Development and distribution of B lineage cells in the domestic cat: analysis with monoclonal antibodies to cat mu-, gamma-, kappa-, and lambda-chains and heterologous anti-alpha antibodies

To trace the development and distribution of B lineage cells in the domestic cat (Felis catus), we have produced monoclonal antibodies against mu-, gamma-, kappa-, and lambda-chains of feline immunoglobulins (Ig). Goat antibodies against human mu-, alpha-, and lambda-chains, which are reactive with shared determinants on their feline counterparts, were used in conjunction with the panel of mouse monoclonal antibodies. Cytoplasmic mu+ pre-B cells and surface IgM+ B lymphocytes were observed in 42 day fetal liver in which pre-B cells were more abundant than IgM+ B cells. Pre-B cells also were found in bone marrow in young cats, and continued to be generated in the marrow throughout life. In the spleen, adult levels of B cells were attained by 12 wk of age, at which time the frequencies of surface IgM+, IgG+, and lambda+ cells were 49, 3, and 40%, respectively. The distributions of Ig isotypes also were determined among plasma cells as a function of age and tissue localization. IgM plasma cells were predominant in the bone marrow of 1-wk-old cats, whereas IgG plasma cells were the prevalent isotype in adult bone marrow. In the mesenteric lymph nodes of adult animals, the frequency distributions of IgM, IgG, and IgA plasma cells were similar to the frequency distributions of IgM, IgG, and IgA isotypes among bone marrow plasma cells. IgA+ plasma cells predominated in the intestinal lamina propria, in which IgG+ and IgM+ plasma cells were relatively infrequent. In the tissues of both young and adult animals, the ratio of lambda:kappa expression was approximately 3:1. We conclude that the pattern of B cell development in the cat resembles that found in other mammals, except that the kappa to lambda ratio is reversed.     

Development of self-tolerance in normal mice. Appearance of suppressor cells that maintain adult self-tolerance follows the neonatal autoantibody response

T cell populations from BALB/c mice at different ages were analyzed to determine when in development Ts cells specific for the anti-mouse RBC (MRBC) autoantibody response become activated. Previous studies have shown that adult CD8+ T cells actively suppress this autoimmune response and adult spleen cells depleted of CD8+ cells can generate an anti-MRBC response in culture with MRBC. The present results demonstrate that T cells from mice less than 1 wk of age do not suppress the in vitro anti-MRBC response of adult spleen cell populations depleted of CD8+ Ts cells. By 2 wk of age Ts cells are detectable in this anti-self response and reach adult levels by 3 wk of age. Non-specific "natural suppressor" cells normally present in neonatal spleen cell populations are unable to suppress this autoantibody response, although they are active in suppressing anti-SRBC responses in the same cultures. Before the appearance of Ts cells active in the anti-MRBC response, neonatal spleen cell populations can generate anti-MRBC antibody-forming cells, both spontaneously in vivo and in vitro. The in vitro anti-MRBC response of neonatal spleen cells was shown to be Ag driven and Ag specific. The ability of unfractionated spleen cells to generate this response in vitro declines with age and is relatively low by 3 wk. This decline in responsiveness occurs simultaneously with the appearance of suppression specific for the anti-MRBC response, suggesting that the two events may be causally related.     

Ontogeny of Cell-Mediated Immunity of Murine Thymocytes and Spleen Cells

The ontogeny of cell-mediated immunity of spleen cells and thymocytes from B10 mice was studied in both in vitro mixed leukocyte culture and cell-mediated lympholysis reactions. Results show that newborn spleens contain cells competent to respond to X-irradiated allogeneic spleen cells in mixed leukocyte culture. The mixed leukocyte culture response of spleen cells, in terms of both index of stimulation and increment of tritiated thymidine incorporation, seems to be higher for mice four weeks or older than for mice less than four weeks old. The cell-mediated lympholysis response of spleen cells is not detectable until two days postpartum. It reaches adult levels in terms of % cytolysis by day four after birth. Thus, the transition period of the ontogeny of cell-mediated lympholysis response of spleen cells is apparently 0–4 days of age.
Newborn and early postnatal thymocytes (0–7 days of age) respond in mixed leukocyte culture at least as strongly as adult thymocytes (2–3 months of age). The cell-mediated lympholysis response of thymocytes is already detectable at birth, but weaker in terms of % cytolysis when compared with the cell-mediated lympholysis response of thymocytes from two days to six weeks of age. The cell-mediated lympholysis response of thymocytes starts to decline at 6–8 weeks of age. Thus, around the time of birth, there is a transition period in the cell-mediated lympholysis response of thymocytes during which thymocytes start to show high cell-mediated lympholysis reactivity. There is a second transition period between six and eight weeks of age during which the cell-mediated lympholysis response of thymocytes diminishes. The early, as well as late, postnatal cell-mediated lympholysis response of both spleen cells and thymocytes seems to be specific in nature.     

Ethinylestradiol and its effects on the macrophages in the prostate of adult and senile gerbils

Prenatal and neonatal exposure to estrogenic compounds, such as ethinylestradiol (EE), promotes a variety of developmental disorders, including malformations and alterations in the morphology of glands, such as the prostate gland. Therefore, the aim of this study was to evaluate the morphological effects of neonatal exposure to EE on prostatic tissue and on the identification and quantification of gerbil gland macrophages in adult and senile Mongolian gerbils. The animals were exposed to EE (10 μg/kg/day) and to the vehicle, mineral oil (100 μL) (control group) during the first 10 days of postnatal life (lactation period). Adult gerbils were euthanized at 120 days and senile gerbils at 12 months of age. Our findings permitted verification of the presence of areas with proliferative foci in the prostate glandular portions in the adult and senile animals exposed to EE. There was also an increase in macrophages in the prostate tissue of adult and senile gerbils; these cell types alter the stromal microenvironment and possibly modify the interactions between the epithelium and stroma. Neonatal exposure to EE changes the pattern of prostatic development, leading to alterations in the arrangement of cells, including macrophages, and may be related to the onset of proliferative disorders in the prostate of adult gerbils and during aging.     

Adult murine lymph node cells respond blastogenically to a new differentiation antigen on isologous and autologous B lymphocytes.

Cells derived from lymph nodes (LN) of adult CBA mice respond blastogenically to mitomycin-treated autologous, as well as isologous spleen cells. This isogeneic LN-to-spleen (mixed lymphocyte culture) is best obtained when both responder and stimulator cells are derived from donors greater than 10 weeks of age. Responsive cells appear restricted to LN since they could not be detected in adult spleen, marrow, or thymus. LN cells do not require the presence of spleen in order to differentiate into responder cells since those derived from neonatally splenectomized mice are fully active. Stimulator cells appear in the spleen, bear Ig on their surfaces, and can be detected in spleens of irradiated, bone marrow-reconstituted mice. Experiments comparing the responsiveness of adult LN cells and that of neonatal T cells toward mitomycin C-treated lymphoid cells from a variety of sources suggest the presence of two iso-antigens on B lymphocytes. Since both antigens apparently are absent on precursor bone marrow cells and develop with time, they have been classified as murine differentiation antigens 1 and 2 (MDA-1, MDA-2). Whereas both appear in the spleen, only one, MDA-1, is also detectable by this methodology in LN. Both MDA-1 and MDA-2 activate neonatal T cells, but MDA-2 triggers only adult LN. Whereas MDA-2 developed in an x-irradiated, bone marrow-reconstituted spleen, MDA-1 did not over a 9-week interval.     

Reduced ability of neonatal and early-life bone marrow stromal cells to support plasmablast survival

In human infants (<1 year), circulating IgG Abs elicited in response to most T-dependent Ags rapidly decline and return to baseline within a few months after immunization for yet-unknown reasons. In mice immunized between 1 and 4 wk of age, a limited establishment of the bone marrow (BM) pool of long-lived plasma cells is observed. In this study, we show that tetanus toxoid (TT)-specific plasmablasts generated in the spleen are efficiently attracted in vitro and in vivo toward early-life BM stromal cells, which express adult levels of CXCL12. Similarly, adoptively transferred TT plasmablasts efficiently reach the BM compartment of 2-wk-old and adult mice. In contrast, TT plasmablasts fail to persist in the early-life BM compartment, as indicated by the persistence of a significantly lower number of TT plasmablasts in the early-life compartment than in the adult BM compartment 48 h after transfer. This limited persistence is associated with an increased rate of in vivo apoptosis of TT-specific plasmablasts that have reached the early-life BM and with a significantly lower survival rate of TT-specific plasmablasts cocultured on early-life BM stromal cells compared with adult BM stromal cells. Thus, early-life BM stromal cells fail to provide the molecular signals that support plasmablast survival and differentiation into surviving plasma cells.     

Light- and electron microscopic observations on parathyroid glands in different age groups of rats

The parathyroid hormone (PTH) acts on bones, intestines, and kidneys to maintain the calcium homeostasis which, in turn, is a main factor in controling the parathyroid (PT) gland activity. In all mammals studied, the chief cells of PT glands changed their size, shape, and cytoplasmic structure due to different functional states which vary the serum calcium levels. The chief cells of the rat PT glands were classified as dark and light. The dark cells may constitute an active form, characterized mainly by the abundant free ribosomes, conspicuous rough endoplasmic reticulum, and GOLGI complexes, greater number of secretory granules (SG) and increased tortuosity of the plasma membranes as compared to the light ones which were considered as a less active type of cells. Due to different calcium requirements in newborn and young rats for the ossification of growing skeleton and in adult and senile rats with consolidate mature bones, the PT glands studied with electron microscope showed various cytological features. The parenchyma of newborn and young PT glands was composed by dark chief cells. The light chief cells were more frequent in adult and senile animals as a less active type of cell. Mature SG were only occasionally observed in dark cells of newborn, young and adult PT glands. They may constitute a reserve supply of PTH but probably not the main way of secretion, according to their little number. Another pool of PTH probably answers the needs for the small basal variations in the steady-state secretion and may be represented by the vesicles observed in the chief cells cytoplasm.     

The expression of fetuin in the development and maturation of the hemopoietic and immune systems

 The distribution and expression of fetuin, a fetal plasma protein that has been shown to have a widespread intracellular presence in many developing tissues including the central nervous system, has been studied in the developing immune and hemopoietic organs of fetal and adult sheep. The presence of fetuin was demonstrated using immuno-cytochemistry and expression of fetuin was studied using northern blot analysis and in situ hybridization. In the developing sheep fetus, fetuin was shown to be expressed first in the hemopoietic cells of the fetal liver and subsequently in the forming spleen. The very first stromal, bone marrow-forming cells, also expressed fetuin mRNA. These cells became more numerous during gestation and by embryonic day (E)115 (term is 150 days), fetuin-expressing cells were identified morphologically to be monocytes/macrophages. Fetuin protein, on the other hand, was present in all hemopoietic and immune organs from the earliest age studied (E30) but was confined initially to matrix, mesenchymal tissue. Fetuin-positive cells could be identified in the spleen at E60 as early hemopoietic cells, in the lymph nodes at E60 as stromal cells and macrophages, and at E115 in the thymus as macrophages and squamous cells. In the adult, fetuin mRNA was only detectable by northern blot in the liver and the bone marrow. Using in situ hybridization in adult tissue, fetuin mRNA-positive cells were identified in the bone marrow to be monocytes/macrophages. Additionally, in the spleen germinal centres, fetuin mRNA was identified in cells with the morphology of dendritic cells. Using three separate cellular markers: lysozyme, S-100, and α₁-antitrypsin, the cellular identification of fetuin-positive cells was confirmed to be in the monocyte/macrophage lineage. Accepted: 3 May 1996     

Appearance of lymphocyte surface markers and functional responses in neonatal and young rabbit spleens

We examined spleen cells from newborn to 1-month-old rabbits for easily detectable surface immunoglobulin, complement receptors, and for in vitro proliferative responsiveness to anti-immunoglobulin antisera and several mitogens. From birth through the first month of life about 15% of the cells from rabbit spleens had easily detectable surface immunoglobulin while about 45% had C3 receptors. In adults as many as 77% of the spleen cells had easily detectable surface Ig but the proportion with C3 receptors remained about 45%. The proliferative response to anti-allotype antisera was present at birth, and was at adult levels by 1 month of age. The proliferative response to pokeweed mitogen was low when cells were obtained during the first week of life but was comparable in magnitude to the response of adult cells by 2 weeks of age. In vitro responsiveness to concanavalin A was present at low levels at birth and increased sharply during the first week. We did not observe significant stimulation of spleen cells from neonatal to 4-week-old rabbits by lipopolysaccharide from Salmonella typhosa. Our data suggest that lymphocyte surface markers and functional responses appear asynchronously in spleen cells of developing rabbits.     

Measurement and comparison of the proliferative and antibody response of neonatal, immature and adult murine spleen cells to T-dependent and T-independent antigens.

Mouse spleen cell antigenic responses to the thymic-dependent antigen sheep red blood cells (SRBC), and the thymic-independent antigens, E. Coli lipopolysaccharide (LPS) and pneumococcal polysaccharides Type I and II (SI, SII) were studied as as a function of age, employing both in vitro spleen cell stimulation and plaque-forming cell (PFC) assay systems. Primary spleen cell proliferative and PFC responses to SRBC, were either absent or meager in comparison to adult (8–12 weeks) values for the first 3 weeks of life. Thereafter responses rose achieving adult values between 4 and 8 weeks of age. The inability of young mice to respond to SRBC was not because of a different immunizing dose requirement for SRBC, since immunization with SRBC over a 200-fold range did not enhance their capability to respond. Also, addition of adherent cells or macrophages from adult mice did not enhance the immune responses of young mice. Furthermore, immunization of 2–4 week old mice with SRBC inhibited the secondary response to SRBC. In contrast, young murine spleen cell proliferative and PFC responses to SI, SII, and LPS were approximately the same as the adult by 7–14 days of life. These data suggest that B-cell immunologic activity, as measured by immunologic assays utilized in this study, develops much earlier than does T-cell responsiveness.     

Abnormal activation and loss of suppressor T cells in the spontaneously hypertensive rat.

Suppressor T cell function in the spontaneously hypertensive rat (SHR) and normotensive Wistar Kyoto (WKY) rats was analyzed using syngeneic mixed lymphocyte reaction (SMLR) and concanavalin A (Con A) activation. A depressed SMLR was found in adult SHR but not in adult WKY. IL-2 synthesized by SHR was 40-fold lower than that of WKY, and the suppressor T cells generated in the SMLR were incapable of suppressing IgG synthesis. Precursors of cells that can be activated by Con A to become functional suppressor cells are reduced in adult SHR. Supernatant fluids derived from Con A-activated spleen cells from adult SHR failed to significantly inhibit IgG synthesis by cultures of syngeneic spleen cells compared to supernatant fluids from young SHR or WKY Con A-activated spleen cells. However, spleen cells from both adult SHR and WKY proliferated strongly and released equivalent amounts of IL-2 in response to Con A. Addition of exogenous IL-2 to the SMLR cultures in vitro restored the ability of SHR T cells to respond in the SMLR, with generation of cells capable of suppressing IgG synthesis. Administration of SHR with IL-2 in vivo also restored the suppressor T cell function in the SMLR. These results suggest a defective suppressor T cell activation and loss of suppressor T cell activity as the SHR age.     

B lymphocyte differentiation induced by lipopolysaccharide. III. Suppression of B cell maturation by anti-mouse immunoglobulin antibodies.

Lipopolysaccharide-(LPS) induced differentiation of mouse B lymphocytes to cells synthesizing large amounts of cytoplasmic IgM and IgG2 could be suppressed by antibodies to mu-chains. Maximal inhibition of LPS-induced differentiation was associated with increased cellular proliferation as measured by incorporation of 3H-thymidine, whereas treatment with anti-mu alone over a wide dosage range did not stimulate cellular proliferation. Spleen cells from newborn mice were suppressed by concentrations of anti-mu several hundred-fold lower than required for adult spleen cells; the adult pattern of susceptibility to suppression was acquired by 1 week of age. No significant differences in susceptibility to anti-mu were found in comparisons of adult spleen, lymph node, bone marrow, and Peyer's patch lymphocytes.     

Neonatal susceptibility to MHV3 infection in mice. I. Transfer of resistance.

Up to 3 weeks of age, mice of the resistant A/J strain are fully susceptible to mouse hepatitis virus type 3 infection (MHV3). Immune deficiency, however, resulting from neonatal thymectomy or long term ALS administration led A/J animals to remain susceptible when tested at adult age. Whole spleen cells transferred from normal adult A/J donor mice protected suckling syngeneic recipients from i.p. infection with MHV3. Such a protective capacity of spleen cells was abolished after treatment with anti-theta serum and complement. Spleen cell separation by means of adherence to plastic also showed that neither the nonadherent nor the adherent populations injected separately were able to confer resistance to young mice challenged with the virus. Protection was not achieved with peritoneal cells originating from adult syngeneic animals. Transfer of resistance to MHV3 was obtained, however, when peritoneal cells were associated with adherent spleen cells. This study indicated that two types of mature cells, at least, were required for transferring MHV3 resistance into newborn mice of the A/J strain: T lymphocytes and an adherent spleen cell population.     

Studies of the development of frog hemopoietic tissue in vitro. I. Spleen culture assay of an erythropoietic factor in anemic frog blood.

A new in vitro technique has been described for demonstrating the presence of an erythropoietic factor in the circulating blood of frogs. The assay system consisted of MC33 medium, erythropoietically active spleen cells from Rana pipiens, and plasma or serum from frogs made anemic via phenylhydrazine or bleeding. The spleen cells, which remain erythropoietically active for up to nine days, were found to incorporate 59Fe, [3H]thymidine, [3H]uridine, and [3H]leucine at a greater rate in the presence of plasma or serum from anemic versus normal frogs. The hormones triiodothyronine, prolactin, and erythropoietin were not effective in eliciting an hemopoietic response. The data presented suggest that the spleen from that adult frog is a major site of erythroid differentiation and maturation.     

Demonstration of active suppressor cells in spleens of young NZB mice

NZB mice, a strain prone to the development of autoimmune disease, have during the first 2 weeks of life suppressor cells in their spleens which can in coculture with adult spleen cells suppress the antibody response to sheep red blood cells (SRBC) generated in culture by the adult cells. The suppressive activity of spleen cells from NZB mice in the first week after birth is similar to that of spleen cells from 4-day-old C57BL/6 mice, a strain which does not spontaneously develop autoimmune disease. As in “normal” strains of mice, suppressor cell activity in NZB mice is diminished at 2 weeks and undetectable at 3 weeks of age. The data indicate that there is no defect inherent in the suppressor cells detected in the spleens of newborn and young NZB mice and suggest that the development of autoimmune responses does not result from a lack of suppressor cells in the young animals.     

IL-1 secretion and membrane IL-1 expression by neonatal spleen cells during soluble antigen presentation

Antigen presentation and IL-1 production by neonatal spleen cells were studied in a murine model. The T-helper-cell line (D10-G4.1) (D10), which is specific for soluble antigen presented on syngeneic antigen-presenting cells and dependent on IL-1 for its proliferation, was used as an indicator cell for the ability of syngeneic neonatal or adult spleen cells to present antigen and produce IL-1. The antigen-presenting capacity of neonatal spleen cells is low as attested by D10 proliferation. During antigen presentation there is an augmentation of IL-1 production by the antigen-presenting spleen cell population. However, neonatal spleen cells do not respond to the same levels as do adult spleen cells. These reduced levels of secreted IL-1 cannot be attributed to a low potential for producing IL-1 as attested by the high levels of IL-1 made by these cells after induction by a crude IL-1 inducer factor (IL-1-IF) and by the stimulus of the IL-1-IF produced by D10 cells during antigen presentation by paraformaldehyde-fixed adult cells. The spontaneous expression of membrane IL-1 by neonatal cells is low. Membrane IL-1 levels on neonatal cells can be brought to adult levels by induction with IL-1-IF. Neonatal spleen cells have an impaired capacity to process and/or present soluble antigen. This impairment leads to a decreased stimulus of the T helper cell to produce inducer factors and thus a reduced level of IL-1 production by the neonatal cells during antigen presentation.     

GM-CSF augments the immunosuppressive capacity of neonatal spleen cells in vitro

Addition of exogenous granulocyte-macrophage colony stimulating factor (GM-CSF) to cultures of adult murine spleen cells with sheep red blood cells (SRBC) results in an augmented plaque forming cell (PFC) response. The influence of GM-CSF on the ability of neonatal spleen cells to suppress the anti-SRBC plaque forming response of adult spleen cells was tested by adding GM-CSF to cultures of neonatal and adult spleen cells. The suppressive capacity of the neonatal spleen cells was augmented by exogenous GM-CSF. The augmented suppression of the neonatal spleen cells was dependent on a G-10 adherent population since the addition of GM-CSF to cultures containing G-10 passed neonatal spleen cells resulted in an augmented PFC response and not suppression. Neonatal splenic glass adherent cells were also capable of suppressing the response. Neonatal spleen cells or purified neonatal glass adherent spleen cells cultured in the presence of GM-CSF had markedly increased levels of PGE2 in the culture supernatant. Neonatal spleen cells cultured with GM-CSF had increased numbers of morphologically identifiable macrophages after 48 hr of culture. Both irradiation and G-10 passage of the neonatal spleen diminished the numbers of macrophages formed in response to GM-CSF, and both of these manipulations resulted in reversal of suppression in response to GM-CSF. Thus, the augmented suppressive capacity of neonatal spleen cells in response to GM-CSF is probably mediated by its ability to drive monocyte to macrophage differentiation as well as increase the suppressive capacity of the existing neonatal splenic macrophages by increasing their production of PGE2.     

Effector and regulatory cells in autoimmune oophoritis elicited by neonatal thymectomy.

(C57BL/6 x A/J)F1 (B6AF1) mice thymectomized between days 1 and 4 of age develop autoimmune oophoritis (D3TX oophoritis) 4 to 6 wk later. Oophoritis can be adoptively transferred to young recipients, and the disease in D3TX mice is prevented by reconstitution with normal adult spleen cells. The present study was further defined the nature of the effector and suppressor cells. Contrary to an earlier report, oophoritis is transferred to syngeneic and not allogeneic recipients. The spleen cells from D3TX mice when stimulated in vitro with Con A, also transfer oophoritis to adult recipients. The effector cells are CD4+: oophoritis transfer is abrogated by CD4 antibody and not by CD8 antibody and C. Spleen cells from D3TX male mice transfer disease less efficiently than female cells, thus endogenous ovarian Ag may be required for activation of effector T cells. T cells from normal adult spleen that suppress D3TX oophoritis also appear to be of CD4+ phenotype. These cells are likely to be derived from adult thymus because adult thymocytes also suppress D3TX disease. We were unable to substantiate the earlier claim that suppressor cells in normal mice are ovarian Ag specific. Thus male and female spleen cells suppress disease with comparable efficiency, and deprivation of endogenous ovarian Ag by neonatal ovariectomy of cell donors had no observable effect on disease suppression.     

Ontogeny of the immune system inSebastiscus marmoratus: Histogenesis of the lymphoid organs and effects of thymectomy

Synopsis The ontogenetic development of the immune system in a marine teleostSebastiscus marmoratus was studied by histological examination and removal of the thymus. The pronephros and the spleen had been differentiated at the time of birth and contained small numbers of haemopoietic cells. In contrast to most vertebrates, the rudiments of the thymus were first visible 1 week post-birth in the dorsoposterior part of the pharynx, the same location as in the adults. However, small lymphocytes first appeared in the thymus of fish at 3 weeks of age, followed by the pronephros at 4 weeks and the spleen at 6 weeks. Complete or partial suppression of the antibody response to sheep red blood cells (SRBC) occurred in fish that were thymectomized at 1.5 months of age and immunized 2 weeks later, and a marked decrease in lymphocytes was observed in the pronephros and spleen. The thymectomy of adult fish also caused reduced serum antibody titres in fish immunized 1 month after the operation. These results suggest that the thymus plays an essential role in the development of the immune system and its functions continue into adult life.     

Cryptosporidium parvum infection in gene-targeted B cell-deficient mice

The importance of B cells in host resistance to, and recovery from, Cryptosporidium parvum infection was examined in gene-targeted B cell-deficient (muMT-/-) mice. Neonatal muMT-/- mice infected with C. parvum at 5 days of age completely cleared the infection by day 20 PI. The kinetics of infection and clearance were similar to those seen with age-matched C57BL/6 control mice. Furthermore, B cells were not required to clear existing C. parvum infection in adult mice. Reconstitution of persistently infected Rag-1-/- adult mice with spleen cells from muMT-/- donor mice resulted in significant reduction of infection, as in the results seen with spleen cells from C57BL6 donors. These findings indicate clearly that B cells are not essential for host resistance to, and recovery from, C. parvum infection in mice.