Relation between K+ leakage and damage to band 3 in photodynamically treated red cells.

Potassium leakage is one of the first events that appear after photosensitization of red blood cells. This event may subsequently lead to colloid osmotic hemolysis. The aim of our study was to determine which photodynamically induced damage is responsible for increased membrane cation permeability. This was done by studying the effect of dimethylmethylene blue (DMMB)-mediated photodynamic treatment (PDT) on different membrane transport systems. Inhibition of band 3 activity (anion transport) showed a comparable light dose dependency as PDT-induced potassium leakage, whereas glycerol transport activity was inhibited only at higher light doses. Dipyridamole (DIP), an inhibitor of anion transport, protects band 3 against DMMB-induced damage, and prevents the increase in cation permeability of the membrane. Damage to glycerol transport was partially reduced when PDT was performed in the presence of DIP. Because DIP has no affinity for the glycerol transporter, this protection might result from the reduced photodamage to band 3. These results support the hypothesis that band 3 might be involved in glycerol transport. Glucose transport was not affected by DMMB-mediated PDT. The present results are the first to show a causal relationship between DMMB-mediated photodamage to band 3 and increased cation permeability of red blood cells.

Band 3 and its peptides during aging, radiation exposure, and Alzheimer's disease: alterations and self-recognition.

An aging antigen, senescent cell antigen, resides on the 911 amino acid membrane protein band 3. It marks cells for removal by initiating specific IgG autoantibody binding. Band 3 is a ubiquitous membrane transport protein found in the plasma membrane of diverse cell types and tissues, and in nuclear, mitochondrial, and golgi membranes. Band 3 in tissues such as brain performs the same functions as it does in red blood cells forming senescent cell antigen. Oxidation is a mechanism for generating senescent cell antigen. The aging antigenic sites reside on human band 3 map residues 538-554, and 812-830. Carbohydrate moieties are not required for the antigenicity or recognition of senescent cell antigen. Anion transport site were mapped to residues 588-594, 822-839, and 869-883. The aging vulnerable site which triggers the antigenic site and the transport sites of band 3 were mapped using overlapping synthetic peptides along the molecule. Naturally occurring autoantibodies to regions of band 3 comprising both senescent cell antigen and B cells producing these antibodies were demonstrated in the sera of normal, healthy individuals. The presence of these antibodies tend to increase with age. Individuals with autoimmune diseases (rheumatoid arthritis and systemic lupus erythematosus) have increased antibodies to senescent cell antigen peptides. Radiation exposure results in an increase in antibodies to peptides 588-602 which lies in a transport region containing the aging vulnerable site. Band 3 ages as cells and tissues age. Our studies, to date, indicate, that the anion transport ability of band 3 decreases in brains and lymphocytes from old mice. This decreased transport ability precedes obvious structural changes such as band 3 degradation and generation of SCA, and is the earliest change thus far detected in band 3 function. Other changes include a decreased efficiency of anion transport (decreased Vmax) in spite of an increase in number of anion binding sites (increased Km), decreased glucose transport, increased phosphorylation, increased degradation to smaller fragments as detected by quantitative binding of antibodies to band 3 breakdown products and residue 812-830, and binding of physiologic IgG autoantibodies in situ. The latter 3 findings indicate that post-translational changes occur. In Alzheimer's Disease (AD), our results indicate that post-translational changes occur in band 3. These include decreased band 3 phosphorylation of a 25-28kD segment, increased degradation of band 3, alterations in band 3 recognized by antibodies, and decreased anion and glucose transport by blood cells. Serum autoantibodies were increased in AD patients compared to controls to band 3 peptide 822-839. This band 3 residue lies in an anion transport/binding region.

Ionizing radiation target groups of band 3 inserted into egg lecithin liposomes as determined by Raman spectroscopy.

The purified integral membrane protein, band 3, from human erythrocytes was inserted into egg lecithin liposomes. The insertion of band 3 was determined from thermal transition data from the analysis of the C--H stretching region bands recorded at temperatures from 25 to -22 degrees C. Raman spectra show that band 3 considerably broadens and lowers the thermal transition of egg lecithin liposomes, suggesting the insertion of band 3. The band 3-inserted liposomes were irradiated with gamma-rays (40 Gy) and the radiation target groups were determined by the analysis of the structural sensitive Raman bands in the 1600-1700 cm-1 (amide I), 1200-1300 cm-1 (amide III) and 550-1030 cm-1 (side chain amino groups) regions. The radiation-sensitive groups as identified from Raman spectra in the region 550-1030 cm-1 are tyrosines and cysteines. The radiation-induced changes in the secondary structure were determined from amide I and III bands. Quantitative estimation using the curve fitting method shows that band 3 contains 44% total helix, 48% beta strand and 8% undefined plus turns (error +/- 4%). The secondary structure changes to 35% total helix, 42% total beta-strand and 23% turned and undefined upon irradiating band 3 containing liposomes. We suggest that ionizing radiation preferably damages tyrosine and cysteine side chain residues and reduces the amount of alpha-helical configuration of band 3.

Anion carrier in the human erythrocyte exists as a dimer.

The in situ state of assembly of the human erythrocyte anion carrier (band 3) has been investigated by applying target size analysis on the radiation-induced inactivation of anion flux and degradation of polypeptide band 3. Irradiation with a high energy electron beam resulted in inactivation of carrier-mediated anion flux in intact cells, in inside-out vesicles devoid of cytoskeletal and cytoplasmic proteins, and in inside-out vesicles whose band 3 protein has been partially proteolyzed, with little change in leak pathway. The inactivation showed a single exponential function of radiation dose from which the target size of the anion carrier was estimated to be 210,000, 220,000, and 98,000 daltons in intact cells, in the inside-out vesicles, and in the vesicles after a limited proteolysis, respectively. Irradiation also resulted in degradation of the band 3 of the inside-out vesicles, as detected on sodium dodecyl sulfate-gel electrophoresis, with a dose dependence characteristic of a target size of 220,000 daltons. It is suggested that the human erythrocyte anion carrier exists in situ as a dimer of band 3.

Calorimetric measurements of the effect of 330-MHz radiofrequency radiation on human erythrocyte ghosts.

Irreversible changes in the heat capacity of human erythrocyte ghost suspensions due to the effect of 330-MHz radiofrequency radiation (at a specific absorption rate of approximately 9 mW/g) were detected by the method of scanning differential microcalorimetry. Using the data obtained from the analysis of infrared spectra of air-dried films of erythrocyte membranes, it can be postulated that the observed microcalorimetric changes are connected with the local interaction of electromagnetic radiation with the channel-forming portion of band-3 protein.