Human, guinea pig and rat lympocyte rosette formation with spermatozoids]

In the thymus, spleen and bone marrow of adult guinea pigs, 14--30-week human fetuses, and the peripheral blood of sterile men there were found cells capable of forming the rosettes with homo- or heterologous spermatozoa (RFC). Development of autoimmune orchitis after the trauma of the rat testis or after the guinea pig immunization with the testicular homogenate mixed with complete Freund's adjuvant caused the appearance of RFC with spermatozoa in the thymus and the spleen of rats, and an increase of their number in the lymphoid organs of guinea pigs. Such treatment did not influence the quantity of sheep-cell rosettes in the lymphoid organs of rats and guinea pigs. A possibility of using the detected capacity of animal and human lymphocytes to form spontaneous and immune rosettes with the spermatozoa to test the degree of lympocyte differentiation and their sensitisation to the spermatozoa antigens after the spermatogenesis distrubances of the autoimmune nature is discussed.     

Effects of B-lymphocytes from different organs on hemopoietic colony formation in the spleen by bone marrow cells]

The influence of B-lymphocytes from various sources on splenic colony formation was studied in the syngeneic system. B-lymphocytes were obtained by panning with IgG-fraction of rabbit anti-mouse Ig, absorbed on Petri dishes. In addition, adherent cells, Thy-1+ and SC-1+ were eliminated from the fraction of Ig(+)-cells. SC-1- and SC-1+ fractions, containing, respectively, stem cells and T-lymphocyte precursors, were obtained by panning with IgG-fraction of rabbit anti-SC-1 serum. SC-1- cells transferred to irradiated syngeneic mice did not induce colony formation in the spleen. Introduction of SC-1- and SC-1+ cells induced formation of colonies. A similar helper effect occurred when SC-1(-)-cells were introduced with bone marrow or lymph node B-cells, but not with splenic B-cells. Splenic, but not bone marrow and lymph node B-cells inhibited colony formation by combination of SC-1- and SC-1+ cells. All effects of Ig+ cells were abolished by treatment of cells with rabbit anti-MBLA serum. Thus, B-cells of various origin can either enhance or inhibit colony formation. The enhancing of inhibitory effect after B (MBLA+)-cells elimination from suspension of bone marrow and lymph node (but not spleen) Ig(+)-cells resulted from the activity of B-contrasuppressors.     

Clonogenic hemopoietic cells (CFU-S) in mouse pre- and postnatal ontogeny

Content of three classes of clonogenic haemopoietic cells (CFU-S-7, CFU-S-11 and CFU-S-ep) was determined in haemopoietic organs of mouse during embryogenesis (10, 14 and 18 day) and postnatal ontogenesis (2, 3 and 7 day, 1, 2, 3 and 18 month). CFU-S-7 and CFU-S-11 that from big splenic colonies on 7th and 11th days of transplantation are present in liver, spleen and bone marrow at all developmental stages. However their concentration and CFU-S-7 CFU-S-11 ratio change in haemopoietic organs. CFU-S-ep that form small colonies on 11th day are observed before birth in liver and spleen and 1 week after birth there and also in bone marrow but are practically absent from haemopoietic organs of older animals. Thus, CFU-S compartment structure is characterized by definite ratio of its subpopulations. It seems to reflect functional state of haemopoietic system during development.     

An immunofluorescence analysis of the ontogeny of myeloid, T, and B lineage cells in mouse hemopoietic tissues

The population dynamics of granulopoietic cells, B-lineage cells, and T lymphocytes were analyzed by immunofluorescence in mouse hemopoietic tissues as a function of age. Mac-1+ myeloid cells were present on day 11 of gestation in the liver, where they peaked shortly after birth and declined subsequently. Waves of myeloid population growth began in spleen and bone marrow by days 15 and 19, respectively. Mac-1+ cells increased in number to relatively low plateau levels in spleen by the 3rd wk after birth, whereas in the bone marrow higher plateau levels were reached around 3 mo of age. The 14.8 monoclonal antibody was utilized as one marker of B-lineage precursor cells. 14.8+ cells were detected in the liver on day 11 of gestation, reached peak numbers during the first week after birth and decreased thereafter. On day 15 and 19, 14.8+ cells were found in spleen and bone marrow, respectively, and progressively increased in numbers to reach plateau levels in both sites by 3 mo of age. Mu+ pre-B cells appeared in significant numbers in the 13-day fetal liver, reached a peak shortly after birth, and disappeared from the liver by the end of the second postnatal week. Pre-B cells were found in the spleen and bone marrow on days 15 and 19, respectively. In the spleen pre-B cells reached peak values at birth and disappeared 2 wk later. In spite of the sequential appearance of mu+ pre-B cells in fetal liver, spleen, and bone marrow, their sIgM+ B cell progeny appeared in all these hemopoietic tissues on day 17 of gestation. In the liver, sIgM+ B cells reached their peak at birth and declined thereafter. In the spleen and bone marrow, B cells increased to plateau levels between 1 and 4 mo of age. Thy-1.2+ T cells were relatively late acquisitions in all three hemopoietic tissues. Finally, the expression of the 14.8 antigen by mu+ cells was examined as a function of gestational age. While pre-B cells from day-13 fetuses had no detectable 14.8 antigen, the antigen was weakly expressed on the vast majority of the mu+ pre-B cells by day 17 of gestation. Newborn liver cells expressing 14.8 antigen were found to include a small proportion of cells with peroxidase+ granules. Thus, demonstration of rearrangement and expression of immunoglobulin genes may be required for precise identification of cells of B lineage early in ontogeny.     

Cell surface antigens expressed by subsets of pre-B cells and B cells

A large number of monoclonal antibodies, produced by immunizing rats with mouse pre-B cell lines, have been analyzed for their ability to define cell surface antigens expressed by B cells at early stages of differentiation. Whereas many antibodies recognized antigens on pre-B cell lines, only two clones detected cell surface antigens that were distinguished by their restricted distribution among a panel of continuous cell lines and cells from various tissues. Monoclonal antibody clone AA4.1 recognized a cell surface antigen found on all pre-B lymphomas and on one of three B lymphomas tested. This antigen was found on cells at highest frequency in the bone marrow. Adult spleen and fetal liver also have detectable numbers of AA4.1+ cells. Cells that did not express this antigen include plasmacytomas, two of three B lymphomas, T lymphomas, a stem cell line, adult liver, brain, thymus, and lymph node cells. Clone GF1.2 detected an antigen on some pre-B cell lines, one of three B lymphomas tested, and a small fraction of cells from adult bone marrow, spleen, lymph node, and fetal liver. Plasmacytomas, some pre-B lymphomas, two B lymphomas, T lymphomas, adult liver, brain, and thymus cells were negative. In adult bone marrow, AA4.1 bound to all cytoplasmic IgM+ pre-B cells, whereas GF1.2 detected one-half of these cells. Both antibodies recognized approximately 50% of surface IgM+ (sIgM+) bone marrow cells. A small population of bone marrow cells lacking any detectable Ig (surface or cytoplasmic) also reacted with these antibodies. Depletion of AA4.1 or GF1.2 antigen-bearing cells from bone marrow reduced the ability of bone marrow B cells to respond to LPS by 50 to 65%. Experiments with a cloned pre-B lymphoma demonstrate that AA4.1+ pre-B cells become sIgM+ GF1.2+ B cells after activation with LPS. These antibodies recognize cell surface determinants with restricted distribution among the B lymphocyte lineage because they detect antigens displayed by normal and transformed immature B lymphocytes.     

Immuno-cyto-adhesion and sublethal irradiation]

1. In sublethally irradiated CBA mice, the relative and absolute numbers of spontaneous rosetts forming cells against sheep erythrocytes are markedly decreased in bone marrow. 2. The decrease of the absolute number of spontaneous RFC is also important in the spleen in spite of an increase of the RFC relative number above the normal values between the 8th and 12th day after irradiation. 3. The graft of normal bone marrow cells immediately after irradiation of the shielding of a medullary area during irradiation promotes the recovery of the immunocytoadherence capacity of the bone marrow cells but not of the spleen cells.     

Influence of a sublethal irradiation on the immune response of the mouse to sheep erythrocytes]

In the CBA mice, the immunological response of the spleen cells (RFC and PFC direct and indirect) against the sheep erythrocytes is highly depressed by a 400 R dose of X rays. The recovery is not complete at the 30th day after irradiation. The response of the bone marrow cells either irradiated or unirradiated to the antigenic stimulation is very low.     

Guinea pig and gerbil erythrocytes rosette with different cells in the blood, bone marrow, and thymus of the cat

Cat thymocytes, bone marrow cells, and peripheral blood leukocytes (PBL) formed rosettes with guinea pig (GP) and gerbil (G) erythrocytes (E). In PBL from adult cats the frequency of rosettes was 27% with GPE and GE, while an average of 33% bone marrow cells formed rosettes with GPE and only 4% with GE. Thymocytes from kittens showed a high percentage of rosettes with both GPE and GE (35 to 81%), with the frequency of each type varying with the thymus tested. Fluorescein isothiocyanate labeling of one of the erythrocyte species revealed these cells to be rosetting with different nucleated cells; i.e., a low percentage (3-5%) of the rosettes formed with PBL and bone marrow had both labeled and unlabeled erythrocytes. In contrast, "mixed" rosettes were observed with a significant number of thymocytes, averaging 33% of thymocytes from six animals. A further distinction between the GE- and GPE-rosetting cells was revealed by a monoclonal antibody which blocked GE rosette formation without interfering with the binding of GPE to PBL and thymocytes. PBL could be depleted of either GPE- or GE-rosetting cells, with retention of IgG+ cells and cells capable of rosetting with the second erythrocyte species in the nonrosetting fractions. Stimulation of the latter nonrosetting fractions with pokeweed mitogen for induction of Ig synthesis revealed a T-lymphocyte specificity of the GE- and GPE-rosetting cells. PBL depleted of GE-rosetting cells yielded an increased Ig production, two- to threefold above the control; in contrast, depletion of GPE-rosetting cells from PBL resulted in a failure of the remaining cells to respond. These results suggest that T-suppressor cells of the cat are contained in the GE-rosetting fraction and T-helper cells are rosetted with GPE.     

Types of cells involved in antigen-stimulated and spontaneous rosette formation with Toxoplasma gondii.

Antigen-binding cells were identified by using rosette formation of Toxoplasma gondii and defined lymphoid populations under different experimental conditions. Treatment of immunized spleen cell suspensions with anti-Thy 1 serum plus complement inhibited 5 to 29% of the rosette-forming cells (RFC). Higher numbers of thymus-derived lymphocyte-RFC were obtained after incubation at 4 degrees C and by the centrifugation method than by simple incubation at 20 degrees C. RFC were also observed with thymocytes. Combined treatment with anti-Thy 1 serum plus complement and depletion of adherent cells indicated that the major proportion, 46 to 70%, of RFC were B cells. Spleenocytes of nu/nu mice formed similarly high numbers of rosettes. Spontaneous RFC were observed in nonimmunized mice with both spleen and thymus populations. Numbers of rosettes varied considerably depending on the method and the source of cell population used. Removal of adherent cells from spleen suspensions resulted in RFC reduction of 14 to 25% in immunized and 14 to 33% in nonimmunized animals. Pretreatment with anti-mouse immunoglobulin inhibited completely the spleen and spontaneous thymus RFC and partially the thymus RFC in immunized animals.     

Rescue of embryonic lethality in reduced folate carrier-deficient mice by maternal folic acid supplementation reveals early neonatal failure of hematopoietic organs

The reduced folate carrier (RFC1) is an important route by which the major blood folate, 5-methyltetrahydrofolate, is transported into mammalian cells. In this study we determined the consequences of inactivation of RFC1 in mice by homologous recombination. While RFC1-null embryos died in utero before embryonic day 9.5 (E9.5), near-normal development could be sustained in RFC1(-)/- embryos examined at E18.5 by supplementation of pregnant RFC1(+/-) dams with 1-mg daily subcutaneous doses of folic acid. About 10% of these animals went on to live birth but died within 12 days. These RFC1(-)/- mice showed a marked absence of erythropoiesis in bone marrow, spleen, and liver along with lymphoid depletion in the splenic white pulp and thymus. In addition, there was some impairment of renal and seminiferous tubule development. These data indicate that in the absence of RFC1 function, neonatal animals die due to failure of hematopoietic organs.     

Iron metabolism and erythropoiesis in the prenatal and early postnatal periods of the rat

Spectrophotometric studies have been made on iron balance in the liver, spleen, bone marrow, and blood serum of 15-, 17- and 20-day rat embryos, as well as 1-90 days old rats. It was shown that foetal period is the main one for the formation of iron-accumulating function of the liver. Anaemic period in 14-28-day rat puppies results from insufficient hemoglobin synthesis, rather than from iron deficiency in the organism. The latter is observed in 35-60-days old rats. Maturation of the spleen as the organ involved in reutilization of iron was noted in 42-60-day rats.     

Cellular events in tolerance. V. Detection, isolation and fate of lymphoid cells which bind fluoresccinated antigen in vivo.

The binding of tolerogen to specific receptors of lymphocytes and the subsequent fate of such cells was directly studied in Lewis rats injected with fluorescein-labeled sheep gamma globulin (F-SGG). This tolerogen produced unresponsiveness both in SGG-specific T cells (carrier tolerance) and F-specific antibody-forming cell precursors. The former (T-cell tolerance) was still significant more than 60 days after tolerogen whereas tolerance in the latter (B-cell tolerance) had waned by that time.Cells which have bound the tolerogen (antigen-binding cells, ABC) in vivo were detectable by direct immunofluorescence of washed spleen cell suspensions from rats injected with F-SGG up to 7 days previously. These cells were isolated using antifluorescein affinity columns, and shown to contain immunocompetent precursors for F- and SGG specific responses.The frequency of such ABC was between 30 and 80 per 10⁵ spleen, lymph node or bone marrow cells; no ABC were detected in the thymus. Both Ig positive and Ig negative cells were found to be ABC; Ig negative ABC usually showed a “capped” fluorescent pattern whereas Ig positive ABC generally were “spotted.”By 10 days after injection, ABC were not detectable in the spleen, lymph nodes, thymus or bone marrow of tolerant rats. Furthermore, reinjection of F-SGG after this time did not label any cells. This suggests that antigen-binding cells are not present at this time or that such cells, if available, lack receptors. In contrast, rats previously injected with a lower non-tolerogenic dose of F-SGG or an immunogenic form (F-SGG on bentonite) possessed cells at these later times which could be labeled with F-SGG. Thus, ABC remain detectable following immunogen or a subtolerogeic dose of F-SGG, but disappear in tolerant rats.By approximately 40 days after initial high dose tolerogen injection (when B cell tolerance has started to wane), cells capable of binding a second dose of F-SGG again became detectable. It is suggested that high doses of F-SGG are bound by specific lymphocytes (identifiable as ABC) and that these cells either fail to regenerate new receptors or die. As tolerance begins to wane, either new receptors or new cells are generated.     

Ontogeny of IgE-bearing lymphocytes in the rat

IgE-bearing lymphocytes were detected by immunofluorescence in the spleen of neonatal Hooded Lister strain rats within 24 hr after birth. The same cells were detected in the bone marrow as early as the 4th day after birth. Both fetal spleen and liver obtained 1 day before birth contained IgM-bearing cells but no detectable IgE-bearing cells. The proportion of IgE-bearing cells in the spleen and bone marrow increased during the neonatal period and reached an adult level within 3 to 4 weeks after birth. In adult Hooded Lister rats, IgE-bearing cells were 3 to 6% of total spleen cells and 1.5 to 2.2% of bone marrow cells. Most of the IgE-bearing cells from bone marrow cells. Most of the IgE-bearing cells from both newborn and adult animals carried IgM determinants on their surface. Capping experiments showed that epsilon chain determinants and mu chain determinants belonged to separate molecules. IgG2a-bearing lymphocytes were detected in the neonatal spleen as early as the 4th day after birth, but a significant number of these cells was not detected in the bone marrow until the 4th week. In newborn spleen the percentage of IgE-IgM double bearing cells was higher than that of IgG2a-bearing cells.     

Increased cellular hypoxia and reduced proliferation of both normal and leukaemic cells during progression of acute myeloid leukaemia in rats

The microenvironmental changes in the bone marrow, spleen and liver during progression of the transplantable promyelocytic leukaemia in the Brown Norwegian rat (BNML) have been studied. We used flow cytometry to estimate cellular hypoxia and proliferation based on in vivo pulse-labelling with a mixture of 2-nitroimidazole linked to theophylline (NITP) and bromodeoxyuridine (BrdUrd). The leukaemic cells were identified with the RM124 antibody. In rats inoculated with leukaemic cells the fraction of RM124+ cells was significantly increased from day 20 onwards in the spleen and from day 27 in the bone marrow and liver, reaching a level of 65-87% in these organs at day 32. At day 32, the NITP+ fraction of RM124+ cells had increased significantly in the bone marrow and spleen to 88% and 90%, respectively. The corresponding fractions of NITP+ normal cells reached 63% and 65%, respectively. From day 13 to day 32, the DNA-synthesizing (BrdUrd+) fraction of RM124+ cells in the bone marrow decreased significantly from 52% to 25%, and of normal cells from about 20% to 6%. In the bone marrow and spleen at day 27 and 32, the S-phase and G2/M-phase fractions according to DNA content were higher for the NITP+ than for the NITP- cells. This could partly be explained by an impaired cell cycle progression due to hypoxia. Nevertheless, we found indications of leukaemic cells that were simultaneously labelled with NITP and BrdUrd, in the bone marrow and spleen. These latter findings suggest that in contrast to normal cells some of the leukaemic cells can proliferate even during hypoxia, and this subpopulation may consequently renew and expand the leukaemic cell load.     

Ontogeny of terminal deoxynucleotidyl transferase-positive cells in lymphohemopoietic tissues of rat and mouse.

The ontogeny of hemopoietic cells which contain the enzyme terminal deoxynucleotidyl transferase (TdT) was studied in rats and mice. During fetal life, TdT-positive cells were first detected in the thymus, where they appeared on or about day 17 of gestation. TdT-positive cells were not found in fetal liver, spleen, or bone marrow, but appeared in bone marrow and spleen on the day after birth. In the rat, peak levels of TdT-positive cells were attained at 3 to 4 weeks of age in thymus, bone marrow, and spleen, accounting for 67, 3.9, and 2.3% of nucleated cells, respectively. The percentages of TdT-positive cells in thymus and bone marrow decreased gradually thereafter, whereas, TdT-positive cells in spleen were no longer detectable by 7 weeks of age. Normal percentages of TdT-positive cells were found in bone marrow and spleen from neonatally thymectomized rats and congenitally athymic (nu/nu) mice. Dexamethasone treatment resulted in a marked decrease in TdT-positive cells. The results are discussed with respect to the putative role of TdT-positive hemopoietic cells as thymocyte progenitors.     

Repair processes of hemopoiesis after applying cyclophosphamide. II. Quantitative changes in basic proteins and DNA in the bone marrow, spleen, and thymus

The effect of cyclophosphamide on the organ weight, DNA and basic protein content in nuclei of bone marrow, thymus and spleen of rats was studied. Animals were examined 6, 12 and 24 hours and 3, 5, 10, 20 and 30 days after intraperitoneal application of cyclophosphamide in the doses of 100 and 200 mg X kg-1 of body weight. From the 5th day after application a marked decrease in weight and cellularity of all organs was observed. Amounts of DNA and basic proteins in nuclei of bone marrow and spleen were higher as compared with controls and their increase occurred prior to recovery of cellularity and organ weight, that was initiated within 5 and 10 days after cyclophosphamide treatment. Changes in the thymus persisted for a longer period of time and recovery was incomplete even at the day 30 after cyclophosphamide application. In accordance with these data no increase in DNA and basic protein amounts in the thymus nuclei was observed.     

Antigen-binding cells in central and peripheral lymphoid tissues of the rabbit

The rosette assay was used to study antigen-binding activity by cells in lymphoid tissues of rabbits immunized with sheep red blood cells and in unimmunized controls. Percentages of rosette-forming cells (RFC) observed were compared with those of cells which secreted antibody (plaque-forming cells, PFC) and cells which both bound antigen and secreted antibody. Rosette-forming cells and PFC were shown to be two distinct reactive cell populations. Thus, in the spleen less than 1% of RFC also formed plaques. Immediately following antigen stimulation, the number of RFC in the bone marrow decreased to below detectable limits. After an initial rise, the number of RFC in the appendix declined similarly. In contrast, RFC levels in the spleen rose steadily from the time of immunization. These patterns suggest that bone marrow and appendix may function as a reservoir of antigen-binding cells which are released to other sites following antigenic stimulation. Rosette-forming cells were rarely observed in the thymus. Rosette-inhibition studies using antisera specific for bone marrow-derived cells (anti-B) and thymus-derived cells (anti-T) revealed a markedly greater proportion of T-RFC in the appendix than in the spleen.     

Migration and differentiation of bone marrow lymphocytes: development of surface immunoglobulin, Fc receptor, complement receptor, and functional responsiveness as studied with anti-allotype serum

Immunofluorescent studies using fluorescein isothiocyanate-conjugated mouse anti-allotype antibody were carried out to study the migration pattern and the development of surface Ig (SIg), Fc receptor for IgG (FcR gamma), and complement receptor (CR) or mouse bone marrow lymphocytes following intravenous injection into congenic mice. After transfer of bone marrow cells from CSW mice into untreated congenic CWB mice, the absolute number of donor-type SIg-bearing (SIg+) cells and the proportion of either FcR gamma- or CR-bearing (FcR gamma+ or CR+) cells in donor-type SIg+ cells were evaluated in the recipient spleen and the results were compared with those obtained after the transfer of CSW spleen cells. After injection of donor bone marrow cells, detectable donor-type SIg+ cells, although few initially, increased from day 1 to Day 2 and reached a plateau thereafter. The proportion of FcR gamma+ cells in donor-type SIg+ cells, although very low in the donor marrow inoculum, increased progressively after 1 day to reach a maximum at Day 5 (90%). On the other hand, following the transfer of spleen cells, the proportion of FcR gamma+ cells remained at high levels (90%) for 5 days after transfer. Likewise, the proportion of CR+ cells in donor-type SIg+ cells was very low (less than 1%) in the original donor bone marrow cells but high (60%) in the donor spleen cells. However, in transferring bone marrow cells this proportion also increased in the recipient spleen to reach a maximum (49%) at Day 5 although it was lower compared to the percentage of FcR gamma+ cells in donor SIg+ cells. Furthermore, the ability of functional responsiveness to antigen was also examined in the same system by detecting plaque-forming cells (PFC) from donor origin. In transferring donor bone marrow cells into recipient, the participation of donor cells in the PFC response was very low when the recipients were primed with sheep red blood cells at Day 3 after transfer. However, when the recipients were primed at Days 7 to 21 after transfer, increasing numbers of the donor marrow-derived cells were involved in the PFC response. Thus, the present study demonstrates that the bone marrow-derived lymphocytes, albeit lacking both distinctive surface receptors (IgM, FcR gamma, CR) and the functional responsiveness to antigen, continue their development along the B-cell lineage after migrating into the spleen, as evidenced by the surface receptor expression and participation in the antibody response.     

Effect of various periods of social isolation of juvenile rats on the level of their intraspecies aggression at a sexually mature age

Isolation of male outbred white rats from the same age rats at 12-30 and 15-30 days of postnatal life increases their aggressiveness in pubertal age and causes a change of aggressive reactions spectrum towards the decrease of attacks and increase of threats in relation to intruders. These changes in the ontogenetic formation of rats aggressive behaviour are not compensated by the experience of rats social intercourse in the period 30-70th days. A hypothesis is made about the existence of sensitive period of rats aggressive behaviour formation with the approximate limits 15th-30th days of postnatal life during which under the influence of contacts with rats of the same age prerequisites are created for consolidation of various agonistic reactions in resultant act of mature aggression.     

An experimental study on the pathway of iron transfer from macrophages to erythrocytes in rat liver

In order to reveal the pathway of iron release from macrophages, a 59Fe-labelled ferric hydroxide-potassium polyvinyl sulfate complex (Fe-PVS) was injected intravenously into anemic rats and the level of radioactivity in the liver, spleen, bone marrow, blood plasma and red blood cells (RBC) was estimated at various time intervals after the injection. Histochemical observation of ferric iron and ferritin in the liver was also made on anemic rats treated using unlabelled Fe-PVS. Fe-PVS injection promoted the recovery of anemia causing a rapid increase in the RBC number, with activated erythropoiesis occurring in the spleen and bone marrow. Soon after the injection, most of the radio iron was found in the liver with a small amount in the circulating erythrocytes, bone marrow and spleen. The iron level in the liver decreased gradually with a rapid increase in the iron level of the erythrocytes which reached a very high level 6 days after the 59Fe-PVS injection. Histochemical observations showed a heavy deposition of ferritin in the Kupffer cells 3 days after Fe-PVS injection. This deposition was minimized after 6 days with an increase in the level of ferritin in the parenchymal cells in the central area of acini. The level of radioferritin estimated biochemically in the nonparenchymal cell fractions of the liver revealed that the level dropped by about one third approximately 3.5 days after the Fe-PVS injection, showing the stimulated ferritin release at this stage. Results indicate that Kupffer cells in the liver play an important role in ferritin synthesis from the phagocytized iron compounds and that the iron is supplied for erythroid cell proliferation.