N. Kors

Depletion and repopulation of macrophages in spleen and liver of rat after intravenous treatment with liposome-encapsulated dichloromethylene diphosphonate

SummaryRats received a single intravenous injection with liposome-encapsulated dichloromethylene diphosphonate (Cl2MDP). This treatment resulted in the elimination of macrophages in spleen and liver within 2 days. Macrophages ingest the liposomes and are destroyed by the drug, which is released from the liposomes after disruption of the phospholipid bilayers under the influence of lysosomal phospholipases. Repopulation of macrophages in spleen and liver was studied at different time intervals after treatment. Macrophages in the liver (Kupffer cells) and red pulp macrophages in the spleen were the first cells to reappear, followed by marginal metallophilic macrophages and marginal-zone macrophages in the spleen. Different markers of the same cell did not reappear simultaneously. On the other hand, the same marker (recognized by the monoclonal antibody ED2) reappeared much more rapidly in the liver than in the spleen. The present results in the rat were different from those earlier obtained in the mouse. Red pulp macrophages were the first cells and marginal zone macrophages were the last cells to repopulate the spleen in both rodents after treatment with Cl2MDP liposomes. However, there was much more overlap in the repopulation kinetics of splenic macrophage subpopulations in the rat, when compared with the mouse.

Repopulation of Macrophages in Popliteal Lymph Nodes of Mice After Liposome-Mediated Depletion

Macrophages lining the subcapsular sinus (SCS) and those located in the medulla of popliteal lymph nodes (PLN) of mice were eliminated after subcutaneous (s.c.) injection of dichloromethylene diphosphonate (CI2MDP)‐containing liposomes. No effect of liposome‐entrapped CI2MDP could be seen on nonphagocytic cells, e.g., interdigitating cells (IDC) and B‐ and T‐lymphocytes. One month after injection the eliminated subsets of macrophages were still absent. After 2 mo a small number of macrophages had reappeared along the SCS and in the medulla of the PLN of a few animals. Complete repopulation of the PLN with macrophages was observed only after 5 mo.

Elimination of Spleen and of Lymph Node Macrophages and Its Difference in the Effect on the Immune Response to Particulate Antigens

To study the role of macrophages in the in situ immune response to particulate antigens in spleen and popliteal lymph nodes (PLN), mice were injected with dichloromethylene diphosphonate (Cl2MDP)-containing liposomes to eliminate macrophages, followed by immunization with trinitrophenylated sheep red blood cells (TNP-SRBC). Depletion of macrophages in the spleen caused a strong decrease in the number of antibody-forming cells (AFC), which develop after intravenous (i.v.) injection of the antigen. These results strongly suggested the involvement of splenic macrophages in the processing of TNP-SRBC. In particular, the populations of marginal zone macrophages may be involved in the inductive phase of an antibody response to particulate antigens. These macrophages are strategically positioned at the end of the white pulp capillaries in the marginal zone of the spleen and they have their cell processes between the marginal zone-B cells. Elimination of macrophages in PLN had no effect on the number of AFC, which develop after subcutaneous (s.c.) injection of the antigen in the hind footpads. This indicates that the macrophages are not essential for the induction of a local immune response to the particulate antigen TNP-SRBC. After depletion of lymph node macrophages, the number of AFC developing in the spleen after s.c. footpad injection of the antigen increased and the anti-TNP serum titers were elevated. This may well be caused by the fact that more of the antigen reaches the circulation and subsequently stimulates the spleen.

Double immunocytochemical staining in the study of antibody-producing cells in vivo. Combined detection of antigen specificity (anti-TNP) and (sub)class of intracellular antibodies.

Mice and rabbits were immunized with trinitrophenyl (TNP)-conjugated keyhole limpet hemocyanin (KLH). Cells producing specific antibodies against the hapten TNP were detected in vivo in spleen and lymph nodes using a TNP--alkaline phosphatase (AP) conjugate. Using horseradish peroxidase (HRP)-conjugated anti-mouse (sub)class (IgG2A, IgG2B, IgM) antibodies and anti-rabbit class (IgG, IgM) antibodies and a double immunocytochemical staining technique for simultaneous demonstration of the enzymes AP and HRP, we were able to determine both the antigen specificity (anti-TNP) and the (sub)class of intracellular antibodies produced by individual antibody-forming cells in vivo.

Double-enzyme conjugates, producing an intermediate color, for simultaneous and direct detection of three different intracellular immunoglobulin determinants with only two enzymes.

A new double-enzyme conjugate was synthesized by coupling alkaline phosphatase (AP) to horseradish peroxidase (HRP). After AP (blue) and subsequent HRP (red) cytochemistry, this new conjugate produced a stable intermediate-colored (violet) product. By coupling this double-enzyme conjugate to an antigen (trinitrophenyl, TNP) or an antibody (anti-mouse immunoglobulin G2a), anti-TNP or -IgG2a-producing cells could be demonstrated as violet cells in spleen sections. This led to the development of a rapid one-step incubation--two-step cytochemical procedure for simultaneous detection of three different determinants in a single tissue section. To demonstrate this novel triple staining method, we coupled three different antigens to, respectively, AP, HRP, and AP-HRP. When spleen sections of immunized animals were incubated with a mixture of these three antigen-enzyme conjugates, we could distinguish antibody-forming cells against each of these three antigens simultaneously as red (HRP), blue (AP), and violet (AP-HRP) cells. The simultaneous detection of three different classes of intracellular antibodies in a single section also proved to be possible with this method. With this study we provide a new direct method for detection of three different intracellular immunoglobulins after a one-step incubation and a two-step standard cytochemical procedure.

The in situ immune response of the rat after intraperitoneal depletion of macrophages by liposome-encapsulated dichloromethylene diphosphonate

This study concerns the contribution of peritoneal macrophages in vivo to local and systemic immune responses in the rat. Peritoneal macrophages as well as macrophages in the draining parathymic lymph nodes were selectively eliminated by intraperitoneal inoculation of dichloromethylene-diphosphonate-containing liposomes. This depletion resulted in an enhanced immune reaction to intraperitoneally administered trinitrophenyl keyhole limpet haemocyanin in the parathymic lymph nodes, as demonstrated by the higher numbers of specific anti-TNP antibody-forming cells in macrophage-depleted animals than in control animals from day 5 after immunization. The immune reaction peaked at day 7 and remained high until day 10. Specific antibody-forming cells were found occasionally in the mesenteric lymph nodes and spleen, but not in the mucosa of the gut or in the bronchus-associated lymphoid tissue. An elevated immune reaction found in parathymic lymph nodes associated with the depletion of local macrophages by liposome treatment indicates a regulatory role of peritoneal macrophages in local humoral immune response.

Antigen-coupled beads adherent to slides: a simplified method for immunological studies.

Small amounts of antigen-coupled beads adherent to object slides provide a simple, quick, economical and sensitive immunohistochemical means of detecting antibodies in serum by both immunofluorescence and immunohistoperoxidase procedures. Sensitivity increases with decreasing quantities of antigen-coupled beads, as was demonstrated in the fluorescence procedure.

Double immunocytochemical staining in the study of antibody-producing cells in vivo. Detection of specific antibody-producing cells in the spleen and simultaneous determination whether or not they produce immunoglobulin G antibodies.

Rabbits were primed intravenously with human serum albumin (HSA) and boosted with the same antigen 2 months later. Cells producing specific antibodies against HSA could be detected in vivo and it could be determined whether or not they belonged to the immunoglobulin (Ig) G class using a combined peroxidase (HRP) and alkaline phosphatase (AP) immunocytochemical technique. HRP-HSA conjugate was used for detection of anti-HSA-producing cells and AP-sheep anti-rabbit IgG (SRIgG) was used to determine the IgG class of the antibodies produced by these cells in the same spleen section. After performing both HRP and AP cytochemistry, cells with a red-stained cytoplasm represent anti-HSA-producing cells not stained for their antibody class and cells with a blue-stained cytoplasm represent cells producing IgG antibodies not directed against HSA. Cells with a double-stained cytoplasm represent cells producing anti-HSA antibodies belonging to the IgG class. We also attempted to determine whether or not part of the anti-HSA-producing cells belonged to the IgM class using AP-sheep anti-rabbit IgM (SRIgM). In this case no double-stained cells were detected, indicating that the affinity of intracellular IgM-anti-HSA antibodies is too low to allow detection using the present technique.

Double immunocytochemical staining in the study of antibody-producing cells in vivo. Simultaneous detection of cells producing monospecific antibodies and cells producing cross-reacting antibodies in the spleen of rabbits after injection of two related antigens.

Rabbits were injected simultaneously with both human gamma globulin (HGG) and bovine gamma globulin (BGG). Sections of spleen tissue were prepared from spleen biopsies taken during the primary or secondary immune response, and incubated simultaneously with horseradish peroxidase (HRP)-HGG conjugate and alkaline phosphatase (AP)-BGG conjugate in order to detect cells containing specific antibodies against one or both of the antigens. After both HRP and AP cytochemistry, cells with a red-stained cytoplasm, cells with a blue-stained cytoplasm, and cells with a violet-stained cytoplasm were detected in the spleen. The red-stained cells had bound the HRP-HGG conjugate, indicating that these cells contained anti-HGG antibodies. The blue-stained cells had bound the AP-BGG conjugate, indicating that these cells contained anti-BGG antibodies. The violet-stained cells had obviously bound both the HRP-HGG conjugate and the AP-BGG conjugate, indicating that these cells contained antibodies cross-reacting with both antigens. Results are compared with earlier studies on the antigenic similarities and differences between HGG and BGG when used as antigens in rabbits.

Peroxidase Immunocytochemistry for the Detection of Specific Anti-Hapten (Penicilloyl) Antibody Producing Cells in the Spleen, After Injection of a Hapten-Carrier Conjugate

Cells producing specific antibodies against the hapten penicilloyl (Pen) are demonstrated in tissue sections of the spleen, using peroxidase immunocytochemistry. Horseradish peroxidase-human serum albumin-penicilloyl (HRP-HSA-Pen) conjugate, prepared by coupling Pen to HRP-HSA conjugate, was used for detection of anti-Pen producing cells in the spleen after intravenous injection of bovine gamma globulin-penicilloyl (BGG-Pen) conjugate. HRP-HSA conjugate was used as a control to exclude the possibility that positive cells contained antibody against a common determinant in both HSA and BGG. The method may be applied for the detection of cells producing antibodies against other haptens as well.