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Query: UMLS:C0596978 (Leukemia)
 15,069 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Molecular analysis of T cell receptor (TCR) genes is frequently used to prove or exclude clonality and thereby support the diagnosis of suspect T cell proliferations. PCR techniques are more and more being used for molecular clonality studies. The main disadvantage of the PCR-based detection of clonal TCR gene rearrangements, is the risk of false-positive results due to 'background' amplification of similar rearrangements in polyclonal reactive T lymphocytes. Therefore, PCR-based clonality assessment should include analyses that discern between PCR products derived from monoclonal and polyclonal cell populations. One such method is heteroduplex analysis, in which homo- and heteroduplexes resulting from denaturation (at 94 degrees C) and renaturation (at lower temperatures) of PCR products, are separated in non-denaturing polyacrylamide gels based on their conformation. After denaturation/renaturation, PCR products of clonally rearranged TCR genes give rise to homoduplexes, whereas in case of polyclonal cells heteroduplexes with heterogeneous junctions are formed. We studied heteroduplex PCR analysis of TCR gene rearrangements with respect to the time and temperature of renaturation and the size of the PCR products. Variation in time did not have much influence, but higher renaturation temperatures (>30 degrees C) clearly showed better duplex formation. Nevertheless, distinction between monoclonal and polyclonal samples was found to be more reliable at a renaturation temperature of 4 degrees C, using relatively short PCR products. To determine the sensitivity of heteroduplex analysis with renaturation at 4 degrees C, (c)DNA of T cell malignancies with proven clonal rearrangements was serially diluted in (c)DNA of polyclonal mononuclear peripheral blood cells and amplified using V and C primers (TCRB genes) or V and J primers (TCRG and TCRD genes). Clonal TCRB and TCRD gene rearrangements could be detected with a sensitivity of at least 5%, whereas the sensitivity for TCRG genes was somewhat lower (10-15%). The latter could be improved by use of Vgamma member primers instead of Vgamma family primers. We conclude from our results that heteroduplex PCR analysis of TCR gene rearrangements is a simple, rapid and cheap alternative to Southern blot analysis for detection of clonally rearranged TCR genes.
Leukemia 1997 Dec
PMID:Heteroduplex PCR analysis of rearranged T cell receptor genes for clonality assessment in suspect T cell proliferations. 944 40

In order to gain insight into immunoglobulin (Ig) and T cell receptor (TCR) gene rearrangements in adult acute lymphoblastic leukemia (ALL), we studied 48 adult patients: 26 with precursor-B-ALL and 22 with T-ALL. Southern blotting (SB) with multiple DNA probes for the IGH, IGK, TCRB, TCRG, TCRD and TAL1 loci revealed rearrangement patterns largely comparable to pediatric ALL, but several differences were found for precursor-B-ALL patients. Firstly, adult patients showed a lower level of oligoclonality in the IGH gene locus (five out of 26 patients; 19%) despite a comparable incidence of IGH gene rearrangements (24 out of 26 patients; 92%). Secondly, all detected IGK gene deletions (n = 12) concerned rearrangements of the kappa deleting element (Kde) to Vkappa gene segments, which represent two-thirds of the Kde rearrangements in pediatric precursor-B-ALL and only half of the Kde rearrangements in mature B cell leukemias. Thirdly, a striking predominance of immature Ddelta2-Ddelta3 cross-lineage recombinations was observed (seven out of 16 TCRD rearrangements; 44%), whereas more mature Vdelta2-Ddelta3 gene rearrangements occurred less frequently (six out of 16 TCRD rearrangements; 38% vs >70% in pediatric precursor-B-ALL). Together these data suggest that the Ig/TCR genotype of precursor-B-ALL is more immature and more stable in adults than in children. We also evaluated whether heteroduplex analysis of polymerase chain reaction (PCR) products of rearranged Ig and TCR genes can be used for identification of molecular targets for minimal residual disease (MRD) detection. Using five of the major gene targets (IGH, IGK, TCRG, TCRD and TAL1 deletion), we compared the SB data and heteroduplex PCR results. High concordance between the two methods ranging from 96 to 100% was found for IGK, TCRG and TAL1 genes. The concordance was lower for IGH (70%) and TCRD genes (90%), which may be explained by incomplete or 'atypical' rearrangements or by translocations detectable only by SB. Finally, the heteroduplex PCR data indicate, that MRD monitoring is possible in almost 90% of adult precursor-B-ALL and >95% of adult T-ALL patients.
Leukemia 1998 Jul
PMID:Immunoglobulin and T cell receptor gene rearrangement patterns in acute lymphoblastic leukemia are less mature in adults than in children: implications for selection of PCR targets for detection of minimal residual disease. 966 94

Analysis of minimal residual disease (MRD) can predict outcome in acute lymphoblastic leukemia (ALL). A large prospective study in childhood ALL has shown that MRD analysis using immunoglobulin (Ig) and T cell receptor (TCR) gene rearrangements as PCR targets can identify good and poor prognosis groups of substantial size that might profit from treatment adaptation. This MRD-based risk group assignment was based on the kinetics of tumor reduction. Consequently, the level of MRD has to be defined precisely in follow-up samples. However, current PCR methods do not allow easy and accurate quantification. We have tested 'real-time' quantitative PCR (RQ-PCR) using the TaqMan technology and compared its sensitivity with two conventional MRD-PCR methods, ie dot-blot and liquid hybridization of PCR amplified Ig/TCR gene rearrangements using clone-specific radioactive probes. In RQ-PCR the generated specific PCR product is measured at each cycle ('real-time') by cleavage of a fluorogenic intrinsic TaqMan probe. The junctional regions of rearranged Ig/TCR genes define the specificity and sensitivity of PCR-based MRD detection in ALL and are generally used to design a patient-specific probe. In the TaqMan technology we have chosen for the same approach with the design of patient-specific TaqMan probes at the position of the junctional regions. We developed primers/probe combinations for RQ-PCR analysis of a total of three IGH, two TCRD, two TCRG and three IGK gene rearrangements in four randomly chosen precursor-B-ALL. In one patient, 12 bone marrow follow-up samples were analyzed for the presence of MRD using an IGK PCR target. The sensitivity of the RQ-PCR technique appeared to be comparable to the dot-blot method, but less sensitive than liquid hybridization. Although it still is a relatively expensive method, RQ-PCR allows sensitive, reproducible and quantitative MRD detection with a high throughput of samples providing possibilities for semi-automation. We consider this novel technique as an important step forward towards routinely performed diagnostic MRD studies.
Leukemia 1998 Dec
PMID:Real-time quantitative PCR for the detection of minimal residual disease in acute lymphoblastic leukemia using junctional region specific TaqMan probes. 984 31

A large series of 202 childhood precursor-B cell acute lymphoblastic leukemia (ALL) patients was analyzed by Southern blotting (SB) for cross-lineage rearrangements and/or deletions in the T cell receptor TCRB, TCRG and TCRD loci. In 93% (187/201) of the precursor-B-ALL patients one or more genes were rearranged and/or deleted. TCRB gene rearrangements were found in 35% (69/196), TCRG gene rearrangements in 59% (113/192), TCRD gene rearrangements in 55% (112/202), and isolated monoallelic or biallelic deletions of TCRD loci in 34% (68/202) of the cases. TCRB gene rearrangements involved exclusively the Jbeta2 locus with complete V(D)Jbeta2 joinings in 53% of gene rearrangements and incomplete Dbeta-Jbeta2 gene rearrangements in 33%. TCRG gene rearrangements frequently occurred on both alleles (65% of cases) and in approximately 70% concerned rearrangements to Jgamma1 gene segments. Most rearranged TCRD alleles (80%) represented incomplete Vdelta2-Ddelta3 or Ddelta2-Ddelta3 gene rearrangements, while the remaining TCRD gene rearrangements remained unidentified. Subsequently, we evaluated, whether heteroduplex PCR analysis of rearranged TCRG and TCRD genes can be used for reliable identification of PCR targets for detection of minimal residual disease (MRD). The concordance between SB and heteroduplex PCR analysis for detection of the various types of clonal TCRG and TCRD gene rearrangements ranged between 78% and 87%. The discrepancies could be assigned to the presence of 'atypical' TCRD gene rearrangements or translocations only detectable by SB, but also to efficient PCR-based detection of rearrangements derived from small subclones, which are difficult to detect with SB. Indications for oligoclonality were observed in 38% and 30% of patients with TCRG and TCRD gene rearrangements, respectively, which is comparable to the frequency of oligoclonality in IGH locus. Based on the combined data it was possible to reduce the broad panel of six TCRD and 12 TCRG primer combinations for MRD studies to two TCRD combinations (Vdelta2-Ddelta3 and Ddelta2-Ddelta3) and six TCRG combinations (VgammaI, VgammaII, VgammaIV family-specific primers with Jgamma1.1/2.1 and Jgamma1.3/2.3 primers) resulting in the detection of 80% and 97% of all TCRD and TCRG gene rearrangements, respectively. Finally, the heteroduplex PCR data indicate that MRD monitoring with TCRG and/or TCRD targets is possible in approximately 80% of childhood precursor-B-ALL patients; approximately 55% of patients even have two TCRG and/or TCRD targets.
Leukemia 1999 Feb
PMID:Cross-lineage T cell receptor gene rearrangements occur in more than ninety percent of childhood precursor-B acute lymphoblastic leukemias: alternative PCR targets for detection of minimal residual disease. 1002 93

Thirty T cell receptor (TCR)gammadelta+ T cell acute lymphoblastic leukemias (T-ALL) were analyzed for their immunophenotype, as well as for the rearrangements and junctional regions of the TCRG and TCRD genes. In 15 cases membrane expression of TCRgammadelta proteins could be studied extensively by flow cytometry with a new Vgamma/Vdelta antibody panel. Virtually all TCRgammadelta+ T-ALLs expressed TdT, CD2, CD3, CD5, CD6, and CD7, but they were heterogeneous in their CD1/CD4/CD8 immunophenotype. The majority expressed either CD4+/CD8- or CD4+/CD8+, whereas only 7/30 TCRgammadelta+ T-ALLs lacked both antigens. Despite heterogeneity in the rearranged TCRG and TCRD genes, we found preferential protein expression of VgammaI (21/30), Jgamma2.3 (19/30) and Cgamma2 (21/30) gene products in the TCRgammadelta+ T-ALL. Expressed TCRD genes were largely limited to Vdelta1-Jdelta1, except for six patients who expressed non-Vdelta1 TCRdelta chains (Vdelta2-Jdelta1, Vdelta2-Jdelta3, Vdelta3-Jdelta1, Vdelta6-Jdelta2, and two Valpha-Jdelta1). In spite of the relatively limited combinatorial repertoire of the TCRG and TCRD genes, the junctional region diversity of the expressed genes was extensive. The Vgamma/Vdelta antibody panel confirmed the predominant, but not exclusive, expression of VgammaI and Vdelta1 proteins. Importantly, not a single T-ALL expressed the common peripheral blood Vgamma9+/Vdelta2+ phenotype. These immunogenotypic and immunophenotypic characteristics represent excellent targets for flow cytometric and PCR-based detection of 'minimal residual disease' in all TCRgammadelta+ T-ALL. Comparison of non-Vdelta1+ TCRgammadelta T-ALLs with the more common Vdelta1+ type showed a trend towards a more mature immunogenotype in the former. Firstly, more complete TCRD rearrangements were identified on the non-expressed allele in the non-Vdelta1+ group (83% vs 43%); secondly, a higher frequency of 'end-stage' Jgamma2.3 gene rearrangements was found in non-Vdelta1 cases on both TCRG alleles (83% vs 66%); thirdly, a higher frequency of complete TCRB rearrangements was found in non-Vdelta1 cases (79% vs 50%).
Leukemia 1999 Feb
PMID:Immunophenotypic and immunogenotypic characteristics of TCRgammadelta+ T cell acute lymphoblastic leukemia. 1002 94

It is now widely accepted that the detection of minimal residual disease (MRD) has prognostic value in acute leukemia. However clinical MRD studies need standardized techniques. Therefore, several European laboratories have aligned their goals and performed comparative studies to achieve optimization and standardization of MRD techniques. This was achieved via the BIOMED-1 Concerted Action "Investigation of minimal residual disease in acute leukemia: International standardization and clinical evaluation." This report describes the development of PCR primers and protocols for the detection of MRD in acute lymphoblastic leukemia (ALL) using clone-specific junctional regions of immunoglobulin and T cell receptor gene rearrangements and TAL1 deletions as PCR targets. A total of 54 primers was developed (1) to amplify rearrangements of the TCRD, TCRG, and IGK (Kde) genes as well as TAL1 deletions; (2) to sequence the junctional regions and breakpoint fusion regions; and (3) to perform MRD detection in bone marrow or peripheral blood samples during follow-up of ALL patients. Protocols were established to identify PCR targets at diagnosis by performing 25 PCR reactions per patient using appropriate positive and negative controls. Standardized protocols were developed for MRD monitoring via single amplification of the PCR target followed by dot blot hybridization with the corresponding patient-specific junctional region probe. In addition, alternative approaches were designed for cases where the target sensitivity of at least 10(-4) was not obtained. The standardization described here of MRD-PCR techniques is essential for the process of translating MRD research into clinical practice.
Leukemia 1999 Jan
PMID:Primers and protocols for standardized detection of minimal residual disease in acute lymphoblastic leukemia using immunoglobulin and T cell receptor gene rearrangements and TAL1 deletions as PCR targets: report of the BIOMED-1 CONCERTED ACTION: investigation of minimal residual disease in acute leukemia. 1148 May 75

The IGH gene configuration was investigated in 97 childhood precursor-B-ALL patients at initial diagnosis. Rearrangements were found by Southern blotting in all but three patients (97%) and in 30 cases (31%) we observed oligoclonal IGH gene rearrangements. Heteroduplex PCR analysis revealed at least one clonal PCR product in all Southern blot-positive cases. In 89 patients (92%) complete V(D)J rearrangements were found, while incomplete D(H)-J(H) rearrangements occurred in only 21 patients (22%). In 5% of cases the D(H)-J(H) rearrangements were the sole IGH gene rearrangements. Sequence analysis of the 31 identified incomplete rearrangements revealed preferential usage of segments from the D(H)2, D(H)3 and D(H)7 families (78%). While D(H)2 and D(H)3 gene rearrangements occur frequently in normal B cells and B cell precursors, the relatively frequent usage of D(H)7-27 (19%) in precursor-B-ALL patients is suggestive of leukemic transformation during prenatal lymphopoiesis. Among J(H) gene segments in the incomplete D(H)-J(H) rearrangements, the J(H)6 segment was significantly overrepresented (61%). This observation together with the predominant usage of the most upstream D(H) genes indicates that many of the identified clonal D(H)-J(H) gene rearrangements in precursor-B-ALL probably represent secondary recombinations, having deleted pre-existing D(H)-J(H) joinings. The patients with incomplete D(H)-J(H) gene rearrangements were frequently characterized by hyperdiploid karyotype with additional copies of chromosome 14 and/or by IGH oligoclonality. The presence of incomplete D(H)-J(H) joinings was also significantly associated with a less mature immunogenotype: overrepresentation of V(H)6-1 gene segment usage, absence of biallelic TCRD deletions, and low frequency of TCRG gene rearrangements. This immature immunogenotype of precursor-B-ALL with incomplete IGH gene rearrangements was not associated with more aggressive disease.
Leukemia 2001 Sep
PMID:Precursor-B-ALL with D(H)-J(H) gene rearrangements have an immature immunogenotype with a high frequency of oligoclonality and hyperdiploidy of chromosome 14. 1151 2

PCR-based monitoring of minimal residual disease (MRD) in acute leukemias can be achieved via detection of fusion gene transcripts of chromosome aberrations or detection of immunoglobulin (Ig) and T cell receptor (TCR) gene rearrangements. We wished to assess whether both PCR targets are complementary in acute myeloid leukemia (AML). We investigated 105 consecutive AML cases for the presence of fusion gene transcripts by reverse transcriptase polymerase chain reaction (RT-PCR): AML1-ETO associated with t(8;21), CBFB-MYH11 with inv(16), PML-RARA with t(15;17), BCR-ABL with t(9;22), and MLL-AF4 with t(4;11). In 17 out of 105 AML cases (16%), fusion gene transcripts were found. Ninety-five of these AML patients (13 with fusion gene transcripts) were also investigated for the presence of IGH, IGK, TCRG and TCRD rearrangements by Southern blot and/or PCR heteroduplex analysis and sequencing. In nine out of 95 patients (9.5%), such rearrangements were found. Combined data revealed that only one patient with a fusion gene transcript had a coexistent Ig/TCR rearrangement. The nine AML patients with Ig/TCR rearrangements, as well as five additional AML patients from a previous study were investigated in more detail, revealing that Ig/TCR rearrangements in AML are immature and unusual. The presence of Ig/TCR rearrangements in AML did not correlate with RAG gene expression levels as determined by real-time quantitative PCR. In conclusion, fusion gene transcripts and Ig/TCR rearrangements are infrequent, but complementary MRD-PCR targets in AML.
Leukemia 2002 Mar
PMID:Fusion gene transcripts and Ig/TCR gene rearrangements are complementary but infrequent targets for PCR-based detection of minimal residual disease in acute myeloid leukemia. 1189 40

Chromosomal aberrations with breakpoints in T-cell receptor (TCR) gene loci are recurrent in several T-cell malignancies. Although the importance of interphase cytogenetics has been extensively shown in B-cell lymphomas, hardly any molecular cytogenetic tools are available for recurrent changes in T-cell disorders. Thus, we have established fluorescence in situ hybridization (FISH)-based break-apart assays for the TCRA/D (14q11), TCRB (7q34) and TCRG (7p14) genes and the TCL cluster (14q32). The assays were validated in normal controls as well as in 43 T-cell malignancies with cytogenetically proven 14q11, 7q34-35 or 7p13-21 aberrations. Breakpoints in TCRA/D, TCRB and TCRG could be diagnosed by these assays in 32/33 T-cell neoplasms with chromosome 14q11, 3/6 with 7q34-35 and 1/7 with 7p13-21 alterations, respectively. Application of the new FISH assays to a series of 24 angioimmunoblastic and 12 cutaneous T-cell lymphomas confirmed the cytogenetic evidence of lack of breakpoints in the TCRA/D or TCRB locus. Simultaneous detection of TCRA/D or TCRB breaks was achieved in a multicolor approach, which was further combined with detection of the T-cell-specific CD3 antigen in a multicolor FICTION (Fluorescence Immunophenotyping and Interphase Cytogenetics as a Tool for the Investigation of Neoplasm) assay. These new FISH and FICTION assays provide sensitive, rapid and accurate tools for the diagnosis and biological characterization of T-cell malignancies.
Leukemia 2003 Apr
PMID:Molecular cytogenetic detection of chromosomal breakpoints in T-cell receptor gene loci. 1268 31

Detection of minimal residual disease (MRD), using immunoglobulin (Ig) and T-cell receptor (TCR) gene rearrangements as clone-specific targets, represents the most recent development in diagnosis and treatment of acute lymphoblastic leukaemia (ALL). Nevertheless, risk of false-negative results, due to secondary or ongoing rearrangements of Ig/TCR genes during the disease course, might hamper MRD detection. Therefore, to gain extensive information on clonal stability, we performed PCR-GeneScan analysis of Ig/TCR gene rearrangements at diagnosis and subsequent relapse in bone marrow samples from 53 childhood precursor-B-ALL patients. In addition, sequencing analysis of junctional regions at diagnosis and relapse provided a detailed insight in the stability and changes of Ig/TCR gene rearrangements during the disease course. At least one stable clonal Ig/TCR target was found in 94% of patients. In three patients complete differences in Ig/TCR rearrangements between diagnosis and relapse were observed, suggesting relapse with a new clone. At relapse, 71% of diagnostic clonal PCR targets was conserved. Since the comparison of Ig/TCR gene rearrangements at diagnosis and relapse in our precursor-B-ALL patients did not show significant difference in the stability of different clonal PCR targets (IGH, 70%; IGK, 71%; TCRD, 67%; TCRG, 75%), we conclude that there is no 'preferential' clone-specific target for MRD monitoring.
Leukemia 2003 Aug
PMID:Clonality profile in relapsed precursor-B-ALL children by GeneScan and sequencing analyses. Consequences on minimal residual disease monitoring. 1288 45


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