T-cell receptor gamma and delta gene rearrangements and junctional region characteristics in south Indian patients with T-cell acute lymphoblastic leukemia

Clonal T-cell receptor (TCR) gamma and delta gene rearrangements were studied in 40 T-ALL cases (pediatrics, 29; adults, 11) using PCR with homo-heteroduplex analysis. At least one clonal TCRG or TCRD rearrangement was detected in 34 (85%) cases. TCR gamma (TCRG) rearrangement was detected in 25 (62.5%) cases that included 16 (55%) pediatrics and 9 (81.8%) adults. TCR delta (TCRD) rearrangement was detected in 14/40 (35%) cases, which included 12 (41%) pediatrics and 2 (18%) adults. The frequency of VgammaI-Jgamma1.3/2.3 was significantly more in adults than pediatrics (81.8% vs. 41.3%, P=0.02). In TCRD, Vdelta1-Jdelta1 was rearranged in 10 (25%) cases. The surface membrane CD3 positive cases are significantly associated with absence of TCRD rearrangements (surface membrane CD3+ TCRdelta- 84% vs. surface membrane CD3- TCRdelta- 48%, P value=0.03). Junctional region sequence analyzed with 10 cases each, of TCRG and TCRD, revealed an average junctional region of 7.4 nucleotides (range 2-18 nucleotides) in TCRG and 27 nucleotides (range 14-42 nucleotides) in TCRD-complete rearrangements. In TCRG, trimming at the ends of Vgamma and Jgamma germline nucleotides resulted in deletion, on an average of 9.2 nucleotides. In TCRD, deletion of nucleotides of the Vdelta and Jdelta gene segments on an average was 3.5 nucleotides. The junctional region of TCRD is more diverse than TCRG; nevertheless, the frequency of TCRG was more than that of TCRD and hence we rely more on TCRG clonal markers to quantitate the minimal residual disease in T-ALL.     

Analysis of clonal rearrangements of the Ig heavy chain locus in acute leukemia

Clonal rearrangements of the Ig heavy chain (IGH) locus occur in nearly all cases of B-cell precursor acute leukemia (BCP-ALL). Some of these rearrangements may be detected by polymerase chain reaction (PCR) using VH gene framework III (FRIII) and JH consensus primers. However, about 20% of BCP-ALLs fail to amplify with this technique. To determine the causes of these PCR failures and to investigate any possible association with specific subgroups of disease, we analyzed 72 acute leukemias of defined immunophenotype and cytogenetics, comparing FRIII with VH-family leader-specific PCR methods and Southern blotting. Of 37 BCP-ALL cases, 6 (16.2%) failed totally to amplify with FRIII and JH primers. None of these cases amplified with VH leader primers. Additionally, all cases retained germline VH6 genes and 5 of 11 rearranged alleles amplified with a consensus DH primer, indicating that these rearrangements represented biallelic DH-JH recombinations. Among the 6 FRIII and VH leader PCR-negative BCP-ALL cases, there was no common immunophenotype or consistent cytogenetic abnormality, although all showed structural chromosomal abnormalities and 3 of 5 successfully karyotyped had abnormalities of chromosome 12p. 13 cases with t(9;22)(q34;q11) Philadelphia chromosome-positive [Ph+]) and IGH rearrangements (9 BCP-ALL and 4 biphenotypic cases) were also analyzed. Of 23 rearranged IGH alleles, 19 (82%) were positive by FRIII PCR, and all 4 remaining alleles were amplified by VH leader primers. Use of the leader primers in these Ph+ cases also detected 3 additional clonal rearrangements that were not anticipated from Southern blotting; such unexpected bands were not observed in 21 other Ph- cases. The additional bands represented "new" and unrelated VH rearrangements rather than VH-VH replacement events. We conclude that biallelic DHJH rearrangements occur in a subgroup of BCP-ALL; in these cases, the activation of the full VHDHJH recombination mechanism had not occurred. Therefore, these cases of BCP-ALL were arrested at an early stage of B- cell differentiation. In contrast, all Ph+ BCP-ALLs and biphenotypic acute leukemias, which may represent the transformation of multipotent hemopoietic stem cells, had undergone VHDHJH recombination. Of 9 Ph+ BCP-ALL cases, 3 also showed ongoing VHDHJH rearrangement, reflecting the persistent expression of the VHDHJH recombinase. Finally, sequence analysis of 33 rearranged VHDHJH genes showed that only 3 including 2 Ph+ BCP-ALL maintained an intact open-reading frame. Loss of the open- reading frame occurred not only because of out-of-frame VHDH and DHJH joining, but also because of VH gene mutation and deletion. These data show that most BCP-ALLs may represent the neoplastic transformation of BCPs destined to die in the bone marrow.     

Minimal residual disease monitoring in adult T-cell acute lymphoblastic leukemia: a molecular based approach using T-cell receptor G and D gene rearrangements

BACKGROUND AND OBJECTIVES: Minimal residual disease (MRD) is important in the measurement of response to treatment in childhood B- and T-cell acute lymphoblastic leukemia (ALL) and in adult B-cell ALL. Little is known about MRD evaluation in adult T-cell ALL. This study aimed to determine the prognostic significance of MRD measurements in adult T-cell ALL. DESIGN AND METHODS: T-cell receptor (TCR) gamma (G) and TCR delta (D) gene analyses were carried out at presentation in 49 patients with de novo T-ALL using a polymerase chain reaction (PCR) approach. In 26 of the patients bone marrow (BM) samples were collected at sequential time points (0-2, 3-5, 6-9, 10-24 months) after diagnosis for MRD investigation. The relationship between MRD status and clinical outcome was investigated and correlated with age, gender and white blood cell count at presentation. RESULTS: TCRG clonal gene rearrangements were found in 40 patients (82%). Eleven patients showed TCRD rearrangements (22%), in one of them as the sole molecular marker. V(gamma)I family rearrangements predominated (45 of 65 alleles) together with V(delta)1-J(delta)1/2 (9 of 13 alleles). Continuous clinical remission (CCR) occurred in 17 patients while nine patients relapsed. MRD analysis showed that negative tests during the first 6 months post-induction, and persisting negative MRD after induction were the best predictors of CCR. A positive test after 5 months was better at predicting relapse. In only four of seven patients was relapse preceded by a positive test the 5 months preceding relapse. INTERPRETATION AND CONCLUSIONS: Overall the ability of positive and negative tests to predict relapse or CCR was weaker in this cohort of adult T-ALL patients than in T- and B-lineage childhood ALL and B-lineage adult ALL. TCRG and TCRD gene analysis provides a clonal marker in the majority of adult T-ALL. These results suggest that caution should be taken in using MRD data based on TCR gene rearrangements to predict prognosis in adult T-ALL. Biological reasons may underlie differences between the performance of MRD tests in B- and T-lineage ALL. Further studies in a larger cohort of patients are needed to determine the exact role that MRD determination has in the management of T-ALL in adults.     

Low frequency of clonotypic Ig and T-cell receptor gene rearrangements in t(4;11) infant acute lymphoblastic leukaemia and its implication for the detection of minimal residual disease

Infant t(4;11) acute lymphoblastic leukaemia (ALL) is a rare but cytogenetically well defined subgroup of immature B-cell precursor (BCP) ALL. To date, the configuration of their antigen receptor genes has not been studied in a large group of patients so far. In this study on 27 t(4;11) infant ALL, we have used standardized primer sets for the detection of all incomplete and complete immunoglobulin (Ig) heavy chain (IGH) rearrangements, as well as for the Ig light chain kappa (IGK), T-cell receptor delta (TCRD) and gamma (TCRG) rearrangements that are most common in childhood BCP ALL. Only 52% of cases displayed clonotypic antigen receptor gene rearrangements (IGH in 48%, IGK, TCRD and TCRG in 12%, 41% and 6% respectively). This low frequency suggests, together with the findings of predominantly incomplete DJh joins and monoallelic IGH rearrangements, that they are derived from an immature progenitor cell. As 48% of the t(4;11) infant ALL cases had no detectable antigen receptor gene rearrangements that could be used for minimal residual disease (MRD) analysis, we established an expression-independent, leukaemia-specific polymerase chain reaction (PCR) using the genomic sequence of the MLL-AF4 fusion genes. This method had high sensitivity and specificity and resulted in identical estimations of tumour loads when compared with IGH targets. Thus, genomic MLL-AF4 fusion genes are a good alternative target for the analysis of MRD in patients with t(4;11) leukaemias.     

Molecular features responsible for the absence of immunoglobulin heavy chain protein synthesis in an IgH(-) subgroup of multiple myeloma

This study involved 12 patients with multiple myeloma (MM), in whom malignant plasma cells did not contain immunoglobulin heavy chain (IgH) protein chains. Southern blot analysis revealed monoallelic J(H) gene rearrangements in 10 patients, biallelic rearrangement in 1 patient, and biallelic deletion of the J(H) and C(micro) regions in 1 patient. Heteroduplex polymerase chain reaction analysis enabled the identification and sequencing of 9 clonal J(H) gene rearrangements. Only 4 of the joinings were complete V(H)-(D)-J(H) rearrangements, including 3 in-frame rearrangements with evidence of somatic hypermutation. Five rearrangements concerned incomplete D(H)-J(H) joinings, mainly associated with deletion of the other allele. Curiously, in at least 1 of these 5 cases the second allele seemed to be in germline configuration, whereas the in-frame V(kappa)-J(kappa) gene rearrangements contained somatic mutations. The configuration of the IGH genes was further investigated by use of C(H) probes. In 5 patients the rearrangements in the J(H) and C(H) regions were not concordant, probably caused by illegitimate IGH class switch recombination (chromosomal translocations to 14q32. 3). These data indicate that in many IgH(-) MM patients illegitimate IGH class switch rearrangement or illegitimate deletion of the functional V(H)-(D(H))-J(H) allele are responsible for IgH negativity. For example, the exclusive presence of D(H)-J(H) rearrangements in combination with mutated IGK genes can only be explained in terms of normal B-cell development, if the second (functional) IGH allele is deleted, which was probably the case in most patients. Therefore, defects at the DNA level are responsible for the lack of IgH protein production in most IgH(-) MM patients.     

Comparative analysis of Ig and TCR gene rearrangements at diagnosis and at relapse of childhood precursor-B-ALL provides improved strategies for selection of stable PCR targets for monitoring of minimal residual disease

Immunoglobulin (Ig) and T-cell receptor (TCR) gene rearrangements are excellent patient-specific polymerase chain reaction (PCR) targets for detection of minimal residual disease (MRD) in acute lymphoblastic leukemia (ALL), but they might be unstable during the disease course. Therefore, we performed detailed molecular studies in 96 childhood precursor-B-ALL at diagnosis and at relapse (n = 91) or at presumably secondary acute myeloid leukemia (n = 5). Clonal Ig and TCR targets for MRD detection were identified in 94 patients, with 71% of these targets being preserved at relapse. The best stability was found for IGK-Kde rearrangements (90%), followed by TCRG (75%), IGH (64%), and incomplete TCRD rearrangements (63%). Combined Southern blot and PCR data for IGH, IGK-Kde, and TCRD genes showed significant differences in stability at relapse between monoclonal and oligoclonal rearrangements: 89% versus 40%, respectively. In 38% of patients all MRD-PCR targets were preserved at relapse, and in 40% most of the targets (> or = 50%) were preserved. In 22% of patients most targets (10 cases) or all targets (10 cases) were lost at relapse. The latter 10 cases included 4 patients with secondary acute myeloid leukemia with germline Ig/TCR genes. In 5 other patients additional analyses proved the clonal relationship between both disease stages. Finally, in 1 patient all Ig/TCR gene rearrangements were completely different between diagnosis and relapse, which is suggestive of secondary ALL. Based on the presented data, we propose stepwise strategies for selection of stable PCR targets for MRD monitoring, which should enable successful detection of relapse in most (95%) of childhood precursor-B-ALL.     

Early rearrangements of genes encoding murine immunoglobulin kappa chains, unlike genes encoding heavy chains, use variable gene segments dispersed throughout the locus.

Immunoglobulin heavy-chain variable region (TH) gene segments located closest to the joining (JH) gene segments are preferentially rearranged during ontogeny, indicating that chromosomal position influences the frequency of rearrangement. In addition, certain VH gene segments are repeatedly rearranged, suggesting that the DNA sequence or structure surrounding these segments may increase the probability of rearrangement. To determine whether there is similar based rearrangement of kappa variable (V kappa) gene segments, 25 rearrangements were sequenced from murine fetal and neonatal B-cell hybridomas and from subclones of a pre-B cell line that rearranged V kappa genes during in vitro culture. Four gene segments were isolated twice and one gene segment was isolated three times, suggesting that the process that targets individual variable gene segments for repeated rearrangement operates on both the VH and V kappa loci. Based on a current map of the V kappa locus, the rearranged gene segments belong to nine families that are dispersed throughout the locus. Thus, in these cell types, V kappa rearrangements use germ-line gene segments located across the entire locus, whereas the corresponding VH rearrangements use gene segments proximal to the JH gene segments. Heterogeneity of V kappa rearrangements would add diversity to the biased pool of VH rearrangements, producing a broad repertoire of antibodies early in development.     

Physical linkage of a human immunoglobulin heavy chain variable region gene segment to diversity and joining region elements.

Antibody genes are assembled from a series of germ-line gene segments that are juxtaposed during the maturation of B lymphocytes. Although diversification of the adult antibody repertoire results in large part from the combinatorial joining of these gene segments, a restricted set of antibody heavy chain variable (VH), diversity (DH), and joining (JH) region gene segments appears preferentially in the human fetal repertoire. We report here that one of these early-expressed VH elements (termed VH6) is the most 3' VH gene segment, positioned 77 kilobases on the 5' side of the JH locus and immediately adjacent to a set of previously described DH sequences. In addition to providing a physical map linking human VH, DH, and JH elements, these results support the view that the programmed development of the antibody VH repertoire is determined in part by the chromosomal position of these gene segments.     

Southern blot patterns, frequencies, and junctional diversity of T-cell receptor-delta gene rearrangements in acute lymphoblastic leukemia

Southern blot analysis of T-cell receptor (TCR)-delta gene rearrangements is useful for diagnostic studies on the clonality of lymphoproliferative diseases. We have developed 18 new TCR-delta gene probes by use of the polymerase chain reaction (PCR) techniques. Application of these probes for detailed analysis of the TCR-delta genes in normal control samples, 138 T-cell acute lymphoblastic leukemias (T-ALL), and 91 precursor B-ALL allowed us to determine the TCR-delta gene restriction map for five restriction enzymes, as well as the Southern blot restriction enzyme patterns of all theoretically possible TCR-delta gene rearrangements. Based on this information, it appeared that 97% of all 213 detected TCR-delta gene rearrangements in our series of ALL could be detected by use of the TCRDJ1 probe and that the majority (76%) of the 213 rearrangements could be identified precisely. In T-ALL, we found a strong preference for the complete rearrangements V delta 1-J delta 1 (33%), V delta 2-J delta 1 (10%), and V delta 3-J delta 1 (7%) and the incomplete rearrangement D delta 2- J delta 1 (11%). In precursor B-ALL, the majority of rearrangements consisted of V delta 2-D delta 3 (72%) and D delta 2-D delta 3 (10%). The junctional diversity of these 6 preferential TCR-delta rearrangements was analyzed and showed an extensive junctional insertion (approximately 30 nucleotides) for complete V delta-J delta rearrangements, whereas incomplete rearrangements had correspondingly smaller junctional regions. The detailed TCR-delta gene restriction map and probes presented here, in combination with the Southern blot patterns of TCR-delta gene rearrangements, are important for TCR-delta gene studies in ALL; all TCR-delta gene rearrangements can be detected and the majority can be identified precisely. Identification of rearrangements is a prerequisite for subsequent PCR analysis of TCR- delta gene junctional regions, eg, for detection of minimal residual disease during follow-up of ALL patients.     

T-cell receptor delta/alpha rearrangements in lymphoid neoplasms

Rearrangements within the T-cell receptor (TCR)delta/alpha locus were analyzed in a wide variety of lymphoid neoplasms by eight DNA probes specific for TCR J delta, J alpha and C alpha segments. In all 11 T- cell malignancies, rearrangement and/or deletion of TCR delta was detected irrespective of the stage of maturation of the tumor. The organization of TCR delta correlated with the phenotype of the tumor: In "prethymic" T-cell acute lymphocytic leukemia (ALL), TCR delta was the only TCR gene to be rearranged. More mature T cell malignancies expressing CD4 together with CD3 showed deletion of both alleles of TCR delta, suggestive of TCR V alpha-J alpha rearrangement. All 43 B-cell tumors expressing surface immunoglobulin (sIg), including two cases of adult B-cell ALL, had germline configuration of TCR delta/alpha. In contrast, all 17 B-cell precursor ALLs (null, common, and pre-B-cell ALLs) had rearrangement and/or deletion of TCR delta/alpha. A single case of "histiocytic" lymphoma also showed biallelic deletion of TCR delta. Oligoclonal rearrangements of Ig and TCR genes were observed in two cases of B-cell precursor ALL and in one case of T-cell lymphoblastic lymphoma. Patterns of such "aberrant" TCR rearrangement were similar to those observed in T-lineage malignancies. In particular, seven of eight cases of B-cell precursor ALL and the histiocytic lymphoma which demonstrated biallelic TCR delta deletion, (suggestive of a V alpha-J alpha rearrangement) had clonal TCR beta rearrangement. These data support the hypothesis that supposedly aberrant rearrangements of the TCR genes may follow the same developmental controls as found in T-cell differentiation, despite the lack of evidence for further commitment to the T-cell lineage. TCR delta rearrangement is a useful marker of clonality of immature T-cell tumors which may have only this gene rearranged but is not specific to the T-cell lineage.     

Acute myeloid and T-cell acute lymphoblastic leukaemia with aberrant antigen expression exhibit similar TCRδ gene rearrangements

TCRδ gene recombination patterns were analysed by Southern blot, polymerase chain reaction and nucleotide sequencing in acute myeloid leukaemias with coexpression of lymphoid antigens (Ly⁺ AML, n = 10) as well as in early T-cell acute lymphoblastic leukaemias with (My⁺ T-ALL, n = 10) and without coexpression of myeloid antigens (My^? T-ALL, n = 9). These 29 acute leukaemias exhibiting TCRδ gene rearrangements were selected from 66 Ly⁺ AML, 14 My⁺ T- ALL and 12 My^? T-ALL cases. Similar recombination patterns, namely Dδ2Jδ1 and Vδ1Jδ1 gene rearrangements, were observed in Ly⁺ AML and My⁺ T-ALL. In contrast to Vδ2Dδ3 rearrangements in B-cell precursor ALL, these rearrangements require activation of a T-cell-specific TCRδ enhancer. Comparison of My⁺ T-ALL and Ly⁺ AML with My^? T-ALL exhibited a higher incidence of incomplete Dδ2Jδ1 rearrangements in My⁺ T-ALL and Ly⁺ AML. Since a Dδ2Jδ1 rearrangement is an early event in TCRδ recombination, these leukaemias seem to be arrested at an earlier stage of differentiation. Similar patterns of TCRδ rearrangements in My⁺ T-ALL and Ly⁺ AML suggest existence of a common myeloid/T-lymphoid progenitor cell. Although weak or missing expression of terminal deoxynucleotidyl transferase (TδT) was found in 7/10 Ly⁺ AML cases, no difference was observed in numbers of N-nucleotides inserted in junctional regions when comparing with 3/10 cases exhibiting TdT expression. Since TdT activity is necessary for N-nucleotide addition, this finding suggests down-regulation of TδT expression after rearrangement took place in these Ly⁺ AML cases.     

Analysis of immunoglobulin and T-cell receptor gene rearrangements in human fetal bone marrow B lineage cells

Fetal bone marrow B lineage cells representing multiple stages of B cell development were isolated by two-color cell sorting and analyzed for immunoglobulin H and T-cell receptor (TCR) gamma and delta gene rearrangements. Analysis of CD10+/surface mu- cells using a JH probe revealed a high frequency of rearrangements; some of these rearrangements used the 3' D region gene DQ52. Analysis of CD10+/surface mu- cells revealed no detectable TCR-gamma or -delta rearrangements, nor were TCR-delta rearrangements detected in CD10+/surface mu+ cells, despite the limited repertoire of these genes. These observations are surprising given the high frequency of TCR delta/gamma rearrangements in B cell precursor acute lymphoblastic leukemia, and identify a potential difference in patterns of gene rearrangement that distinguish normal and leukemic B cell precursors.     

The incidence of clonal T-cell receptor rearrangements in B-cell precursor acute lymphoblastic leukemia varies with age and genotype

B-cell precursor acute lymphoblastic leukemias (BCP-ALLs) are increasingly treated on risk-adapted protocols based on presenting clinical and biological features. Residual molecular positivity of clonal immunoglobulin (IG) and T-cell receptor (TCR) rearrangements allows detection of patients at an increased risk of relapse. If these rearrangements are to be used for universal follow-up, it is important to determine the extent to which they are informative in different BCP-ALL subsets. We show that IGH V-D-J rearrangements occur in 89% of 163 BCP-ALL, with no significant variation according to age or genotype (BCR-ABL, TEL-AML1, MLL-AF4, and E2A-PBX1). In contrast, TCRG rearrangements, which occur in 60% of patients overall, are frequent in BCR-ABL and TEL-AML1, are less so in MLL-AF4, and are virtually absent in infants aged predominantly from 1 to 2 years and in E2A-PBX1 ALLs. Incidence of the predominant TCRD Vdelta2-Ddelta3 rearrangement decreases with age but is independent of genotype. These differences are not due to differential recombination activating gene activity, nor can they be explained adequately by stage of maturation arrest. Analysis of MLL-AF4 BCP-ALL is in keeping with transformation of a precursor at an early stage of ontogenic development, despite the adult onset of the cases analyzed. We postulate that the complete absence of TCRG rearrangement in E2A-PBX1 cases may result from deregulated E2A function. These data also have practical consequences for the use of TCR clonality for the molecular follow-up of BCP-ALL.     

Immunoglobulin and T cell receptor gene rearrangements in human lymphoma and leukemia

DNA samples from blood leukocytes or tumor biopsies of 45 patients with phenotypic B or T cell neoplasms were analyzed for rearrangements of the immunoglobulin (Ig) or T cell receptor (TCR) genes by Southern blot hybridization analysis. Rearrangements of the Ig heavy chain joining region genes (JH) were present in DNA from each of 28 B cell lymphomas and leukemias; 14 of 21 of these tumors also had rearrangements of the Ig kappa light chain joining (JK) or deleting element (KDel) genes. Conversely, 16 of 17 T cell lymphomas and leukemias had rearranged TCR beta chain genes. One B cell and one T cell tumor had rearrangements of both Ig and TCR genes. There was a strong correlation between the rearrangements of specific genes and the immunophenotype of the tumor: JH rearrangement without TCR beta chain rearrangement occurred only in B cell tumors; TCR beta chain rearrangement with or without JH rearrangement occurred only in T cell tumors, with one exception; and JK and KDel rearrangements were found only in B cell tumors. Thus, rearrangements of the Ig heavy and light chain genes and the TCR beta chain genes were found to be highly sensitive markers of monoclonal human lymphomas and lymphoid leukemias, with the type of gene rearrangements well correlated with the cell lineage of these neoplasms.     

Molecular characterization of illegitimate TCRδ gene rearrangements in acute myeloid leukaemia

SUMMARY. Recently, we and others have shown the occurrence of TCRδ gene rearrangements in acute myeloid leukaemia (AML). In this study we describe the molecular characteristics of these rearrangements by the polymerase chain reaction (PCR) and the direct sequencing of PCR products. 11 rearrangements were characterized in blast cell samples from six patients. We found a heterogenous pattern of TCRδ gene rearrangements with involvement of Vδ1-5 regions. These findings differ from observations in T-ALL and B-cell precursor ALL, where predominantly usage of Vδ1 and Vδ2 regions has been described. Furthermore, extensive diversity of junctional sites was observed, including addition of up to 37 N nucleotides, nucleotide deletions at junction sites of Vδ and Jδ segments and usage of up to three Dδ segments. The Dδ3 fragment was the most frequently used diversity element and was found in 10 rearrangements. Nine of the 11 rearrangements were non-functional, either incomplete or out of the reading frame. Therefore a functional TCRδ cannot be expressed in these myeloid blast cells.     

Vdelta2-Jalpha rearrangements are frequent in precursor-B-acute lymphoblastic leukemia but rare in normal lymphoid cells

The frequently occurring T-cell receptor delta (TCRD) deletions in precursor-B-acute lymphoblastic leukemia (precursor-B-ALL) are assumed to be mainly caused by Vdelta2-Jalpha rearrangements. We designed a multiplex polymerase chain reaction tified clonal Vdelta2-Jalpha rearrangements in 141 of 339 (41%) childhood and 8 of 22 (36%) adult precursor-B-ALL. A significant proportion (44%) of Vdelta2-Jalpha rearrangements in childhood precursor-B-ALL were oligoclonal. Sequence analysis showed preferential usage of the Jalpha29 gene segment in 54% of rearrangements. The remaining Vdelta2-Jalpha rearrangements used 26 other Jalpha segments, which included 2 additional clusters, one involving the most upstream Jalpha segments (ie, Jalpha48 to Jalpha61; 23%) and the second cluster located around the Jalpha9 gene segment (7%). Real-time quantitative PCR studies of normal lymphoid cells showed that Vdelta2 rearrangements to upstream Jalpha segments occurred at low levels in the thymus (10(-2) to 10(-3)) and were rare (generally below 10(-3)) in B-cell precursors and mature T cells. Vdelta2-Jalpha29 rearrangements were virtually absent in normal lymphoid cells. The monoclonal Vdelta2-Jalpha rearrangements in precursor-B-ALL may serve as patient-specific targets for detection of minimal residual disease, because they show high sensitivity (10(-4) or less in most cases) and good stability (88% of rearrangements preserved at relapse).     

Clonal evolution in B-lineage acute lymphoblastic leukemia by contemporaneous VH-VH gene replacements and VH-DJH gene rearrangements

B-cell acute lymphoblastic leukemia (B-ALL), more frequently than any other B-lineage neoplasm, exhibits oligoclonal Ig heavy chain (IgH) gene rearrangement in 15% to 43% of all cases studied. To study the molecular processes that promote multiple IgH rearrangements, a comprehensive sequence analysis of a B-ALL case was performed in which seven clonal IgH gene rearrangements were identified. The genetic profiles suggested that a single leukemic progenitor clone evolved into several subclones through dual processes of variable (VH) to preexisting diversity-joining (DJH) gene segment rearrangement and VH to VH gene replacement. Predominant IgH-V usage and the uniquely rearranged clonotype-specific VHDJH region gene sequences were identified using a novel DNA-based gene amplification strategy. Polymerase chain reaction (PCR) was directed by an IgH-J generic primer and a complement of family-specific IgH-V primers that defined the major B-cell IgH-V gene usage. Clonality of rearranged VHDJH bands was substantiated by high resolution denaturant gel electrophoretic analysis. Sequence patterns of the amplified VHDJH fragments segregated into two groups defined by common DJH sequences. Partial N region homology at the VHD junction as well as shared DJH sequences firmly established VH to VHDJH gene replacement as a mechanism generating clonal evolution in one group. In the second subset, oligoclonality was propagated by independent VH gene rearrangements to a common DJH precursor. The contributions of all clonal Ig-VHDJH repertoires for each group was approximately 50% and reflected a symmetric distribution of leukemic subclones generated by either process. Thus, oligoclonal rearrangements evolved by two independent, yet seemingly contemporaneous molecular genetic mechanisms. All seven clones displayed nonfunctional Ig-VHDJH recombinations. These observations may have relevance to the recombinatorial opportunities available during normal B-cell maturation.     

Rearrangement of immunoglobulin and T cell receptor genes in acute and chronic leukaemias.

The pattern of immunoglobulin (Ig) and T cell receptor (TCR) gene rearrangements was determined in 87 patients with acute and chronic leukaemias and myelodysplastic syndromes by Southern blot hybridisation. All 31 cases of common, B cell and null cell acute lymphoblastic leukaemia, and B cell chronic lymphocytic leukaemia showed Ig heavy chain (JH) rearrangement, and TCR (beta-chain) rearrangement was seen in all 5 cases of T cell acute lymphoblastic leukaemia. Inappropriate JH and TCR (beta) rearrangements were present in some cases of T-ALL (60%) and common acute lymphoblastic leukaemia (18%), respectively. For the 19 patients with acute leukaemias following chronic myeloid leukaemia, blastic transformation, all 4 with lymphoid transformation and 3 of the 15 with myeloid transformation had JH rearrangement, and 3 CD10-positive lymphoid transformation and 2 myeloid transformation had their TCR (beta) genes rearranged. In conclusion, the pattern of Ig and TCR gene rearrangements correlated well with the cell lineage. However, cross-lineage rearrangements were more commonly seen in patients with acute leukaemias following chronic myeloid leukaemia blastic transformation, as compared to the de novo cases.