Influence of the maternal effect on allogenic inhibition of hematopoietic stem cells]

Bone marrow cells (0,5-10(6)) of female mice of CBA or C57BL strains were injected intravenously to lethally irradiated CBA, C57BL/6, (femaleCBA X maleC57BL/6)F1 and (femaleC57BL/6 X maleCBA)F1 mice. Spleen of recipients as assayed for colony count on the 9th day after bone marrow transplantation by the method of Till and McCullouch. Stem cells of CBA mice demonstrated failure of allogenic inhibition in (CBA X C57BL/6)F1 hybrid mice and formed the same number of colonies as in the spleen of syngenic recipients. The level of allogenic inhibition of CBA stem cells transplanted to (C57BL/6 X X CBA)F1 hybrid mice was 50%. Bone marrow cells of C57BL/6 mice formed colonies in spleen of (CBA X C57BL/6)F1 mice at least in 20 times less than in syngenic combination. In the transplantation of bone marrow from C57BL/6 mice to (C57BL/6 X CBA)F1 hybrid mice the allogenic inhibition was less pronounced (77-85%) as compared with the transfer of cells to (CBA X C57BL/6)F1 hybrid mice (95%). The sex of a recipient did not influence the number of formed colonies. The different level of allogenic inhibition of parental stem cells can not be explained by the effect of linkage with sex as the female of reciprocal hybrid mice have identical structure of sex chromosomes (X(CBA)XC57BL/6). The data obtained indicate that the maternal effect affects allogenic inhibition of stem cells in parent--F1 system. It is possible that the maternal influence may be determined by cytoplasmic factors of inheritance which affect the expressivity of recessive genes Hh, controlling the inheritance of specific haematopoietic cell antigens.     

Effect of syngenic lymphocytes on allogenic inhibition of hematopoietic stem cells of embryonic liver]

The transplantation of liver from the embryos and newborn C57BL-6 mice to the lethally irradiated hybrids (CBA X C57BL/6) F1resulted in 90% allogenic inhibition of the colony-forming activity of the donor elements. The degree of allogenic inhibition of liver cells of 19 days old embryos and newborn mice may be changed with the help of syngenic lymphocytes of adult mice or delayed transplantation of cells 72 hrs following the irradiation of recipients but these procedures proved to be ineffective with the liver cells of 13 and 16 days old embryos. A suggestion is put forward to the effect that the allogenic inhibition is based on the active reaction of recipient hybrids (CBAXXC57BL/6) F1 to the stem hemopoietic cells of C57BL/6 mice.     

Genetic control of allogenic inhibition of hematopoietic stem cells]

Adult mice of C57BL/6, CBA (CBA X C57BL/6) F1, (CBA X C57BL/6) F2, F1 X CBA and F1 X C57BL/6 strains were lethally irradiated and reconstituted with a constant dose of 3-10(5) C57BL/6 bone marrow cells. At the 9th day after the bone marrow transplantation the colony count was performed in spleen of irradiated recipients. In the spleen of F1, CBA and C57BL/6 mice were registered low (0--8, intermediate (6--18) and high (22-40) numbers of colonies respectively. The segregation ratios in F2 progeny were close to 2 (low): 1(intermediate): 1(high). The segregation ratios in backcross (F1 X CBA) were close to 1(low): 1(intermediate)numbers of colonies. Backcrosses (F1 X C57BL/6) were distributed to low and high numbers of colonies with the ratio 1:1. The number of spleen colonies of males and females was the same in all segregating progeny. The results of hybrid analysis suggest that a single pair of allelic genes is involved in genetic control of allogenic inhibition, and that the resistance (manifestation of inhibition) to C57BL/6 stem cells is conferred by the dominant allele.     

Effect of age of mouse recipients on the functional activity of transplanted hematopoietic and lymphoid cells]

When transplanting the bone marrow cells from adult C57BL mice to the lethally irradiated (CBA X C57BL) F1 hybrids of different age, the decrease of the colony forming activity of the stem haemopoietic cells was observed in the spleen of the older recipients, as compared with the 3 months old ones. The joint transplantation of the bone marrow and thymus cells resulted in both the cases in the stimulation of the growth of colonies. The number of endogenous colonies of haemopoietic cells arising in the spleen of animals following the sublethal irradiation was greater in younger hybrids. After the induction of the "transplant versus host" reaction by the lymph node or spleen cells from the CBA mice, the relative weight of spleen and regional lymph node, respectively, in the older recipients exceeded those in the younger ones.     

Elimination of allogeneic inhibition of hematopoietic stem cells by treatment of the recipient mice with cyclophosphane]

The experiments demonstrated that pretreatment of lethally irradiated recipient (CBA X C57BL/6) F1hybrid mice with cyclophosphamide (200 mg/kg of body weight) on day before the bone marrow transplantation (4 hours after the irradiation) suppressed the allogeneic inhibition of hematopoietic stem cells to 24% (while the inhibition in the untreated animals was 92.5%). It is suggested that cyclophosphamide acted on the recipient's radioresistant lymphoid cells effecting the allogeneic inhibition of stem cells.     

Effect of abrogating hybrid resistance on the survival of radiation chimeras]

A study was made of the effect of the hybrid resistance abrogation by means of the lymphoid cell administration on the survival of the lethally irradiated mice protected by the transplantation of the semiallogeneic bone marrow. Injection to the C57BLxCBA recipients of the C57BL lymphoid cells one day before the irradiation and the transplantation of the bone marrow of the same genotype (C57BL) increased the chimera survival in comparison with the untreated recipients; such pretreatment 7 days before the irradiation decreased the chimera survival. Parental spleen lymphocytes administration produced but an insignificant effect on the radioresistance both of the stem hemopoietic cells (by the endocolonisation test) and of the organism as a whole (by the 30-day survival test) of the F1 hybrid. On this basis a conclusion was drawn that the differences in the splenocyte efficacy, when they were injected at different periods before the irradiation, could not be attributed to the changes in radioresistance.     

The dynamic morphofunctional state of the adrenals in irradiated recipients following bone marrow transplantation

The influence of syngenic bone marrow transplantation in the dose of 1.10(7) cell/ml upon the adrenal gland state of lethally irradiated recipients at various stages of posttransplantation period during 3 months has been studied at 150 linear F1 (CBA x C57B) male mice. Histological and histochemical studies conducted have shown the transplantation of native and cryopreserved bone marrow of the lethally irradiated recipients to result, depending upon observation time, in undulating change in adrenal gland weight, cortex thickness and lipid content in spongiocytes, which testifies to the certain dynamics of processes, occurring in recipients' adrenal gland.     

Effects of restoring lethally irradiated mice with anti-Thy 1.2-treated bone marrow: graft-vs-host, host-vs-graft, and mitogen reactivity.

In vitro treatment of A/J mouse bone marrow with anti-Thy 1.2 serum and guinea pig complement (GPC) eliminated its ability to induce graft-vs-host (GVH) mortality in lethally irradiated C57BL/6J x A/F1 (BAF1) mice. The anti-Thy 1.2 and GPC treatment of A/J marrow significantly reduced spleen cell activation by phytohemagglutinin (PHA) but not lipopolysaccharide (LPS) stimulation in A/J mice assayed 6 weeks after lethal irradiation and reconstitution with the treated marrow. However, the anti-Thy 1.2 treatment of A/J bone marrow did not impair the ability of the lethally irradiated, reconstituted, syngeneic mice to reject C57BL/6J skin grafts. We conclude that lymphocytes in bone marrow which are susceptible to inactivation by anti-Thy 1.2 mediate allograft reactions and/or that radioresistant cells which persist in the recipient initiate rejection of allogeneic skin grafts.     

The effect of allogeneic lymphocytes on colony formation during culturing of hematopoietic precursor cells in the peritoneal cavity

The number of colonies formed in the peritoneal cavity (on the artificial underlayer made of peritoneal cells) and in the spleen of lethally irradiated recipients, (CBA X X C57BL) F1 mice, after the intraperitoneal injection of marrow cells depends on the cell donor's genotype: syngeneic cells and cells from mice of the parent strain CBA form fewer colonies in the peritoneal cavity than in the spleen, while cells from C57BL mice produce the reverse distribution of colonies between the peritoneal cavity and the spleen. Allogenic lymphocytes, when transplanted simultaneously with hematopoietic cells, suppress colony formation in the peritoneal cavity from day 2 of cultivation and eliminate the already developed foci of hematopoiesis by day 5.     

Abolishment of allogeneic inhibition of colony formation with the aid of various RNA classes]

The authors analysed the capacity of various temperature fractions of RNA isolated from the spleen of donors of the bone marrow cells (of mice C57BL/6I) and recipients--hybrids (CBA X C57BL/6I) F1 to abolish the depression of colony formation in the nonsyngenous organism. In the administration of bone marrow cells of mice of parental genotype C57BL/6I of the irradiated recipients F1 there is observed a sharp depression of the number of colony forming units in the spleen F1. This depression can be eliminated by preliminary incubation of the bone marrow cells of mice of parental genotype with a 63 degrees fraction of the recipient's RNA. Preliminary inculation of the bone marrow cells of mice of parental genotype with 85 degrees and cytoplasmic fractions of recipient's RNA led to a partial restoration of colony formation only. The 45 degrees and 55 degrees RNA fractions of the recipient's RNA produced no restoring action. None of the temperature RNA fractions of the RNA of donor bone marrow cells were capable of abolishment of the colony formation depression in the nonsyngenous organism. It is supposed that restoration of the colony forming capacity in the nonsyngenous organism was connected with the activity of matrix RNA of the 63 degrees fraction obtained from the recipient's spleen.     

Modeling of the "universal" bone marrow using monoclonal antibodies

The data on the application of monoclonal antibodies (ICO-10) and rabbit complement for working the conditions of allogeneic bone marrow transplantation are presented in the paper. The treatment with monoclonal antibodies and bone marrow complement from BALB/c mice for 2 times prevented the development of transplant versus host reaction and completely protected lethally irradiated (CBA X X C57B1/6)FI mice-recipients from death. Thymus atrophy and the absence of T-cells in the peripheral blood was observed in these mice. The erythrocytes had markers characteristic of BALB/c and (CBA X C57B1/6)FI mice. Mouse splenocytes did not respond to the cells of donors and recipients in mixed lymphocyte culture reaction.     

The competitive ability of stem cells from mice with Hertwig's anemia

Mice homozygous for the gene, an, have a macrocytic, normochromic anemia. In this report, attempts have been made to cure Hertwig's anemia (an/an) by injecting genetically normal (+/+) stem cells. The anemia of unirradiated an/an mice was alleviated but not completely cured by injection of as many as 3 X 10(7) +/+ bone marrow cells. Lethal irradiation of the an/an recipients was necessary before injections of 10(7) +/+ marrow cells were effective in normalizing the blood parameters. The inability to achieve normal blood values without first destroying the host's own stem cells suggested that the indigenous an/an cells compete effectively with injected +/+ cells. This hypothesis was tested by injecting varying numbers of stem cells from C57BL/6J-+/+ mice, together with stem cells from either WBB6F1-an/an or, as controls, from their WBB6F1-+/+ littermates, into lethally irradiated hosts. The C57BL/6J and WBB6F1 mice have electrophoretically distinguishable hemoglobins. The an/an cells are able to compete in the repopulation of the host hematopoietic tissue as shown by the presence of WBB6F1 hemoglobin in the recipients. The cells from mice with Hertwig's anemia, however, do not compete as effectively as do the same number of cells from the +/+ littermates. These results indicate that the pluripotent hematopoietic stem cells of an/an mice are reduced in number, seeding capacity, or proliferative potential.     

Effect of diiodobenzotefa on the functionally different subpopulations of T-lymphocytes]

Diiodobenzo-tepa (DIB) was given orally to CBA mice in a dose of 25 mg/kg for 3 successive days. The number of nucleus-containing cells decreased 3.9 fold in the thymus and 1.4 fold in the bone marrow. In experiments on transplantation of lymphoid cells to intact or lethally irradiated (CBA X C57BL/6J)F1 mice treated with DIB this substance did not influence the helper activity of T lymphocytes but inhibited the activity or B and T lymphocytes, inducing "graft-versus-host" and T cell-suppressor functions.     

Genetically determined resistance to foreign bone marrow transplantation in mice: characterization of the effector cells

Mice of most strains show a genetically determined ability to reject a variety of foreign marrow grafts even after lethal irradiation. The phenomenon is both host strain and donor marrow graft-dependent. To characterize the effector cell responsible for graft rejection, attempts were made to 1) determine to what morphologic subclass it belongs; 2) determine its life span; and 3) establish whether genetically different host environments influence the functioning of the effector cell. Mice of the 129/J strain (normally nonresistant), C57BL/6 strain (made non-resistant), and the homozygous mutants of C57BL/6, i.e., C57BL/6 (bg/bg), were recipients of C57BL/6 marrow or spleen cells. After lethal irradiation, hosts were given marrow or spleen cells from normal, strongly resistant C57BL/6 donors pretreated with a) 950 R whole body irradiation or b) twice daily injections for 4 days of the cell cycle toxic drug hydroxyurea followed by 950 R. In other cases, hosts were recipients of the lymphoid cell-rich fraction of marrow from irradiated C57BL/6 donors or adherent cells taken from cultures of marrow cells of unirradiated C57BL/6 donors. Three hours after receiving C57BL/6 marrow or spleen cells, irradiated hosts were given allogeneic DBA/2 marrow (always strongly rejected by C57BL/6 mice and always accepted by 129/J strain mice). Seven days later, host spleens were removed and the numbers of microscopic colonies were counted from subserial sections. The results demonstrate that 1) mice either normally or rendered nonresistant to a marrow allograft can be made to develop resistance by the administration of either whole spleen cells or marrow lymphoid cells from lethally irradiated strongly resistant donors; 2) adherent cells from cultures of marrow from strongly resistant mice are ineffective in conferring resistance; 3) the cell effective in conferring resistance has a life span greater than 4 but less than 7 days; and 4) the effector cell can function in genetically different environments of nonresistant strains.     

The effect of bone marrow transplantation on the dynamic recovery of the morphofunctional properties of the pancreas in irradiated recipients

Effect of transplantation of syngeneic bone marrow in the dose of 1 X 10(7) cell/ml on the state of pancreatic gland in lethally irradiated recipients has been studied at different stages of posttransplantation period for 3 months using 250 linear male rats G (CBA x C57B). Histological and biochemical investigation, conducted in dynamics, have shown that transplantation of native and cryopreserved bone marrow to lethally irradiated animals facilitates activation of compensatory-restoration processes manifesting themselves in mitotic division of glandular and epithelial cells, as well as optimizes exchange of carbohydrates in the irradiated organism.     

Murine cytomegalovirus infection can enhance hybrid resistance through modulation of host natural killer activity

Studies were undertaken to assess the effect of murine cytomegalovirus (MCMV) in two different models involving injection of parental cells into F1 hosts. In both of these systems, MCMV-induced enhancement of hybrid resistance was found. In the first model, parent-into-F1 graft-vs-host reaction, MCMV infection of (C57BL/6 x C3H)F1 (B6C3F1) hosts was found to prevent the GVHR normally induced by injection of B6 parental splenocytes into the F1 hosts. The second model involved injection of parental bone marrow into lethally irradiated B6C3F1 and (C57BL/6 x DBA/2)F1 (B6D2F1) hosts. These irradiated hosts are known to exhibit resistance to engraftment by parental C57BL/6 (B6) bone marrow. This resistance was found to be markedly enhanced by injection of the hosts with MCMV 3 days before irradiation and bone marrow injection. In contrast, engraftment into B6C3F1 hosts of syngeneic marrow, or bone marrow from the C3H parent, was not affected by MCMV infection. Engraftment of DBA/2 marrow into B6D2F1 hosts was reduced at lower doses of injected marrow, suggesting enhanced resistance against the minor Hh Ag Hh-DBA. To test whether the MCMV-induced enhancement of resistance was mediated by NK cells, splenic NK activity (YAC-1 killing) and frequency (NK1.1 staining) were assessed. Both parameters were found to be elevated at 3 days after MCMV infection but to return to normal levels by 9 days. B6 bone marrow engraftment was in fact found to be normal when the marrow was administered to F1 mice 9 days after MCMV infection. Furthermore, anti-asialoGM1 administration prevented MCMV-induced enhancement of resistance to marrow engraftment. Thus, the NK enhancement resulting from MCMV infection appears to play a major role in the enhanced HR observed in the marrow engraftment model. This effect may be of importance in clinical bone marrow transplantation, a situation in which patients are susceptible to viral infection.     

Status of T- and B-lymphocytes in long living CBA--F1 (CBA X C57BL/6) chimeras]

Semiallogeneic chimeras were produced by injecting 3 X 10(7) spleen cells of mice CBA (H--2k, Mlsd) to lethally irradiated mice (CBA X C57BL/6)F1. Two days later recipients were given cyclophosphamide (CP), 2 mg per mouse, to prevent death of graft versus host reaction (GVHR). For 1.5--2 months after the creation of chimerism in 23 of 26 mice under study all cells producing antibodies to SRBC were represented by donor cells of H-2 phenotype; 3 mice were partial chimeras. Spontaneous blast transformation in the cultures of chimera spleen did not exceed the control level, and in the mixed lymphocyte culture chimera cells failed to proliferate on addition of irradiated lymphocytes (CBA X C57BL/6) F1. At the same time chimera gave intensive blast transformation to the irradiated lymphocytes of the third line of mice DBA/2 (H--2d, Mlsa). Among the chimera spleen cells no killers capable of destroying target cells of donor or recipient origin were revealed. Similar results were obtained in vivo: chimera cells gave no positive local GVHR after administration to mice (CBA X C57BL/6) F1. Prolonged chimerism was accompanied by a reactivity of donor T-lymphocytes to the recipient transplantation antigens. A blocking factor was revealed in the blood serum of chimeras. The substitution of donor lymphocytes for the recipient cells begins after 3 to 5 months. At the same period donor T-cell population reconstitutes partially the responsiveness to the recipient antigens and the blocking factor disappears from chimeras blood.     

Idiopathic paraproteinemia. II. Transplantation of the paraprotein-producing clone from old to young C57BL/KaLwRij mice.

Transplantation experiments in the C57BL/KaLwRij mouse model of idiopathic paraproteinemia (IP) showed that an IP-producing clone can be further propagated in young, lethally irradiated mice and also equally as well in nonirradiated recipients by a bone marrow and/or spleen cell transfer. The latency period before the original paraprotein was detected in the sera of recipients varied in different experiments between 1 and 9 months after transplantation. With subsequent transplantations, the "take" frequency gradually decreased. Propagation of IP for three to four generations seems to be the final limit. In comparison to age-matched seems to be the final limit. In comparison to age-matched control groups, no substantial influence of the transplanted IP on the survival of the recipients was observed. In contrast, transplantation of cells from mice with a B cell lymphoma or a myeloma led to continuous propagation of the malignancy, with a high "take" frequency, progressive development of the paraproteinemia, and a shortened survival time of the recipients. These findings indicate that IP represents in its final stage in the aging C57BL mice an intrinsic cellular defect within the affected B cell clone, which is, however, different from that found in B cell malignancies.     

Evidence for a B lymphocyte defect underlying the anti-X anti-erythrocyte autoantibody response of NZB mice.

The autoimmune hemolytic anemia of NZB mice is pathogenetically mediated by a genetically prescribed anti-erythrocyte autoantibody response directed to the X erythrocyte autoantigen. The cellular locus of the immunoregulatory defect underlying the anti-X response was explored by adoptively transferring bone marrow cells (BMC) from NZB mice to lethally irradiated histocompatible recipients. Before adoptive transfer, BMC from donor mice were assayed for antigen-binding lymphocytes with receptors for the X autoantigen (X-ABL) by immunocytoadherence assays and for anti-X autoantibody-secreting cells (X-PFC) by plaque-forming cell assays. Twelve weeks after adoptive transfer, splenic lymphocytes from recipient mice were assayed for X-PFC and humoral anti-X autoantibody by Coombs' tests. Transfer of 15 to 30 x 10(6) BMC containing 6 to 12 x 10(3) X-ABL but no X-PFC from 6- to 8-week-old NZB mice to lethally irradiated BALB/c, B10.D2, C57BL/Ks, and DBA/2 mice produced X-PFC in 70% of the recipients. Development of X-PFC was not simply dependent upon available X-ABL since transfer of 15-30 x 10(6) BMC, containing comparable numbers of X-ABL, from BALB/c, B10.D2, C57BL/Ks, or DBA/2 mice to NZB or syngeneic recipients did not produce X-PFC. Transfer of BMC from NZB mice to BALB/c, B10.D2, and DBA/2 mice with weekly administrations of AKR anti-theta antiserum had no effect on the development of X-PFC; Tlymphocyte ablation was evidenced by the absence of theta+ spleen cells. These results suggest that the pathogenetic anti-X response is not genetically prescribed at the level of macrophages, humoral factors, or T cells, but rather appears to be a phenotypic expression of a primary B lymphocyte defect permitting or promoting differentiation of NZB X-ABL.     

Experimental Models for Prevention of Graft-versus-Host Reaction in Bone Marrow Transfusion

Induction and suppression of splenomegaly and cytotoxicity against C57BL/6 cells were studied in (AKR × C57BL/6) F1 hybrid adult mice after the transfer of AKR lymphoid and bone marrow cells. 1) Splenomegaly and cytotoxicity were dissociated in the developmental stages of the graft-versus-host reaction. When lymphoid and bone marrow cells of normal AKR mice were injected into F1 recipients, splenomegaly was prominent on days 5 and 7, but cytotoxicity of spleen cells was not detected. Splenomegaly became less prominent but the cytotoxicity became detectable on day 14 after the injection. 2) Cytotoxic activity of spleen cells of F1 recipients was suppressed by the treatment of AKR donors with C57BL/6 lymphoid cells in Freund's complete adjuvant. Splenomegaly, however, was substantially enhanced by such a treatment of the donors. On the other hand, induction of the cytotoxic activity was facilitated by the treatment of donors with C57BL/6 skin grafts. 3) F1 hybrid mice could be protected from the graft-versus-host reaction by the injection of AKR anti-C57BL/6 serum or pretreatment of AKR donors with sonicated cellular antigens of C57BL/6.