The age-dependent loss of bone marrow B cell precursors in autoimmune NZ mice results from decreased mitotic activity, but not from inherent stromal cell defects

The formation of B lymphocytes is abnormal in autoimmune NZB and (NZB x NZW)F1 mice. With age, the proportion of sIg- Ly-5(220)+ pre-B cells and less mature B cell progenitors in the bone marrow progressively declines, reaching only approximately one-third of normal levels in 20-wk-old NZ mice. To determine the mechanisms responsible for the deficiency of NZ B lineage precursors, the mitotic activity of sIg- Ly-5(220)+ bone marrow cells in vivo was determined in NZ and conventional inbred mice as a function of age. The proportion of sIg- Ly-5(220)+ B cell precursors in (S + G2/M) stages of the cell cycle steadily decreased with age in NZ autoimmune mice. Furthermore, upon metaphase arrest, the rate of entry of sIg- Ly-5(220)+ bone marrow cells into G2/M also decreased with age in NZ mice. Therefore, the mitotic activity of sIg- Ly-5(220)+ B cell precursors is substantially decreased in NZ mice greater than or equal to 20 wk of age. The capacity of the bone marrow stromal microenvironment of NZ mice to support B lineage precursor growth was tested in two ways: 1) the capacity of preformed NZ bone marrow stroma to support B lineage cell growth in long term bone marrow cell culture under lymphopoietic conditions was assessed and 2) the capacity of NZ bone marrow B lineage precursors to expand in vivo after sublethal (200 rad) whole body irradiation was determined. Stroma derived from adult NZ mice supported the growth and development of B lineage lymphocytes in long term bone marrow cell culture to a greater extent than did age-matched conventional murine stroma. Furthermore, sublethal irradiation of older adult NZ mice resulted in some expansion of bone marrow sIg- Ly-5(220)+ B cell precursors in vivo. Therefore, the deficiency of B cell progenitors in the bone marrow of older NZ autoimmune mice is associated with diminished mitotic activity. However, this does not result from defects in the capacity of NZ bone marrow stroma to permit B lineage cell expansion as determined by both in vitro and in vivo experiments. In the absence of a detectable stromal cell defect, it is possible that an active inhibitory process within the bone marrow influences the mitotic activity of B cell precursors in NZ mice.     

Interleukin 1-mediated induction of kappa-light chain synthesis and surface immunoglobulin expression on pre-B cells

In this study we have examined the effect of interleukin 1 (IL 1) on the maturation of normal and neoplastic pre-B cells. We have found that IL 1 can enhance the in vitro functional maturation of surface immunoglobulin negative (sIg-) pre-B cells from normal bone marrow. In addition, IL 1 specifically induced sIg expression on an established pre-B cell line, 70Z/3. These effects of IL 1 were obtained with the same concentrations of IL 1 that are effective in assays for T cell proliferation and functional activation. Previous studies by other investigators have demonstrated that LPS can also induce the expression of sIg on 70Z/3 cells. The stimulatory effect of LPS was dependent on the stimulation of kappa-light chain synthesis, the synthesis of mu-chains being constitutive. Our results indicate that IL 1 may also enhance sIg expression via the induction of kappa-light chain synthesis. The stimulatory effect of IL 1 was not due to contaminating LPS in the IL 1 preparations, because removal of the IL 1 by using specific antibodies against IL 1 and fixed Staphylococcus aureus cells resulted in the disappearance of kappa-chain inducing activity. In addition to IL 1, a pH 2-sensitive mediator(s) present in concanavalin A (Con A)-stimulated spleen cell supernatants was also shown to induce kappa-chain synthesis and the appearance of sIg on 70Z/3 cells. Removal of IL 1 or the inhibition of any contaminating LPS activity with polymyxin B did not diminish the activity of the pH 2-sensitive Con A supernatant factor(s). On the basis of our findings, we have concluded that IL 1 may enhance antibody responses by not only increasing the number of helper T cells but also by stimulating the maturation of B cell precursors.     

Tyrosine phosphorylation of CD19 in pre-B and mature B cells.

Cross-linking of B cell surface immunoglobulins (sIg) results in activation of mature B cells and stimulates a molecular signaling mechanism for antigen-specific B cell expansion and differentiation. This signaling pathway is dependent on tyrosine (Tyr) phosphorylation and results in the activation of sIg-associated src family kinases and p72SYK. Rapid Tyr phosphorylation occurs on multiple protein substrates. Here we show that activation of B cells by cross-linking sIg results in an increase in Tyr phosphorylation of the lineage-restricted B cell surface antigen CD19, and show that it is a major substrate of activated Tyr kinase following sIg stimulation. Lower levels of constitutive CD19 Tyr phosphorylation occurred in most sIg+ mature B cell lines examined and in normal dense tonsillar B cells. We also find that when CD19 is Tyr-phosphorylated it becomes competent to interact with SH2 domains suggesting a mechanism whereby, following B cell activation, CD19 could be linked to intracellular signaling pathways. In sIg- pre-B cell lines, CD19 was expressed but was not constitutively phosphorylated on tyrosine. Upon CD19 cross-linking, Tyr phosphorylation of CD19 was induced in sIg- pre-B cell lines. CD19 cross-linking also directly induced Tyr phosphorylation of CD19 and other substrates in mature B cells. The ability of CD19 to signal in the absence of sIg expression may provide important stimulation in pre-B cell development.     

Ontogeny of B lymphocyte function. XV. A role for thymus cells in the maturation of the capacity of a subpopulation of B cells to re-express surface immunoglobulin after treatment with anti-immunoglobulin

The maturation of the C57BL/6 B cell population to be able to re-express surface immunoglobulin (sIg) after its removal by treatment with rabbit antimouse Ig (RAMIg) was studied in a cell transfer system. It was found that thymus cells were required for the maturation of a subset of the B cell population to be able to re-express sIg. The B cell population of irradiated, thymectomized mice reconstituted with spleen cells from donors under 2 wk of age remained deficient in their ability to re-express sIg even after 4 wk residence in the cell transfer recipient. In contrast, if adult thymus cells were transferred together with the immature B cells, the B cell population matured to be able to re-express sIg after treatment with RAMIg. Approximately one-third of the B cell population appears to require thymus cells for this maturation. The maturation of the thymus cell population to be capable of mediating this maturation of the B cell population occurs in two steps: between 2 and 3 and between 3 and 4 wk of age. This timing corresponds to the age at which the B cell population of C57BL/6 mice normally acquires the capacity to re-express sIg, which we have previously shown to also occur in two steps. Thymus cells from 3-wk-old donors can mediate the first step in B cell maturation to be able to re-express sIg, but cannot mediate the second step in this maturation of the B cell population. Thymus cells from 4-wk-old donors can mediate both steps in the maturation of the B cell population. The results suggest that thymus cells are involved in regulating some aspects of B cell differentiation.     

NZB serum factor (NZB-SF): B precursor cell maturation factor identified in murine lupus. I. Identification of 60-kDa glycoprotein as the major component from both spleen cell supernatant and serum

NZB serum factor (NZB-SF), initially identified in sera of very young NZB mice, can enhance maturation and proliferation of sIg- pre-B cells in marrow. In the present study, spleen cell supernatant from young NZB mice was used as a source of NZB-SF. NZB mice were treated with Corynebacterium parvum 2 weeks prior to sacrifice, and harvested spleen cells obtained at sacrifice were cultured for 24 hr in serum-free medium. One liter of spleen cell supernatant prepared in this way contained NZB-SF-like activity equivalent to that present in 10 ml of serum collected from young NZB mice. NZB-SF was purified on an affinity chromatographic column conjugated with mouse IgG1 monoclonal antibody (mAb) against NZB-SF. The purified NZB-SF had pI 7.8 and showed one major band of 60 kDa and a faintly stained 35-kDa band upon SDS-PAGE under nonreducing conditions. The 60-kDa NZB-SF extracted from the gel slice was also more potent in dot blot ELISA (greater than 100 times) than the 35 kDa NZB-SF and was biologically active. After endoglycosidase F treatment, but not after treatment with a reducing agent (2-ME), the two bands merged into a single band at the 15-kDa position. Amino acid sequence analysis of endo-F treated NZB-SF indicated that the N-terminus of this protein is blocked. Serological and functional studies of affinity-purified NZB-SF have revealed that NZB-SF is distinguishable from IL-1 alpha, IL-2, IL-3, IL-4, IL-5, IL-6, CSF-GM, IFN-gamma, and TNF alpha. Therefore, a major component of NZB-SF(s) in the spleen cell supernatant may be an apparently novel 60-kDa glycoprotein with a single amino acid backbone. Sera and spleen cell supernatants from normal strains of mice (DBA/2, B6, or BALB/c) were also applied to the immuno-affinity column used to purify NZB-SF. It was found that trace amounts of NZB-SF are present also in serum of normal strains of mice and that spleen cells of these mice can also produce NZB-SF in vitro following stimulation with C. parvum. In SDS-PAGE, the 60-kDa NZB-SF is also the major component of NZB-SF in normal strains of mice. These results suggest that the 60-kDa NZB-SF may be of physiological importance in B cell differentiation and that this physiological factor is autoimmune-prone NZB mice.     

Age-dependent changes in B lymphocyte lineage cell populations of autoimmune-prone BXSB mice

BXSB mice, a recently developed autoimmune strain, develop a human lupus-like disease with B cell hyperplasia in peripheral lymphoid organs. Unlike other experimental models of autoimmunity and human lupus, BXSB male mice manifest accelerated autoimmune phenomena through the influence of a Y chromosome-linked enhancing factor. The present studies were performed to investigate the features of B lymphopoiesis in BXSB mice and to determine whether differences exist between BXSB males and females in this respect. B lineage cell populations in the marrow of BXSB mice were identified phenotypically by studying the cytoplasmic mu-heavy chains of IgM (c mu), and functionally by their ability to acquire clonability and sIg in short-term liquid cultures. Male BXSB mice became deficient in both the precursors of functional B cells and c mu + pre-B cells by the age of 8 to 12 wk. This followed a transient increase in this population, which peaked when the mice were 2 to 4 wk old. In females, substantial numbers of functional B cell precursors and c mu + cells were maintained until more than 4 mo of age. Cells lacking Ig but bearing a B lineage cell antigen (14.8) were elevated in numbers in both BXSB males and females until 16 wk of age when compared to normal strains of mice. At the time pre-B cells and functional B precursors were elevated in numbers, some sIg- cells were shown to form colonies in mitogen-stimulated semisolid agar cultures without a period of preculture. Most of these sIg- cells seemed to bear the B lineage cell antigen (14.8). They were independent of both G-10 adherent regulatory cells and Thy-1+ cells for their colony formation. These results indicate that B lymphocyte formation may be maintained in a hyperactive state in BXSB females, whereas males become deficient in B cell precursors very early in life. This early decline might be related to the accelerated development of autoimmune disease in BXSB mice. Bone marrow transplantation studies showed that these unusual characteristics of B lymphopoiesis were reciprocally transferable with unseparated bone marrow cells between BXSB males and females. This finding indicates that sex hormones are not a critical variable in abnormal B lymphocyte formation in this strain, and that the premature deficiency of immediate B precursors in males may be regulated by a genetic factor(s) located on the Y chromosome.     

VH gene family utilization in colonies derived from B and pre-B cells detected by the RNA colony blot assay.

The immunoglobulin heavy chain variable region (VH) genes of the mouse have been categorized into families based upon sequence homology. Utilizing the RNA colony blot assay we have determined the expression of eight of these families in B cell colonies derived from either surface immunoglobulin positive (sIg+) adult spleen B cells or sIg- fetal liver pre-B cells. We demonstrate, based upon the analysis of greater than 6000 individual colonies, that VH gene usage is a characteristic of the mouse strain studied. C57BL/6 mice most frequently (45%) utilize family VHJ558, the largest VH family, whereas BALB/c mice most frequently (22%) utilize family VH7183, the most JH proximal family in BALB/c mice. Moreover, colonies derived from sIg- fetal liver derived precursors show similar patterns, suggesting that selection based on exogenous antigen is not an important parameter in determining VH gene family usage.     

IL 1-like activities present in murine amniotic fluid. A significantly larger amount of IL 1 beta-like activity is present in the amniotic fluid of autoimmune NZB mice

Rapid progress in studies of cytokines have clarified their roles in processes of lymphocyte proliferation and differentiation. However, the involvement of these molecules in lymphopoiesis during embryonic development has not yet been well documented. In this study we screened for possible existence of cytokines that influence lymphopoiesis in murine amniotic fluid (AF) obtained from non-autoimmune prone "normal" strains of mice (CBA/J, BALB/c, A/J, SWR, and C57B/6) and autoimmune-prone NZB mice. Significant colony stimulating activity-1 (CSA-1)-like activities were found in AF of all of the strains tested, but relatively low activities were present in AF of NZB mice. No interleukin 2 (IL 2) or interleukin 3 (IL 3)-like activities were detected, Weak IL 1-like activity was found in AF of most of the strains tested; however, the results of the standard thymocyte proliferation assays varied with each AF sample. This variation is probably related to the presence of nonspecific inhibitors including alpha-fetoprotein in murine AF. Therefore, pooled AF from CBA and NZB strains of mice were subjected to several purification procedures to assess the actual amount of IL 1-like activity present in murine AF. After (NH4)2SO4 precipitation and hydrophobic phenyl-Sepharose chromatography, the measurable level of IL 1-like activity could be increased significantly. With lentil-lectin affinity chromatography, IL 1-like activity was completely dissociated from CSA-like activity. Moreover, a significantly larger amount of IL 1-like activity was found in NZB AF fractions (approximately sixfold higher). Apparent pI values estimated by preparative isoelectric focusing (IEF) were 5.9, 7.2, and 7.4 in CBA AF fractions, and 6.5 and 7.3 in NZB AF fractions. The NZB AF fraction with pI of 7.3 showed significantly higher IL 1 activity than the other fractions studied. These partially purified molecules were found to be resistant to pH 2 and the reducing agent, 2-mercaptoethanol, but were inactivated by heat (56 degrees C, 1 hr) or trypsin. None of the fractions showed IL 2-like activity but some that had IL 1-like activity induced IL 2 production in a IL 1-dependent, IL 2-producing B lymphoma cell line. Apparent m.w. of these IL 1-like activities were 14,000, 14,500, 17,000, 18,000, and 21,000 in CBA AF fractions, and 15,000, 19,000, and 21,000 in NZB AF fractions according to SDS-polyacrylamide gel electrophoresis.(ABSTRACT TRUNCATED AT 400 WORDS)     

Characterization of a B cell defect in the NZB mouse manifested by an increased ratio of surface IgM to IgD.

In an effort to define the cellular basis of abnormalities in polyclonal B cell activation previously noted in NZB mice, the surface immunoglobulin (sIg) isotypes of spleen cells from NZB mice were examined. After lactoperoxidase-catalyzed radioiodination, the cell surface immunoglobulins were analyzed by sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS-PAGE). Spleen cells from 8- to 10-week-old NZB mice were found to have an increased ratio of cell surface IgM/IgD compared to cells from 11 control strains. The altered ratio of sIg isotypes was not a consequence of increased proteolytic activity present in NZB cell suspensions or of the presence of cytophilic antibody or autoantibody. Ontogenetic studies of the sIgM/sIgD (mu/delta) ration on splenocytes from NZB and BALB/c mice revealed that the former cells had higher mu/delta ratios as early as 2 weeks after birth. By 4 weeks of age the mu/delta ratios were equivalent. Between 4 weeks and 1 year of age, the mu/delta ratios on NZB splenocytes remained constant whereas those on BALB/c splenocytes decreased and reached adult levels at 6 weeks.     

Differences in antibody repertoires for (4-hydroxy-3-nitrophenyl)acetyl (NP) in splenic vs immature bone marrow precursor cells

To evaluate the contribution of environmental regulatory mechanisms in fashioning the primary B cell repertoire, we have compared the repertoire of (4-hydroxy-3-nitrophenyl)acetyl (NP)-specific primary splenic B cells with that of precursor cells present as surface immunoglobulin-negative (sIg-) cells in adult bone marrow of C.B20 (Ighb) mice. Previous analyses using a variety of antigens have led to the conclusion that the antibody repertoire expressed in the spleen is similar to that expressed in newly generated B cell precursors with respect to both repertoire diversity and the representation of various predominant clonotypes. However, in the response to NP of C.B20 precursor cells, two marked disparities have been identified between the repertoire of sIg- bone marrow cells vs splenic precursor cells. The first concerns precursor cells that give rise to lambda-bearing NP-specific antibodies with heteroclitic fine specificity. Such antibodies normally dominate the primary response of Ighb mice; however, the representation of precursor cells giving rise to lambda-bearing antibodies is disproportionately low in the sIg- bone marrow cell population of C.B20 mice. Thus, during the maturation of these cells, post-sIg receptor expression, there is an apparent increase in the proportionate representation of lambda-bearing NP-specific cells. The second disparity concerns precursor cells whose antibody products bear kappa-light chains and exhibit high affinity and homoclitic binding for the NP haptenic determinant. Such precursor cells are poorly represented in the spleen, but represent a sizeable proportion of the sIg- NP-specific precursor cell population. Thus, there seems to be a selective elimination of high affinity, kappa-homoclitic anti-NP antibody-bearing cells as they acquire their sIg receptors. The elimination of this cell population could partially account for the dominance of lambda-heteroclitic antibodies in the serum responses to NP of C.B20 mice.     

The role of IL-4 in the generation of B lymphocytes in the bone marrow

It has been indicated that IL-4 supports the maturation of pre-B cells to B lymphocytes. The present study was designed to investigate the mechanism by which IL-4 influences this maturational process. In order to determine whether IL-4 acts directly on pre-B cells, we sorted out B220+, sIg- cells from bone marrow of young adult (C3H X C57BL/6)F1 mice. These purified populations of pre-B cells (greater than 95%) were incubated with and without 4 to 200 U/ml of rIL-4, and the generation of new B lymphocytes in these cultures was followed for several days. We found that the frequency of newly generated B lymphocytes (%sIg+) was similar in control and in IL-4-containing cultures. However, the total number of B lymphocytes was significantly higher in IL-4-containing cultures. This high number of B lymphocytes was a result of an increased survival of cells in IL-4-containing cultures. The effect was IL-4 specific because anti-IL-4 antibodies completely prevented this phenomenon. We thus conclude that IL-4 does not induce the maturation of pre-B cells but may be important in the process of B lymphocytes generation by providing a signal for survival of these cells.     

Role of I-A molecules in early stages of B cell maturation.

The role of the Ia molecule in the early phase of B cell development remains controversial. In contrast to previous studies, we have detected minute amounts of Ia (I-A) molecule on early B lineage (B220+IgM-) cells from normal bone marrow, using ELISA. The presence of the I-A molecule even on pro-B cells was deduced from experiments in which a monoclonal anti-I-A antibody completely blocked the generation of pre-B cells from B progenitor (B220-) cells in stromal cell-dependent B cell culture. Inasmuch as this antibody did not inhibit the maturation of pre-B cells to IgM+ B cells in culture, the I-A molecule on early B lineage cells probably plays a role in their maturation. We also examined the role of the I-A molecule in early B cell development, using transgenic mice harboring the antisense DNA to I-A beta-chain gene. The amount of I-A molecule on splenic B cells from the young transgenic mice decreased in the presence of abundant amounts of the antisense RNA. B cell development was perturbed in spleen from the transgenic mice. Stromal cell-dependent B cell cultures from these mice clearly showed that the maturation of B lineage cells was delayed at a very early stage of development (B220- to B220+). We propose that the I-A molecule on early B lineage cells may play an essential role in their maturation.     

Phenotypic features and proliferative activity of B cell progenitors in X-linked agammaglobulinemia

In this study, we applied mAb and heterologous antisera in double marker combinations to investigate the phenotype and the proliferative activity of immature B lineage cells in XLA. Bone marrow (BM) samples from eight male adult patients with no circulating B lymphocytes were studied. The proportions and the phenotype of the earliest identifiable B cell progenitors, expressing nuclear terminal deoxynucleotidyl transferase (TdT), cytoplasmic CD22, and membrane CD19 and CD10 were identical to those observed in normal BM. In XLA these cells represented 1.2% to 22% of BM mononuclear cells; 5% to 42% and 1% to 45% of such cells weakly expressed CD20 and CD37, respectively, and invariably lacked CD13 and CD33. Cytoplasmic mu+ sIg- pre-B cells were seen in low numbers (0.1% to 0.3%) in four samples and were undetectable in the remaining four. Consequently, the ratio TdT+/c mu+ was greater than 100 in five out of eight samples studied in contrast to the less than 10 values seen in normal individuals. The proliferative activity of B lineage progenitor cells was studied by using Ki67 and anti-bromodeoxyuridine mAb. Although the proliferation of TdT+ cells in XLA was comparable with that seen in normal BM samples (24% to 59% of TdT+ were Ki67+ and 11% to 27% incorporated bromodeoxyuridine), this was dramatically reduced in the c mu+ cells (no c mu+, Ki67+ seen in three samples where pre-B cells were observed). Thus, the abnormalities of B cell differentiation in XLA are first seen at the c mu+ pre-B stage and suggest a maturation block in the transition between TdT+, c mu- pre-pre-B cells and c mu+ pre-B cells. The severity of this block may be variable, allowing the generation of a near normal number of pre-B cells in some patients, which nevertheless have a defective proliferative activity. Finally, our study further supports the concept that the effects of the "XLA gene" are confined within the B lineage by demonstrating that the proportions of T cells bearing TCR-alpha beta and TCR-gamma delta in XLA are similar to those seen in normal individuals.     

Phylogeny of lymphocyte heterogeneity: the cellular requirements for in vitro antibody responses of channel catfish leukocytes

Three functionally distinct leukocyte subpopulations were isolated from the peripheral blood of channel catfish. Surface immunoglobulin-positive (sIg+) and sIg- lymphocytes were isolated by an indirect "planning" procedure employing monoclonal antibodies specific for channel catfish Ig. A third population composed of macrophages was isolated by adherence to baby hamster kidney cell microexudate-coated surfaces. Functional features of these three cell types were established by assessing their role(s) in primary in vitro anti-hapten PFC responses to known murine thymus-dependent (TD) and thymus-independent (TI) antigens. The results indicated that anti-hapten PFC responses to a TI antigen required the presence of sIg+ lymphocytes and macrophages. In contrast, all three cell types were required for responses to TD antigens. Furthermore, the results of studies involving the depletion of antigen-reactive lymphocytes demonstrated that both hapten-specific sIg+ cells and carrier-specific sIg- cells were required for anti-hapten responses to TD antigens. These studies provide direct evidence that catfish have separable B cells (sIg+ lymphocytes), T helper cells (sIg- lymphocytes), and accessory cells (macrophages) quite similar to those seen in higher animals.     

Proteins associated with B lymphocyte hyperactivity in New Zealand black mice

New Zealand Black (NZB) mice exhibit polyclonal B cell activation and elevated immunoglobulin production, an abnormality associated with the spontaneous autoimmune disease that affects this strain. To further our understanding of this abnormality of B cell differentiation and maturation, we have employed two-dimensional polyacrylamide gel electrophoresis to analyze the proteins synthesized by lymphocytes of several strains. Two proteins were produced by lymphocytes from NZB mice but not those from normal strains. One was a 16 kd protein with a pI of 5.1, and the other was a 27.5 kd protein with a pI of 4.5. The presence of the xid gene on the NZB background suppressed production of both proteins. They were synthesized by spleen cells but not by bone marrow or lymph node cells, and production was restricted to enlarged B lymphocytes. p16 was synthesized by normal mouse strain B cells upon stimulation with LPS. The 27.5 kd protein was shown to be secreted. On the basis of partial amino acid sequence determination of proteins eluted from gels, p27.5 was identified as J chain and p16 as the C terminal fragment of mu-chain. The synthesis of two other proteins, 13 kd and 18 kd in size, was elevated in NZB spleen lymphocytes. The 18 kd protein was identified as translation initiation factor eIf-4D. The increased level of this protein may be related to the upregulation of immunoglobulin synthesis.     

Sphingomyelinase activities in cultured skin fibroblasts from patients with Niemann-Pick disease

Summary Sphingomyelinase activity in cultured skin fibroblasts from a fetus affected with infantile-type Niemann-Pick disease was 0.5% of control activity; the activities in cells from two patients with adult-type disease (Cases 2 and 3) were 5.0% and 59.0%.Sphingomyelinase activity was separated into three peaks (I–III) by isoelectric focusing. The isoelectric points were 4.5, 4.9, and 5.2 for peaks I, II, and III, respectively. The three peaks in the Case 2 cells were drastically reduced; only a very small peak could be distinguished (pI of 4.7). On the other hand, three peaks were observed in the Case 3 cells. Peak I had a pI of 4.4, peak II a pI of 4.7, and peak III a pI of 5.2. Peak I was found at near normal level, but both peaks II and III were markedly reduced.Sphingomyelinase in the peak I fraction obtained from isoelectric focusing in Case 3 cells was found to have the same Km value as that in control cells.     

B-B cell interactions in the spontaneous activation of B cells in autoimmune NZB mice.

We analyzed the mechanism of spontaneous B cell activation in lupus mice by using anticlass-II antibody in vitro. The in vitro culture of B cells from old NZB mice markedly produced Ig without any stimulation, while B cells from NZW mice did not. The addition of anticlass-II antibody (anti-Iad antibody) to the culture inhibited Ig production of NZB B cells in a concentration-dependent manner. On the other hand, the addition of anticlass-I antibody (anti-H-2Dd antibody) and anticlass-II antibody with different specificity (anti-Iak) gave no effect on the Ig production of NZB B cells. When mitomycin C-treated B cells were added to in vitro culture of responder B cells as a stimulator, Ig production of responder B cells was enhanced in a concentration-dependent manner. However, the enhancing effect of the stimulator B cells was abrogated by the pretreatment with anticlass-II antibody. The stimulator B-cell activity to NZB B cells was marked in NZB B cells, moderate in NZB/W F1 B cells, and weak in NZW B cells. Furthermore, the stimulator B-cell activity with regard to NZB B cells was marked in old female NZB B cells, moderate in old male NZB B cells, and weak in young NZB B cells. The expression of class II antigens on the surface of old female NZB B cells was significantly higher than that of old male NZB and young NZB B cells. These results suggest that in lupus mice the spontaneous B-cell activation is induced by an abnormal B-B cell interaction mediated by class II antigens.     

Comparison of response to stem cell differentiation signals between normal and autoimmune mouse strains

Normal DBA/2 and autoimmune NZB mice were studied with regard to signals eliciting differentiation and division of bone marrow stem cells. Irradiated (NZB X DBA/2)F1 mice were repopulated with various combinations of T-depleted bone marrow from NZB and DBA/2 mice. In response to the repopulation signal of irradiation, recipients of autoimmune NZB marrow initially demonstrated expansion of LY-5+ lymphoid and hemopoietic cells, particularly of the B cell lineage. The greater the proportion of NZB marrow, the higher the percentage of lymphoid cells observed 2 wk post-repopulation. B cells (ThB-positive cells) were increased in disproportionate numbers in recipients of NZB marrow, even those that had received as little as 20% NZB bone marrow cells. However, by 2 mo, the initially observed increase in lymphoid cells in recipients of NZB marrow was no longer observed. Up to 6 mo post-repopulation, cytogenetic analysis revealed that irradiated recipients were repopulated in the same proportion of DBA/2: NZB as was in the injected marrow. Endogenous colony formation assays indicated that recipients of 100% NZB, 80% NZB, and 20% NZB marrow all had greater numbers of splenic endogenous colonies than did recipients of DBA/2 marrow alone. These studies indicated that autoimmune NZB marrow repopulated irradiated mice in the proportion in which it was injected, but there was a disproportionate early increase in cells of the B lineage as well as a disproportionate increase in splenic colony formation.     

Abnormalities of B lineage cells are demonstrable in long term lymphoid bone marrow cultures of New Zealand black mice

The formation of B lymphocytes in young New Zealand Black (NZB) mice proceeds at an accelerated rate resulting in a deficiency of B lineage precursors in adult (greater than 15 wk old) animals. To study the characteristics of B lineage cells in young (4 wk) and old (6 mo) NZB mice, bone marrow from these animals was used to initiate long term lymphoid bone marrow cultures (LBMC) that permit the long term maintenance of B cells and their precursors. Age-matched cultures from BALB/c mice and NZB.xid marrow were established in parallel. Primary LBMC were readily established from these strains and showed similar patterns of growth for the 3-mo observation period. No significant differences in numbers of 14.8 positive cells were observed. However, NZB mice at both ages had a higher percentage of membrane IgM (mIgM)-expressing cells. Significant levels of supernatant IgM were found only in cultures of 6-mo NZB and BALB/c mice; levels were highest in NZB culture supernatants and were often more than 500 ng/ml; significant, although much lower, levels of IgG were likewise detected. Lymphoid cells from NZB.xid mice were unable to generate significant levels of IgM in supernatant fluids indicating the effects of the xid gene were displayed in vitro. Autoantibodies were not detected in any of the culture supernatants. Additional evidence for NZB hyperactivity in primary B lymphopoiesis was observed upon initiation of primary myeloid bone marrow cultures (MBMC) from these strains of mice and subsequently transferring them to LBMC conditions. This results in the cessation of myelopoiesis at the initiation of B lymphopoiesis. At the time of converting MBMC to LBMC, cultures of NZB and BALB/c mice morphologically resembled myeloid cultures and had neither B cell colony-forming units nor cells that expressed 14.8 or mIgM. However, following the switch, NZB mice had a 5-fold higher number of B cell colony-forming units. Further, MBMC established from NZB bone marrow cells had a reduced capacity to form colonies in the granulocyte-macrophage colony-forming unit assay. These studies indicate that defects of NZB hemopoietic cells are manifest in vitro and suggest the use of in vitro long term cultures as a valuable technique to further dissect the hematopoietic abnormalities of NZB mice and possible underlying microenvironmental defects.