Successful cardiac allografts in syngeneic radiation chimeras

Summary Successful cardiac allografts were accomplished across the major histocompatibility complex of rats. LEW and F344 (Ag-B ²) rats were lethally irradiated and grafted with WF (Ag-B ¹) hearts on day 0. Either on day 0 or day 2, the hosts were repopulated with syngeneic hemopoietic cells. The best results were obtained (86%) when a mixture of 3.0 × 10⁷ non-adherent syngeneic bone marrow and thymus cells were used to repopulate the recipients. In contrast, all of the WF to LEW heart grafts were rejected within 30 days if syngeneic thoracic duct and bone marrow cells were used to repopulate the host.Supported by Grant HL18186 from the National Institutes of HealthRecipient of a Research Career Development Award CA70879 from the National Institutes of Health     

Genetic identification of a locus linked to the rat MHC that codes for a membrane antigen detectable with cytotoxic lymphocytes.

Cell-mediated cytolytic (CMC) responses resulted from immunizations between rat strains purported to be identical at Ag-B, the major histocompatibility complex (MHC), but differing at other loci not linked to Ag-B. In vivo-priming followed by secondary in vitro stimulation was required to generate a measurable CMC response as determined by a 51Cr-release assay. Neither in vivo nor in vitro stimulation alone was adequate. The CMC responses generated in a strain combination considered Ag-B identical (LEW . B3:BN) were specific for a determinant controlled by a gene linked to Ag-B, which has been designated Ag-L. The CMC response appears not to be restricted to sygeneity at Ag-B. In addition, the data presented demonstrate a recombinant between Ag-B and Ag-L, and suggest that the gene has failed to transfer with the MHC during the isolation of the LEW . B3 and F-344 . B3 congenic strains.     

Genetic and immunological characterization of naturally occurring recombinant B3 rats

The B-stock population of rats was bred for homozygosity at the loci controlling coat color. In this process, theAg-B1 andAg-B3 haplotypes became fixed in Hardy-Weinberg equilibrium. Extensive immunization and absorption studies showed that the specificities in the B-stock rats homozygous for theAg-B1 haplotype were the same as those found in the inbred F344 strain (Ag-B1), and that the specificities in the rats homozygous for theAg-B3 haplotype were the same as those found in the inbred BN (Ag-B3) strain. A homozygous line derived from the rats carrying theAg-B3 haplotype (B3) has the mixed lymphocyte reactivity and antibody responsiveness to poly (Glu⁵²Lys³³Tyr¹⁵) characteristic of the inbred strains in theAg-B4 group. Thus, it represents a naturally occurring recombination between the loci controlling MLR and immune responsiveness, on the one hand, and those controlling the Ag-B antigens on the other. Antibody responsiveness segregated with theAg-B3 haplotype in crosses between the B3 homozygotes and the low responder BUF and M520 strains; hence, this recombination is a stable one. There was no linkage of antibody formation or haplotype to coat color. The finding of a strain with a naturally occurring recombination in the major histocompatibility complex between the loci controlling mixed lymphocyte reactivity and the Ag-B histocompatibility antigens provides evidence for the separateness of these loci. Since the portion of the genetically determined mechanism controlling antibody responsiveness which is linked to the MHC was that characteristic of the MLR type, it too must lie outside the region defined by the serological specificities of theAg-B haplotype.     

Polymorphism of the major histocompatibility locus in the wild Norway rat

Specific alloantisera against the eight Ag-B groups found in inbred strains of rats were capable of reacting with all wild Norway rats (Rattus norvegicus) tested. Absorption studies, antisera production, and progeny testing involving wild rats showed that the antigenic specificities detected in the wild rat population were similar, if not identical, to the Ag-B antigens present in inbred strains. Xenoantisera prepared in rabbits against rat erythrocyte antigens (Ag-C1 and/or C2) reacted with erythrocytes from each wild rat tested. Progeny testing involving these erythrocyte antigens was identical to that observed in inbred strains. The restricted genetic polymorphism of theAg-B alleles in the wild rat population suggests that the functional and evolutionary significance of the major histocompatibility complex in the rat may not depend upon a high degree of genetic variability.     

Rat interstrain antibody response and crossidiotypic specificity

Interstrain analysis of the humoral response of rats to streptococcal group A carbohydrate (SACHO) 1, employing seven inbred strains representing six histocompatibility haplotypes at the Ag-B locus, suggests that the immune response genes to SACHO are not linked to the major rat histocompatibility locus. The low-precipitin response of all seven inbred rat strains was similar to the precipitin response of F₇ Sprague-Dawley rats selectively bred for a low-precipitin response to SACHO. Although strain differences were not apparent in the magnitude of the precipitin response to SACHO, the qualitative expression of anti-SACHO antibodies with restricted heterogeneity was more frequently observed in the August strain of rats than in the six other inbred strains examined. Cross-idiotypic specificity was demonstrated for anti-SACHO antisera obtained from nine inbred rat strains. The observations on idiotypy favor the importance of germ-line genes coding for rat antibody variable region determinants in response to SACHO.In this paper, the following abbreviations are used SACHO streptococcal group A carbohydrate - Aug August 2887 - W/Fu Wistar Furth - M520 Marshall 520 - Cop Copenhagen - F344 Fisher 344 - Buf Buffalo/Cr - BN Brown Norway - GASV group A streptococcal vaccine - DEAE diethylaminoethyl-cellulose - RIA radioimmunoassay     

Cardiac allografts in mice congenic at non-H-2 histocompatibility loci

Neonatal mouse heart fragments were grafted under the ear skin of adult recipients. Cardiac allograft survival was evaluated by visual observation of pulsation, electrocardiography, and histology. Employing a series of congenic resistant strains differing from C57BL/10Sn at theH-1, H-3,H-4, H-7, H-8, H-9, H-10, H-11, andH-12 loci, the median survival times of the heart grafts to and from C57BL/10Sn were obtained. The various interallelic combinations resulted in a wide variation of graft survival. Reciprocal transplants frequently showed different survival times.H-1 ^c grafts were rejected by B10.129(5M)/nSn female mice with a median survival time of 90 days.H-1 ^b grafts were not rejected by C57BL/10Sn mice for the experiment's duration of 200 days. The weaker the histocompatibility barrier, the more variable the survival times and the smaller the ratio of rejected to total grafted heart fragments. Female recipients were observed to reject their grafts more rapidly and to reject a higher proportion than males of the same strain. Although the strength of the different non-H-2 barriers generally paralleled that determined by skin transplants, the rankings of the strongest minor barriers were not the same for both tissues.     

Recipient contributions to serial passive transfer of experimental allergic encephalomyelitis

EAE can be adoptively transferred into normal recipients by the transfer of BP-specific EAE effector cells. After cell transfer, a series of ill-defined events occur in the recipient that culminate in the development of paralysis associated with neural tissue damage. We investigated the subsequent recipient response to the adoptively transferred disease and examined the role that recipient lymphocytes play in the development of adoptively transferred EAE. Recipient involvement was assessed by the transfer of EAE through a series of normal F1 animals as recipients and at the endpoint of the experiment, determining the MHC restriction pattern of the BP-sensitive cells present. The serial transfer of EAE from BP-CFA-sensitized LEW----(LEW X F-344)F1----(LEW X P2)F1, and from BP-CFA sensitized LEW----(LEW X F344)F1----(LEW X F-344)F1, resulted in the development of BP-sensitive cells in the spleens of the secondary recipients that were able to transfer disease into normal LEW recipients. To test directly for the development of host-derived BP-sensitive cells that might arise in the F1 animal, the serial transfer of EAE from LEW----(LEW X ACI)F1----(LEW X ACI)F1 was performed. When BP-sensitive cells obtained from the secondary (LEW X ACI)F1 recipient animal were transferred into either normal LEW and ACI, or irradiated LEW and ACI animals as final recipients, transfer of disease was successful only into the LEW parental. These results suggest that the development of passive EAE is due solely to the transferred BP-sensitive cells originating from the actively immunized donor, and that no host-derived lymphocytes are recruited into the pool of EAE effector precursor cells found in the spleen of animals after the development of adoptively transferred EAE.     

Differentiation of adrenomedullary catecholamine synthesizing enzyme responses to repeated immobilization in hybrid rats

The response of adrenomedullary catecholamine synthesizing enzymes to repeated immobilization was studied in hybrid (F₁) offspring of 2 inbred rat strains (LEW and F344). Immobilization-induced increases in tyrosine hydroxylase (TH), dopamine-beta-hydroxylase (DBH) and phenylethanolamine-N-methyl-transferase (PNMT) activities in one of the parental strains (F344) previously were shown to be dependent upon intact adrenal gland innervation but independent of the pituitary gland, while responses in the other parental strain (LEW) were independent of adrenal innervation but dependent upon pituitary function. Factors determining immobilization-induced increases in adrenal enzymes of F₁ offspring were enzyme-specific. Increased PNMT activity was pituitary dependent in F₁ rats, whereas increased TH and DBH activities after immobilization were dependent upon an intact adrenal gland innervation. These results suggest that the factor(s) regulating PNMT responses are differentiable from those regulating TH and DBH responses. The results also indicate that analysis of PNMT responses to immobilization in backcross populations is feasible, and could indicate whether strain-specific response mechanisms are heritable.     

Liver tissue graft rejection in murine major histocompatibility complex mutants

Liver tissue grafts between seven H-2 mutants and their parental strains have been studied. Each of these mutants was originally identified by reciprocal mutant—parental strain skin graft rejection. However, liver grafts among mutants and parental standard strains are not uniformly rejected. Liver graft rejection also fails to correlate with mutant—parental stimulation in CML and MLC. In addition, the immune reaction pattern of female mutant animals against grafts of male liver differs from the reaction pattern found in parental standard strains. Several explanations for the differences between immune response to liver and skin grafts are proposed, including different T cell subsets involved in recognition, availability of antigenic sites to immunocompetent cells, and structural differences between mutant and parental H-2 antigens. Abbreviations used in this paper: bml, 2, 3, 4,14; dml; fm2=mutants of strains C57BL/6, B10.D2 and B10.M respectively; B6=C57BL/6     

Hybrid immune response to parental liver tissue grafts

Parental-to-F₁-hybrid liver tissue grafts in like-sex donor-recipient combinations survive indefinitely, although several F₁ recipients demonstrate an immunological response to the parental graft. Female F₁ recipients, particularly those carrying theH-2 ^b haplotype, respond vigorously to male parental liver grafts. However F₁ female responses to male parental liver tissue grafts differ substantively from the responses of parental females to syngeneic male grafts. C3H male liver grafts are rejected vigorously by F₁ females as long as the F₁ carries theH-2 ^b haplotype. These findings support previous reports of strong immunological responses to C3H H-Y antigen in female F₁ and C3H.SW animals, a response which is absent in C3H females. Female F₁ hybrids carrying theH-2 ^b haplotype do not reject grafts of B10 or B6 male liver as rapidly as do B10 or B6 parental females. This reduced F₁ response may be related to the formation of hybrid antigens and consequent alteration of the anti-H-Y response. Alternatively, cells that specifically suppress the anti-H-Y response may be present in F₁ hybrids. Factors responsible for suppression appear to be controlled by non-MHC antigens, at least in (OH x B6 or B10) F₁ hybrids.     

Application of Allogeneic Bone Marrow Cells in View of Residual Alloreactivity: Sirolimus but Not Cyclosporine Evolves Tolerogenic Properties

Background

Application of bone marrow cells (BMC) is a promising strategy for tolerance induction, but usually requires strong depletion of the host immune system. This study evaluates the ability of immunosuppressants to evolve tolerogenic properties of BMC in view of residual alloreactivity.

Methods

The rat model used a major histocompatibility complex (MHC) class II disparate bone marrow transplantation (BMT) setting (LEW.1AR1 (RT1^auu) → LEW.1AR2 (RT1^aau)). Heart grafts (LEW.1WR1 (RT1^uua)) were disparate for the complete MHC to recipients and for MHC class I to BMC donors. Limited conditioning was performed by total body irradiation of 6 Gy. Cyclosporine (CsA) or Sirolimus (Srl) were administered for 14 or 28 days. Transplantation of heart grafts (HTx) was performed at day 16 or at day 100 after BMT. Chimerism and changes in the T cell pool were detected by flow cytometry.

Results

Mixed chimeras accepted HTx indefinitely, although the composition of the regenerated T cell pool was not changed to a basically donor MHC class II haplotype. Non-chimeric animals rejected HTx spontaneously. BMC recipients, who received HTx during T cell recovery at day 16, accepted HTx only after pre-treatment with Srl, although chimerism was lost. CsA pre-treatment led to accelerated HTx rejection as did isolated application of BMC.

Conclusion

Srl evolves tolerogenic properties of allogeneic BMC to achieve indefinite acceptance of partly MHC disparate HTx despite residual alloreactivity and in particular loss of chimerism.     

TheRT1.G locus in the rat encodes a Qa/TL-like antigen

A new antigenic system in the rat homologous to theQa/TL antigen system in the mouse has been characterized. It was detected by antibodies raised in donor-recipient combinations that were matched for theRT1. A, B, D, E loci in the major histocompatibility complex (MHC): (R11×BN)F₁ anti-BN.1L(LEW), (R18×BN)F₁ anti-BN.1L, and BN.1LV1(F344) anti-BN.1L. Absorption analyses using these antisera and a variety of inbred, congenic and recombinant strains identified three alleles,RT1.G ^a ,G ^b ,G ^c , of whichG ^c is a null allele. The strain distribution of these alleles was determined, using 37 strains of rats representative of all of the prototypic haplotypes and a number of congenic and recombinant strains. The use of the congenic and recombinant strains showed that theRT1.G locus was linked to the MHC and that the most probable gene order wasA-E-G. Testcross analysis showed that the map distance betweenA andG was 1.4 cM(4/285 recombinants). The RT1.G antigen has a heavy chain ofM _r 46 000 and is present on both T and B cells.     

A histocompatibility region (H-2IC) in theIC region of theH-2 complex of the mouse

Skin graft rejection in congenic pairs of mice differing only at theH-2 complex appears to be influenced by at least 3 genes (H-2K, H-2D, H-2I); we now describe a fourth,H- 2IC: Grafts transplanted across anIC difference are sometimes rejected. TheI-C regions of three differentH-2 haplotypes (d,k,s) were studied in different combinations, and variable patterns emerged: (a)IC ^d : B10.S(7R) show delayed or no rejection of first B10.S(9R) grafts, but grafts to immunized recipients were usually rejected in 20 days; (b)IC ^k : in two combinations (A.AL A and B10.HTT B10.S[9R]) first grafts were rejected by day 30, although grafts to immunized mice showed a different pattern. In the third combination (B10.HTTB10.S[7R]) first grafts were retained but immunized mice rejected their grafts, (c)IC ^s : B10.S(9R) regularly reject B10.S(7R) first grafts, but immunized mice retain their grafts. In two other combinations first grafts were retained but grafts to immunized recipients were rejected; while in a third combination rejection did not occur at all. The background of the recipient appeared to be important in determining the variable pattern of rejection, and there is evidence for a similarity of the H-genes inIC ^s andIC ^k , and inIC ^k andIC ^p . Graft rejection occurred independently of known differences in Ia specificities, indicating thatH-2IC and the genes determining Ia specificities are probably different, although when grafts were performed in the presence of known la differences, graft rejection usually occurred.     

Amiloride does not alter NaCl avoidance in Fischer-344 rats

Fischer-344 (F-344) rats differ from other common rat strains in that they fail to show any preference for NaCl at any concentration in two- bottle preference tests. Because 100 microM amiloride partially blocks the NaCl-evoked chorda tympani (CT) response in electrophysiological studies, we tested NaCl preference (0.068-0.273 M) in F-344 rats with and without 100 microM amiloride solution as the solvent. A third group was tested with unadulterated NaCl solutions following CT transection. Amiloride had no significant effect on the NaCl preference-aversion function, whereas CT transection significantly reduced NaCl avoidance. These results suggest that the amiloride-sensitive component of the NaCl response is not necessary for F-344 rats to display avoidance of NaCl, but the entire CT input is.      

The LEW.BN(2R) strain: a recombinant in the rat MHC

Cell-mediated cytolytic (CMC) responses resulting from immunizations between rat strains considered to be RT1 (Ag-B) identical (LEW.B3:BN) are capable of detecting a membrane determinant(s) controlled by a locus linked to RT1, which has been designated Ag-L. The Ag-L gene region has been isolated in a recombinant line, tentatively designated as LEW.BN(2R), and has been assigned the RT1r5 haplotype. The data presented demonstrate that the genes responsible for MLR stimulation in the 2R strain are of LEW origin. In addition, LEW.B3 anti-BN CTL appear to recognize multiple specificities, only one of which is in the 2R strain. Some of the remaining specificities in BN may be the result of interactions between undetected genes that have been separated in the LEW.B3 and 2R strains.     

Genetic map of seven polymorphic markers comprising a single linkage group on rat Chromosome 5

Seven polymorphic markers comprising a single linkage group were assigned to rat Chromosome (Chr) 5 by linkage analysis of the progeny of an F₂ intercross of Fischer (F344/N) and Lewis (LEW/N) inbred rats. Three genes, -L-fucosidase 1 (FUCA1), mitochondrial superoxide dismutase (SOD2), and glucose transporter (GLUT1), were mapped by restriction fragment length polymorphism (RFLP) analysis. Two genes, glucose transporter (GTG3) and elastase II (ELAII), one pseudogene for tubulin (TUBAPS), and one sequence related to the 6-phosphofructo-2-kinase/fructose-2,6-bisphosphatase gene (PFKFBP1-related sequence) were mapped by simple sequence repeat (SSR) polymorphism analysis. The loci are in the following order: SOD2, GTG3/GLUT1, FUCA1, ELAII/PFKFBP1-related sequence, and TUBAPS. This linkage group covered 68.3 cM of rat Chr 5. The SSR markers were highly polymorphic in 13 inbred rat strains (SHR/N, WKY/N, MNR/N, MR/N, LOU/MN, BN/SsN, BUF/N, WBB1/N, WBB2/N, ACI/N, LER/N, F344/N, and LEW/N). These markers, located on rat Chr 5, will be useful in genetic studies of inbred rats.     

A reassessment of the systematics and a proposal for the phylogeny of some cosmopolitan Lineus species (Nemertea)

Morphological, behavioural and biochemical characters of 9 cosmopolitan, benthic species of the nemertean genus Lineus are used both to clarify their taxonomy and to discuss their phylogenetic relationships. Data analysis shows that all fissiparous species of Lineus collected in the world seas up to date can be placed in a single species, L. sanguineus, with three recognisable subspecies, L. s. sanguineus, L. s. nigricans and L. s. pseudolacteus. These taxa were originally described as separate species mainly according to their geographic origin under the names L. sanguineus (shores of European seas), L. socialis (Atlantic North American shores), L. vegetus (Pacific North American shores), L. pseudolacteus (shores of the English Channel) and L. nigricans (Mediterranean coasts of Italy and France). Examination of the character value matrix suggests a phylogenetic tree developing from two ancestral branches. The first branch includes the two related species L. ruber and L. viridis, the second branch the three species L. longissimus, L. lacteus and L. sanguineus. This approach to the taxonomic and phylogenetic relationships of Lineus nemertean species is in agreement with the intra- and interspecies histocompatibility data in nemerteans: (i) grafts transplanted from donors to recipients of the same species succeed and grafts transplanted from donors to recipients of different species fail; (ii) grafts are rejected more rapidly when the donor and recipient species diverged earlier in evolution and, a contrario, grafts are accepted better when the donor and recipient species have been more recently isolated.     

Preliminary report on the biological effects of space flight on the producing strain of a new immunosuppressant, Kanglemycin C

Kanglemycin C (K-C) is a new immunosuppressant isolated from the culture broth of Nocardia mediterranei var. kanglensis 1747-64. To improve the productivity of K-C and to study the biological effects of space flight on its producing strain, spores from five K-C producing strains (U-10, U-15, U-7, M-13, γ-33) mutated from the wild strain N. mediterranei var. kanglensis 1747-64 were carried into space by an unmanned spaceship, “Shenzhou III” (Divine Vessel III) on March 25, 2002. Comparatively, the strain U-7 was the highest K-C producing strain among the above five starting strains when cultivated in 500-ml Erlenmeyer flasks. After a 6 day and 18 h flight, the treated spores went through serial screening processes to screen for high-yield K-C mutant strains, using thin layer chromatography and high performance liquid chromatography (HPLC). The K-C yield produced by one mutant strain, designated as F-16, derived from the starting strain U-7 was increased by up to 200% when compared to that produced by the starting strain U-7 in 500-ml Erlenmeyer flasks after careful postflight HPLC analysis. Another mutant strain, designated as F-210, derived from the starting strain M-13 showed reduced productivity of K-C as well as exhibited changes in some morphological and physiological characteristics. For example, the broth color of the strain F-210 changed from yellow to purple after 96 h of culture, but that of the ground control strain M-13 remained yellow. Similarly, the mycelium morphological change from filamentous to coccoid of F-210 occurred later than that of ground control M-13. Examination of the survivability of postflight spores indicated that exposure to radiation, during the 162 h of space flight, plays a critical role in the survival rates of spores such that spores exposed to strong radiation exhibited lower survival rates than spores exposed to weak radiation.Jianqin Zhou and Chenghang Sun have contributed equally to this work.     

Antigraft responses to the H-28c antigen by B6 and B6D2F1 mice

The survival of minor H antigen-bearing skin grafts from donors congenic with C57BL/6 (B6) was compared in B6, B6D2, and AB6 hybrid recipients. In a case singled out for further study, B6 mice were found to reject HW 110 skin (H-28^c antigen) rapidly, whereas B6D2 mice rejected HW110 skin much more slowly and variably. Both major histocompatibility complex (MHC)-linked and non-MHC genes appeared to affect the survival of HW110 strain skin grafts on B6 and B6D2 recipients. Results of several experiments appear to rule out the sharing of H-28° epitopes between donors and recipients as an explanation for the relatively poor response of B6D2 mice to HW 110 skin grafts. Experiments involving bone marrow chimeras produced by the reciprocal exchange of bone marrow between irradiated B6 and B6D2 mice suggest that bone marrow-derived donor cells and non-bone-marrow-derived host cells each contribute to the immune response phenotype with respect to the H-28° antigen. An attempt was made to determine whether B6D2 mice that failed to reject HW110 strain skin grafts possessed suppressor cells specific for the H-28^c antigen. Spleen cells from poorly responsive B6D2 mice failed to suppress the rejection of HW 110 skin grafts when assayed in immunodeficient mice that were provided with cells from immune 136132 donors that were highly responsive to HW110 skin grafts.     

Map of seven polymorphic markers on rat Chromosome 14: linkage conservation with human Chromosome 4

Seven polymorphic markers identified by polymerase chain reaction (PCR) amplification, including markers for six genes—DRD1L (dopamine receptor, D1-like-2), GLUKA (glucokinase), PF4 (platelet factor 4), ALB (albumin), AFP (-fetoprotein), and BSP (bone sialoprotein)—and one anonymous locus (D14N52), were mapped to a single 67-cM linkage group with F₂ intercross progeny of F344/N and LEW/N inbred rat strains. Two of these markers, ALB and AFP, have previously been assigned to rat Chromosome (Chr) 14, allowing assignment of this entire linkage group. Five of the markers—DRD1L, PF4, ALB, AFP, and PBSP—have been physically mapped to a large region of human Chr 4 encompassing the p arm and the q arm to band q28. Homologs of two of the markers, ALB and AFP, have been mapped to Chr 5 in the mouse. Comparison of human Chr 4 with the homologous regions on Chr 14 of the rat and Chr 5 of the mouse indicated that linkage conservation with human Chr 4 extends over a greater region in the rat than in the mouse. The markers described here were found to be highly polymorphic in twelve inbred strains (F344/N, LEW/N, ACI/N, BUF/N, BN/SsN, LOU/MN, MNR/N, MR/N, SHR/N, WBB1/N, WBB2/N, and WKY/N). These polymorphic markers should be useful in genetic linkage studies of important phenotypes in rats.