Reconstitution of SCID mice with human lymphoid and myeloid cells after transplantation with human fetal bone marrow without the requirement for exogenous human cytokines.

Investigation of human hematopoietic maturation has been hampered by the lack of in vivo models. Although engraftment of irradiated C.B-17 scid/scid (SCID) mice with human progenitor cells occurred after infusion with human pediatric bone marrow cells, significant engraftment of the mouse bone marrow with human cells was dependent upon continuous treatment with exogenous human cytokines. Furthermore, despite cytokine treatment, only minimal peripheral engraftment of these mice with human cells was observed. In the present study, after infusion of irradiated SCID mice with pre-cultured human fetal bone marrow cells (BM-SCID-hu mice), their bone marrow became significantly engrafted with human precursor cells and their peripheral lymphoid compartment became populated with human B cells and monocytes independently of the administration of extraneous human cytokines. Examination of the bone marrow of the BM-SCID-hu mice for human cytokine mRNA gene expression demonstrated human leukemia inhibitory factor mRNA and interleukin 7 mRNA in nine of nine BM-SCID-hu mice and macrophage-colony-stimulating factor mRNA in seven of eight BM-SCID-hu mice. This was an intriguing observation because these cytokines regulate different stages of human hematopoiesis. Since engraftment occurs in the absence of exogenous cytokine treatment, the BM-SCID-hu mouse model described should provide a useful in vivo system for studying factors important in the maturation of human myeloid and lymphoid cells in the bone marrow and the behavior of the mature human cells after dissemination into the peripheral lymphoid tissue.     

Inhibition of murine natural killer cell differentiation by dehydroepiandrosterone.

Dehydroepiandrosterone (DHEA) is a naturally occurring steroid. We have previously shown that dietary DHEA (0.45% wt/wt) inhibits murine lymphopoiesis but not myelopoiesis. To assess the effect of DHEA on stages of natural killer (NK) cell differentiation, lethally irradiated mice fed DHEA or not were infused with 10(6) or 20 x 10(6) syngeneic bone marrow cells (BMC) as a source of transplantable NK cell progenitors. The differentiation of progenitor cells to lytic NK cells was assessed by the ability to clear radiolabeled YAC-1 tumor cells from the lungs. DHEA-fed recipients of 10(6) or 20 x 10(6) BMC failed to generate NK activity. Because NK progenitor cells are believed to differentiate into interleukin-2 (IL-2)-responsive precursor cells before maturation, BMC from recipient mice were cultured with IL-2 and the generation of NK cells was assessed. DHEA feeding prevented the generation of IL-2-responsive precursor cells in recipients of 10(6) BMC, but this inhibition was overcome in recipients of 20 x 10(6) BMC. To evaluate the capacity of stem cells to generate NK progenitor cells in DHEA-fed mice, the ability of marrow cells from primary recipients to generate NK activity in irradiated secondary recipients was determined. The production of NK progenitors was inhibited 20-fold. Thus, DHEA appears to inhibit the generation of NK progenitors from more primitive stem cells, the differentiation of progenitors into IL-2-responsive precursors cells and the maturation of IL-2-responsive precursor cells into mature NK cells.     

Lymphoid progenitors in normal mouse lymph nodes develop into NK cells and T cells in vitro and in vivo

We have identified a population of normal mouse LN cells, termed LN lymphoid progenitor (LNLP), resembling common lymphoid progenitor (CLP) in the bone marrow. LNLPs lack lineage markers and express CD127, low levels of CD117 (c-Kit), and Sca-1, but lack fms-related tyrosine kinase 3. They efficiently differentiate in vitro into natural killer (NK) cells and T cells, but not mature B cells. LNLPs injected into nonirradiated lymphopenic mice that have no LN develop into mostly splenic T cells with low numbers of NK cells and B cells. When injected into irradiated mice, they generate NK cells and T cells, but not B cells, in the LN. By contrast, bone marrow CLPs develop into mostly B cells with very small numbers of T and NK cells in recipients' spleen and LN. LNLPs have NK and T-cell potentials, but little B-cell potential, and they can develop into NK cells within the LN of normal mice, but their contribution to the T-cell lineage is unknown.     

Effects of bone marrow transplantation and polyinosinic-polycytidylic acid (poly I:C) on the rescue of animals from busulfan-induced NK suppression

Repeated injections of busulfan (Bu) in CAF1 mice caused a long-lasting (greater than 16 weeks) decrease in their natural killer (NK) cell activity and impaired their resistance to transplantable lymphoma. Bu-treated mice had fewer spleen cells capable of binding to NK-sensitive YAC-1 target cells and reduced lymphokine-activated killer (LAK) cell activity as compared to normal age-matched controls. In contrast, interleukin 1 (IL-1) and interleukin 2 (IL-2) production were normal. Transplantation of normal bone marrow cells into Bu-treated mice resulted in an elevation of IL-2 production as well as in complete restoration of NK activity, target cell binding, and partial restoration of LAK activity. Resistance to transplantable lymphoma was equal to that of age-matched control mice. Polyinosinic-polycytidylic acid (Poly I:C) treatment resulted in immunomodulation in both control and Bu-pretreated mice. Twenty-four hours after Poly I:C injection, control and Bu-treated mice had higher levels of NK activity than did normal age-matched control mice, but the NK activity of Poly I:C/Bu-treated mice remained significantly lower than that of Poly I:C/control mice. The super-normal levels of NK activity in control and Bu-treated mice following Poly I:C administration were attributable, in part, to endogenous LAK activity. The generation of splenic LAK cells in vitro and target binding cells, which were reduced in Bu-pretreated mice, normalized following treatment with Poly I:C. Poly I:C treatment caused an increase in both IL-1 and IL-2 production in control and Bu-pretreated mice and in the ability of the treated mice to reject transplanted lymphoma cells. These results suggest that repeated injections of Bu decrease NK and LAK activity, but do not eliminate NK and LAK precursor cells. Thus, treatment with agents that increase IL-2 and/or interferon production can activate these cells to become effective killers and counter the long-lasting immunosuppressive effects of chemotherapy.     

scid mutation in mice confers hypersensitivity to ionizing radiation and a deficiency in DNA double-strand break repair.

C.B-17 severe combined immunodeficient (scid) mice carry the scid mutation and are severely deficient in both T cell- and B cell-mediated immunity, apparently as a result of defective V(D)J joining of the immunoglobulin and T-cell receptor gene elements. In the present studies, we have defined the tissue, cellular, and molecular basis of another characteristic of these mice: their hypersensitivity to ionizing radiation. Bone marrow stem cells, intestinal crypt cells, and epithelial skin cells from scid mice are 2- to 3-fold more sensitive when irradiated in situ than are congenic BALB/c or C.B-17 controls. Two independently isolated embryo fibroblastic scid mouse cell lines display similar hypersensitivities to gamma-rays. In addition, these cell lines are sensitive to cell killing by bleomycin, which also produces DNA strand breaks, but not by the DNA crosslinking agent mitomycin C or UV irradiation. Measurement of the rejoining of gamma-ray-induced DNA double-strand breaks by pulsed-field gel electrophoresis indicates that these animals are defective in this repair system. This suggests that the gamma-ray sensitivity of the scid mouse fibroblasts could be the result of reduced repair of DNA double-strand breaks. Therefore, a common factor may participate in both the repair of DNA double-strand breaks as well as V(D)J rejoining during lymphocyte development. This murine autosomal recessive mutation should prove extremely useful in fundamental studies of radiation-induced DNA damage and repair.     

Use of scid mice to identify and quantitate lymphoid-restricted stem cells in long-term bone marrow cultures

Mice homozygous for an autosomal recessive scid (severe combined immune deficiency) mutation on chromosome 16 exhibit a defect that specifically impairs lymphoid differentiation but not myelopoiesis. Consequently such mice are deficient in both humoral and cell-mediated immune functions. Despite their defect, scid mice survive under pathogen-free conditions and are fertile. The mutation does not impair the hematopoietic microenvironment necessary for lymphoid differentiation, since these mice can be cured with grafts of normal bone marrow (BM) or cells from long-term BM cultures (LTBMC); however, reconstitution requires sublethal (400 cGy) irradiation of recipients. Engraftment with cells from LTBMC gave near-normal levels of colony-forming B cells (CFU-B) in spleen and BM of the recipients by 6 weeks postgrafting. Since LTBMC are devoid of all mature B and pre-B cells but contain stem cells that restore lymphoid function in scid mice, we used a limiting-dilution assay to characterize and enumerate the number of stem cells in LTBMC capable of restoring lymphoid function. Curing was determined by the CFU-B-cell assay, since CFU-B are not detectable in normal scid mice. The results indicate that fewer cells from LTBMC than from fresh BM are required to obtain lymphoid reconstitution. As few as 10(3) LTBMC cells can repopulate significant B- and T-cell function in scid recipients. From these results we conclude that scid mice can be used as recipients to quantify lymphoid-restricted stem cells and that there is a functional separation of lymphoid- and myeloid-restricted stem cells in LTBMC with an enrichment for lymphoid-restricted stem cells in these cultures.     

Development of B-lineage cells in the bone marrow of scid/scid mice following the introduction of functionally rearranged immunoglobulin transgenes.

Mice homozygous for the mutation scid (scid mice) are severely immunodeficient and generally lack detectable numbers of pre-B, B, and T cells. This condition is believed to result from a defect in the mechanism responsible for rearrangement of immunoglobulin and T-cell receptor genes in developing B and T lymphocytes. To test this hypothesis and evaluate whether scid affects only the process of gene recombination, we introduced functionally rearranged immunoglobulin genes into the scid mouse genome. As scid mice appear to contain early lymphoid cells committed to the B lineage (pro-B cells), we asked whether the introduction of an IgM heavy-chain gene alone (mu-transgenic scid mice) or both IgM heavy- and kappa light-chain genes (mu kappa-transgenic scid mice) would allow further differentiation of scid pro-B cells into pre-B and B cells. We found that normal numbers of pre-B cells appeared in the bone marrow of mu-transgenic scid mice and that both pre-B and B cells appeared in the bone marrow of mu kappa-transgenic scid mice. However, in the latter case, the number of pre-B and B cells was 2- to 3-fold less than in the controls (mu kappa-transgenic scid heterozygotes) and few, if any, B cells were detectable in the peripheral lymphoid tissues. The implications of these results for the above hypothesis are discussed.     

Species-specific metastasis of human tumor cells in the severe combined immunodeficiency mouse engrafted with human tissue.

We have attempted to model human metastatic disease by implanting human target organs into the immunodeficient C.B-17 scid/scid (severe combined immunodeficiency; SCID) mouse, creating SCID-hu mice. Preferential metastasis to implants of human fetal lung and human fetal bone marrow occurred after i.v. injection of human small cell lung cancer (SCLC) cells into SCID-hu mice; the homologous mouse organs were spared. Clinically more aggressive variant SCLC cells metastasized more efficiently to human fetal lung implants than did cells from classic SCLC. Metastasis of variant SCLC to human fetal bone marrow was enhanced in SCID-hu mice exposed to gamma-irradiation or to interleukin 1 alpha. These data indicate that the SCID-hu mice may provide a model in which to study species- and tissue-specific steps of the human metastatic process.     

Natural killer cell depletion by anti-asialo GM1 antiserum treatment enhances human hematopoietic stem cell engraftment in NOD/Shi-scid mice

The scid mutation was backcrossed on to the NOD/Shi mouse background, resulting in the development of NOD/Shi-scid mice, which showed lack of mature lymphocytes, macrophage dysfunction and absence of circulating complement, but were not as impaired in natural killer (NK) cell activity as NOD/LtSz-scid mice. We then examined the effect of recipient NK cell depletion by anti-asialo GM1 antiserum on the repopulation of human cord blood (CB) hematopoietic stem cells (HSC) in NOD/Shi-scid mice to clarify the role of recipient NK cells in human HSC engraftment. The anti-asialo GM1 antiserum treatment significantly enhanced the engraftment of CB CD34+ cells, but did not affect the differentiation of the engrafted HSC into each hematopoietic lineage. The NK cell depletion was effective at early stages of the engraftment, but not 3 weeks after the transplantation. The anti-asialo GM1 antiserum treatment did not improve the engraftment by human HSC in scid mice which lack mature lymphocytes, but show neither macrophage dysfunction nor a reduction in circulating complement, indicating that macrophages and/or complement also have roles in HSC graft rejection. The present study indicates that the preconditioning targeting of recipient NK cells in addition to T cell suppression and myeloablation might prevent HSC graft failure, and that NOD/Shi-scid mice treated with anti-asialo GM1 antiserum could provide a useful tool for evaluating the repopulating ability of transplantable human HSC.     

RECOGNITION OF MARROW ELEMENTS BY NATURAL KILLER CELLS: ARE NK CELLS INVOLVED IN HAEMOPOIETC REGULATION?

S ummary . NK cells from young normal mice are cytolytic in vitro for a virus-induced tumour cell line, YAC-1. Cytotoxicity is inhibited by the addition of unlabelled homologous YAC-1 cells and by regenerating bone marrow cells from the spleens of lethally irradiated, bone-marrow-grafted mice. Quiescent marrow from syngeneic and allogeneic mice produces little or no competition. This suggests that NK cells recognize, and may regulate, marrow progenitor cells.     

In vitro differentiation of embryonic stem cells into lymphocyte precursors able to generate T and B lymphocytes in vivo.

Embryonic stem cells can be induced in vitro, by coculture with the stromal line RP.0.10 and a mixture of interleukins 3, 6, and 7, to differentiate into T (Joro75+) and B (B-220+) lymphocyte progenitors and other (Thy-1+, PgP-1+, c-kit+, Joro75-, B-220-, F4/80-, Mac-1-) hemopoietic precursors. The progeny of in vitro-induced embryonic stem cells can reconstitute the lymphoid compartments of T- and B-lymphocyte-deficient scid mice and generate mature T and B lymphocytes in sublethally irradiated normal mice. Exogenous cytokines can dramatically alter the developmental fate of embryonic stem cells in culture. The in vitro system described here should facilitate the study of molecular events leading to cell-lineage commitment and to the formation of hemopoietic stem cells and their immediate lymphoid progeny.     

Human bone marrow and umbilical cord blood cells generate CD4+ and CD8+ single-positive T cells in murine fetal thymus organ culture.

Murine fetal thymus lobes isolated from both normal and scid/scid mice can be colonized by donor cells from either human bone marrow or human umbilical cord blood in vitro. Subsequent organ culture results in a transient production of a few CD4+ CD8+ (double-positive) cells and then the accumulation of CD4+ or CD8+ (single-positive) T cells. A significant number of immature T-cell intermediates (e.g., CD8low, CD3-/low cells) were present in early organ cultures, suggesting that these were progenitors of the mature CD3+/high single-positive T cells that dominated late cultures. Depletion of mature T cells from the donor-cell populations did not affect their ability to colonize thymus lobes. However, colonization depended on the presence of CD7+ progenitor T cells. Limiting dilution experiments using mature T-cell populations (human peripheral blood leukocytes, human bone marrow cells, and human umbilical cord blood cells) suggested that thymic organ culture supports the growth of progenitor T cells but does not support the growth of mature human T cells. Each of these donor populations produced single-positive populations with different CD4/CD8 ratios, suggesting that precursor cells from different sources differ qualitatively in their capacity to differentiate into T cells.     

Recognition of beta 2-microglobulin-negative (beta 2m-) T-cell blasts by natural killer cells from normal but not from beta 2m- mice: nonresponsiveness controlled by beta 2m- bone marrow in chimeric mice.

The role of major histocompatibility complex (MHC) class I expression in control of the sensitivity of normal cells to natural killer (NK) cells was studied by the use of mutant mice made deficient for expression of beta 2-microglobulin (beta 2m) through homologous recombination in embryonal stem cells. T-cell blasts from beta 2m-deficient (beta 2m -/-) mice were killed by NK cells from normal mice in vitro, while beta 2m +/- blasts were resistant. The beta 2m defect also affected the NK effector cell repertoire: NK cells from beta 2m -/- mice failed to kill beta 2m -/- blasts, while they retained the ability to kill the prototype NK cell target lymphoma YAC-1, although at reduced levels. The inability to recognize beta 2m -/- blasts could be transferred with beta 2m -/- bone marrow to irradiated beta 2m-expressing mice. In contrast, the development of CD8+ T cells (deficient in beta 2m -/- mice) was restored in such chimera. These results indicate that loss of MHC class I/beta 2m expression is sufficient to render normal cells sensitive to NK cells, and that the same defect in the hemopoietic system of a mouse renders its NK cells tolerant to beta 2m-deficient but otherwise normal cells. In the beta 2m -/- mice, NK cells may be selected or educated by other bone marrow cells to tolerate the MHC class I deficiency. Alternatively, the specificity may be controlled directly by the class I molecules on the NK cells themselves.     

In vitro and in vivo evidence for the long-term multilineage (myeloid, B, NK, and T) reconstitution capacity of ex vivo expanded human CD34(+) cord blood cells

The aim of the present report is to describe clinically relevant culture conditions that support the expansion of primitive hematopoietic progenitors/stem cells, with maintenance of their hematopoietic potential as assessed by in vitro assays and the NOD-SCID in vivo repopulating capacity.CD34(+) cord blood (CB) cells were cultured in serum-free medium containing stem cell factor, Flt3 ligand, megakaryocyte growth and development factor, and granulocyte colony-stimulating factor. After 14 days, the primitive functions of expanded and nonexpanded cells were determined in vitro using clonogenic cell (colony-forming cells, long-term culture initiating cell [LTC-IC], and extended [E]-LTC-IC) and lymphopoiesis assays (NK, B, and T) and in vivo by evaluating long-term engraftment of the bone marrow of NOD-SCID mice. The proliferative potential of these cells also was assessed by determining their telomere length and telomerase activity.Levels of expansion were up to 1,613-fold for total cells, 278-fold for colony-forming unit granulocyte-macrophage, 47-fold for LTC-IC, and 21-fold for E-LTC-IC. Lymphoid B-, NK, and T-progenitors could be detected. When the expanded populations were transplanted into NOD-SCID mice, they were able to generate myeloid progenitors and lymphoid cells for 5 months. These primitive progenitors engrafted the NOD-SCID bone marrow, which contained LTC-IC at the same frequency as that of control transplanted mice, with conservation of their clonogenic capacity. Moreover, human CD34(+)CDl9(-) cells sorted from the engrafted marrow were able to generate CD19(+) B-cells, CD56(+)CD3(-) NK cells, and CD4(+)CD8(+)alphabetaTCR(+) T-cells in specific cultures. Our expansion protocol also maintained the telomere length in CD34(+) cells, due to an 8.8-fold increase in telomerase activity over 2 weeks of culture.These experiments provide strong evidence that expanded CD34(+) CB cells retain their ability to support long-term hematopoiesis, as shown by their engraftment in the NOD-SCID model, and to undergo multilineage differentiation along all myeloid and the B-, NK, and T-lymphoid pathways. The expansion protocol described here appears to maintain the hematopoietic potential of CD34(+) CB cells, which suggests its relevance for clinical applications.     

Implantation and maintenance of functional human bone marrow in SCID-hu mice.

Human fetal bone fragments implanted in the immunodeficient C.B-17 scid/scid (SCID) mouse were shown to sustain active human hematopoiesis in vivo. Human progenitor cell activity was maintained for as long as 20 weeks after implantation and was associated with multilineage differentiation in the engrafted bone. Thus, the bone implants provided stem cells as well as the microenvironment requisite for their long-term maintenance and multilineage differentiation. Administration of human erythropoietin (Epo) stimulated human erythropoiesis in human bone implants. This animal model may facilitate direct analysis of a wide variety of physiologic and pathologic conditions of human bone marrow (BM) in vivo.     

Age-associated impairment of murine natural killer activity.

Natural cell-mediated cytotoxicity may be critical in the resistance displayed by animals and humans to tumors and various pathogenic microorganisms. Because the frequency of tumors and infections increases markedly in aging populations, we have compared the natural killer (NK) competence of lymphoid tissues (spleen, bone marrow) and of peritoneal cells of young adult and aged mice. Spontaneous NK activity was much lower, and the rate of target cell lysis was much less, in aged mice. The level of NK activity was only modestly increased in old, compared to young, mice when they were exposed to Trypanosoma musculi, an organism that provides strong stimulation of NK activity. Restricted NK activity of aged mice was not attributable to suppressor cells. The NK effector cells in old mice were characterized as being nonadherent to plastic, completely susceptible to lysis by complement plus an antiserum against specificity NK 1.2, and only slightly affected by treatment with antiserum against specificity Thy-1.2. Two indirect methods were employed to assess the relative frequency of splenic NK cells at the time of maximal stimulation by T. musculi: a cytotoxicity assay with antiserum against NK 1.2 and a binding assay involving monolayers of YAC-1 tumor target cells. Similar results were obtained in both assays, indicating that at maximal stimulation about 10% of the total spleen cells of both young and old mice were NK cells. We conclude (cautiously) that the functional efficiency of aged NK cells is impaired and that this defect may account, in part, for reduced ability of aged individuals to resist certain types of cancer and certain pathogenic microorganisms.     

In utero transfer of adult bone marrow cells into recipients with severe combined immunodeficiency disorder yields lymphoid progeny with T- and B-cell functional capabilities

To determine if in utero transplantation could restore the immune system of mice with a severe combined immunodeficiency (SCID) disorder, C57BL/6Sz-scid/scid fetuses were injected on day 14/15 of gestation with adult congenic donor bone marrow (BM) cells. Congenic BM engrafted in one of eight (13%) recipients. Reconstitution of both lymphoid and nonlymphoid lineages was observed. In vitro and in vivo T-cell function was documented. Stem cells were shown to have engrafted by secondary transfer studies. When fully allogeneic C57BL/6 (H-2b) or B10.BR (H-2k) adult. BM cells were given to C.B-17-scid/scid (H-2d) fetal recipients, 15 of 54 (28%) recipients had evidence of engraftment, with up to 76% of peripheral blood (PB) being of in utero donor BM origin on day 131 postnatally. In all mice with persistent leukocyte engraftment, T- and B-lymphoid cells were entirely of donor origin. Donor T cells were tolerant to host but not third party alloantigens as measured in vitro. In vivo, T-cell function appeared intact. Although most mice had lower levels of B-cell engraftment than T-cell engraftment, mice with > or = 10% B cells were able to produce normal levels of IgM. Despite transplantation of fully allogeneic BM cells, stem cell engraftment could be demonstrated by secondary transfer of BM cells into lethally irradiated recipients that were congenic to the original in utero donor BM source. These data indicate that adult BM cells, even those fully allogeneic with the fetal recipient, can give rise to progeny with multilineage potential, which leads to restoration of T-cell and B-cell function.     

Erythropoietin induces the expansion of c-kit+ progenitors for myeloid and erythroid cells, but not for lymphoid cells, in the bone marrow and liver

In humans, the numbers of erythrocytes and granulocytes, but not that of lymphocytes, tend to increase in parallel. To determine the mechanism, we investigated how the administration of erythropoietin induces the expansion of erythroid cells and other lineage cells in the bone marrow, liver, and other organs of mice. When mice were injected twice (days 1 and 2) with erythropoietin at a dose of 20 or 200 IU/day/ mouse, a prominent expansion of TER 19+ (erythroid cells) and Gr-1high cells (granulocytes) occurred in the liver, spleen, and bone marrow day 3 after the initial injection. On the other hand, lymphoid cells, including NK cells, extrathymic T cells, and conventional T cells, did not expand. In parallel with the expansion of erythroid cells and granulocytes, the levels of c-kit(+)Lin- cells increased in the liver and bone marrow. Despite the increase in the proportion of c-kit(+) Lin(-) cells, the generation of lymphocytes (e.g., T cells) decreased when such bone marrow cells were injected to scid mice. These results suggest that erythropoietin has the ability to induce the expansion of not only erythroid cells but also granulocytes in the liver, spleen, and bone marrow. Furthermore, c-kit+ progenitors which may commit themselves to erythroid and myeloid cells, but not to lymphoid cells, were also activated in the liver and bone marrow of mice treated with erythropoietin.     

Lyme borreliosis in genetically resistant and susceptible mice with severe combined immunodeficiency.

The evolution of Lyme borreliosis was examined in genetically resistant C.B-17 and susceptible C3H/He(C3H) mice homozygous for the severe combined immune deficiency (scid) gene, or their immunocompetent counterparts. The C.B-17, C.B-17-scid, C3H, and C3H-scid mice were inoculated intradermally with 10(4) Borrelia burgdorferi and examined on days 14, 21, 30, 45, and 60 after inoculation. Spirochetemia was detected through 30 days, but was cleared in all groups by 45 days. Kidney and brain were inconsistently culture positive, but spleen and ear punch samples were positive in most mice. Immunocompetent C.B-17 and C3H mice seroconverted with equivalent IgG titers to B. burgdorferi, while C.B-17-scid and C3H-scid mice did not seroconvert. Arthritis occurred in nearly all joints examined in all genotypes on day 14, was of equal severity among C.B-17, C.B-17-scid, and C3H mice, but was more severe in C3H-scid mice. By days 30 and 45, arthritis began to resolve in immunocompetent mice, with C3H mice having more severe disease than C.B-17 mice. Arthritis persisted in C.B-17-scid and C3H-scid mice. Carditis occurred to an equal degree in all groups on day 14, remained active in scid mice, but regressed in immunocompetent mice at later intervals. Many spirochetes were visualized with silver stain in inflamed synovial tissues of scid mice, and were present in other tissues in smaller numbers. These studies show that specific immunity is not involved in arthritogenesis or genetically determined susceptibility to arthritis, but is involved in arthritis and carditis regression.