Increased frequency of pre-pro B cells in the bone marrow of New Zealand Black (NZB) mice: implications for a developmental block in B cell differentiation.

Reductions in populations of both Pre-B cell (Hardy fractions D) and Pro-B cells (Hardy fractions B-C) have been described in association with murine lupus. Recent studies of B cell populations, based on evaluation of B cell differentiation markers, now allow the enumeration and enrichment of other stage specific precursor cells. In this study we report detailed analysis of the ontogeny of B cell lineage subsets in New Zealand black (NZB) and control strains of mice. Our data suggest that B cell development in NZB mice is partially arrested at the fraction A Pre-Pro B cell stage. This arrest at the Pre-Pro B cell stage is secondary to prolonged lifespan and greater resistance to spontaneous apoptosis. In addition, expression of the gene encoding the critical B cell development transcription factor BSAP is reduced in the Pre-Pro B cell stage in NZB mice. This impairment may influence subsequent B cell development to later stages, and thereby accounts for the down-regulation of the B cell receptor component Ig alpha (mb-1). Furthermore, levels of expression of the Rug2, lambda5 and Ig beta (B29) genes are also reduced in Pre-Pro B cells of NZB mice. The decreased frequency of precursor B cells in the Pre-Pro B cell population occurs at the most primitive stage of B cell differentiation.

B220- bone marrow progenitor cells from New Zealand black autoimmune mice exhibit an age-associated decline in Pre-B and B-cell generation.

New Zealand Black (NZB) autoimmune mice exhibit progressive, age-dependent reduction in bone marrow pre-B cells. To ascertain the capacity of NZB bone marrow B220- cells to generate pre-B cells in a supportive environment, B-lineage (B220+) cell-depleted and T-cell-depleted bone marrow cells from NZB mice at 1 to 3, 6, and 10 to 11 months of age were adoptively transferred into irradiated (200R) C.B17 severe combined immunodeficient (SCID) mice. Bone marrow pre-B cells (sIgM- CD43[S7]- B220+) were assessed 3 and 10 weeks posttransfer. Pre-B cells and B cells were reconstituted in SCID recipients of older NZB progenitor cells by 10 weeks posttransplant, in contrast to the very low numbers of pre-B cells present in the donor bone marrow. However, B220- bone marrow progenitor cells from greater than 10-month-old NZB donors were deficient in the reconstitution of both pre-B and B cells in SCID recipients at 3 weeks post-transfer. This reflected a slower kinetics of repopulation, because older NZB-->SCID recipients had numbers of both pre-B and B cells similar to recipients of young NZB progenitor cells by 10 weeks posttransplant. Adoptive transfer of equal mixtures of BALB/c and older NZB bone marrow B220- progenitor cells into irradiated C.B17 SCID recipients failed to demonstrate active suppression. These results suggest that, with age, NZB bone marrow has reduced numbers and/or function of early B220- B-lineage progenitors. Consistent with this hypothesis, B220- bone marrow cells from older NZB mice were deficient in progenitors capable of yielding interleukin-7 (IL-7) responsive pre-B cells in vitro on stimulation with the pre-B-cell potentiating factor, insulin-like growth factor 1 (IGF-1).

Natural autoantibodies are involved in the haemolytic anaemia of NZB mice.

NZB is a mouse strain that spontaneously develops autoimmune haemolytic anaemia at 10-12 months of age. We analysed the autoantibodies present throughout their life and compared them to natural autoantibodies found in the normal mouse. Sera and Coombs' antibodies eluted from red blood cells (RBC) were tested for their activities against RBC and a panel of antigens: actin, myoglobin, myosin, tubulin, spectrin, DNA and trinitrophenyl bovine serum albumin (TNP-BSA), F(ab')2 and Fc fragments of IgG by using enzyme immunoassays (EIA) and Western blotting analysis of RBC membrane extracts. In NZB mouse sera, activities of IgM and IgG against the whole panel, compared to those of sera from age-matched BALB/c mice, increased progressively throughout life with oscillating values in parallel with the anti-RBC activity. Two periods of autoantibody production seem to exist: the first is characterized by a fluctuating high level of IgM and stable level of IgG natural autoantibodies, and the second by a rise of IgG natural autoantibodies in parallel with IgG anti-RBC antibodies. The presence of idiotype D23 (IdD23), which is characteristic of natural polyspecific autoantibodies, was high on serum IgM and low on IgG autoantibodies throughout life. To further analyse autoantibody level oscillations, we tested IgM and IgG fractions after their separation from whole serum and observed highly enhanced autoantibody activities of both IgM and IgG. These autoreactivities markedly diminished when the separated IgM and IgG fractions were recombined, suggesting humoral control of the autoreactivity as we had already noted for IgG in normal animals. During the first period of autoantibody production, IgM and IgG antibodies eluted from RBC (Combs' antibodies) and those eluted from serum using an RBC-immunoadsorbent (circulating antibodies) reacted with all RBC membrane components, with all antigens of the panel and with F(ab')2 and Fc. Some of these reactivities were comparable to those exhibited by a monoclonal antibody recognizing bromelain-treated RBC. In the second period, both IgM and IgG Coombs' antibodies reacted more strongly with spectrin, and exhibited new specificities, for example against the band 3 polypeptide. IdD23 was abundant on Combs' IgG antibodies in the second period. Taken together, these data suggest that IgM and IgG natural autoantibodies, able to recognize not only RBC antigens but also other antigens, particularly F(ab')2 and Fc fragment of IgG, predominate in Coomb's antibody population.(ABSTRACT TRUNCATED AT 400 WORDS)

Early development in mice. VI: Additive and interactive effects of offspring genotype and maternal environments.

Ovarian transplantation (OT) and fostering (F) methods were used concomitantly to test for genotype effects and cytoplasmic, uterine and postnatal maternal effects on nine sensori-motor responses employed for measuring development in two inbred stains of mice: NZB (N) and CBA/H (H). Parental strain differences were observed for six responses: forelimb placing, hindlimb placing, visual placing, crossed extensor, vibrissae placing and bar holding. Reciprocal F1 comparison alone indicates a single H vs. N global maternal effect (visual placing), whereas the joint use of the OT and F methods shows a parental vs. F1 global maternal effect on parental pups for three responses (hindlimb placing, grasping and visual placing) and on F1 pups for two responses (forelimb placing and visual placing). Moreover, a postnatal maternal effect is reported for five responses; righting, forelimb placing, grasping, crossed extensor and visual placing. The effect of the maternal genotype via the uterine environment is observed for four responses: righting, fore- and hindlimb placing and visual placing. Genotypic effects are also demonstrated on fore-and hindlimb placing, bar holding and visual placing. These results confirm the absence of a general genetic factor and demonstrate the absence of a general environmental factor the rate of the early sensori-motor development.

[Morphogenetic characteristics of the mammary glands of autoimmune F1 mice (NZB x NZW)]. / Osobennosti morfogeneza molochnykh zhelez autoimmunnykh myshei F1 (NZB x NZW).

The morphogenesis of mammary glands was studied in the normal and autoimmune F1(NZW X NZB) mice. In the lactation cycle of the autoimmune mice the normal course of structural-functional rearrangements of parenchyma and stroma in the developing and involuting mammary glands was disturbed. A conclusion has been reached that the modification of stromal elements, first of all involved in the autoimmune disease, is the leading link in the abnormal development of mammary glands.