Kristina Hinz

Translocations t(11;18)(q21;q21) and t(14;18)(q32;q21) are the main chromosomal abnormalities involving MLT/MALT1 in MALT lymphomas.

The recently discovered MLT/MALT1 gene is fused with the API2 gene in the t(11;18)(q21;q21), which characterizes about one-third of MALT lymphomas. In order to screen for variant translocations and amplifications of MLT/MALT1, we have developed a novel, undirected two-color interphase fluorescence in situ hybridization (FISH) assay with two PAC clones flanking MLT/MALT1. This assay was applied to 108 marginal zone B-cell lymphomas (MZBCLs), including 72 extranodal MALT lymphomas, 17 nodal, and 19 splenic MZBCL. In 19 MALT lymphomas (26%), but in none of the nodal or splenic MZBCL, separated hybridization signals of the MLT/MALT1 flanking probes, were found. Further FISH analyses showed that 12 of these 19 cases displayed the classical t(11;18) and the remaining seven cases revealed the novel t(14;18)(q32;q21), involving the MLT/MALT1 and IGH genes. The frequency at which these translocations occurred varied significantly with the primary location of disease. The t(11;18) was mainly detected in gastrointestinal MALT lymphomas, whereas the t(14;18) occurred in MALT lymphomas of the parotid gland and the conjunctiva. Amplification of MLT/MALT1 was not observed in any of the lymphomas analyzed. We conclude that the translocations t(11;18)(q21;q21) and t(14;18)(q21;q32) represent the main structural aberrations involving MLT/MALT1 in MALT lymphomas, whereas true amplifications of MLT/MALT1 occur rarely in MZBCL.

Genetic abnormalities in marginal zone B-cell lymphoma.

Marginal zone B‐cell lymphoma (MZBCL) including extranodal mucosa‐associated lymphoid tissue (MALT)‐type lymphoma, nodal, and splenic MZBCL represents a distinct subtype of B‐non‐Hodgkins lymphoma. Recently, important progress in the elucidation of the genetic mechanisms underlying the pathogenesis and disease progression of these lymphomas has been made. The API2 gene, an inhibitor of apoptosis, and the novel MLT gene have been found to be altered by the t(11;18)(q21;21), which represents the most frequent structural chromosomal abnormality in extranodal low‐grade MALT lymphoma. Another gene involved in the regulation of apoptosis, the BCL10 gene, has been cloned from a MALT lymphoma cytogenetically characterized by the t(1;14)(p22;q32). Along the same lines, inactivating mutations of the proapoptotic FAS gene have been detected in a relatively high proportion of extranodal MZBCLs. Considering these data and the fact that at least some MALT lymphomas show low levels of apoptosis and seem to escape from FAS‐mediated apoptosis one may speculate that abrogation of apoptosis constitutes a central pathogenetic mechanism in the development of these lymphomas. The pathogenetic role of trisomy 3, the most frequent numerical chromosomal change of MZBCL, is not known. The minimal overrepresented region has been delineated to 3q21‐23 and 3q25‐29 using comparative genomic hybridization. The BCL6 proto‐oncogene, located on 3q27, which is rearranged in some MZBCL and a high proportion of large cell B‐cell lymphomas with extranodal localization, represents one of the candidate genes residing in these critical regions. Copyright

A novel cryptic translocation t(12;17)(p13;p12-p13) in a secondary acute myeloid leukemia results in a fusion of the ETV6 gene and the antisense strand of the PER1 gene

The ETV6 gene is a member of the ETS family of transcription factors and the main target of chromosomal rearrangements affecting chromosome band 12p13. To date, more than 15 fusion partners of ETV6 have been characterized at the molecular level. Most of these fusions encode chimeric proteins with oncogenic properties. However, some of the translocations do not produce a functional fusion protein, but may induce ectopic expression of oncogenes located close to the breakpoint. We herein report the characterization and cloning of a novel cryptic translocation, t(12;17)(p13;p12–p13), occurring in a patient with an acute myeloid leukemia evolving from a chronic myelomonocytic leukemia. Cytogenetic analysis suggested the presence of a deletion of the short arm of chromosome 12, del(12)(p13), in three of the five metaphase cells analyzed. However, fluorescence in situ hybridization (FISH) with the ETV6‐specific cosmid clones 179A6, 50F4, 163E7, and 148B6 as well as probes hybridizing to the TP53 gene on 17p13 and the subtelomeric region of 17p revealed the presence of a translocation between 12p and 17p. By FISH, the breakpoints could be localized in intron 1 of ETV6 and centromeric to TP53. By 3′ rapid amplification of cDNA ends–polymerase chain reaction (3′ RACE‐PCR), a fusion transcript between exon 1 of ETV6 and the antisense strand of PER1 (period homolog 1, Drosophila), a circadian clock gene, could be identified. This ETV6‐PER1 (antisense PER1 strand) fusion transcript does not produce a fusion protein, and no other fusion transcripts could be detected. We hypothesize that in the absence of a fusion protein, the inactivation of PER1 or deregulation of a gene in the neighborhood of PER1 may contribute to the pathogenesis of leukemias with a t(12;17)(p13;p12–p13).

Chromosomal gains and losses are uncommon in hairy cell leukemia: a study based on comparative genomic hybridization and interphase fluorescence in situ hybridization

In contrast to other subtypes of lymphoproliferative malignancies, the genetic mechanisms underlying the pathogenesis of hairy cell leukemia (HCL) are unknown. We studied densely infiltrated splenic tissue of 14 cases of HCL for the presence of chromosomal gains and losses by comparative genomic hybridization (CGH). Chromosomal imbalances were detected in only four of the 14 cases. Chromosomal gains involved the regions 5q13-q31 (two cases) and 1p32-p36.2 (one case). A loss of the region 11q14-q22 was found in one additional patient. The imbalances affecting the regions 5q and 11q were confirmed by interphase fluorescence in situ hybridization (FISH) using PAC clone 144G9 (5q31) and YAC clones 755B11 (11q22.3-q23.1) and 801E11 (11q22.3-q23.1 spanning the ATM gene) and occurred in 61% to 75% of analyzed nuclei. The latter DNA probes and probes hybridizing to chromosomal regions, which are frequently deleted in other subtypes of non-Hodgkin lymphomas (NHL), namely 9p21/ P16(INK4A), 13q14/D13S25, and 17p13/P53 were subsequently applied to all 14 cases of HCL, but no additional abnormalities were found. We conclude that overrepresentation of chromosome 5 represents a recurrent aberration in HCL and that the commonly overrepresented region resides in 5q13-q31. Chromosomal imbalances including deletions of the tumor suppressor gene loci 9p21/P16(INK4A), 13q14/D13S25, and 17p13/P53 rarely occur in HCL in contrast to some other subtypes of B-cell NHL. The pathogenetic role of 11q/ATM alterations in HCL remains to be determined.

Analysis of the P53, RB/D13S25, and P16 tumor suppressor genes in marginal zone B-cell lymphoma: An interphase fluorescence in situ hybridization study.

The genetic mechanisms underlying the genesis, disease progression, and high-grade transformation of marginal zone B-cell lymphoma (MZBCL) are poorly understood. We analyzed 33 cases of histologically and immunophenotypically well-characterized MZBCL (12 extranodal, 11 nodal, and 10 splenic MZBCL; 27 at primary diagnosis and six during the course of disease) by dual-color interphase fluorescence in situ hybridization (FISH) for deletions of tumor suppressor genes. We investigated loci known to play a role in the genesis or disease progression of other subtypes of lymphoid malignancies, namely the P53 gene (17p13), the retinoblastoma gene (RB, 13q14), the D13S25 locus (13q14), and the P16(INK4A) gene (9p21). Heterozygous deletions of P53 were detected in three out of the 33 cases, including two splenic and one extranodal MZBCL. One of these patients was analyzed at primary diagnosis and two during the course of disease. Heterozygous deletions of the RB gene (nodal MZBCL) and D13S25 (splenic MZBCL) were found in one case each. P16 deletions were not detected in any of our cases. We conclude that deletions of the analyzed tumor suppressor genes are relatively rare in MZBCL, which contrasts with the findings in some other subtypes of NHL.

A novel fusion of the MALT1 gene and the microtubule-associated protein 4 (MAP4) gene occurs in diffuse large B-cell lymphoma

Rearrangements of the MALT1 gene by the t(11;18)(q21;q21) and t(14;18)(q32;q21) are the most frequent structural chromosomal abnormalities in MALT lymphomas. These translocations lead to fusions of BIRC3–MALT1 and IGH–MALT1 respectively, and activate the NF‐κB pathway. Among 122 diffuse large B‐cell lymphomas and 28 Burkitts lymphomas screened by interphase FISH, we found two cases with a break within MALT1, but without a t(11;18) or a t(14;18). Molecular genetic analyses in one of these cases revealed a novel “in frame” fusion of exon 9 of MALT1 and exon 9 of the microtubule‐associated protein 4 (MAP4) gene. The translocation was accompanied by a deletion of MALT1 sequences distal to the breakpoint including the caspase‐like domain, which is essential for activation of NF‐κB. As a result of the deletion, the reciprocal 5′MAP4‐3′MALT1 transcript was not present, demonstrating that the 5′MALT1‐3′MAP4 fusion represents the pathogenetically relevant transcript. Immunohistochemistry with amino‐terminal and carboxy‐terminal MALT1 antibodies, indicated a strong expression of the chimeric MALT1–MAP4 protein. Moreover, NF‐κB activation was not increased in this case as shown by the levels of IκBα phosphorylation and NEMO ubiquitination. Our data demonstrate that the pathogenetic consequences of the novel MALT1–MAP4 fusion are different from those of the known MALT1‐associated chromosomal rearrangements and do not involve NF‐κB activation.

Deletion of chromosome 15 represents a rare but recurrent chromosomal abnormality in myelocytic malignancies

Abstract We report on three cases with myelocytic malignancies cytogenetically characterized by a deletion of chromosome 15 occurring as the sole cytogenetic aberration. The deletions were defined as del(15) (q12q21) (two cases) and del(15)(q11q21) (one case). Cytogenetic analysis was supplemented by fluorescence in situ hybridization (FISH) using a chromosome 15 specific whole chromosome painting probe and probes hybridizing to the UBE3A gene on 15q11~q13, the PML gene on 15q22, and the telomeric region of 15q. Hereby, an interstitial deletion of 15q including UBE3A , but not PML and the telomeric region of 15q could be demonstrated. Two of our patients were diagnosed as acute myelocytic leukemia (AML) with bone marrow dysplasia classified as AML-M6 and AML-M4, respectively, according to the French–American–British classification; the third patient suffered from a chronic myelomonocytic leukemia (CMMoL). In two cases, the aberration was found at the time of primary diagnosis, whereas the third case showed the del(15) only during relapse of leukemia. Both cases with acute leukemia did not adequately respond to intensive chemotherapeutic treatment and died 13 and 11 months, respectively, after primary diagnosis. Our findings and the data of five previously published cases with an isolated del(15) indicate that: 1) del(15) represents a rare but recurrent abnormality in myelocytic hemopathies; 2) in our cases, del(15) was interstitial and included the region 15q11~q13/ UBE3A , but not 15q22/ PML and the telomeric region of 15q as shown by FISH; 3) del(15) occurs frequently in disorders with myelodysplastic or myeloproliferative features and may therefore affect early hematopoietic progenitor cells; and 4) del(15) may occur during disease progression and is often associated with an unfavorable prognosis.

The novel t(11;12;18)(q21;q13;q21) represents a variant translocation of the t(11;18)(q21;q21) associated with MALT-type lymphoma.

The novel t(11;12;18)(q21;q13;q21) represents a variant translocation of the t(11;18)(q21;q21) associated with MALT-type lymphoma

Polysomy 13 with concomitant deletion of 13q13-14 involving the retinoblastoma gene and the D13S25 locus in a case of acute myeloid leukemia.

We herein describe a case of acute myeloblastic leukemia (AML), FAB subtype M4, with an unfavorable clinical course and a complex karyotype, including 4-9 copies of chromosome 13. Polysomy 13 was a result of clonal evolution. Fluorescence in situ hybridization (FISH) revealed a cytogenetically unrecognizable deletion within 13q13-14 that included the retinoblastoma gene (RB) and the D13S25 locus in all but one copy of chromosome 13. The only chromosome 13 that did not show a deletion affecting the q13-14 region was translocated to chromosome 7, resulting in a dic(7;13)(q21;p11). In this case, the coexistence of polysomy and a partial deletion within the same chromosome point toward a possible formation of a fusion product with oncogenic potential and its consecutive amplification as a critical alteration in this case.

MLT/MALT1 involving translocations and amplifications are important mechanisms in the pathogenesis of non-Hodgkin’s lymphoma

6582 Background: The t(11;18)(q21;q21) and the t(14;18)(q32;q21) involving the MLT/MALT1 gene are the main structural abnormalities in extranodal marginal zone lymphoma (MZL). In addition, amplification of MLT/MALT1 has been proposed as a pathogenetic mechanism in NHL. Amplifications in 18q21 frequently involve the BCL2 gene, which lies about 5Mb telomeric to MLT/MALT1. However, a recent study described amplification of MLT/MALT1 without BCL2 coamplification, suggesting that MLT/MALT1 and BCL2 are independent targets of amplification in NHL. Methods: In order to screen for translocations and amplifications of MLT/MALT1, we have analyzed 214 NHL with a novel FISH assay using probes flanking the MLT/MALT1 gene (PACs 117B5 and 59N7). The assay was applied to 91 MALT lymphomas, 19 splenic MZL, 17 nodal MZL, 17 follicular lymphomas (FL), 8 mantle cell lymphomas (MCL), 15 chronic lymphocytic leukemias (CLL), 3 B-cell prolymphocytic leukemias (PLL), 9 Burkitt’s lymphomas (BL), 30 diffuse large B-cell lymphomas (...