In vitro phagocytosis of carrier mouse red blood cells is increased by Band 3 cross-linking or diamide treatment.

Chemical alteration of red blood cells (RBCs) can induce increased phagocytosis of modified cells by macrophages. In this study we have used different chemical treatments for the modification of the mouse red-blood-cell membrane surface, namely oxidant compounds, such as ascorbate/Fe(+2) and diamide [azodicarboxylic acid bis(dimethylamide)], or Band 3-cross-linking reagents. We monitored the phagocytosis of oxidized or Band 3-cross-linked mouse red blood cells by peritoneal macrophages. The extent of phagocytosis of RBCs is not affected by oxidation with ascorbate/Fe(3+), but it is increased (up to 10%) by oxidation with 2 mM diamide. Furthermore, phagocytosis is greatly increased (up to 40%) as a result of cross-linking with either of two Band 3 bifunctional reagents [bis(sulphosuccinimidyl) suberate (BS(3)) and 3,3'-dithiobis(sulphosuccinimidyl propionate) (DTSSP)]. To evaluate targeting towards macrophages of such modified RBCs for therapeutical purposes, we have determined the phagocytosis of Band 3 carrier RBCs loaded with carbonic anhydrase. In this case phagocytosis is high enough (25%) to deliver the enzyme into macrophages. We have also assayed the influence of serum components and IgG on the efficiency of phagocytosis and discuss the possible phagocytosis mechanisms. In the case of BS(3)-cross-linked carrier RBCs, phagocytosis is markedly enhanced (from 12% up to 25%) by serum components. This opens a way for therapeutic application of these carrier RBCs, with special relevance in short-term delivery to cells of the mononuclear phagocytic system.

Influence of oxidation and crosslinking on oxygen binding properties of mouse erythrocytes.

Different chemical treatments for mouse erythrocyte modification has been used. Oxidation treatments with Ascorbate/Fe(3+), a system able to react with intracellular proteins, produced a displacement of the O(2) binding equilibrium curve to a higher affinity behaviour with loss of the haemoglobin cooperativity for oxygen binding. Incubation of mouse erythrocytes with diamide showed that at low reagent concentration (0.8 mM) no modification on oxygen binding equilibrium curves was observed. At higher reagent concentration (2.0 mM), an increased affinity and a disappearance of the cooperative behaviour can be observed. Additionally, crosslinking reactions on mouse erythrocytes with band 3 crosslinkers seemed to affect oxygen binding properties when used at a crosslinker concentration of 5 mM. Oxyhaemoglobin levels in crosslinked and diamide-treated erythrocytes are similar to those found in control cells. In contrast, ascorbate/Fe(3+) treatments produced an increment in the proportion of methaemoglobin, decreasing the oxyhaemoglobin levels in these oxidized erythrocytes.

Differential in vitro and in vivo behavior of mouse ascorbate/Fe3+ and diamide oxidized erythrocytes.

Chemical oxidation of mouse erythrocytes has been carried out using two different oxidizing systems namely: Diamide and Ascorbate/Fe3+ together with different concentrations of the oxidant. These oxidation treatments produced different extents of modification in membrane proteins as was observed by electrophoretic analyses that showed a possible formation of high molecular weight aggregates. Lipid peroxidation was also observed as the result of these chemical treatments. The action of these two oxidation treatments produced different extents of lipid peroxidation in which the effect Ascorbate/Fe3+ reached higher values than that shown by diamide treatments. To study the resulting in vitro behavior of such oxidized erythrocytes, we have evaluated the recognition of oxidized erythrocytes by peritoneal macrophages. In the conditions used, diamide oxidized erythrocytes were more highly recognized by macrophages than Ascorbate/Fe3+ treated erythrocytes. However, in both cases an influence of serum factors in the recognition process can be inferred. Additionally, we have correlated on one side the action of different oxidation systems on mouse erythrocytes with different in vivo behavior and organ uptake of the oxidized erythrocytes. On the other side, differential targeting of oxidized erythrocytes to a liver or spleen was observed on dependence of the oxidant used.

Influence of aerobic oxidation of mouse erythrocytes on their recognition by macrophages.

Membrane protein modification can change cell surface properties which can be correlated with altered macrophage-erythrocyte interactions. Mouse erythrocytes were incubated in phosphate buffer for different times to induce protein modification. Mouse erythrocyte membrane changes were analyzed by infrared analyses and gel electrophoresis. Proteolytic digestion of membrane proteins was observed. After 22 hours preliminary incubation, the number of erythrocytes adhering to a monolayer of macrophages reached a maximum, the majority of which had not been phagocytosed. Most of the erythrocytes incubated for 40 hours underwent phagocytosis after adhesion to the macrophages.

Delivery to macrophages of interleukin 3 loaded in mouse erythrocytes.

Mouse carrier erythrocytes containing 125I-interleukin 3 have been prepared and treated with band 3 crosslinking reagents. The incorporation of interleukin 3 by hypotonic treatment into mouse erythrocytes reached levels of about 15% of the interleukin 3 added to the medium being predominantly present in the cytosolic fraction (73%). Uptake fell to about 7.4% when using the same conditions but omitting hypotonic shock. The interaction of band 3 crosslinked interleukin 3 loaded erythrocytes with macrophages was also studied. A high level of incorporation of interleukin 3 into macrophages was observed either from band 3 crosslinked, interleukin 3-loaded erythrocytes or from interleukin 3 loaded erythrocytes. The observations encourage the view that the system may be able to deliver and target cytokines and other growth factors to macrophages.

In vivo behaviour of rat band 3 cross-linked carrier erythrocytes.

Rat band 3 cross-linked carrier erythrocytes have been prepared. Iodinated carbonic anhydrase has been encapsulated into rat erythrocytes. Then, carrier erythrocytes were labeled with 51chromium. Eventually, these doubly labeled rat RBCs were treated with a band 3 cross-linking reagent, namely bis(sulfosuccinimidyl)suberate (BS3). 51Chromium labeling and 125I CA showed to have cytosolic localization in cross-linked carrier erythrocytes. Estimation of the band 3 cross-linking induced by BS3 on rat carrier erythrocytes has been done rendering values around 25% of band 3 monomer reduction. BS3-cross-linked carrier erythrocytes when injected into rats are mainly targeted to liver as shown by chromium labeling localization. Also, encapsulated CA radioactivity carried by cross-linked carrier rat erythrocytes when injected into rats is localized predominantly in liver as shown by in vivo experiments. Accordingly, cross-linked carrier erythrocytes are highly recognized by peritoneal macrophages as detected by in vitro analyses of macrophage recognition. Thus, our data revealed a targeting of carrier rat erythrocytes induced by cross-linking of band 3 protein by BS3. These results support claims in favor of this animal model as a feasible system to analyze cross-linked carrier erythrocytes survival and targeting as well as the in vivo efficacy of targeting of loaded compounds to liver.

Differential induction of macrophage recognition of carrier erythrocytes by treatment with band 3 cross-linkers.

Mouse native and hypotonically loaded erythrocytes were treated with two cross-linking reagents: bis(sulphosuccinimidyl)suberate (BS3)- and 3,3'-dithiobis-(sulphosuccinimidyl propionate) (DTSP), excluding clustering agents. Microscopic analyses revealed that band 3 cross-linked native and hypotonically loaded erythrocytes are more strongly recognized by peritoneal macrophages than native and loaded erythrocytes as a result of the cross-linking of band 3 protein in accordance with studies in vivo. Macrophage-recognition analyses of 51Cr-labelled erythrocytes also demonstrated increased recognition of cross-linked and cross-linked loaded erythrocytes. This shows that the only action of these two band 3 cross-linkers on mouse erythrocytes promotes recognition by macrophages without requiring the use of clustering agents. The extent of recognition of BS3 cross-linked and cross-linked loaded erythrocytes by macrophages is dependent on the presence or absence of homologous serum or immunoglobulins. In contrast, the presence of serum factors or IgG in the incubation medium did not seem to influence the recognition of DTSP-modified erythrocytes by macrophages. These results seem to indicate a different mechanism of recognition for the erythrocytes modified with either one or the other band 3 cross-linker. In summary, the unique use of both band 3 cross-linkers procedures can be used to target carrier erythrocytes conveying active compounds to macrophages, with possible therapeutical applications. Different mechanisms of induction of macrophage recognition by these band 3 cross-linkers could reveal differential actions on erythrocytes or the involvement of different factors in the recognition process.

Cross-linking treatment of loaded erythrocytes increases delivery of encapsulated substance to macrophages.

Previous investigation has shown that osmotically loaded erythrocytes can act as drug carriers in systemic circulation, whereas chemically modified erythrocytes can be targeted to organs of the mononuclear phagocytic system because of changes introduced in the membrane that are recognized by macrophage cells. In this study we have examined the delivery of 125I-labelled carbonic anhydrase (125I-CA) carried by mouse erythrocytes, either loaded, or loaded and cross-linked with bis(sulphosuccinimidyl)suberate (BS3) and 3,3'-dithiobis-(sulphosuccinimidyl propionate), into homologous peritoneal macrophages maintained in culture. The hypotonically loaded mouse erythrocytes show a slight recognition by macrophages, similar to native erythrocytes. CA loaded into erythrocytes is thus delivered to a limited extent into macrophages. Neither the number of recognized loaded 51Cr-labelled erythrocytes nor the amount of delivered 125I-CA is affected by the presence of serum components or IgG. In contrast, cross-linking these loaded erythrocytes results in a greater phagocytosis by macrophages as assessed by microscopic observations, producing a markedly increased amount of targeted enzyme. The amount of CA delivered into macrophages, after BS3 cross-linker treatment of erythrocytes, is dependent on the presence of serum components in the incubation medium. Thus these cross-linking treatments improve the capacity of loaded mouse erythrocytes to deliver significant amounts of targeted enzyme to macrophage cells, increasing the therapeutic potential of carrier erythrocytes.