Crosslinking of isolated cytoskeletal proteins with hemoglobin: a possible damage inflicted to the red cell membrane

Crosslinking of isolated red cell membrane cytoskeletal proteins and hemoglobin mediated by H2O2 was studied. The products of spectrin and hemoglobin interaction were demonstrated electrophoretically to be high-molecular-weight polypeptides crosslinked by nondisulfide covalent bonds. The molecular weight of the protein bands correlated with various combinations of spectrin and hemoglobin chains and the relative amount of the different products was dependent on the molar ratio of the interacting proteins. Free hemin caused spectrin crosslinking as well, but globin in the absence of hemin was inactive. Since the H2O2-mediated reaction resulted in reduction of the spectrin tryptophan fluorescence, the latter was used to monitor the reaction progress under various conditions. Both oxyhemoglobin and methemoglobin were found to be most efficient, whereas cyanmethemoglobin and hemichrome were relatively inactive. Analysis of the data implied that tryptophan oxidation as well as spectrin conformational changes follow an iron-induced crosslinking of the interacting proteins. Actin, the second major protein in the red cell cytoskeleton, behaved similarly to spectrin. The intrinsic fluorescence intensity of both G- and F-actin was decreased upon addition of H2O2 to the mixture of hemoglobin and each of the actin forms. SDS-polyacrylamide gel electrophoresis revealed that G-actin crosslinked one or two hemoglobin chains. F-actin-hemoglobin interaction induced by H2O2 produced very high aggregates that could not penetrate the gel. It is suggested that crosslinking of cytoskeletal proteins in red cells containing membrane-associated hemoglobin provides a rationale for the loss of membrane flexibility.     

The role of calcium in differentiation of leukemic cell lines

Increased calcium influx associated with differentiation of four human myeloid leukemic cell lines: HL-60, KG-1, U-937 and K-562, to either monocytic or granulocytic direction was demonstrated. Calcium influx was measured employing two methods; measurement of radioactive calcium influx rate at 4 degrees C and employing the fluorescent probe, fura-2 acetoxymethyl ester. The increase in Ca2+ influx was demonstrated with three chemically unrelated differentiation inducers: retinoic acid, 1 alpha, 25 dihydroxy vitamin D3 and dimethyl sulfoxide. Inhibitors of calcium uptake such as verapamil diltiazem and cromolyn, partially reduced differentiation, suggesting that differentiation of myeloid leukemic cell lines is dependent on the availability of extracellular calcium.     

Differentiation-associated changes of cation-transport activities in myeloid leukemic cell lines

Induction of differentiation in HL-60 and U-937 leukemic cell lines, resulted in 1.5-10-fold increase in 45Ca2+ uptake. The increased 45Ca2+ uptake in the differentiating cells was inhibited by verapamil, cromolyn and amiloride. Elevation in Ca2+ uptake in differentiating cells was also demonstrated using the fluorescent probe, fura-2 acetoxymethyl ester. The increased 45Ca2+ uptake was accompanied by a decrease in ouabain-insensitive and -sensitive 86Rb+ uptake. Furthermore, correlation between the changes in these activities was observed. Modulation of extracellular pH affected differentiation: higher pH increased the extent of differentiation.     

Disintegration of red cell membrane cytoskeleton by hemin

Spectrin and actin were isolated and their oligomeric state after association with hemin at various conditions was studied. Intact cytoskeletons were prepared by Triton X-100 extraction of red blood cells and incubated with hemin and their stability analyzed by the appearance of dissociated proteins in the supernatant. The cytoskeletons dissociated in a time, temperature and hemin concentration-dependent manner. Following 18 hours incubation in the presence of 0.3 mM hemin there was no dissociation at 4 degrees C, while at the same hemin concentration after 2 hours complete dissociation of the cytoskeletons occurred at 37 degrees C. Microscopy indicated that the cytoskeletons incubated with hemin lost their "cell like" shapes in a time dependent manner. Hemin applied to intact cells also caused dissociation of their cytoskeletons as judged by the failure to separate integer cytoskeletons from red cells treated with hemin. From hemin-induced dissociation profiles of separated actin, spectrin and whole cytoskeletons under various conditions, a mechanism of cytoskeleton breakdown was analyzed, as a release of band 4.1 in the first step which is followed by spectrin dimerization and eventually dissociation of the entire cytoskeletons.     

The interaction of hemin with skeletal muscle actin

The ability of actin to interact with hemin was studied. It was found that the Soret absorption band of hemin changes in the presence of actin and that hemin is capable of quenching the fluorescence intensity of actin. These findings were indicative of hemin binding to actin. The binding constant for the high affinity site was calculated to be 5.3 X 10(6) M-1. The amounts of native G- and F-actin were estimated by their DNAase I inhibition activity. It was observed that the binding of hemin to G-actin is followed by a slow decrease in the ability of actin to inhibit DNAase I activity and to polymerize upon addition of salts. Binding of hemin to F-actin resulted in a gradual depolymerization of the filaments, to an inactivated form, as expressed by a reduction in the ability of hemin-bound F-actin to inhibit DNAase I activity in the absence as well as in the presence of guanidine-HCl. Electron microscopy studies further corroborated these findings by demonstrating that: (1) hemin-bound G-actin failed to show formation of polymers when salts were added; (2) a marked reduction in the amount of actin polymers was observed in the specimens examined 24 h after mixing with hemin. It is suggested that the elevated amounts of free hemin formed under pathological conditions, might be toxic to cells by interfering with actin polymerization cycles.     

Effect of Carbon Source and the Role of Cyclic Adenosine 3′,5′-Monophosphate on the Caulobacter Cell Cycle

The expression of cell cycle events in Caulobacter crescentus CB13 has been shown to be associated with regulation of carbohydrate utilization. Growth on lactose and galactose depends on induction of specific enzymes. Prior growth on glucose results in a delay in enzyme expression and cell cycle arrest at the nonmotile, predivisional stage. Dibutyryl cyclic adenosine 3',5'-monophosphate (AMP) was shown to stimulate expression of the inducible enzymes and, thus, the initiation of the cell cycle. beta-Galactosidase-constitutive mutants did not exhibit a cell cycle arrest upon transfer of cultures from glucose to lactose. Furthermore, carbon source starvation results in accumulation of the cells at the predivisional stage. The cell cycle arrest therefore results from nutritional deprivation and is analogous to the general control system exhibited by yeast (Hartwell, Bacteriol. Rev. 38:164-198, 1974; Wolfner et al., J. Mol. Biol. 96:273-290, 1975), which coordinates cell cycle initiation with metabolic state. Transfer of C. crescentus CB13 from glucose to mannose did not result in a cell cycle arrest, and it was demonstrated that this carbon source is metabolized by constitutive enzymes. Growth on mannose, however, is stimulated by exogenous dibutyryl cyclic AMP without a concomitant increase in the specific activity of the mannose catabolic enzymes. The effect of cyclic AMP on growth on sugars metabolized by inducible enzymes, as well as on sugars metabolized by constitutive enzymes, may represent a regulatory system common to both types of sugar utilization, since they share features that differ from glucose utilization, namely, temperature-sensitive growth and low intracellular concentrations of cyclic guanosine 3',5'-monophosphate.     

The interaction of deoxyhemoglobin with the red cell membrane

The interaction of deoxyhemoglobin with the red cell membrane is characterized by comparing the affinity of deoxyhemoglobin for the membrane with that of oxyhemoglobin. The two techniques used, namely light scattering induced changes and quenching of the fluorescence intensity of a membrane embedded probe, demonstrate that deoxyhemoglobin exhibits a much lower affinity for the membrane than that of oxyhemoglobin. The binding constant of 2×10 M^?1 calculated for deoxyhemoglobin at 5 mM phosphate buffer and pH=6.0 is two orders of magnitude lower than the one calculated for oxyhemoglobin. It is estimated that under physiological conditions the only species capable of interacting with the membrane is the oxyhemoglobin.     

Spontaneous frequency of a developmental mutant in Volvox

Two types of mutants, those resistant to the base analog 5-bromo-2′-deoxyuridine (BrdU) and somatic regenerator (SR) mutants, have been analyzed in Volvox carteri. In somatic regenerator mutants, the somatic cells which are normally terminally differentiated dedifferentiate and regenerate gonidia [Sessoms, A., and Huskey, R. J. (1973). Proc. Nat. Acad. Sci. USA70, 1335–1338; Starr, R. C. (1970). Develop. Biol. Suppl.4, 59–100]. The SR phenotype allows recovery of SR mutations arising in somatic cells, since such somatic cells would regenerate gonidia and give rise to mutant clones. Mutants of any phenotype other than SR can only be recovered if the mutation first appears in a gonidium. Since the somatic cells are 100-fold more numerous than reproductive cells (gonidia), we have determined the spontaneous frequency of both somatic regenerator mutants and mutations to BrdU resistance in order to determine if the SR mutation exerts its effect in the gonidium or in the somatic cell. The two frequencies were found to be nearly identical, suggesting that the SR mutation must first appear in a gonidium in order to be expressed.     

Mechanism of low-density lipoprotein oxidation by hemoglobin-derived iron

Excellular hemoglobin is an extremely active oxidant of low-density lipoproteins (LDL), a phenomenon explained so far by different mechanisms. In this study, we analyzed the mechanism of met-hemoglobin oxidability by comparing its mode of operation with other hemoproteins, met-myoglobin and horseradish peroxidase (HRP) or with free hemin. The kinetics of met-hemoglobin activity toward LDL lipids and protein differed from that of met-myoglobin and HRP, both quantitatively and qualitatively. Those differences were further clarified by analyzing heme transfer from the above-mentioned hemoproteins to LDL. It appeared that met-hemoglobin transferred most of its hemin to LDL, and the presence of H(2)O(2) accelerated the process. In contrast, met-myoglobin partially released hemin, but only in the presence of H(2)O(2), while HRP could not transfer heme at all. The minor amount of hemin transferred from met-myoglobin to LDL sufficed to trigger ApoB oxidation, forming covalent aggregates via inter-bityrosines. This indicated that heme bound to high affinity site(s) is responsible for oxidation. LDL components providing the sites were analyzed by binding heme-CO monomers to LDL. Soret spectra revealed that the high affinity site of monomeric hemin is located on the LDL protein, ApoB. The complex heme-CO-ApoB underwent instantaneous oxidation to hemin-ApoB, and the bound hemin then slowly disintegrated in conjunction with LDL oxidation. Hemopexin prevented LDL oxidation by trapping hemoprotein transferable heme. We concluded that met-hemoglobin exerts its oxidative activity on LDL via transfer of heme, which serves as a vehicle for iron insertion into the LDL protein, leading to formation of atherogenic LDL aggregates.