Endogenous CD8+ T cell expansion during regression of monoclonal EBV-associated posttransplant lymphoproliferative disorder.

There are experimental data which suggest that the primary immune effector cell responsible for maintaining immune surveillance against the outgrowth of EBV-transformed B cells in humans is the CTL, but in vivo proof of this is lacking. In this study we perform a series of cellular and molecular assays to characterize an autologous, endogenous immune response against a transplantation-associated, monoclonal, EBV+ posttransplant lymphoproliferative disorder (PTLD). Following allogeneic bone marrow transplantation, a patient developed a monoclonal PTLD of donor B cell origin. With a decrease in immune suppression, we document the emergence of endogenous, donor-derived CD3+CD8+ CTLs, followed by regression of the PTLD. The TCR Vbeta repertoire went from a polyclonal pattern prior to the development of PTLD to a restricted TCR Vbeta pattern during the outgrowth and regression of PTLD. Donor-derived CD3+CD8+ T lymphocytes displayed MHC class I-restricted cytolytic activity against the autologous EBV+ B cells ex vivo without additional in vitro sensitization. The striking temporal relationship between the endogenous expansion of a TCR Vbeta-restricted, CD3+CD8+ population of MHC class I-restricted CTL, and the regression of an autologous monoclonal PTLD, provides direct evidence in humans that endogenous CD3+CD8+ CTLs can be responsible for effective immune surveillance against malignant transformation of EBV+ B cells.

Rearrangement of ALL1 (MLL) in acute myeloid leukemia with normal cytogenetics.

Approximately 45% of adults with acute myeloid leukemia (AML) have normal cytogenetics and therefore lack structural abnormalities that can assist in the localization and characterization of molecular defects. The partial tandem duplication of the ALL1 (MLL) gene has been found in several such cases of AML, yet its frequency and clinical significance are unclear. We performed Southern analysis of the ALL1 gene in pretreatment samples from 98 AML patients with normal cytogenetics. Eleven of 98 such patients (11%; 95% confidence interval, 6-19%) showed rearrangement of ALL1 at diagnosis. The partial tandem duplication of ALL1 was responsible for ALL1 rearrangement in all such cases examined, making it a frequent molecular defect in adult AML patients with normal cytogenetics. Furthermore, patients with ALL1 rearrangement had a significantly shorter duration of complete remission when compared to patients without ALL1 rearrangement (P = 0.01; median, 7.1 versus 23.2 months). This defect defines for the first time a subset of AML patients with normal cytogenetics who have short durations of complete remission and thus require new therapeutic approaches.

The partial tandem duplication of ALL1 in acute myeloid leukemia with normal cytogenetics or trisomy 11 is restricted to one chromosome.

The molecular defects responsible for tumorigenesis in adult de novo acute myeloid leukemia (AML) with a normal karyotype or an additional copy of one chromosome (i.e., trisomy) remain largely unknown. We recently discovered that approximately 90% of adult patients with de novo AML and trisomy 11 (+11) as a sole abnormality and 11% of adult patients with de novo AML and normal cytogenetics carry a molecular rearrangement of the ALL1 (MLL, HRX, or HTRX) gene. The rearranged ALL1 gene has been shown to result from the direct tandem duplication of a portion of ALL1 itself. To better understand the underlying mechanisms of leukemogenesis, we asked whether in cytogenetically normal cases one or both chromosomes carry the mutated allele and whether in trisomic cases the mutation is present in one, two, or three chromosomes. Herein we show that in cytogenetically normal cases of AML and in cases with +11 as a sole cytogenetic abnormality, only one chromosome contains the mutated ALL1 allele. Thus a single mutated ALL1 allele with the partial tandem duplication is sufficient for ALL1-associated leukemogenesis, irrespective of the number of normal genes present. The frequently occurring specific association of +11 and ALL1 gene mutation in the leukemic clone remains unexplained.

Persistence of the AML1/ETO fusion transcript in patients treated with allogeneic bone marrow transplantation for t(8;21) leukemia.

The AML1/ETO fusion transcript is expressed in virtually all patients with t(8;21) (q22;q22) acute myeloid leukemia (AML). The fusion transcript can be detected by reverse transcription-polymerase chain reaction (RT-PCR) in most of these patients in long-term complete remission (CR) following conventional chemotherapy or autologous bone marrow transplantation (BMT). However, AML1/ETO expression has not been analyzed in a series of patients following allogeneic BMT. We examined CR bone marrow (BM) samples and, in some cases, blood samples from 10 patients with t(8;21) leukemia who underwent allogeneic BMT in either first or second remission or first or second relapse. A variety of myeloablative regimens were used. Eight patients received non-T-cell depleted BM from matched sibling donors, one patient received a T-cell depleted haploidentical BM, and one patient received a non-T-cell depleted BM from a matched unrelated donor (MUD). Five patients developed acute and/ or chronic graft versus host disease (GVHD). The furthest time points analyzed for the AML1/ETO transcript in the 10 patients in CR following allogeneic BMT ranged from 7.5 to 83.0 months. Sufficient RNA was extracted from the most recent BM or BM and blood samples from nine patients to assay for presence or absence of the AML1/ETO fusion transcript by RT-PCR. The fusion transcript was detected by RT-PCR in all nine of these patient samples; eight were positive in BM and one was negative in BM, but positive in blood. The fusion transcript could not be detected in a BM sample from the tenth patient obtained 7.5 months after BMT, but the amount of RNA available was suboptimal. Hematopoietic chimerism could be demonstrated in sorted CD34+ BM cells from two of four patient CR BM samples with RT-PCR evidence of the fusion transcript. Additionally, in one of the two cases with chimerism, we demonstrated an abnormal clonal population of recipient cells in the CR BM sample by fluorescence in situ hybridization. One patient died of complications from GVHD, while the other nine patients remain alive without evidence of relapse, with a median follow-up time of 27 (range, 7.5 to 87) months post-BMT. These data suggest that allogeneic BMT, like conventional chemotherapy and autologous BMT, is not sufficient to eradicate cells expressing AML1/ETO, and that a positive RT-PCR for the fusion transcript post allogeneic BMT is compatible with continued CR.

Description of an efficient and highly informative method for the evaluation of hematopoietic chimerism following allogeneic bone marrow transplantation.

The significance of full donor hematopoietic engraftment or hematopoietic chimerism (HC) following allogeneic bone marrow transplantation (BMT) remains unresolved. To study this phenomenon properly, informative genetic loci must be prospectively identified and followed for several years after allogeneic BMT in large numbers of consecutive patients treated with uniform conditioning and immunosuppressive regimens. In addition, sensitive methods that can be performed on small numbers of cells are required in order to extend the analysis for HC to individual hematopoietic lineages and specific anatomic compartments (eg bone marrow, peripheral blood, and lymph nodes). Although polymerase chain reaction (PCR) amplification of polymorphic minisatellite and microsatellite DNA loci has improved the sensitivity of detection of HC, a single rapid, sensitive, and highly informative test that can consistently distinguish donor from recipient elements for the majority of allogenic BMT patients has not been described. In the present report, we describe a single PCR that simultaneously amplifies four microsatellites and was able to identify an informative locus in 48 of 50 (96%) consecutive recipient/donor pairs. A HC of as little as 0.5% could be detected, and HC of 10% could be detected in as few as 100 cells. This technique should allow the detection of an informative microsatellite locus in most patients undergoing allogeneic BMT, using minimal amounts of DNA and requiring 16 h for completion.