4% (v/v) methanol-modified supercritical fluid carbon dioxide (2.5 ml min(-1)) as mobile phase. The column temperature was 45 degrees C and the outlet pressure was set at 8.83 MPa. The detection was done using a UV-Vis detector set at 280 nm. The limit of quantification was 0.10 ng ml(-1) (BZ) and 0.14 ng ml(-1) (N-OH-diacetylbenzidine) using 1 ml plasma specimen. The mean extraction recovery of BZ was found to be 98.6%. The SFC method was directly compared to a published HPLC-UV method. With respect to speed, organic solvent usage, sensitivity, specificity and accuracy, SFC was found to be superior. The method has been successfully used to estimate the BZ, N-OH-diacetylbenzidine levels in blood plasma of the animals who were administered 15 microg kg(-1) body weight of benzidine.Further, this method has been also applied for the detection and quantification of benzidine DNA and hemoglobin adducts from the blood and tissue samples of the benzidine dosed animals.     

Microcapillary clonogenic assays for human marrow hematopoietic progenitor cells

The capillary clonogenic cell assay was developed and adapted to culture myeloid and erythroid colonies from human bone marrow cells. The plating efficiencies for femoral bone marrow granulocyte-macrophage progenitors (CFU-gm), erythroid colony-forming units (CFU-e) and erythroid burst-forming units (BFU-e) were 0.143%, 0.229% and 0.141%, respectively. Standard bone marrow progenitor Petri dish assays require a total culture volume of 1 ml per dish, and as such are not suitable for the small numbers of cells often obtained from human bone marrow samples. The microcapillary assay as developed and standardized in our laboratory has the unique advantage of being able to utilize small numbers of cells. This technique is suitable for evaluating the myelotoxicity of investigational new anti-cancer and anti-HIV agents and for further investigation of the mechanisms underlying chemotherapy-induced bone marrow toxicity.     

Erythroid differentiation of cultured murine erythroleukemia cells by the spermine analogue canavalmine

Canavalmine, an analogue of spermine, induced erythroid differentiation of murine erythroleukemia cells 745A, as evidenced by benzidine staining and heme content of cultured cells. Benzidine-positive cells synthesizing hemoglobin appeared on day 4 after addition of 250 μM canavalmine. The canavalmine-induced cell differentiation was inhibited by the addition of agents which alter the structure of the cell membrane, such as local anesthetics (procainamide and lidocaine) or Ca²⁺ antagonists (nifedipine and verapamil) at dosages not toxic for the cell growth. Canavalmine did not significantly affect the levels of conjugated polyamines in the acid-insoluble fraction of the cells. In contrast, the level of free spermidine in the acid-soluble fraction greatly decreased during the 18 h after canavalmine treatment. Putrescine and spermidine, when added externally to the growth medium, showed dose-dependent inhibition of canavalmine-induced cell differentiation. Neither cadaverine nor spermine had any significant effect. These results suggest that not only structural change of cell membrane but alteration of the polyamine metabolism, especially a regulation of the cellular level of free spermidine, might have a key importance in erythroid differentiation of murine erythroleukemia cells induced by canavalmine.     

Intracellular signals for developmental hemoglobin switching

We have detected trans-acting factors that regulate developmental hemoglobin switching by fusing erythroid cells of different developmental programs. Adult erythroid cells of one anuran species, Xenopus laevis, were fused with tadpole erythroid cells of another frog, Rana catesbeiana. In a second set of experiments, dimethyl sulfoxide-induced murine erythroleukemia cells, which express only adult mouse globins, were fused with Rana tadpole erythroid cells, which express only embryonic and fetal-like globins. Adult Rana globin gene expression was detected in both sets of transient heterokaryons at 6 hr after fusion. Dot blots and Northern blots of total RNA from the heterokaryons contained material that reacted with an adult Rana alpha-globin probe; newly synthesized adult Rana hemoglobin tetramers were detected with native polyacrylamide gel electrophoresis. These results show that developmental stage-specific transacting factors for globin genes can function across vertebrate classes (mammalia to amphibia) and suggest that the mechanisms that regulate developmental hemoglobin switching are highly conserved.     

Studying the enucleation process, DNA breakdown and telomerase activity of the K562 cell lines during erythroid differentiation in vitro

During erythropoiesis, some organelles such as mitochondria and nucleus are lost by autophagy and enucleation processes in the presence of macrophages in vivo. In vitro production of erythrocytes has raised many questions about the mechanism of enucleation. The aim of this work was to study the DNA breakdown, enucleation, hemoglobin synthesis and telomerase activity of K562 cells during erythroid differentiation. For these purposes, K562 cells were induced to differentiate by erythropoietin + rhGM-CSF, DMSO, and sodium butyrate separately up to 14 d. In different time intervals, hemoglobin synthesis was evaluated by benzidine staining and RT-PCR for γ-globin gene expression. DNA breakdown was analyzed by 4′,6-diamidino-2-phenylindole (DAPI) staining, DNA ladder electrophoresis and comet assay. The telomerase activity was evaluated by TRAP assay. Our result indicated that, sodium butyrate and DMSO inhibited K562 cell growth about 50–60% in comparison to untreated control cells. The percentage of benzidine-positive cells was about 45% in the presence of sodium butyrate after 10 d. Densitometric analysis of RT-PCR and calculated data indicated a 1.5-fold increase in relative γ-globin gene expression at 96 h, in the presence of 1 mM sodium butyrate in comparison with untreated cells. DAPI staining did not reveal any evidence of internal lysis of the nucleus during erythroid differentiation at first wk, but this was obvious in the second wk. DNA laddering pattern was not observed in differentiated cells during 14 d. In comet assay, the percentage of DNA in tail, tail length, and tail moment were significantly different between untreated and treated cells (p?<?0.05). Telomerase activity was inhibited up to 90.3% during erythroid differentiation of these cells.     

ERYTHROPOIESIS DURING AMPHIBIAN METAMORPHOSIS : III. Immunochemical Detection of Tadpole and Frog Hemoglobins (Rana catesbeiana) in Single Erythrocytes

Rabbit antibodies specific for the major tadpole and frog hemoglobin components of R. catesbeiana were used for the detection of the two hemoglobins inside single cells. The antisera, after fractionation by ammonium sulfate precipitation and diethylaminoethyl (DEAE)-cellulose chromatography, were conjugated with fluorescein isothiocyanate for the antifrog hemoglobin serum and tetramethylrhodamine isothiocyanate for the antitadpole hemoglobin serum. The conjugated fractions, refractionated by stepwise elution from a DEAE-cellulose column, were used for the fluorescent staining of blood smears, liver tissue imprints, and smears of liver cell suspensions. Both simultaneous and sequential staining with the two fluorescent preparations indicated that larval and adult hemoglobins were not present within the same erythrocyte during metamorphosis. In other experiments, erythroid cells from animals in metamorphosis were spread on agar containing specific antiserum. Precipitates were formed around the cells which contain the particular hemoglobin. The percentages of cells containing either tadpole or frog hemoglobin were estimated within the experimental error of the method. The data showed that the two hemoglobins are in different cells. It is concluded that the hemoglobin change observed during the metamorphosis of R. catesbeiana is due to the appearance of a new population of erythroid cells containing exclusively frog hemoglobin.     

Constitutive synthesis of globins within most of the members of an uninduced, proliferating population of Friend erythroluekemic cells.

The proteins synthesized by Friend erythroleukemic cells (clone 745), before and after they have been induced by treatment with dimethylsulfoxide to undergo overt erythroid maturation, have been analyzed by a number of biochemical methods. None of these techniques has, however, revealed any consistent observable differences (other than quantitative variations in the concentrations of particular proteins) between the “uninduced” and the “induced” cells. Thus, various classes of cellular proteins (whole cell, cytoplasmic, and nuclear) appear to be very similar in the two types of cells when analyzed by two-dimensional gel electrophoresis. Of particular interest is the finding that the strain-specific hemoglobins of $\text{DBA}\text{2}$ mice (the line from which the Friend cells were derived by viral transformation) are being synthesized in both the uninduced and the induced cells but at apparently markedly different rates. A monospecific antibody preparation against purified $\text{DBA}\text{2}$ mouse α- and β-globins was used to quantify the amount of these proteins in Friend cells during the course of dimethylsulfoxide-induced differentiation. Rocket gel immunoelectrophoresis, radial immunodiffusion analysis, and competitive radioimmunoassay revealed that the uninduced Friend cells contained, on the average, about 0.45 pg of hemoglobin per cell and this amount increased about 32-fold (to about 14.4 pg per cell) after 5 days of induction. Furthermore, use of the antibody preparation in indirect immunofluorescence studies revealed the constitutive synthesis of low levels of globins in virtually all of the uninduced, actively dividing, leukemia cells. These studies indicate that the standardly used benzidine staining method for detecting hemoglobins is insensitive for the detection of low levels of these proteins. The results of this study indicate that the cells in this particular leukemic population are, in reality, already “differentiated.” This suggests that the cells may represent an intermediate stage of erythroid maturation whose further progress along the normal in vivo terminal differentiation pathway has been blocked by viral transformation. Perhaps various “inducers,” such as dimethylsulfoxide, may enable these cells to partially overcome this block.     

Plasma hemoglobin determination in beagle dogs. An adaptation of the method of Crosby and Furth.

The plasma hemoglobin concentration of beagle dogs was measured following an improved bleeding technic which minimized trauma of the red cells. The benzidine reaction (benzidine dihydrochloride) was used to measure the hemoglobin present. Plasma hemoglobin values of the first 2 ml of blood collected were statistically significantly higher (P less than 0.01) than values of the next 2-3 ml of blood. Plasma hemoglobin values of normal beagles were 0.5-2.5 mg/dl in minimally hemolyzed samples. Recovery rates of up to 92% of hemoglobin added to plasma were possible with this method.     

Peroxidase-catalyzed benzidine binding to DNA and other macromolecules

[14C]Benzidine is rapidly oxidized by a peroxidase/H2O2 system to products which bind irreversibly to DNA. The presence of exogenous DNA also prevented benzidine polymerization to 'benzidine brown' and azobenzidine. Two molar equivalents of H2O2 were required to oxidize the benzidine and achieve maximal DNA binding. Furthermore, 95% of the benzidine was trapped and 36 nmol benzidine was bound per mg DNA. Polyriboguanylic acid was as effective as DNA in binding benzidine, but polyriboadenylic acid, polyribouridylic acid and polyribocytidylic acid were much less effective. Binding of [14C]benzidine correlated well with the absorbance at 295 nm and 390 nm of the modified DNA or various synthetic homopolymers of ribonucleotides isolated from the reaction mixture. The peroxidase/H2O2 system also catalyzed the binding of dichlorobenzidine, o-tolidine and o-dianisidine to DNA but 3,5,3',5'-tetramethylbenzidine, a non-carcinogen, did not bind. The binding could be prevented by various biological hydrogen donors, thiols, or phenolic antioxidants. The mechanisms for DNA protection were investigated; the oxidized benzidine species involved in binding can be reduced with ascorbate, NADPH, or thiols, and trapped by thiols or phenolic antioxidants to form conjugates or adducts.     

Diagnostic Accuracy of the HemoCue Hb 301, STAT-Site MHgb and URIT-12 Point-of-Care Hemoglobin Meters in a Central Laboratory and a Community Based Clinic in Durban,South Africa

In South Africa, various point-of-care hemoglobin meters are used. However, the regulatory framework for approval, implementation and oversight of use of point-of-care hemoglobin meters is suboptimal. We assessed the diagnostic accuracy of the HemoCue Hb 301, STAT-Site M^Hgb and URIT-12 point-of-care hemoglobin meters, compared to a central laboratory based reference assay, in a central laboratory and a community based clinic in Durban, South Africa. Differences in performance of the point-of-care assays, compared to the reference assay, were more pronounced in the community based clinic. Results were reasonable for the HemoCue Hb 301, but poor for the STAT-Site M^Hgb and the URIT-12. Poor test performance of point-of-care hemoglobin meters, and inadequate evaluations and oversight in South Africa, leads to suboptimal clinical care and clinical research, and increased costs. There is a need for proper evaluation and quality assurance of point-of-care tests, the results of which should be made widely available to key stakeholders.     

OAZ1基因诱导慢粒白血病K562细胞向成熟红系方向分化

近年来,鸟氨酸脱羧酶抗酶(OAZ)作为肿瘤治疗的潜在靶点备受关注.本文研究了OAZ1基因过表达对慢粒白血病K562细胞红系分化的作用.构建框移位点突变的OAZ1 过表达慢病毒载体pLVX-Neo-OAZ1-IRES-ZsGreen,包装病毒并感染K562细胞, Western 印迹验证其过表达效果.FACS检测细胞分化标志物CD71和GPA,结合联苯胺染色分析细胞红系分化情况.对比氯化高铁血红素(hemin)诱导组,实时RT-PCR检测与K562细胞红系分化、癌变的关键基因(GATA1、BCR/ABL、TGFβ)转录水平,对OAZ1 诱导分化的机制进行初步探索.结果表明,慢病毒过表达载体及K562细胞过表达体系构建成功.OAZ1过表达后细胞红系分化标志物CD71+/GPA+为(11.22±2.09)%,与对照组(4.07±1.04)%、空病毒组(1.79±2.36)%相比差异极显著(P<0.01);联苯胺蓝染阳性率为(14.037±0.083)%,与对照组、空病毒组比较,差异也极显著(P<0.01).定 量分析结果提示,相对于GATA1、BCR/ABL 基因mRNA转录水平的影响,OAZ1对TGFβ 基因的作用更为明显.为此推断,OAZ1基因可诱导白血病K562细胞向成熟红系方向分化,其作用机制可能与TGFβ信号转导通路相关.