We examined the efficacy of long-term subcutaneous deferoxamine therapy in the prevention of iron-related cardiac disease in patients with thalassemia major who began treatment after the age of 10 years. Of 36 such patients without preexisting cardiac disease, 19 did not comply with the program of chelation therapy. Over the course of treatment (1977 to 1983) serum ferritin and aspartate aminotransferase levels fell in the compliant group, from mean values (+/- S.D.) of 4765 +/- 2610 to 2950 +/- 1850 ng per milliliter and 58.1 +/- 22 IU to 30 +/- 20 IU per liter, respectively (P less than 0.05), but rose in the noncompliant group, from 5000 +/- 2316 to 6040 +/- 2550 ng per milliliter and 56.6 +/- 20 to 90 +/- 35 IU per liter, respectively. Only one patient in the compliant group acquired cardiac disease and died of fulminant congestive heart failure. In contrast, 12 noncompliant patients acquired cardiac disease, and 7 died. In addition, the mean age of the compliant population (18.9 +/- 4.5 years) now approaches the mean age of acquisition of cardiac disease in the noncompliant group (19 +/- 4.3). These data demonstrate that compliance with treatment with deferoxamine may protect patients from cardiac disease induced by iron overload.
Spectrin dimers interact weakly with F-actin under physiological solvent conditions (with an association constant of about 5 X 10(3) M-1 at 20 degrees C). In the presence of the membrane skeletal constituent, protein 4.1, strong binding is observed; an analysis of the profiles for formation of a ternary complex leads to an association constant of about 1 X 10(12) M-2. This association becomes weaker at low ionic strength, whereas the opposite applies to the spectrin-actin interaction. The stability of the ternary complex is maximal at physiological ionic strength and somewhat above. The effect of temperature in the range 0-20 degrees C on the formation of the ternary complex is small, whereas the spectrin-actin interaction almost vanishes at low temperature. There is no detectable calcium sensitivity in either the binary or the ternary system within the limits of precision of our assay. The ternary complex resembles the natural system in the membrane in that the actin is resistant to dissociation and unavailable in the deoxyribonuclease assay; after selective proteolytic destruction of spectrin and 4.1, all the actin becomes available. In the absence of 4.1, spectrin dimers do not measurably protect the actin against dissociation.
During liquid preservation under blood bank conditions, red cell membranes inexorably undergo damage that decreases erythrocyte survival after transfusion. Accordingly, we have surveyed membrane skeletal protein interactions during storage.We uncovered a decrease in the in vitro formation of spectrinactin complex in the absence (50%) or presence (60%) of protein 4.1. Actual formation of the spectrin-actin-protein 4.1 complex fell in a linear fashion during the storage period. This fall in spectrin-actin interaction tightly correlated with the decline in total red cell phospholipid (R = 0.9932) measured simultaneously. This decrement of spectrin-actin association could be restored to >70% of normal values by preincubation of stored spectrin with 50 mM dithiothreitol.This storage injury to spectrin-actin interaction might weaken the membrane skeleton and lead to decreased red cell survival. In vitro reversability of the damage by reducing agents suggests a possible new direction for prolonging the shelf life of stored blood.
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