Wild-type Grafts Research Articles

Comparison of Ab−/−β, H2-DM−, and CIITA−/− in Second-Set Skin Allograft Rejection

Background. Responses against donor MHC antigens are the major contributor to allograft rejection. Currently, it is unclear whether both direct and indirect recognition pathways are necessary and/or sufficient for allograft rejection. Previously, we found donor MHC class II and H2-DM to have dramatic effects on cardiac allograft survival.Methods. Here, we used H2-DM− mice, which express CLIP–MHC class II complexes, and CIITA−/− mice, which lack all class II proteins, to examine the role of direct and indirect recognition on skin allograft rejection. Recipients were primed with donor cultured keratinocytes and later tested for accelerated memory response by challenge with full-thickness tail skin grafts.Results. As previously reported, Ab−/−β grafts survived longer than wild-type grafts, while H2-DM− grafts were rejected as rapidly as wild-type grafts. Skin grafts deficient for both β2m and H2-DM survived longer than grafts lacking only H2-DM, but not as long as Ab−/−β grafts. Additionally, CIITA−/− grafts survived as long as Ab−/−β grafts.Conclusions. The delayed rejection of Ab−/−β compared to H2-DM− suggests that indirect recognition of surface-expressed donor MHC class II is sufficient to mediate rapid skin allograft rejection. The equivalent survival of CIITA−/− and Ab−/−β grafts suggests that indirect presentation of donor class II molecules (Aα or Eβ) present in Ab−/−β but not CIITA−/− mice does not contribute to graft rejection. These results reveal a modest role for surface-expressed donor class II in primed keratinocyte rejection, but also reveal a dramatic contrast to the cardiac allograft system and indicate tissue/organ-specific mechanisms of rejection.

Dramatic remodeling of advanced atherosclerotic plaques of the apolipoprotein E–deficient mouse in a novel transplantation model

Objective: Regression of atherosclerotic lesions is an important goal. No extensive experimental evidence shows that it can be achieved for advanced lesions. To study this, we developed a model to maintain a long-term change in the plasma lipoprotein environment of advanced arterial lesions of hyperlipidemic (apolipoprotein E [apoE]–deficient) mice. Methods: The apoE-deficient mice (plasma total cholesterol of 1334 ± 219 [± SEM] mg/dL) on a typical Western diet for 38 weeks had advanced atherosclerotic lesions (ie, beyond the macrophage foam cell stage) throughout the arterial tree. Lesion-containing thoracic aortas were transplanted (replacing a segment of abdominal aorta) into either apoE-deficient or wild-type (WT) (total cholesterol of 86 ± 10 mg/dL) recipients. Grafts were harvested after 9 weeks. Results: Compared with pretransplant lesions (area = 0.0892 ± 0.0179 mm2), lesion size tended to increase in apoE-deficient to apoE-deficient grafts (0.2411 ± 0.0636 mm2; P =.06), whereas a significant reduction was seen in apoE–deficient to WT grafts (0.0214 ± 0.0049 mm2; P <.001). Also, foam cells were absent in apoE-deficient to WT grafts, but abundant in pretransplant lesions and apoE-deficient to apoE-deficient grafts. Grafts were evaluated noninvasively in vivo with magnetic resonance imaging, and wall thickening was detected in the apoE-deficient to apoE-deficient group. Conclusions: Nearly complete regression of advanced atherosclerotic lesions can be achieved with sustained normalization of the plasma lipoprotein profile. Syngeneic arterial transplantation in mice is a novel and valuable model system for atherosclerosis research; and magnetic resonance imaging can detect differences in characteristics in lesions undergoing regression. (J Vasc Surg 2001;34:541-7)

Rejection of mouse cardiac allografts by costimulation in trans.

The activation of T cells by B7 costimulation in trans has been demonstrated in vitro, but the in vivo relevance is unknown. To study costimulation in trans of CD4(+) T cells in vivo, we performed cardiac transplants from B7-1/B7-2-deficient mice to recipients that do not express MHC class II molecules on peripheral APCs, but do have functional CD4(+) T cells (II(-)/4(+) mice). This model restricts the B7-dependent activation of CD4(+) T cells to costimulation in trans and excludes any contribution from indirect Ag presentation. We find that II(-)/4(+) recipients reject B7-deficient grafts as rapidly as wild-type grafts, suggesting that costimulation in trans can mediate rejection as potently as costimulation in cis. Treatment of II(-)/4(+) recipients of B7-deficient grafts with depleting Abs to CD4 or CD8 demonstrates that indirect Ag presentation to CD8(+) cells does not significantly contribute to rejection. This is the first demonstration that costimulation in trans can mediate an immune response in vivo and has important therapeutic implications.

Human membrane cofactor protein (MCP, CD 46) protects transgenic pig hearts from hyperacute rejection in primates.

Recently, we and others have shown the prolongation of xenograft survival with the use of transgenic pigs bearing human CD 59 and DAF complement regulatory proteins (CRP). We now report heart transplantation using a new line of transgenic pigs bearing a different human CRP, membrane cofactor protein (MCP, CD 46). We transplanted three MCP transgenic and three wild-type porcine hearts into baboons suppressed with cyclosporine, methylprednisone, and rapamycin or cyclophosphamide. In addition, recipients were treated with extracorporeal plasma perfusion to remove alpha-Gal reactivity. The wild-type grafts were rapidly rejected at 60 to 80 min. Two functioning MCP hearts were removed after 5 and 46 h for histological examination. One MCP heart showed vigorous function until postoperative day 16. Immunohistochemistry of both wild-type and MCP-transgenic hearts showed strong deposition of IgM. In contrast, there was less MAC deposition in the transgenic graft as compared to the wild-type control. MCP is another CRP capable of decreasing the features of hyperacute rejection of cardiac xenografts in baboon recipients.

FULMINANT HEPATITIS BY Fas-LIGAND EXPRESSION IN MRL-lpr/lpr MICE GRAFTED WITH Fas-POSITIVE LIVERS AND WILD-TYPE MICE WITH Fas-MUTANT LIVERS1

Fulminant hepatitis in mice could be induced by gene-transfection of Fas ligand (FasL). However, the mechanisms of this event still remain controversial as to whether it is mediated by direct Fas/FasL interaction and/or neutrophil migration. To investigate the role of exogenous FasL-expression, we established a simple but clear mouse model on which we performed liver transplantation between Fas-mutant mice (MRL-lpr/lpr) and wild-type mice (MRL+/+). The controls were nontransplanted wild-type (group 1) and MRL-lpr/lpr (group 2) mice. We obtained recipients with a Fas defect only in the liver (group 3; MRL-lpr/lpr liver graft in wild-type mice) and Fas-defected recipients with Fas-positive livers (group 4; wild-type graft in MRL-lpr/lpr). We successfully expressed FasL in the liver by cotransfection of two types of adenoviral vectors, AxCALNFasL and AxCANCre, with a Cre-loxP switching system. FasL-expression in the livers in groups 3 and 4 resulted in animal death due to fulminant hepatitis within 48 hr after administration of the vectors. We obtained similar findings in group 1, whereas the mice in group 2 survived without any evidence of hepatitis. Immune staining revealed a marked infiltration of CD11b-positive cells in group 1 and group 3. Despite the number of apoptotic cells, a few infiltration of CD11b-positive cells were seen in group 4. We observed no remarkable findings in the FasL-expressed livers in group 2. The results indicated that exogenous FasL-expression induces hepatocyte apoptosis both by direct interaction with Fas and by recruiting Fas-positive inflammatory cells. These findings are important for generating a new strategy to prevent hepatitis as well as for understanding the role of the Fas/FasL interaction in the pathophysiology of hepatitis.

H2-DMalpha(-/-) mice show the importance of major histocompatibility complex-bound peptide in cardiac allograft rejection.

The role played by antigenic peptides bound to major histocompatibility complex (MHC) molecules is evaluated with H2-DMalpha(-/)- mice. These mice have predominantly class II-associated invariant chain peptide (CLIP)-, not antigenic peptide-bound, MHC class II. H2-DMalpha(-/)- donor heart grafts survived three times longer than wild-type grafts and slightly longer than I-A(beta)(b)-(/)- grafts. Proliferative T cell response was absent, and cytolytic response was reduced against the H2-DMalpha(-/)- grafts in vivo. Residual cytolytic T cell and antibody responses against intact MHC class I lead to eventual rejection. Removal of both H2-DMalpha and beta2-microglobulin (beta2m) in cardiac grafts lead to greater (8-10 times) graft survival, whereas removal of beta2m alone did not have any effect. These results demonstrate the significance of peptide rather than just allogeneic MHC, in eliciting graft rejection.

Prolonged survival of heart allografts from p53-deficient mice.

Acute rejection of the heart allograft is the major cause of heart failure in the first month after transplantation. Most studies on the prevention of acute rejection have concentrated on immune suppression of the recipients, whereas little is known about the effects of genetically manipulated donor organs on heart allograft survival. Herein, we describe a mouse model of heart allografts donated by p53-/- mice that can prolong the survival time of the grafts. Hearts of p53-/- or p53+/+ C57BL/6J mice were grafted to the neck carotid artery and jugular vein of BALB/c mice using a cuff technique. The graft survival was observed daily. The hearts were analyzed using several techniques, including histology, immunofluorescence, terminal deoxynucleotidyl transferase-mediated dUTP-biotin nick end labeling (TUNEL), and Western blot analysis. p53+/+ allografts ceased beating at 7.6+/-0.5 days, whereas p53-/- hearts were beating at 10.5+/-1.1 days after transplantation (P<0.01). Mean histological rejection scores were significantly lower in allografts donated by p53-deficient mice. Furthermore, apoptotic cells, determined by TUNEL and a reagent kit for detection of cardiac apoptosis, were of high numbers in the allograft sections from wild-type hearts but rare in p53-/- allografts (4.2+/-1.3 vs. 0.7+/-0.5/250x field). Immunofluorescence staining and Western blot analysis revealed that high levels of p53 and proapoptotic protein Bax were expressed in wild-type grafts but not p53-/- allografts. Interestingly, Bcl-2, an antiapoptotic protein, was abundant in cardiac allografts from p53-/- mice and almost undetectable in grafts from wild-type mice. Thus, p53 is involved in cardiac apoptosis induced by alloimmune reaction, and prolonged survival of heart allografts can be achieved when p53 is lacking.

Modulation of Nucleotide Triphosphate Diphosphohydrolase-1 (NTPDase-1)/cd39 in Xenograft Rejection

There is increasing evidence showing that extracellular nucleosides [corrected] may be important mediators of vascular inflammation. Nucleoside [corrected] triphosphate diphosphohydrolase-1 (NTPDase-1, identical to CD39), the major vascular endothelial ectonucleotidase, is responsible for the hydrolysis of both extracellular ATP and ADP in the blood plasma to AMP. Studies were therefore conducted to evaluate the role of vascular NTPDase-1/cd39 in modulating platelet activation and vascular injury in cardiac xenografts. Cardiac xenografts from both wild-type and cd39 knockout mice (C57BL/6 x 129 Svj) were transplanted into Lewis rats. Alterations in cd39 mRNA transcripts and NTPDase activity expression were evaluated in wild-type grafts in untreated rats and then following complement depletion and immunosuppression. Rejection responses were studied with both mutant and wild-type grafts in the following models: presensitization with or without complement depletion, complement depletion alone, and with chronic immunosuppression to induce long-term graft survival. NTPDase biochemical activity in wild-type xenografts rapidly decreased after transplantation but soon rebounded with graft survival. Elevated levels of cd39 mRNA with associated increases in NTPDase activity were observed in all long-term surviving wild-type grafts. Hyperacute xenograft rejection times were comparable in wild-type and mutant grafts but cd39-deficient grafts were subject to more rapid rejection and exhibited pronounced vascular injury in complement-depleted, presensitized rats. The cd39-deficient grafts in immunosuppressed recipients were subject to increased intravascular platelet sequestration and fibrin deposition; this resulted in focal myocardial infarction in long-term surviving mutant xenografts. Augmentation of NTPDase-1 activity may be an important adaptive response for graft survival. Our results suggest that NTPDase-1/cd39 influences pathways of vascular injury in cardiac xenografts.

Acute, Lethal Graft‐Versus‐Host Disease in an F1‐Hybrid Model using Grafts from Parental‐Strain, T‐Cell Receptor‐δ Gene Knockout Donors

Gammadelta T cells have been implicated in the pathogenesis of acute graft-versus-host disease (GVHD). We therefore performed experiments to determine whether mortality from GVHD is reduced in C57BL/6 x DBA/2 F1-hybrid (BDF1-hybrid) mice when parental strain, T-cell receptor-delta (TCRdelta) knockout (KO) donors are used. We compared mortality, weight loss, interferon-gamma (IFN-gamma) production and cytotoxic activity in recipients of either wild-type or TCRdelta KO grafts. In both groups there was significant weight loss and an identical level of mortality. Elevated IFN-gamma levels were present in both groups, but recipients of TCRdelta KO grafts produced twice as much as recipients of wild-type grafts. Elevated natural killer (NK) and NK-like activity was also seen in both. These results demonstrate that TCRdelta KO grafts can induce GVHD as severe as that seen in recipients of wild-type grafts, a finding that is at odds with studies demonstrating reduced mortality when gammadelta T cells are purged from donor mice. We suggest that the inconsistency may lie in the higher levels of IFN-gamma seen with TCRdelta KO grafts and that the protection afforded by the absence of gammadelta T cells in the graft is overwhelmed by the higher levels of IFN-gamma.

Murine Graft-Versus-Host Disease in an F1-Hybrid Model Using IFN-γ Gene Knockout Donors

AbstractThese experiments were performed to determine whether the absence of donor-derived IFN-γ would influence the outcome of acute graft-vs-host disease (GVHD). Graft-vs-host reactions were induced in B6D2F1 hybrids using grafts from either IFN-γ gene knockout (gko) or wild-type, C57BL/6J, parental strain donors. GVHD was equally lethal in both groups, but IFN-γ gko graft recipients developed a more protracted form of the disease. These mice developed early wasting that persisted until death. IFN-γ was present in spleen cell cultures from wild-type graft recipients, but was absent in cultures from IFN-γ gko graft recipients. Both recipient groups showed macrophage priming for LPS-induced TNF-α release. Engraftment of donor-derived CD4+ and CD8+ cells was greater in IFN-γ gko graft recipients. Pathologic changes in IFN-γ gko graft recipients were different from those typically seen in acute GVHD. The syndrome developing in IFN-γ gko recipients consisted of patchy alopecia, corneal dryness and clouding, and lymphocytic infiltration of the liver, pancreas, salivary gland, lung, and kidney. Lymphocytic infiltrates were also present in the epidermis and the epithelium of both bile and salivary gland ducts. Some of the lesions closely resembled those seen in the “sicca”/Sjogren’s-like syndrome associated with chronic GVHD; however, there was no evidence of immune complex deposition in the kidney. These results indicate that GVHD in IFN-γ gko graft recipients shares many features with acute GVHD, but both the duration of the disease and its pathologic manifestations are different. Our results suggest that IFN-γ plays a significant role in the pathogenesis of acute GVHD by increasing the rate at which mortality develops.

Uterine and vaginal organ growth requires epidermal growth factor receptor signaling from stroma.

Estrogens are crucial for growth and function of the female genital tract. Recently, we showed that induction of uterine epithelial proliferation by estradiol is a paracrine event requiring an estrogen receptor-positive stroma. Growth factors [such as EGF (epidermal growth factor) ligands] are likely paracrine mediators, which may directly or indirectly regulate epithelial proliferation in estrogen target organs via cell-cell interactions. In this report, we used mice with a null mutation in their EGF receptor (EGFR) to examine the role of EGFR signaling in growth of the uterus and vagina and in estrogen-induced uterine and vaginal epithelial proliferation. When WT and EGFR-knockout (EGFR-KO) uteri and vaginae were grown as renal capsule grafts in nude mice, growth of uterine and vaginal grafts of EGFR-KO mice was reduced, compared with their WT counterparts. Grafts of both EGFR-KO uteri and vaginae were about one third smaller (wet weight) than their corresponding WT organs, even though differentiation of both epithelium and mesenchyme were normal in both cases. Both wild-type and EGFR-KO vaginal grafts contained within their lumina alternating layers of cornified and mucified epithelial cell layers, indicating cyclic alteration of epithelial differentiation. In response to estradiol treatment, stromal cell labeling index (LI), as assessed by incorporation of 3H-thymidine, was severely depressed in EGFR-KO uterine and vaginal grafts vs. stromal cell LI in WT uterine and vaginal grafts. Unexpectedly, epithelium of both EGFR-KO and wild-type grafts responded comparably to estradiol with a marked elevation (approximately 7-fold overall) of epithelial LI in response to estradiol in uterine and vaginal epithelia. These data supported the hypothesis that overall uterine and vaginal organ growth, in response to estrogen, required EGFR signaling for DNA synthesis in the fibromuscular stroma, whereas EGFR signaling was not essential for estrogen-induced epithelial growth in the uterus and vagina.

Rejection of wild-type and genetically engineered major histocompatibility complex-deficient glial cell xenografts in the central nervous system results in bystander demyelination and Wallerian degeneration

Mixed glial cell cultures prepared from neonatal wild type and mutant male mice lacking either major histocompatibility complex class I, class II or both class I and II molecules (major histocompatibility complex class I o/oII o/o), and from syngeneic male rats were transplanted into female rat spinal cord white matter. Graft survival was monitored using DNA probes specific to the Y chromosome. Survival of major histocompatibility complex class-deficient grafts was not prolonged compared to wild-type grafts and in most cases grafts could not be detected at 28 days post-transplantation, at which time syngeneic grafts were still present. However, rejection of xenografts resulted in significant bystander damage to host tissue. In recipients of wild-type and major histocompatibility complex class I o/o xenografts the predominant pathology was demyelination. Demyelination was also observed in recipients of major histocompatibility complex class II o/o and major histocompatibility complex class I o/oII o/o xenografts, however in addition there was marked collagen deposition and meningeal cell invasion. Significantly more axons had undergone Wallerian degeneration in recipients of major histocompatibility complex class II o/o and major histocompatibility complex class I o/oII o/o xenografts than recipients of wild-type and major histocompatibility complex class I o/o xenografts. These findings were interpreted as evidence of a more destructive immune response associated with rejection of grafts lacking major histocompatibility complex class II molecules. It was proposed that the difference in the severity of bystander damage may be related to the previously demonstrated ability of xenogeneic major histocompatibility complex class II molecules to activate host T cells directly, whereas xenografts lacking major histocompatibility complex class II molecules were capable of activating host T cells only by the indirect pathway.

Transplantation of mesencephalic cell suspensions from wild-type and heterozygous weaver mice into the denervated striatum: Assessing the role of graft-derived dopaminergic dendrites in the recovery of function

The Weaver ( wv) mutation leads to a loss of mesencephalic dopamine cells and nigrostriatal dopamine axons in homozygosity ( wv/wv) and to a deficiency of nigral dopaminergic dendrites without a concomitant loss of dopamine cell somata or axons in heterozygosity ( wv/+). Previous studies have shown that grafts of foetal dopamine cells from wild-type (+/+) donors can survive when implanted into the wv/wv striatum, supply both an axonal and a dendritic innervation to the host, establish synaptic connections with host striatal neurons, and bring about a functional recovery evidenced by rotational asymmetry tests. The aims of the present study were to examine whether wv/+ dopamine cells maintain a “dendrite-poor” phenotype after transplantation to the denervated striatum, and to compare their functional effects with those of wild-type (+/+) grafts in reversing amphetamine-induced turning behaviour. To that end, +/+ and wv/+ ventral mesencephalic tissue (dissected out from E10-E12 foetal mice and made into a cell suspension by enzymatic and mechanical dissociation) was stereotactically grafted into the right striatum of either wv/wv hosts or +/+ hosts subjected in advance to 6-OHDA lesions of the right substantia nigra. Viability and morphology of grafted neurons were assessed by tyrosine hydroxylase immunocytochemistry on serial sections of the host forebrains. Dopamine cell bodies survived in comparable numbers in the grafts regardless of donor genotype; however, grafts of either genotype contained fewer dopaminergic cells when they were hosted in the wv/wv striatum as compared to the striatum of +/+ mice with 6-OHDA lesions. Despite the survival of cell somata, the dendritic arborisation of wv/+ cells was strikingly poorer than that of +/+ cells in grafts placed into both host types, most likely reflecting their in situ phenotypic abnormality. Recipient wv/wv mice with +/+ and wv/+ grafts exhibited 88% and 83% left rotations, respectively; 6-OHDA hosts with +/+ and wv/+ grafts showed 178% and 165% reversals of asymmetry, respectively. The differences between the effects of +/+ and wv/+ grafts were not statistically significant. We conclude that (i) wv/+ and +/+ dopamine cell somata survive in comparable numbers after intrastriatal grafting; (ii) grafted wv/+ dopamine cells express an anatomical phenotype consistent with that seen in the wv/+ substantia nigra in situ; and (iii) the axonal innervation supplied by wv/+ grafts to the denervated striatum induces a functional recovery comparable to that brought about by +/+ cells, which in addition supply a substantial dendritic innervation to the host; (iv) the wv/wv host environment may be associated with smaller numbers of graft dopamine neurons compared to the environment of +/+ mouse hosts with 6-OHDA lesions.

Transplantation of mesencephalic cell suspensions from wild-type and heterozygous Weaver mice into the denervated striatum: assessing the role of graft-derived dopaminergic dendrites in the recovery of function.

The Weaver (wv) mutation leads to a loss of mesencephalic dopamine cells and nigrostriatal dopamine axons in homozygosity (wv/wv) and to a deficiency of nigral dopaminergic dendrites without a concomitant loss of dopamine cell somata or axons in heterozygosity (wv/+). Previous studies have shown that grafts of foetal dopamine cells from wild-type (+/+) donors can survive when implanted into the wv/wv striatum, supply both an axonal and a dendritic innervation to the host, establish synaptic connections with host striatal neurons, and bring about a functional recovery evidenced by rotational asymmetry tests. The aims of the present study were to examine whether wv/+ dopamine cells maintain a "dendrite-poor" phenotype after transplantation to the denervated striatum, and to compare their functional effects with those of wild-type (+/+) grafts in reversing amphetamine-induced turning behaviour. To that end, +/+ and wv/+ ventral mesencephalic tissue (dissected out from E10-E12 foetal mice and made into a cell suspension by enzymatic and mechanical dissociation) was stereotactically grafted into the right striatum of either wv/wv hosts or +/+ hosts subjected in advance to 6-OHDA lesions of the right substantia nigra. Viability and morphology of grafted neurons were assessed by tyrosine hydroxylase immunocytochemistry on serial sections of the host forebrains. Dopamine cell bodies survived in comparable numbers in the grafts regardless of donor genotype; however, grafts of either genotype contained fewer dopaminergic cells when they were hosted in the wv/wv striatum as compared to the striatum of +/+ mice with 6-OHDA lesions. Despite the survival of cell somata, the dendritic arborisation of wv/+ cells was strikingly poorer than that of +/+ cells in grafts placed into both host types, most likely reflecting their in situ phenotypic abnormality. Recipient wv/wv mice with +/+ and wv/+ grafts exhibited 88% and 83% left rotations, respectively; 6-OHDA hosts with +/+ and wv/+ grafts showed 178% and 165% reversals of asymmetry, respectively. The differences between the effects of +/+ and wv/+ grafts were not statistically significant.(ABSTRACT TRUNCATED AT 400 WORDS)

Characterization of a wilty sunflower (Helianthus annuusL.) mutant

The present study was conducted to evaluate phenotypic interaction in reciprocal grafts between wilty (w-1) sunflower mutant and normal (W-1) plants. The w-1 genotype is a 'leaky' ABA-deficient mutant, characterized by high stomatal conductance, in both light and dark conditions, and high transpiration rate. In well-watered conditions, mutant scions grafted on to normal rootstock (w-1/W-1 showed higher leaf relative water content, leaf water potential and ABA levels than those of control grafts (w-1/w-1). In addition, detached leaves of w-1/W-1 exhibited lower water loss than w-1/w-1 grafts, while mutant rootstock did not affect the transpiration rate of detached W-1 leaves. When drought stress was imposed to potted plants by withholding water, the mutant scions grafted on to normal roots showed a partial phenotypic reversion. A rapid stomatal closure and a rise in ABA levels in response to a small decrease in leaf water potential was observed. By contrast, in w-1/w-1 grafts significant reductions in stomatal conductance and ABA accumulation were detected only in conjunction with a severe water deficit. W-1 scions on mutant stocks (W-1/w-1) maintained the normal phenotype of control wild-type grafts (W1/W-1).

Nerve transplantation shows that motor end-plate disease is not a primary Schwann cell defect

Motor end-plate diseased (MED) mice have altered nerve impulse conduction velocities and refractory periods. To test whether these pathological properties are caused by a primary Schwann cell defect, nerves were transplanted from MED and wildtype (WT) animals onto WT recipients. The donor origin of cells in the regenerated nerve was assessed by prelabeling with [ 3H]thymidine and by electrophoretic analysis of glucose phosphate isomerase allotypes. Nerve fiber regeneration through MED and WT implants was equally efficient. No difference was found in nerve conductivities of MED and WT grafts. Therefore a primary defect in the Schwann cells of the MED mouse is unlikely.