Tubulitis and Epithelial Cell Alterations in Mouse Kidney Transplant Rejection Are Independent of CD103, Perforin or Granzymes A/B

One of the defining lesions of kidney allograft rejection is epithelial deterioration and invasion by inflammatory cells (tubulitis). We examined epithelial changes and their relationship to effector T cells and to CD103/E-cadherin interactions in mouse kidney allografts. Rejecting allografts showed interstitial mononuclear infiltration from day 5. Loss of epithelial mass, estimated by tubular surface area, and tubulitis were minimal through day 7 and severe by day 21. Tubules in day 21 allografts manifested severe reduction of E-cadherin and Ksp-cadherin by immunostaining with redistribution to the apical membrane, indicating loss of polarity. By flow cytometry T cells isolated from allografts were 25% CD103+. Laser capture microdissection and RT-PCR showed increased CD103 mRNA in the interstitium and tubules. However, allografts in hosts lacking CD103 developed tubulitis, cadherin loss, and epithelial deterioration similar to wild-type hosts. The loss of cadherins and epithelial mass was also independent of perforin and granzymes A and B. Thus rejection is characterized by severe tubular deterioration associated with CD103+ T cells but not mediated by CD103/cadherin interactions or granzyme-perforin cytotoxic mechanisms. We suggest that alloimmune effector T cells mediate epithelial injury by contact-independent mechanisms related to delayed type hypersensitivity, followed by invasion of the altered epithelium to produce tubulitis.     

Effects of Donor Age and Cell Senescence on Kidney Allograft Survival

The biological processes responsible for somatic cell senescence contribute to organ aging and progression of chronic diseases, and this may contribute to kidney transplant outcomes. We examined the effect of pre-existing donor aging on the performance of kidney transplants, comparing mouse kidney isografts and allografts from old versus young donors. Before transplantation, old kidneys were histologically normal, but displayed an increased expression of senescence marker p16 ^INK4a . Old allografts at day 7 showed a more rapid emergence of epithelial changes and a further increase in the expression of p16 ^INK4a . Similar but much milder changes occurred in old isografts. These changes were absent in young allografts at day 7, but emerged by day 21. The expression of p16 ^INK4a remained low in young kidney allografts at day 7, but increased with severe rejection at day 21. Isografts from young donors showed no epithelial changes and no increase in p16 ^INK4a . The measurements of the alloimmune response—infiltrate, cytology, expression of perforin, granzyme B, IFN-γ and MHC—were not increased in old allografts. Thus, old donor kidneys display abnormal parenchymal susceptibility to transplant stresses and enhanced induction of senescence marker p16 ^INK4a , but were not more immunogenic. These data are compatible with a key role of somatic cell senescence mechanisms in kidney transplant outcomes by contributing to donor aging, being accelerated by transplant stresses, and imposing limits on the capacity of the tissue to proliferate.     

Donor Fas Is Not Necessary for T‐Cell‐Mediated Rejection of Mouse Kidney Allografts

It is important to resolve whether T‐cell‐mediated rejection (TCMR) is mediated by contact‐dependent cytotoxicity or by contact‐independent inflammatory mechanisms. We recently showed that the cytotoxic molecules perforin and granzymes A and B are not required for TCMR of mouse kidney transplants. Nevertheless, TCMR could still be mediated by cytotoxicity via Fas on donor cells engaging Fas ligand on host T cells. We examined whether the diagnostic TCMR lesions would be abrogated if donor Fas was absent, particularly in hosts deficient in perforin or granzymes A and B. Kidneys from Fas‐deficient donors transplanted into major histocompatibility complex (MHC)‐ mismatched hosts developed tubulitis and diffuse interstitial infiltration indistinguishable from wild‐type (WT) allografts, even in hosts deficient in perforin and granzymes A and B. Gene expression analysis revealed similar molecular disturbances in Fas‐deficient and WT allografts at day 21 transplanted into WT, perforin and granzyme A/B‐deficient hosts, indicating epithelial injury and dedifferentiation. Thus, donor Fas is not necessary for TCMR diagnostic lesions or molecular changes, even in the absence of perforin–granzyme mechanisms. We propose that in TCMR, interstitial effector T cells mediate parenchymal injury by inflammatory mechanisms that require neither the perforin–granzyme nor the Fas–Fas ligand cytotoxic mechanisms.     

Lesions of T-Cell-Mediated Kidney Allograft Rejection in Mice Do Not Require Perforin or Granzymes A and B

Organ allograft rejection is strongly associated with the presence of alloreactive cytotoxic T cells but the role of cytotoxicity in the pathologic lesions is unclear. Previous studies showed that the principal lesions of kidney rejection - interstitial infiltration, tubulitis, and endothelial arteritis - are T-cell-dependent and antibody-independent. We studied the role of cytotoxic granule components perforin and granzymes A and B in the evolution of the T-cell-mediated lesions of mouse kidney transplant rejection. By real-time RT-PCR, allografts rejecting in wild-type hosts at days 5, 7, 21, and 42 showed massively elevated and persistent expression of perforin and granzymes A and B, but evolution of tubulitis and arteritis did not correlate with increasing granzyme or perforin expression. Allografts transplanted into hosts with disrupted genes for perforin or granzymes A and B showed no change in tubulitis, arteritis, or MHC induction. Thus the development of the histologic lesions diagnostic of T-cell-mediated kidney transplant rejection are associated with but not mediated by perforin or granzyme A or B. Together with previous graft survival studies, these results indicate that the granule-associated cytotoxic mechanisms of T cells are not the effectors of T-cell-mediated allograft rejection.     

Cold ischemia augments allogeneic-mediated injury in rat kidney allografts

BACKGROUND: Some clinical studies demonstrate that kidney grafts with prolonged cold ischemia experience early acute rejection more often than those with minimal ischemia. The mechanism, however, is putative. Therefore, the aim of this study was to unravel the impact of ischemia on the immune response in rat kidney allografts compared with that in isografts. METHODS: To induce ischemic injury, donor kidneys were preserved for 24 hours in 4 degrees C University of Wisconsin solution before transplantation. No immunosuppression was administered. The histomorphology according to the BANFF criteria for acute rejection and infiltrating cells were assessed at days 1, 2, 3, 4, 6, and 8 post-transplantation. RESULTS: In allografts, exposure of the kidney to ischemia led to a significantly earlier onset of interstitial cell infiltration and tubulitis compared with nonischemic allografts. The BANFF score of interstitial cell infiltration was 1 +/- 0 vs. 0.25 +/- 0.29 at day 3 and 2 +/- 0 vs. 1.25 +/- 0.25 at day 4. In contrast, in isografts, the effect of ischemia on the histology was not significant. From day 6, the histologic differences between ischemic and nonischemic grafts disappeared. Ischemia led to a more intense expression of P-selectin (day 1), intercellular adhesion molecule-1 (ICAM-1; day 2), and major histocompatibility complex (MHC) class II on endothelium and proximal tubular cells (day 2) in both allografts and isografts. Concurrently with the up-regulated ICAM-1 and MHC expression, significantly more CD4(+) cells and macrophages infiltrated the ischemic allografts at days 2 and 3 and the ischemic isografts at day 4. Importantly, the influx of these cells after ischemia was significantly greater in allografts than in isografts. CONCLUSIONS: Cold ischemia augments allogeneic-mediated cell infiltration in rat kidney allografts. The earlier onset of acute rejection in 24-hour cold preserved allografts may be prevented by better preservation or treatment using tailored immunosuppression.     

T Cell‐mediated Rejection of Kidney Transplants: A Personal Viewpoint

In kidney allografts, T cell mediated rejection (TCMR) is characterized by infiltration of the interstitium by T cells and macrophages, intense IFNG and TGFB effects, and epithelial deterioration. Recent experimental and clinical studies provide the basis for a provisional model for TCMR. The model proposes that the major unit of cognate recognition in TCMR is effector T cells engaging donor antigen on macrophages. This event creates the inflammatory compartment that recruits effector and effector memory CD4 and CD8 T cells, both cognate and noncognate, and macrophage precursors. Cognate T cells cross the donor microcirculation to enter the interstitium but spare the microcirculation. Local inflammation triggers dedifferentiation of the adjacent epithelium (e.g. loss of transporters and expression of embryonic genes) rather than cell death, via mechanisms that do not require known T‐cell cytotoxic mechanisms or direct contact of T cells with the epithelium. Local epithelial changes trigger a response of the entire nephron and a second wave of dedifferentiation. The dedifferentiated epithelium is unable to exclude T cells, which enter to produce tubulitis lesions. Thus TCMR is a cognate recognition‐based process that creates local inflammation and epithelial dedifferentiation, stereotyped nephron responses, and tubulitis, and if untreated causes irreversible nephron loss.     

Heterogeneity in the Evolution and Mechanisms of the Lesions of Kidney Allograft Rejection in Mice

The natural history and pathogenesis of the pathologic lesions that define rejection of kidney transplants have not been well characterized. We studied the evolution of the pathology of rejection in mouse kidney allografts, using four strain combinations across full major histocompatibility complex (MHC) plus nonMHC disparities, to permit more general conclusions. Interstitial infiltrate, MHC induction, and venulitis appeared by day 5, peaked at day 7-10, then stabilized or regressed by day 21. In contrast, tubulitis, arteritis, and glomerulitis were absent or mild at days 5 and 7, but progressed through day 21, indicating separate regulation and homeostatic control of these lesions. Edema, hemorrhage, and necrosis also increased through day 21. All lesions were T-dependent, failing to develop in T-cell-deficient hosts. Allografts into immunoglobulin-deficient hosts manifested typical infiltration, MHC induction, and tubulitis at days 7 and 21, indicating that these lesions are alloantibody-independent. However at day 21 kidneys rejecting in immunoglobulin-deficient hosts showed decreased edema, arteritis, venulitis, and necrosis. Thus the three groups of lesions are: T-cell-mediated interstitial infiltration, MHC induction, and venulitis, which develops rapidly then stabilizes; slower but progressive T-cell-mediated tubulitis and arteritis; and late antibody-mediated endothelial injury, which contributes to late edema, arteritis, and venulitis.     

Gene expression profile during acute rejection in rat-to-mouse concordant cardiac xenograft by means of DNA microarray

Using a rat-to-mouse concordant cardiac transplantation model and DNA microarrays, we studied the gene expression profiles during acute rejection. We used inbred BALB/c and C3H/He mice and Lewis rats for our study, in which heterotopic cardiac transplantations were performed. Total RNA was isolated from xenografts (Lewis to C3H), allografts (BALB/c to C3H), rat isografts (Lewis to Lewis) and mouse isografts (C3H to C3H) on day 5 following transplantation. We screened for gene expression profiles in the xenografts, allografts, and mouse isografts by means of DNA microarrays. With a murine array, we determined that many IFN-gamma inducible genes were profoundly expressed in both the allografts and xenografts relative to the isografts. Mac-1 was specifically induced in the xenografts relative to the allografts. Using a rat array, we observed that the cardionatrin and atrial natriuretic factors were most profoundly expressed in the xenografts in comparison with the rat isografts. In addition to known genes, many expressed sequence tags were induced in the xenografts. We identified a group of genes, including Mac-1 induced specifically in xenografts, as well as many new genes upregulated in xenografts.     

Islet Allograft Rejection in Rats: A Time Course Study Characterizing Adhesion Molecule Expression,MHC Expression,and Infiltrate Immunophenotypes

Wistar Furth (RT1^u) islets transplanted under the renal capsules of streptozotocin-diabetic Lewis (RT1^l) rats reject after 5–6 days of normoglycemia. Hand-picked WF islets (1500–2000) were transplanted under the kidney capsules of diabetic Lew or WF rats. Rats bearing iso- or allografts were killed on posttransplant days 2, 4, and 6. Serial frozen sections of grafts and controls were stained by immunoperoxidase for rat MAC-1, class II MHC, CD2, CD4, CD8, B-cells, VLA-4, LFA-1, L-selectin, ICAM-1, and VCAM-1. Infiltrating cells, parenchymal cells, and endothelial cells in five distinct compartments (i.e., peritoneal reflection, subcapsular perivascular space, islet grafts, graft–kidney interface, and kidney) were evaluated for expression of the various markers at each interval. Significant infiltrates arrived in three distinct waves in both iso- and allografts. First, macrophages blanketed the peritoneal capsular reflection and infiltrated by day 2. Second, the first wave of lymphocytes arrived in the edematous subcapsular soft tissue via capsular vessels by day 2 (allo > iso). Third, the second wave of lymphocytes arrived from the renal parenchyma to form a dense band at the graft–kidney interface and around grafts by days 4 and 6 (allo >>> iso); CD4+ cells vastly outnumbered CD8+ cells, with CD4+ cells being mobilized first and from interstitial vessels throughout the entire kidney. CD8+ cells emigrated only from renal interstitial vessels adjacent to the graft. Large numbers of L-selectin+, VLA-4+, and LFA-1+ cells were seen in the infiltrates with the most intensely staining cells being intravascular. B-cells composed a very small proportion of infiltrating cells in both allo- and isografts. Endothelial staining for ICAM-1 and VCAM-1 was prominent throughout. Both class II MHC and ICAM-1 expression were induced on renal tubular epithelial cells, but neither was found on islet parenchymal cells. In conclusion, this study shows that islet allograft rejection is more complex than previously realized.     

Airway Goblet Cells and Respiratory Epithelial Injury in an Animal Model of Obliterative Airways Disease (OAD)

Goblet cells are important in the maintenance of the epithelial cell population in the airway, defense against injury and storage and release of mucins, which can protect the surface epithelial layer. In our rat tracheal model of acute rejection, there is injury and loss of respiratory epithelium in allografts. This loss of epithelium is associated with obliteration of the airway lumen. In small bowel allografts, studies have shown that the loss of goblet cells is an important histologic feature of rejection. The aims of this study were: (i) to examine for the first time the close time-course of goblet cell proliferation in acute rejection; and (ii) to compare the isograft vs. allograft morphometric changes associated with epithelial damage. METHODS: Heterotopically transplanted rat tracheas (n = 45) were harvested at days 3,5,7, 10 and 12. Hematoxylin & eosin (H & E), Alcian blue and PAS staining was completed. Computerized image analysis was used to assess epithelial coverage. The mean number of PAS-positive goblet cells counted at 40x/field was determined, and 10 fields were counted per tracheal section. RESULTS There was a significant decrease in the number of goblet cells in the allografts between days 5 and 12 (p < 0.006). In the isografts, there was a gradual increase from day 3 to 10 (p < 0.05), then a sharp fall from day 10 to 12 (p < 0.03). In isografts from day 7 to 10, the goblet cell number increased, while the percentage respiratory epithelium remained the same. The percentage respiratory epithelial coverage and the number of goblet cells showed a direct correlation in the allografts (r2 = 0.57). CONCLUSIONS: Our study shows, for the first time, that goblet cell proliferation occurs in the epithelial repair phase in isografts, whereas in allografts the goblet cells are lost and do not recover.