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.     

Diversity of T-cell receptor Gene Rearrangements in South Indian Patients with Common Acute Lymphoblastic Leukemia

Background: Precursor B-Acute Lymphoblastic Leukemia (precursor B-ALL) oc-curs due to the uncontrolled proliferation of B-lymphoid precursors arrested at a par-ticular stage of B-cell development. Precursor-B-ALL is classified mainly into pro-B-ALL, common-ALL and pre-B-ALL. The Common Acute Lymphoblastic Antigen CD10 is the marker for common-ALL. Objective: This study was aimed to examine the diversity of T-cell receptor Gamma (TCRG) and T-cell receptor Delta (TCRD) gene rearrangements in South Indian Common-ALL patients. Methods: Clonality of TCRG and TCRD was studied in 52 cases (pediatric=41 and adolescents and young adults=11) of common-ALL. TCRG and TCRD gene rearrangements were amplified by PCR and the clonality was assessed by Heteroduplex analysis of amplified prod-ucts. Results: In pediatric common-ALL, clonal TCRG and TCRD gene rearrange-ments were detected in 19 (46.3%) and 18 (43.9%) cases respectively. In adolescents and young adults (AYA), TCRG was rearranged in 8 (72.7%) cases and TCRD was rearranged in 4 (36.3%) cases. In the present study of common-ALL, the frequency of a TCRG rearrangement VγII-Jγ1.3/2.3 was significantly high in AYA compared to pediatric (36.3% vs 4.8%; p<0.025). Thus, VγII-Jγ1.3/2.3 was highly diverse in AYA compared to pediatric. That shows the difference in biology of the disease be-tween pediatric and AYA in South Indian population. Conclusion: The reason for the high frequency of VγII-Jγ1.3/2.3 in AYA of common-ALL in South Indian popu-lation in connection with unknown infectious agents or environmental carcinogens needs to be evaluated further.     

Ig heavy chain gene rearrangements in T-cell acute lymphoblastic leukemia exhibit predominant DH6-19 and DH7-27 gene usage, can result in complete V-D-J rearrangements, and are rare in T-cell receptor alpha beta lineage.

Rearranged IGH genes were detected by Southern blotting in 22% of 118 cases of T-cell acute lymphoblastic leukemia (ALL) and involved monoallelic and biallelic rearrangements in 69% (18/26) and 31% (8/26) of these cases, respectively. IGH gene rearrangements were found in 19% (13/69) of CD3(-) T-ALL and in 50% of TCRgammadelta+ T-ALL (12/24), whereas only a single TCRalpha beta+ T-ALL (1/25) displayed a monoallelic IGH gene rearrangement. The association with the T-cell receptor (TCR) phenotype was further supported by the striking relationship between IGH and TCR delta (TCRD) gene rearrangements, ie, 32% of T-ALL (23/72) with monoallelic or biallelic TCRD gene rearrangements had IGH gene rearrangements, whereas only 1 of 26 T-ALL with biallelic TCRD gene deletions contained a monoallelic IGH gene rearrangement. Heteroduplex polymerase chain reaction (PCR) analysis with VH and DH family-specific primers in combination with a JH consensus primer showed a total of 39 clonal products, representing 7 (18%) VH-(DH-)JH joinings and 32 (82%) DH-JH rearrangements. Whereas the usage of VH gene segments was seemingly random, preferential usage of DH6-19 (45%) and DH7-27 (21%) gene segments was observed. Although the JH4 and JH6 gene segments were used most frequently (33% and 21%, respectively), a significant proportion of joinings (28%) used the most upstream JH1 and JH2 gene segments, which are rarely used in precursor-B-ALL and normal B cells (1% to 4%). In conclusion, the high frequency of incomplete DH-JH rearrangements, the frequent usage of the more downstream DH6-19 and DH7-27 gene segments, and the most upstream JH1 and JH2 gene segments suggests a predominance of immature IGH rearrangements in immature (non-TCRalpha beta+) T-ALL as a result of continuing V(D)J recombinase activity. More mature alpha beta-lineage T-ALL with biallelic TCRD gene deletions apparently have switched off their recombination machinery and are less prone to cross-lineage IGH gene rearrangements. The combined results indicate that IGH gene rearrangements in T-ALL are postoncogenic processes, which are absent in T-ALL with deleted TCRD genes and completed TCR alpha (TCRA) gene rearrangements.     

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.     

Detection of T cell receptor delta gene rearrangements in childhood B and T lineage acute lymphoblastic leukaemia by southern blot and PCR: technical comparison of two methods of analysis

Molecular analysis of antigen receptor genes (Ig and TCR) has been useful for clonal studies in acute lymphoblastic leukaemia (ALL) patients. Rearrangements of these genes can be used to track the persistence of the leukaemic clone during the therapy. The purpose of our study was to analyse the percentage and the pattern of the rearrangements at the TCR D locus in a series of ALL patients, comparing the results obtained by Southern blot and PCR. Genomic DNA was extracted from mononuclear BM cells of 40 paediatric ALL cases, digested with different restriction enzymes and hybridized to TCRDJ1 probe to study the TCR delta locus. Amplification of the rearranged TCR delta genes was performed by PCR to define the gene segments involved. The junctional region was deduced from the sequence to obtain patient-specific primers. Among the 31 B lineage ALL samples, one or two TCR delta alleles proved to be rearranged in 53% of cases. Two different types of rearrangements were chiefly detected: Vdelta2Ddelta3 and Ddelta2Ddelta3. In T-ALL patients, the predominant rearrangement involved the Vdelta1 and the Jdelta1 gene segments.     

Size and Composition of T-Cell Receptor δ (TCRD) Junctional Sequences Are Not Predictive of the Sensitivity of Clonospecific Oligonucleotides Designed for Detection of Minimal Residual Disease in Acute Lymphoblastic Leukemia

We characterized 168 junctional regions of T-cell receptor delta (TCRD) rearrangements from 116 children with acute lymphoblastic leukemia (ALL) (101 with precursor B-cell ALL, 15 with T-cell ALL). Application of 101 allele-specific oligonucleotide (ASO) probes representing 85 Vdelta2Ddelta3, 10 Ddelta2Ddelta3, 3 Vdelta1Jdelta1, 1 Vdelta3Jdelta1, and 2 Ddelta2Jdelta1 junctions for the detection of minimal residual disease (MRD) revealed detection levels of 10(-4) to 10(-6) leukemia cells in the vast majority of cases (93 of 101). Of interest was that neither the N, D, P (nontemplated, diversity, palindromic) content and length of the junctional regions nor the number of nucleotides deleted from the flanking V, D, or J (variable, diversity, joining) elements correlated with the sensitivity of ASO probes. These data indicated that in ALL TCRD rearrangements can serve as suitable tools for the detection of MRD irrespective of the specific composition of the junctional region.     

α, β and γ T-cell receptor genes: rearrangements correlate with haematological phenotype in T cell leukaemias

We have studied the arrangement of the alpha, beta and gamma T cell receptor (TCR) genes in 27 patients with T cell lymphoproliferative disorders. Nine patients had acute lymphoblastic leukaemia (T-ALL), nine patients had prolymphocytic leukaemia (PLL), six patients presented with a T-CLL/T-lymphocytosis syndrome, two patients had Sezary syndrome (SS) and one patient had HTLV-I positive T-cell leukaemia/lymphoma (ATLL). alpha TCR gene rearrangement could be demonstrated by the use of three available probes in only one case. By contrast, both beta and gamma TCR gene rearrangement could be demonstrated by Southern blot analysis of DNA samples digested with appropriate restriction enzymes in the majority of cases. In general, when rearrangements were present they involved both alleles. The proportion of rearranged chromosomes was lower in T-ALL than in other forms of T-cell leukaemia and it was lower in cases with the CD4-/CD8+ phenotype than in those with a CD4+/CD8- phenotype. In three out of 34 cases of B-cell leukaemia the TCR beta-gene but not the TCR gamma-gene was rearranged, just as in two out of 26 cases of T-cell leukaemia the immunoglobulin (Ig) heavy chain but not the light chain genes were rearranged. These data suggest that development of the machinery required for gene rearrangement may precede commitment to B or T cell lineage. The use of this technique is especially useful for the classification of cases of ALL in which the cells are negative with respect to most current phenotypic markers and in cases of T cell lymphocytosis in which the finding of a gene rearrangement identifies a monoclonal cell population.     

Stages of T-cell receptor protein expression in T-cell acute lymphoblastic leukemia.

In this study five monoclonal antibodies (MoAbs) to T-cell receptor (TCR) proteins (WT31, alpha F1, beta F1, TCR delta-1 and delta TCS-1) were used to identify discrete maturative stages in 40 cases of T-cell acute lymphoblastic leukemia (T-ALL). These MoAbs reacted exclusively with CD3+ T cells and did not label B-lineage and myeloid cells. In 17 of the 40 T-ALL cases studied the leukemic blasts lacked membrane and cytoplasmic TCR chains (group I). In 12 cases cells did not have membrane CD3/TCR but expressed cytoplasmic TCR proteins heterogenously: nine cases had cytoplasmic TCR beta chains (beta F1+, alpha F1-; group II), one case had cytoplasmic TCR alpha chains (alpha F1+, beta F1-; group III), and two cases were labeled by both alpha F1 and beta F1 MoAbs (group IV). The remaining 11 cases were mCD3+: nine were TCR alpha beta+ (group Va) and two exhibited TCR gamma delta (TCR delta-1+, delta TCS-1+; group Vb). The analysis of the TCR beta, -gamma, and -delta gene configurations in 23 of the 40 T-ALLs showed that: (1) the lack of TCR protein expression was due to the lack of TCR gene rearrangements only in one of nine cases; (2) five of five TCR beta+, TCR alpha- cases studied had germline TCR alpha genes (ie, no detectable TCR delta gene deletions); (3) seven of eight cases with TCR delta gene deletions expressed TCR alpha proteins, whereas in 12 of 20 of the T-ALLs with TCR beta gene rearrangements the synthesis of the corresponding protein occurred; only 2 of 16 cases with rearranged TCR delta genes expressed TCR delta chains. The T-ALL categories identified with anti-TCR MoAbs did not have additional characteristic phenotypic patterns and may correspond to the normal stages of T-cell development more precisely than those defined by other differentiation antigens.     

Unusual T-cell receptor-delta gene rearrangement patterns revealed by screening of a large series of childhood acute lymphoblastic leukaemia by multiplex polymerase chain reaction

Rearrangements of the T-cell receptor (TCR) and immunoglobulin genes are considered as useful clonal markers in lymphoproliferative disorders of B- and T-cell lineage, and are frequently used for the detection of minimal residual disease (MRD). In this paper, we report on the unexpected results of an extensive analysis of TCR-delta chain gene rearrangement frequencies and patterns in leukaemic bone marrow DNA samples collected from 438 children with initial (n = 112) or relapsed (n = 326) acute lymphoblastic leukaemia (ALL). By applying a previously described multiplex polymerase chain reaction, the overall incidence of non-deleted TCR-delta gene rearrangements in ALL was 47% (206/438), 52% in initial ALL (58/112) and 45% in relapsed ALL (148/326). As expected, the majority of B-cell precursor (BCP) ALL had incomplete Vdelta2-Ddelta3 or Ddelta2-Ddelta3 TCR-delta gene rearrangements, whereas most T-ALL showed complete rearrangements of the TCR-delta gene locus (Vdelta1-Jdelta1, Vdelta2-Jdelta1, Vdelta3-Jdelta1). However, unexpectedly, 5/206 rearranged TCR-delta alleles in BCP-ALL showed a complete Vdelta-(Ddelta)-Jdelta gene rearrangement pattern, and 3/31 T-ALL had an incomplete recombination. Theoretically, complete TCR-delta gene rearrangements should not occur in cells other than T-lymphocytes and have only been reported once previously in BCP-ALL. The data contribute to the discussion about the reliable screening for clonal markers in ALL.     

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.     

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.     

Rearrangements of T-cell antigen receptor delta chain gene in hematologic neoplasms

Rearrangements of the T-cell antigen receptor (TCR) delta chain gene were studied in primary neoplastic cells from 137 patients with leukemia or lymphoma. TCR delta gene rearrangements or deletions were observed in all 50 T-cell neoplasms: 5 of 8 CD3- T-cell neoplasms showed rearrangements, whereas biallelic deletion of TCR delta gene was the most common pattern in CD3+ T-cell neoplasm (39 of 42 patients). Rearrangements of TCR delta gene were also detected in 23 of 40 immature B-cell leukemias, including 22 of 25 patients with rearrangements of TCR gamma gene, 2 of 17 mature B-cell neoplasms, and 3 of 30 myeloid leukemias. Thus, TCR delta gene rearrangement or deletion is always found in T-cell neoplasms and is frequently found in immature B-cell leukemias associated with TCR gamma gene rearrangement. Furthermore, TCR delta gene rearrangements associated with the germline configuration of the TCR beta, gamma, and immunoglobulin heavy chain genes were observed in two immature T-cell leukemias, suggesting that TCR delta gene rearrangements precede TCR gamma and beta gene rearrangements. These results indicate that an analysis of TCR delta gene rearrangement provides potential tools to establish the clonality of immature T-cell neoplasms and to identify the normal stages of lymphocyte differentiation.     

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.     

CD5-CD56+ T-cell receptor silent peripheral T-cell lymphomas are natural killer cell lymphomas [see comments]

Non-Hodgkin's lymphomas are divided into B- and T-cell neoplasms. The existence and the clinical relevance of lymphomas derived from the third lymphocyte lineage, ie, natural killer (NK) cells are still controversial. NK cells are lymphocytes that mediate cytotoxicity without prior sensitization. NK cells also have phenotypic and genotypic characteristics: they express the NK-related antigen CD56, T- cell markers such as CD2 and CD7, but do not express CD5 and T-cell receptor (TCR) proteins, and their TCR locus is not rearranged. Therefore, if NK cell lymphomas exist, they should express some T-cell markers, but not alpha beta or gamma delta TCR proteins. Such lymphomas are actually called TCR silent peripheral T cell lymphomas (PTCL). To detect and characterize NK cell lymphomas, we investigated the immunophenotype and immunogenotype of 35 patients with TCR silent PTCL. The first group included 16 patients with a lymphoma of CD5-CD56+ phenotype, which is identical to normal NK cells. These patients had either a nasal/nasopharyngeal lymphoma (11 cases) or a lymphoma with predominant non-nasal/non-nodal initial involvement (five cases). Eight of the nine cases for which immunogenotypic data were available lacked clonal rearrangement of the TCR gamma genes. Thus, these tumors are likely to be NK cell lymphomas. The second group of 15 cases had a CD5+ phenotype (14 were CD56-, and 1 was CD56+) and clonal rearrangement of TCR gamma genes, indicating that they were true PTCL with unproductive TCR rearrangement. The four remaining cases were CD5- CD56- lymphomas and disclosed either a clonal (two cases) or no clonal (two cases) rearrangements of the TCR gamma genes. Altogether these findings show that CD5-CD56+ so-called "TCR silent PTCL" bear the immunophenotype and immunogenotype of normal NK cells and display peculiar clinical features distinct from true PTCL.     

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.     

Immunoglobulin and T-cell receptor gene rearrangement and expression in human lymphoid leukemia cells at different stages of maturation.

The use of probes to genes (IG and TCRB) encoding immunoglobulins (IG) and the beta chain of the T-cell antigen receptor (TCRB), respectively, have become a sensitive means to assess clonality and lineage in lymphoid malignancies. It has become apparent that some individual cases show rearrangements of both IG and TCRB genes. In an attempt to more accurately define cell lineage we have analyzed cells from patients with B- or T-cell leukemia (n = 26) at various stages of maturation with probes to two additional TCR genes, TCRG and TCRA (encoding the TCR gamma and alpha chains, respectively), as well as the IG heavy chain joining region (IGHJ) and TCRB genes. On Southern blot analysis, the mature T-cell leukemia cells studied had rearranged TCRG and TCRB while IGHJ remained as in the germ line. The mature B-cell leukemia cells studied had rearranged IGHJ with germ-line TCRG and TCRB. These data suggest that, in the majority of more mature leukemias, cells have rearranged IG or TCR genes but not both. In contrast, cells from five of nine precursor B-cell leukemia patients and cell lines from one of four precursor T-cell leukemia patients had rearranged both IGHJ and TCR genes. TCRG and TCRB mRNAs were expressed in the cells of precursor T- but not B-cell leukemia patients studied. The spectrum of leukemia cells studied within the T-cell series permitted an assessment of the order of TCR gene rearrangements. Two of 13 patients had cells with germ-line TCRG and TCRB, 2 patients had cells with rearranged TCRG alone, and the remainder had cells with rearranged TCRG and TCRB. TCRG and TCRB mRNAs were expressed in precursor T-cell leukemia cells, whereas TCRB and TCRA were expressed in mature T-cell leukemia cells. These results parallel observations from mouse studies on gene expression and support the view of a hierarchy of TCR gene rearrangements in T-lymphocyte ontogeny. TCRG genes are rearranged first, subsequently TCRB genes are rearranged, followed by TCRA gene activation.     

Rearrangement of the T-cell receptor delta genes in human T-cell leukemias

Two distinct types of T-cell receptors (TCR), designated alpha beta and gamma delta, have been identified on the surface of T cells. In the adult, T cells bearing the gamma delta TCR are a minority and they have the phenotype CD3+, CD4-, CD8-/+. By using appropriate probes, rearrangements of the TCR alpha, beta, and gamma genes have been extensively investigated in a variety of lymphoproliferative disorders. Because the TCR delta gene has been cloned only recently, no comparable information exists with respect to this in human leukemias. We report the analysis of the TCR delta gene configuration in 21 T-cell acute and chronic leukemias, 40 B-cell leukemias, 4 acute myeloid leukemias of difficult classification, and 12 normal controls. The TCR delta genes were structurally modified in all T-cell disorders and in germ-line configuration in all controls and all but one case of non-T-cell leukemias tested. In one case of T-chronic lymphocytic leukemia (CD3+, CD4-, CD8+) we found rearrangement and expression of TCR gamma and delta (but not alpha and beta), suggesting that leukemic transformation took place in a cell bearing a TCR gamma delta rather than a TCR alpha beta. In two cases of pre-T-acute lymphoblastic leukemia, only delta was rearranged out of the three TCR genes tested. This finding is in keeping with the suggestion that the TCR delta gene might be the first to rearrange in T cell ontogeny, and that its mode of rearrangement may play a role in the subsequent choice of the cell between production of a TCR alpha beta or gamma delta. Thus, TCR delta chain gene analysis can provide novel information of the clonal nature of T-cell disorders, particularly if the analysis of the beta and gamma genes has not been helpful.     

Terminal deoxynucleotidyl transferase expression can precede T cell receptor beta chain and gamma chain rearrangement in T cell acute lymphoblastic leukemia

The nuclear enzyme terminal deoxynucleotidyl transferase (TdT) is thought to contribute to the diversity of certain immunoglobulin and T cell receptor gene rearrangements through the addition of random nucleotides at their variable (V)-joining (J) region junctions. An acute lymphoblastic leukemia (ALL) with an immature T cell phenotype (CD7+, CD5+, CD1+/-, CD2+/-, CD3-, CD4-, CD8-) was found to be TdT+ with germline immunoglobulin heavy chain, T cell receptor beta chain, and T cell gamma chain genes. The data indicate that TdT expression can precede T gamma and T beta rearrangement during T lymphoid ontogeny consistent with its proposed association with the T cell receptor rearrangement process. Southern analysis of certain cases of T-ALL may not result in the detection of a monoclonal population of cells.