HOME HELP FEEDBACK TABLE OF CONTENTS ARCHIVE SUBSCRIPTIONS		QUICK SEARCH:   [advanced] Author: Keyword(s): Year:  Vol:  Page:

This Article Abstract Full Text (PDF) Castermans et al. Supplementary data Alert me when this article is cited Alert me if a correction is posted Services Email this article to a friend Similar articles in this journal Similar articles in ISI Web of Science Similar articles in PubMed Alert me to new issues of the journal Download to citation manager Citing Articles Citing Articles via Google Scholar Google Scholar Articles by Castermans, E. Articles by Beguin, Y. Search for Related Content PubMed PubMed Citation Articles by Castermans, E. Articles by Beguin, Y.

Evidence for neo-generation of T cells by the thymus after non-myeloablative conditioning

¹ Department of Medicine, Division of Hematology, University of Liège, Liège, Belgium;
² GIGA Research, University of Liège, Liège, Belgium; Department of Laboratory Medicine, Division of Laboratory Hematology and
³ Immuno-Hematology, University of Liège, Liège, Belgium;
⁴ Department of Genetics, University of Liège, Liège, Belgium;
⁵ Department of statistics, University of Liège, Liège, Belgium;
⁶ Center of Immunology, University of Liège, Liège, Belgium;
⁷ Department of Virology, Institut Pasteur, Paris, France

Correspondence: Frédéric Baron, MD, PhD, University of Liège, Department of Hematology, CHU Sart-Tilman, 4000 Liège. Belgium, E-mail: f.baron{at}ulg.ac.be

	ABSTRACT

TOP ABSTRACT Introduction Design and Methods Results Discussion References

 
Background: Background and objective. We investigated immune recovery in 50 patients given either unmanipulated or CD8-depleted allogeneic peripheral blood stem cells after non-myeloablative conditioning.

Design and Methods: Fifty patients were randomized to receive either CD8-depleted (n=22) or non-manipulated (n=28) peripheral blood stem cells. The median patients age was 57 (range 36–69) years. The conditioning regimen consisted of 2 Gy total body irradiation with or without added fludarabine. Twenty patients received grafts from related donors, 14 from 10/10 HLA-allele matched unrelated donors, and 16 from HLA-mismatched unrelated donors. Graft-versus-host disease pro-phylaxis consisted of mycophenolate mofetil and cyclosporine. Immune recovery during the first year after hematopoietic cell transplantation was assessed by flow cytometry phenotyping, analyses of the diversity of the TCRBV repertoire, and quantification of signal-joint T-cell receptor excision circles (sjTREC).

Results: CD8-depletion of the graft reduced the recovery of CD8⁺ T-cell counts in the first 6 months following transplantation (p<0.0001) but had no significant impact on the restoration of other T-cell subsets. Both sjTREC concentration and CD3⁺ T-cell counts increased significantly between day 100 and 365 (p=0.010 and p=0.0488, respectively) demonstrating neo-production of T cells by the thymus. Factors associated with high sjTREC concentration 1 year after transplantation included an HLA-matched unrelated donor (p=0.029), a high content of T cells in the graft (p=0.002), and the absence of chronic graft-versus-host disease (p<0.0001).

Conclusions: Our data suggest that while immune recovery is mainly driven by peripheral expansion of the graft-contained mature T cells during the first months after non-myeloablative transplantation, T-cell neo-generation by the thymus plays an important role in long term immune reconstitution in transplanted patients.

Key words: hematopoietic cell transplantation, non-myeloablative, T-cell depletion, GVHD, immunity, thymus.

	Introduction

TOP ABSTRACT Introduction Design and Methods Results Discussion References

 
Allogeneic hematopoietic cell transplantation (HCT) following non-myeloablative or reduced-intensity conditioning is being increasingly used in patients with hematologic malignancies who are too old or too sick to tolerate a myeloablative allogeneic HCT,¹ and in those who have failed an autologous or allogeneic HCT following a myeloablative regimen.² These regimens are nearly exclusively dedicated to the treatment of tumors through immune-mediated graft-versus-tumor effects.³ Graft-versus-host disease (GVHD) and infections are the most common complications leading to non-relapse mortality,^4,5 underlying the interest of analyzing immune reconstitution following low-intensity conditioning.^6–16

T-cell recovery after myeloablative allogeneic HCT depends on both peripheral expansion of mature T cells contained in the graft (thymus-independent pathway), and T-cell neo-generation from donor hematopoietic stem cells (thymus-dependent pathway).^17–19 However, adequate broadening of the T-cell repertoire is ensured primarily by the latter.²⁰ Following myeloablative allogeneic HCT, T-cell neo-generation is considered as minimal in the early months post-HCT, most circulating T cells being the progeny of T cells infused with the graft during the first 6 months following HCT.²¹ In contrast, thymic production is thought to play an important role in immune reconstitution beyond day 100 in younger patients able to tolerate myeloablative conditioning, as demonstrated by the quantification of signal joint T-cell receptor excision circles (sjTREC).^20,22–25 However, following myeloablative HCT, naive T-cell counts remain low for prolonged periods, as a consequence of the reduced survival capacity of these cells.²⁶

Previous studies analyzing immune recovery in (younger) myeloablative recipients compared with (older) non-myeloablative recipients have suggested that, early after HCT, patients undergoing non-myeloablative conditioning had higher naive T-cell counts than those given a myeloablative regimen.⁹ This was attributed to the persistence of host-derived naive T cells after non-myeloablative conditioning.^9,27 However, 1 year after HCT, naive T-cell counts were lower in non-myeloablative than in myeloablative recipients, suggesting that neo-generation of T cells might be low in older recipients given non-myeloablative conditioning.⁹ This could be due to age-related thymic atrophy.²⁸ Indeed, after autologous HCT a significant thymic rebound has been demonstrated in approximately 80% of patients younger than 40 years old, in 50% of those 40 to 50 years old, but in less than 15% of patients 50 years old.²⁹ These observations raise the question of whether successful immune recovery through the thymic pathway can occur in older patients given non-myeloablative conditioning, or whether immune recovery in these patients can only occur through peripheral expansion of transplanted T cells.

CD8-depletion of the graft or of a donor lymphocyte infusion has been proposed as a way to decrease the incidence of GVHD without affecting graft-versus-tumor effects.^30–35 We recently performed a comparative study of the impact of CD8-depletion of peripheral blood stem cells (PBSC) on clinical outcomes in a group of 50 patients randomly assigned to receive unmanipulated or CD8-depleted PBSC following non-myeloablative conditioning.³⁶ The results of this study are summarized in Table 1. Briefly, CD8-depletion of PBSC failed to reduce the incidence of grade II–IV acute GVHD, but was associated with an increased risk of graft rejection. Relapse/progression rate and overall survival were similar in the two arms of the study.³⁶

	Design and Methods

TOP ABSTRACT Introduction Design and Methods Results Discussion References

 
T-cell receptor excision circles assay
sjTRECs were quantified in each sample by nested real-time polymerase chain reaction (PCR), as previously described.^26;43;44 Briefly, thawed peripheral blood mononuclear cells (PBMC) were lysed for 30 min at 56°C with Tween-20 (0.05%), NP-40 (0.05%) and proteinase K (100 µg/mL). Cell lysis was stopped by incubation for 15 min at 99°C. Multiplex PCR amplification was achieved for sjTREC together with the CD3 chain, used as a housekeeping gene, with specific 3’/5’ outer primers for each amplicon. Cycle conditions and primers/probes sequences have been reported elsewhere.^26,43 PCR products were diluted 10-fold prior to PCR quantification using Lightcycler^TM technology. The quantitative PCR conditions were: 1 min initial denaturation at 95°C followed by 40 cycles of amplification (1 second at 95°C, 10 seconds at 60°C, 15 seconds at 72°C). Fluorescence emissions were assessed after the hybridization steps. Each PCR product was run for both sjTREC and CD3 chains in two separate Lightcycler experiments. Every sample was run in triplicate, in three different experiments. The results were first calculated as absolute number of sjTREC per 10⁵ PBMC; because each PBMC contains two CD3 chain copies, sjTREC/10⁵ PBMC = (sjTREC/CD3) x 2x10⁵. Because sjTREC are only present in lymphocytes, and because the composition of PBMC is variable, the concentration of sjTREC in peripheral blood was computed using the formula: [(sjTREC/10⁵ PBMC x PBMC/µL)/100 where PBMC/µL = (white blood cells/µL x (%lymphocytes + %monocytes)]/100. Similar adjustments for calculating absolute T-cell subset counts from their frequencies in PBMC have been made previously by other groups of investigators.⁴⁵ The nested character of this quantitative PCR is endowed with a high sensitivity (detection of one copy of sjTREC per PCR reaction).

Statistical analyses
The two-way analysis of variance (ANOVA) test with graft manipulation and time as variables was used to compare T-cell subset recovery and evolution of T-cell chimerism in recipients of unmanipulated graft and those receiving CD8-depleted PBSC. Logarithmic transformation of the data was used before ANOVA analyses. The Mann-Whitney test was used to compare graft composition, TCRBV repertoire diversity and sjTREC levels in recipients of unmanipulated grafts and those receiving CD8-depleted PBSC. Wilcoxon’s matched pair test was used to compare TCRBV repertoire diversity, sjTREC concentration and CD3⁺ T-cell counts at day 40 or 100 after HCT with values obtained in the same patients on day 365 after HCT. Spearman’s correlation test was used to analyze potential associations between graft composition and counts of T-cell subsets and sjTREC levels after HCT, as well as between donor’s and patient’s age and sjTREC levels after HCT. The probabilities of disease progression and severe infection (defined as sepsis, cytomegalovirus disease or invasive fungal infection) from day 100 to day 365 according to immune recovery on day 100 after HCT was assessed using the Kaplan-Meier method. Statistical analyses were carried out with Graphpad Prism (Graphpad Software, San Diego, CA, USA).

To determine factors affecting the counts of CD3⁺ T cells, naive CD4⁺ T cells, and CD8⁺ T cells on days 100, 180 and 365 after HCT, as well as sjTREC concentration on days 100 and 365 after HCT, multivariate linear regression models for the different T-cell subset counts and sjTREC concentrations at each time point were fitted with the SAS Reg procedure (SAS Institute, Cary, NC, USA) using forward stepwise selection. Selected models were refitted for all patients since some patients were excluded in the stepwise selection because of missing values for variables not retained in the final model. Potential factors examined were donor type (HLA-identical sibling vs. 10/10 HLA-allele-matched unrelated donor vs. HLA-mismatched unrelated donor), recipient age, donor age, graft content of CD3⁺ T cells (CD8⁺ T cells for CD8⁺ T-cell counts, and CD34⁺ cells for sjTREC concentration), acute GVHD and chronic GVHD. Logarithmic transformation of the responses was used for all models. The threshold level of statistical significance was 0.05.

	Results

TOP ABSTRACT Introduction Design and Methods Results Discussion References

 
T-cell chimerism
Median donor CD3⁺ T-cell chimerism levels in unmanipulated and CD8-depleted recipients were, respectively, 71 and 51% (p=0.1), 73 and 65% (p=0.5), 75 and 70% p ( =0.23), 75 and 70% (p=0.3), and 89 and 81% (p=0.4) on days 28, 42, 100, 180 and 365. When analyzed together with the two-way ANOVA test, recipients of unmanipulated PBSC had higher levels of donor T-cell chimerism than had recipients of CD8-depleted PBSC (p=0.01) (Online supplementary Figure 1A).

View larger version (18K): [in this window] [in a new window] [Download PPT slide]   Figure 1. A ( ) TCRBV repertoire in five volunteer healthy blood donors, and in patients on days 40, 100 and 365 after HCT. (B) TCRBV repertoire on day 100 after HCT in patients given unmanipulated or CD8-depleted (CD8–) PBSC, as well as in patients receiving grafts from HLA-matched related (MRD), HLA-identical unrelated (HLA-id-URD), or HLA-mismatched unrelated (MM-URD) donors. (C) TCRBV repertoire on day 365 after HCT in patients with or without chronic GVHD.

CD8-depletion of PBSC did not significantly affect CD3⁺, CD4^+, CD4⁺CD45RA⁺, and CD4⁺CD45RO⁺ lymphocyte recovery. In contrast, it significantly reduced the reconstitution efficiency of the CD8⁺ compartment (p<0.0001) as well as that of the CD56⁺ lymphocyte population (p=0.01). Furthermore, the expansion of CD3⁺ T lymphocytes of donor origin was slowed down following CD8-depletion of PBSC (p=0.06). Interestingly, we observed a correlation between the number of CD3⁺ T cells present in the graft and CD3⁺ T-cell counts on days 28 (Spearman’s R=0.39, p=0.02) and 100 (Spearman’s R=0.39, p=0.04) after HCT, but neither at 180 nor at 365 days after HCT.

T-cell repertoire reconstitution
In order to evaluate T-cell repertoire diversity in transplanted patients, we performed a spectratype analysis in both groups of patients at 40, 100, 180 days and 1 year post-transplant. The overall T-cell repertoire complexity was evaluated by scoring the number of peaks identified in the 24 TCRBV families as described previously⁴² and comparing the results from five volunteer donors. At 40 days post-transplantation, TCRBV diversity was slightly reduced in both unmanipulated and CD8-depleted PBSC recipients, as compared to healthy control individuals (mean±SD TCRBV scores were 186±5 peaks in controls, versus 166±31 peaks in the patients (p=0.09)). Moreover, despite a subsequent increase in circulating T-cell numbers during the first year post-transplantation, TCR diversity continued to decrease in both groups of patients (mean ± SD TCRBV scores in all patients: 158±40 peaks (p=0.04 in comparison to the volunteer donors) and 151±40 peaks (p=0.02 in comparison to the volunteer donors) on days 100 and 365, respectively) (Figure 1A). Despite marked differences in the number of transplanted CD8⁺ T cells, TCRBV diversity was similar in unmanipulated PBSC and CD8-depleted PBSC recipients at all time points (p=0.68, p=0.93, and p=0.34 at 40, 100 and 365 days post-transplant, respectively). Furthermore, at day 180 after HCT, TCRBV scores in both CD8⁺ (134±56 vs. 112±73 peaks, p=0.4) and CD4⁺ (152±65 vs. 157±35 peaks, p=0.8) T cells did not differ significantly between unmanipulated and CD8-depleted PBSC recipients. Finally, as shown in Figure 1B–C, graft manipulation, patient-donor relationship and occurrence of chronic GVHD did not significantly affect TCRBV scores.

The observation of a time-dependent reduction of the TCRBV diversity suggests that while the initial reconstitution phase is principally dependent on peripheral expansion of transplanted mature T cells, these cells are then depleted over the first year, leading to a reduced T-cell receptor repertoire. However, this reduction of peripheral T-cell repertoire is accompanied by an increased number of circulating T cells, suggesting another source of these cells.

Thymic function
In order to analyze the contribution of de novo T-cell production by the thymus to the overall T-cell reconstitution, we quantified sjTREC frequencies (sjTREC/10⁵ cells) and sjTREC concentrations (sjTREC/mL) in the two groups of patients on days 100 and 365 after HCT (Online supplementary Figure 2). At day 100 post-HCT, sjTREC frequencies and concentrations were significantly higher in patients receiving unmanipulated PBSC than in those who received CD8-depleted cells (median sjTREC frequency = 67 [1-580] and 10 [1-120] sjTREC/10⁵ cells in the unmanipulated and CD8-depleted groups, respectively (p=0.003); median sjTREC concentration = 391 [9-5614] and 149 [5-1495] sjTREC/mL, respectively (p=0.008, Online supplementary Figure 2A). In contrast, the two groups had similar sjTREC frequencies and concentrations at 1 year post-transplant (median sjTREC frequency = 107 [3-492] and 47 [1-167] sjTREC/10⁵ cells; median sjTREC concentrations = 697 [25-2136] and 1022 [129-22927] sjTREC/mL in the untreated and CD8-depleted groups respectively). Whether or not these levels of thymic output are sufficient to provide successful long-term immune recovery with broad diverse T-cell repertoires several years after HCT is the focus of ongoing studies.

View larger version (17K): [in this window] [in a new window] [Download PPT slide]   Figure 2. (A) Median sjTREC concentrations and CD3+ T-cell counts on days 100 and 365 after HCT in a group of 16 patients for whom we had sjTREC data on both day 100 and day 365 after HCT. The median age of the patients in this cohort was 54 (range, 36–64) years. Error bars indicate interquartile ranges. (B) sjTREC concentrations 1 year after HCT in patients given grafts from related (MRD), HLA-identical unrelated (HLA-id-URD) or HLA-mismatched unrelated (MM-URD) donors. (C) sjTREC concentrations 1 year after HCT in patients with or without chronic GVHD.

Multivariate analysis of factors affecting immunologic recovery (Table 2)
Recipient age
High recipient age was associated with low naive CD4⁺ T-cell counts on day 365 after HCT (p=0.02).

Graft composition
High numbers of transplanted CD3⁺ T cells were associated with high CD3⁺ T-cell counts on day 100 after HCT (p=0.01). This association was not present on day 180 or 365 after HCT. High numbers of transplanted CD3⁺ T cells were also associated with high sjTREC concentrations after HCT (p=0.002). High numbers of transplanted CD8⁺ T cells were associated with high CD8⁺ T-cell counts on days 100 (p=0.001) and 180 (p=0.04) after HCT. This association was not present on day 365 after HCT. There was no association between numbers of transplanted CD34⁺ cells and sjTREC concentrations on day 100 or 365 after HCT.

GVHD
The occurrence of grade II–IV acute GVHD was associated with lower counts of both CD3⁺ T cells (p=0.02) and CD8⁺ T cells (p=0.049) after HCT. The occurrence of chronic GVHD was associated with a low sjTREC concentration on day 365 after HCT (p<0.001) (Figure 2C).

Associations between immune recovery and disease progression/infections
There was no significant association between the occurrence of severe infections (defined as sepsis, cytomegalovirus disease or invasive fungal disease) on days 100 and 365 after HCT in patients with sjTREC concentrations, CD3⁺ cell counts or CD4⁺CD45RA⁺ cell counts below or above the median. Similarly, there was no significant association between the incidence of disease progression on days 100 and 365 after HCT in patients with sjTREC concentrations, CD3⁺ cell counts or CD4⁺CD45RA⁺ cell counts below or above the median.

	Discussion

TOP ABSTRACT Introduction Design and Methods Results Discussion References

 
Whether or not successful immune recovery through the thymic pathway can occur in older patients given non-myeloablative conditioning has remained an important unsolved question. In this study, we evaluated immune recovery in patients receiving allogeneic PBSC transplantation after non-myeloablative conditioning. This study was part of a prospective randomized trial aimed at assessing the impact of CD8-depletion of PBSC on the risk of development of GVHD in patients who cannot undergopre-transplant myeloablative treatment. We show that the immune recovery period can be divided into two major phases. During the first 3 months post-transplantation, most of the immune reconstitution is principally a consequence of the expansion of the mature T cells present in the graft. However, de novo production by the thymus cannot be excluded during this period. In contrast, following this early phase, the thymus seems to be a major source of circulating T cells in the patients.

There was a strong correlation between graft composition and both CD3⁺ T-cell counts and CD8⁺ T-cell counts in the first 100 days after HCT, suggesting that immune recovery was mainly driven by peripheral expansion of mature T cells present in the graft early after HCT. These observations are in agreement with the results of previous studies performed in younger patients undergoing myeloablative allogeneic HCT.⁴⁶ Indeed, Hochberg et al. found that TREC levels remained low in the first 3 months following myeloblative allogeneic bone marrow transplantation in adults.²³ In addition, patients given T cell-depleted grafts had lower levels of both naive T cells⁴⁷ and sjTREC²⁴ in the first months following myeloablative conditioning, in comparison to those given unmanipulated grafts. Furthermore, naive T-cell counts 100 days after myeloablative HCT were strongly correlated with the number of naive T cells in the graft.²¹ Similarly, after non-myeloablative conditioning, the number of TREC-positive cells was shown to decrease gradually in the first 6 months following HCT, suggesting that the main mechanism of T-cell reconstitution early after non-myeloablative conditioning is thymus-independent.¹⁰ Finally, another study suggested that graft composition was the main factor affecting immune recovery during the first 6 months following non-myeloablative HCT.⁷

Importantly, our data demonstrated that neo-generation of T cells through the thymic pathway was a major source of circulating T cells 1 year after HCT. The important role of neo-generation of T cells by the thymus after non-myeloablative conditioning was rather surprising, given the fact that this strategy is mainly proposed for older patients. Indeed, in the current study, 50% of the patients were older than 57 years, and 25% older than 63. While TREC concentrations 1 year after HCT were inversely correlated with the patients’ age in univariate analysis, absence of chronic GVHD, a high number of CD3⁺ T cells in the graft and HLA-matched unrelated donor were the three main factors affecting this concentration. These findings are in agreement with previous observations in younger patients given allogeneic grafts following myeloablative conditioning, which showed that graft composition,²⁴ recipient age^24,48 and absence of chronic GVHD^22,24,25 were the main factors affecting thymic function the first year following HCT.^24,48 While the negative impact of chronic GVHD on thymic function could be due to both direct destruction of host thymic epithelium by chronic GVHD and the negative impact of immunosuppressive drugs,^49,50 the association between high numbers of CD3⁺ T cells in the graft and high sjTREC concentrations could be due to both a higher sjTREC content in the graft and a lower need for peripheral T-cell expansion (and thus less dilution of sjTREC) in patients whose grafts contained more T cells. The association between high sjTREC levels and HLA-matched unrelated donors could be due to both impaired thymic function (maybe through subclinical alloreactivity of donor T cells towards recipient thymic epithelium) in patients given grafts from HLA-mismatched unrelated donors,⁵⁰ and older donors’ age (and thus lower frequency of prethymic T-cell progenitors) in patients given grafts from HLA-identical siblings.¹⁴ Although we did not perform computed tomography scans of the thoracic inlet to demonstrate newly emerging thymic shadows, previous studies found a strong correlation between thymic size increment and sjTREC levels after HCT,²⁹ suggesting that sjTREC-positive cells are mainly generated by the thymus also in the HCT setting.

Finally, our study showed that the T-cell repertoire remained relatively diversified early after HCT, but was more restricted 1 year after HCT. While the relatively complex T-cell repertoire early after HCT could be partly due to the persistence of host-derived T cells,^9,27 the more restricted T-cell repertoire seen at 1 year could be the consequence of gradual eradication of residual host-derived T cells by donor-derived T cells,^9,27 or death of mature T cells contained in the graft following their massive expansion. Alternatively, since analysis of the T-cell repertoire cannot definitively distinguish between T-cell loss and T-cell expansion, the more restricted T-cell repertoire observed at 1 year could be due to massive clonal expansion of specific memory T-cell clones, such as cytomegalovirus-specific clones, or clones causing GVHD.⁵¹

In summary, our results suggest that while immune recovery was mainly driven by peripheral expansion of mature T cells contained in the graft during the first 3 months after non-myeloablative transplantation, T-cell neo-generation by the thymus plays an important role in long-term immune reconstitution in transplanted patients.

	Acknowledgments

 
the study was supported in part by funds from the FNRS, and by the Belgian Foundation against Cancer (FBC). The antibody used for CD8-depletion was generously given by Biotransplant, Inc. We thank Y. Henrotin and M. Mathy for helpful discussions about LC analyses and material availability

	Footnotes

 
^* EC and FB contributed equally to this work.

The online version of this article contains a supplemental appendix.

Authorship and Disclosures

EC performed the sTREC analyses, analyzed the data, and edited the paper; FB designed the study, analyzed the data, and wrote the paper; EW took care of the patients, and analyzed the data; NS-L and AG performed the flow cytometry analyses and edited the paper; NM performed the TCRVB analyses; J-FV and CH performed the chimerism analyses; LS performed the multivariate statistical analyses and edited the paper; VG helped with sjTREC analyses and edited the paper; RC helped with sjTREC analyses, helped with the analyses of the data and with the writing of the paper; YB designed the study, took care of the patients, analyzed the data, and edited the paper. All authors approved the final (revised) version of the manuscript. The authors reported no potential conflicts of interest.

Funding: FB and AG are research associates and VG and YB are research directors at the National Fund for Scientific Research (FNRS), Belgium. EC and EW are Télévie research assistants at the FNRS.

Received for publication May 10, 2007. Accepted for publication November 29, 2007.

	References

TOP ABSTRACT Introduction Design and Methods Results Discussion References

 

1. Sorror ML, Maris MB, Storer B, Sandmaier BM, Diaconescu R, Flowers C, et al. Comparing morbidity and mortality of HLA-matched unrelated donor hematopoietic cell transplantation after nonmyeloablative and myeloablative conditioning: influence of pretransplant comorbidities. Blood 2004;104:961-8.[Abstract/Free Full Text]
2. Baron F, Storb R, Storer BE, Maris MB, Niederwieser D, Shizuru JA, et al. Factors associated with outcomes in allogeneic hematopoietic cell transplantation with nonmyeloablative conditioning after failed myeloablative hematopoietic cell transplantation. J Clin Oncol 2006;24:4150-7.[Abstract/Free Full Text]
3. Baron F, Maris MB, Sandmaier BM, Storer BE, Sorror M, Diaconescu R, et al. Graft-versus-tumor effects after allogeneic hematopoietic cell transplantation with nonmyeloablative conditioning. J Clin Oncol 2005;23:1993-2003.[Abstract/Free Full Text]
4. Sorror ML, Maris MB, Storb R, Baron F, Sandmaier BM, Maloney DG, et al. Hematopoietic cell transplants (HCT) from HLA-matched related (MRD) and unrelated (URD) donors for patients with hematologic malignancies using low-dose TBI conditioning. Blood 106 Part 1 11: 194a#655. 11–16–2005.
5. Maris MB, Sandmaier BM, Storer BE, Maloney DG, Shizuru JA, Agura E, et al. Unrelated donor granulocyte colony-stimulating factor-mobilized peripheral blood mononuclear cell transplantation after nonmyeloablative conditioning: the effect of post-grafting mycophenolate mofetil dosing. Biol Blood Marrow Transplant 2006;12:454-65.[CrossRef][ISI][Medline]
6. Morecki S, Gelfand Y, Nagler A, Or R, Naparstek E, Varadi G, et al. Immune reconstitution following allogeneic stem cell transplantation in recipients conditioned by low intensity vs myeloablative regimen. Bone Marrow Transplant 2001;28:243-9.[CrossRef][ISI][Medline]
7. Baron F, Schaaf-Lafontaine N, Humblet-Baron S, Meuris N, Castermans E, Baudoux E, et al. T-cell reconstitution after unmanipulated, CD8-depleted or CD34-selected nonmyeloablative peripheral blood stem-cell transplantation. Transplantation 2003;76:1705-13.[CrossRef][ISI][Medline]
8. D’Sa S, Peggs K, Pizzey A, Verfuerth S, Thuraisundaram D, Watts M, et al. T- and B-cell immune reconstitution and clinical outcome in patients with multiple myeloma receiving T-cell-depleted, reduced-intensity allogeneic stem cell transplantation with an alemtuzumab-containing conditioning regimen followed by escalated donor lymphocyte infusions. Br J Haematol 2003;123:309-22.[CrossRef][ISI][Medline]
9. Maris M, Boeckh M, Storer B, Dawson M, White K, Keng M, et al. Immunologic recovery after hematopoietic cell transplantation with non-myeloablative conditioning. Exp Hematol 2003;31:941-52.[CrossRef][ISI][Medline]
10. Bahceci E, Epperson D, Douek DC, Melenhorst JJ, Childs RC, Barrett AJ. Early reconstitution of the T-cell repertoire after non-myeloablative peripheral blood stem cell transplantation is from post-thymic T-cell expansion and is unaffected by graft-versus-host disease or mixed chimaerism. Br J Haematol 2003;122:934-43.[CrossRef][ISI][Medline]
11. Mohty M, Mohty AM, Blaise D, Faucher C, Bilger K, Isnardon D, et al. Cytomegalovirus-specific immune recovery following allogeneic HLA-identical sibling transplantation with reduced-intensity preparative regimen. Bone Marrow Transplant 2004;33:839-46.[CrossRef][ISI][Medline]
12. Dodero A, Carrabba M, Milani R, Rizzo E, Raganato A, Montefusco V, et al. Reduced-intensity conditioning containing low-dose alemtuzumab before allogeneic peripheral blood stem cell transplantation: graft-versus-host disease is decreased but T-cell reconstitution is delayed. Exp Hematol 2005;33:920-7.[CrossRef][ISI][Medline]
13. Lamba R, Carrum G, Myers GD, Bollard CM, Krance RA, Heslop HE, et al. Cytomegalovirus (CMV) infections and CMV-specific cellular immune reconstitution following reduced intensity conditioning allogeneic stem cell transplantation with alemtuzumab. Bone Marrow Transplant 2005;36:797-802.[CrossRef][ISI][Medline]
14. Baron F, Storer B, Maris MB, Storek J, Piette F, Metcalf M, et al. Unrelated donor status and high donor age independently affect immunologic recovery after nonmyeloablative conditioning. Biol Blood Marrow Transplant 2006;12:1176-87.[CrossRef][ISI][Medline]
15. Rizzieri DA, Koh LP, Long GD, Gasparetto C, Sullivan KM, Horwitz M, et al. Partially matched, nonmyeloablative allogeneic transplantation: clinical outcomes and immune reconstitution. J Clin Oncol 2007;25:690-7.[Abstract/Free Full Text]
16. Chao NJ, Liu CX, Rooney B, Chen BJ, Long GD, Vredenburgh JJ, et al. Nonmyeloablative regimen preserves "niches" allowing for peripheral expansion of donor T-cells. Biol Blood Marrow Transplant 2002;8:249-56.[CrossRef][ISI][Medline]
17. Storek J, Witherspoon RP. Immunological reconstitution after hemopoietic stem cell transplantation. In: Atkinson K, Champlin R, Ritz J, Fibbe WE, Ljungman P, Brenner MK, ed. Clinical Bone Marrow and Blood Stem Cell Transplantation, Cambridge, UK: Cambridge University Press. 2004. p. 194-226.
18. Crooks GM, Weinberg K, Mackall C. Immune reconstitution: from stem cells to lymphocytes. Biol Blood Marrow Transplant 2006;12 1 Suppl 1: 42-6.[Medline]
19. Peggs KS. Reconstitution of adaptive and innate immunity following allogeneic hematopoietic stem cell transplantation in humans. Cytotherapy 2006;8:427-36.[Medline]
20. Douek DC, Vescio RA, Betts MR, Brenchley JM, Hill BJ, Zhang L, et al. Assessment of thymic output in adults after haematopoietic stem-cell transplantation and prediction of T-cell reconstitution. Lancet 2000;355:1875-81.[CrossRef][ISI][Medline]
21. Storek J, Dawson MA, Maloney DG. Correlation between the numbers of naive T cells infused with blood stem cell allografts and the counts of naive T cells after transplantation. Biol Blood Marrow Transplant 2003;9:781-4.[CrossRef][ISI][Medline]
22. Weinberg K, Blazar BR, Wagner JE, Agura E, Hill BJ, Smogorzewska M, et al. Factors affecting thymic function after allogeneic hematopoietic stem cell transplantation. Blood 2001;97:1458-66.[Abstract/Free Full Text]
23. Hochberg EP, Chillemi AC, Wu CJ, Neuberg D, Canning C, Hartman K, et al. Quantitation of T-cell neogenesis in vivo after allogeneic bone marrow transplantation in adults. Blood 2001;98:1116-21.[Abstract/Free Full Text]
24. Lewin SR, Heller G, Zhang L, Rodrigues E, Skulsky E, van den Brink MR, et al. Direct evidence for new T-cell generation by patients after either T-cell-depleted or unmodified allogeneic hematopoietic stem cell transplantations. Blood 2002;100:2235-42.[Abstract/Free Full Text]
25. Jiménez M, Martínez C, Ercilla G, Carreras E, Urbano-Ispízua A, Aymerich M, et al. Clinical factors influencing T-cell receptor excision circle (TRECs) counts following allogeneic stem cell transplantation in adults. Transpl Immunol 2006;16:52-9.[CrossRef][ISI][Medline]
26. Poulin JF, Sylvestre M, Champagne P, Dion ML, Kettaf N, Dumont A, et al. Evidence for adequate thymic function but impaired naive T-cell survival following allogeneic hematopoietic stem cell transplantation in the absence of chronic graft-versus-host disease. Blood 2003;102:4600-7.[Abstract/Free Full Text]
27. Baron F, Baker JE, Storb R, Gooley TA, Sandmaier BM, Maris MB, et al. Kinetics of engraftment in patients with hematologic malignancies given allogeneic hematopoietic cell transplantation after nonmyeloablative conditioning. Blood 2004;104:2254-62.[Abstract/Free Full Text]
28. Naylor K, Li G, Vallejo AN, Lee WW, Koetz K, Bryl E, et al. The influence of age on T cell generation and TCR diversity. J Immunol 2005;174:7446-52.[Abstract/Free Full Text]
29. Hakim FT, Memon SA, Cepeda R, Jones EC, Chow CK, Kasten-Sportes C, et al. Age-dependent incidence, time course, and consequences of thymic renewal in adults. J Clin Invest 2005;115:930-9.[CrossRef][ISI][Medline]
30. Nimer SD, Giorgi J, Gajewski JL, Ku N, Schiller GJ, Lee K, et al. Selective depletion of CD8+ cells for prevention of graft-versus-host disease after bone marrow transplantation. Transplantation 1994;57:82-7.[ISI][Medline]
31. Giralt S, Hester J, Huh Y, Hirsch-Ginsberg C, Rondón G, Seong D, et al. CD8-depleted donor lymphocyte infusion as treatment for relapsed chronic myelogenous leukemia after allogeneic bone marrow transplantation. Blood 1995;86:4337-43.[Abstract/Free Full Text]
32. Alyea EP, Soiffer RJ, Canning C, Neuberg D, Schlossman R, Pickett C, et al. Toxicity and efficacy of defined doses of CD+ donor lymphocytes for treatment of relapse after allogeneic bone marrow transplant. Blood 1998;91:3671-80.[Abstract/Free Full Text]
33. Andersen MK, Larson RA, Mauritzson N, Schnittger S, Jhanwar SC, Pedersen-Bjergaard J. Balanced chromosome abnormalities inv(16) and t(15;17) in therapy-related myelodysplastic syndromes and acute leukemia: report from an international workshop. Genes, Chromosomes Cancer 2002;33:395-400.[CrossRef][ISI][Medline]
34. Baron F, Frère P, Baudoux E, Schaaf-Lafontaine N, Fillet G, Beguin Y. Low incidence of acute graft-versus-host disease after non-myeloablative stem cell transplantation with CD8-depleted peripheral blood stem cells: an update. Haematologica 2003;88:835-7.[Free Full Text]
35. Baron F, Siquet J, Schaaf-Lafontaine N, Baudoux E, Hermanne JP, Fillet G, et al. Pre-emptive immunotherapy with CD8-depleted donor lymphocytes after CD34-selected allogeneic peripheral blood stem cell transplantation. Haematologica 2002;87:78-88.[Abstract/Free Full Text]
36. Willems E, Castermans E, Baron F, et al. Nonmyeloablative stem cell transplantation with CD8-depleted or unmanipulated peripheral blood stem cells: a prospective randomized trial. ASH Annual Meeting Abstracts 2005;106:1075.[Abstract]
37. Sullivan KM. Graft-vs-host disease. In: Blume KG, Forman SJ, Appelbaum FR, ed. Thomas’ Hematopoietic Cell Transplantation, Oxford, UK: Blackwell Publishing Ltd. 2004. p. 635-64.
38. Frère P, Baron F, Bonnet C, Hafraoui K, Pereira M, Willems E, et al. Infections after allogeneic hematopoietic stem cell transplantation with a nonmyeloablative conditioning regimen. Bone Marrow Transplant 2006;37:411-8.[CrossRef][ISI][Medline]
39. McSweeney PA, Niederwieser D, Shizuru JA, Sandmaier BM, Molina AJ, Maloney DG, et al. Hematopoietic cell transplantation in older patients with hematologic malignancies: replacing high-dose cytotoxic therapy with graft-versus-tumor effects. Blood 2001;97:3390-400.[Abstract/Free Full Text]
40. Baron F, Maris MB, Storer BE, Sandmaier BM, Panse JP, Chauncey TR, et al. High doses of transplanted CD34+ cells are associated with rapid T-cell engraftment and lessened risk of graft rejection, but not more graft-versus-host disease after nonmyeloablative conditioning and unrelated hematopoietic cell transplantation. Leukemia 2005;19:822-8.[CrossRef][ISI][Medline]
41. Baron F, Sandmaier BM. Chimerism and outcomes after allogeneic hematopoietic cell transplantation following nonmyeloablative conditioning. Leukemia 2006;20:1690-700.[CrossRef][ISI][Medline]
42. Genevée C, Diu A, Nierat J, Caignard A, Dietrich PY, Ferradini L, et al. An experimentally validated panel of subfamily-specific oligonucleotide primers (V alpha 1-w29/V beta 1-w24) for the study of human T cell receptor variable V gene segment usage by polymerase chain reaction. Eur J Immunol 1992;22:1261-9.[ISI][Medline]
43. Dion ML, Poulin JF, Bordi R, Sylvestre M, Corsini R, Kettaf N, et al. HIV infection rapidly induces and maintains a substantial suppression of thymocyte proliferation. Immunity 2004;21:757-68.[CrossRef][ISI][Medline]
44. Dion ML, Bordi R, Zeidan J, Asaad R, Boulassel MR, Routy JP, et al. Slow disease progression and robust therapy-mediated CD4+ T-cell recovery are associated with efficient thymopoiesis during HIV-1 infection. Blood 2007;109:2912-20.[Abstract/Free Full Text]
45. Storek J, Dawson MA, Storer B, Stevens-Ayers T, Maloney DG, Marr KA, et al. Immune reconstitution after allogeneic marrow transplantation compared with blood stem cell transplantation. Blood 2001;97:3380-9.[Abstract/Free Full Text]
46. Storek J, Witherspoon RP. Immunologic reconstitution after hematopoietic stem cell transplantation. In: Atkinson K, ed. Clinical Bone Marrow and Blood Stem Cell Transplantation, Cambridge, UK: Cambridge University Press. 2000. p. 111-46.
47. Martínez C, Urbano-Ispizua A, Rozman C, Marín P, Rovira M, Sierra J, et al. Immune reconstitution following allogeneic peripheral blood progenitor cell transplantation: Comparison of recipients of positive CD34+ selected grafts with recipients of unmanipulated grafts. Exp Hematol 1999;27:561-8.[CrossRef][ISI][Medline]
48. Storek J, Joseph A, Dawson MA, Douek DC, Storer B, Maloney DG. Factors influencing T-lymphopoiesis after allogeneic hematopoietic cell transplantation. Transplantation 2002;73:1154-8.[CrossRef][ISI][Medline]
49. Dulude G, Roy DC, Perreault C. The effect of graft-versus-host disease on T cell production and homeostasis. J Exp Med 1999;189:1329-42.[Abstract/Free Full Text]
50. Hauri-Hohl MM, Keller MP, Gill J, Hafen K, Pachlatko E, Boulay T, et al. Donor T-cell alloreactivity against host thymic epithelium limits T-cell development after bone marrow transplantation. Blood 2007;109:4080-8.[Abstract/Free Full Text]
51. Hakki M, Riddell SR, Storek J, Carter RA, Stevens-Ayers T, Sudour P, et al. Immune reconstitution to cytomegalovirus after allogeneic hematopoietic stem cell transplantation: impact of host factors, drug therapy, and subclinical reactivation. Blood 2003;102:3060-7.[Abstract/Free Full Text]

This Article Abstract Full Text (PDF) Castermans et al. Supplementary data Alert me when this article is cited Alert me if a correction is posted Services Email this article to a friend Similar articles in this journal Similar articles in ISI Web of Science Similar articles in PubMed Alert me to new issues of the journal Download to citation manager Citing Articles Citing Articles via Google Scholar Google Scholar Articles by Castermans, E. Articles by Beguin, Y. Search for Related Content PubMed PubMed Citation Articles by Castermans, E. Articles by Beguin, Y.