T(11;18)(q21;q21) is associated with advanced mucosa-associated lymphoid tissue lymphoma that expresses nuclear BCL10

Helicobacter pylori and gastric malignancies

The epidemiological link of Helicobacter pylori and gastric carcinoma was confirmed and the reported rate of gastric carcinoma development in the Japanese population with H. pylori gastritis was 2.9% during a 7.8-year period. Studies showed that gastric atrophy and intestinal metaplasia may partially regress after H. pylori eradication, but whether this will result in a decrease in the development of malignant lesions remains to be confirmed in large studies. Little progress was made towards the identification of criteria applicable to individualized populations that would benefit from H. pylori screening and surveillance of gastric malignancy. Studies of low-grade MALT lymphoma reported clinical and molecular features that may be useful to identify cases that may be responsive to H. pylori eradication therapy, namely evaluation of lymphoma stage by EUS and t(11;18). The role of H. pylori eradication therapy in high-grade MALT lymphoma needs to be evaluated in larger prospective studies. The application of methods of global analysis of gene expression (microarray studies) resulted in the explosion of information on the molecular pathways activated by H. pylori in gastric epithelial cells. New pathways that may play an important role in H. pylori carcinogenesis have been discovered in several studies.

New approaches to lymphoma diagnosis

Recent years have brought an explosion of new diagnostic tools to the pathology of lymphomas, which have permitted more precise disease definition and recognition of factors that can predict prognosis and response to treatment. These new methods exploit both the biological features of normal lymphocytes as they progress through differentiation pathways and the genetic abnormalities that characterize malignant transformation. These features can be assessed in individual tumors with techniques that detect proteins (immunophenotyping), messenger RNA (in-situ hybridization), or changes in DNA [Southern blot, PCR, fluorescence in-situ hybridization (FISH), and gene sequencing]. Recently, the novel technology of "gene chips" or DNA microarrays has greatly enhanced the efficiency of analyzing expression of many genes simultaneously at the RNA level. Understanding the relationship of lymphoid neoplasms to their normal counterparts and the genetic events that lead to malignant transformation in lymphoid cells are essential for physicians caring for patients with lymphoma, since these are the basis of modern classification, diagnosis, and prognosis prediction. Although microarray technology is not ready for prime time in the daily diagnosis of lymphoma, practitioners should understand its potential and limitations. The vast majority of lymphoid neoplasms worldwide are derived from B lymphocytes at various stages of differentiation. The review by Harald Stein and colleagues present the events of normal B-cell differentiation that are relevant to understanding the biology of B-cell neoplasia. These include antigen receptor [immunoglobulin (Ig)] gene rearrangement, somatic mutations of the Ig variable region genes, receptor editing, Ig heavy chain class switch, and differential expression of a variety of adhesion molecules and receptor proteins as the cell progresses from a precursor B cell to a mature plasma cell. Most lymphoid neoplasms have genetic abnormalities, many of which appear to occur during the gene rearrangements and mutations that characterize normal B-cell differentiation. Dr. Riccardo Dalla Favera reviews the mechanisms of these translocations and other abnormalities, and their consequences for lymphocyte biology. The association of specific abnormalities with individual lymphomas is reviewed. Dr. Wing C. Chan reviews the technology and applications of DNA microarray analysis, its promises and pitfalls, and what it has already told us about the biology of lymphomas. Finally, what does this all mean? The applications, both current and future, of these discoveries to the diagnosis and treatment of patients with lymphoma are discussed by Dr. Nancy Lee Harris.

Mucosa-associated lymphoid tissue lymphomas with t(11;18)(q21;q21) and mucosa-associated lymphoid tissue lymphomas with aneuploidy develop along different pathogenetic pathways

t(11;18)(q21;q21) and aneuploidy are recurrent chromosomal aberrations in mucosa-associated lymphoid tissue (MALT) lymphomas. To investigate their relationship and clinical significance, we developed a two-color fluorescence in situ hybridization (FISH) technique to detect t(11;18) and aneuploidy in nuclei isolated from paraffin-embedded tissue. Thirty-seven MALT lymphomas (all previously evaluated for t(11;18) by reverse transcriptase-polymerase chain reaction), 1 large cell lymphoma (LCL) arising subsequent to MALT lymphoma, and 16 controls were tested by FISH using the t(11;18) probe set and multiple centromeric probes. t(11;18)(q21;q21) was present by FISH in 11 of 12 polymerase chain reaction-positive MALT lymphomas (92%). The LCL and its clonally identical antecedent MALT lymphoma both showed t(11;18). The LCL had trisomy 12, and a small subset of MALT lymphoma cells had trisomy 3 and/or 12. Only one other MALT lymphoma with t(11;18) showed aneuploidy (trisomy 3) in a small clone, whereas 15 of 25 t(11;18)-negative MALT lymphomas (60%) showed trisomy of chromosomes 18 (n = 12), 3 (n = 8), 7 (n = 2), and/or 11 (n = 1). t(11;18) and aneuploidy are primarily mutually exclusive events, suggesting different pathogenetic pathways in the development of MALT lymphomas. Both t(11;18) and aneuploidy were seen disproportionately in lung, and both were associated with recurrent disease.

Clinicopathologic comparison between the API2-MALT1 chimeric transcript-positive and -negative gastric low-grade B-cell lymphoma of mucosa-associated lymphoid tissue type

Little is known about the clinicopathological differences between API2-MALT1 chimeric transcript-positive and -negative gastric low-grade B-cell lymphomas of mucosa-associated lymphoid tissue (MALT) type. The aim of this study was to clarify those differences in gastric MALT lymphoma. Twenty-three patients with gastric MALT lymphoma were enrolled in a unicenter study. Helicobacter pylori (H. pylori) infection status and clinical stages were investigated. Antibacterial treatment was performed for every patient. Responsiveness of MALT lymphoma to this treatment was assessed by means of regular follow-up endoscopy combined with biopsy. All cases were examined for API2-MALT1 chimeric transcript by means of RT-PCR and sequencing analyses. H. pylori infection status was assessed as positive in 20 patients and negative in three. With regard to responsiveness to antibacterial treatment, complete remission was observed in two patients, partial remission in 12 and no change in nine. API2-MALT1 chimeric transcript was detected in seven patients, all of whom showed no change in response to antibacterial treatment. API2-MALT1 positivity was found to be significantly correlated with responsiveness to antibacterial treatment (P = 0.0001), absence of H. pylori infection (P = 0.0198), and gross cobblestone mucosa observed endoscopically (P = 0.0198). For the other factors (age, sex, dominant site of lesion, high-grade component, infiltrated layer of gastric wall, nodal involvement or clinical stages), there were no differences between API2-MALT1 chimeric transcript-positive and -negative cases. Gastric API2-MALT1 chimeric transcript-positive MALT lymphoma generally features unresponsiveness to antibacterial treatment, and is thought to be unrelated to H. pylori infection in its pathogenesis. Our findings indicate the presence of different clinical subtypes in gastric MALT lymphomas.

T(11;18) is a marker for all stage gastric MALT lymphomas that will not respond to H. pylori eradication

BACKGROUND & AIMS

Eradication of Helicobacter pylori leads to cure of gastric mucosa-associated lymphoid tissue (MALT) lymphoma in 75% of localized cases. However, prolonged follow-up is necessary to determine whether a lymphoma responds to therapy. In a small series of cases, we showed that t(11;18)(q21;q21)-positive MALT lymphomas failed to respond to H. pylori eradication. The present study aimed to verify this finding in a large cohort and confirm whether the translocation predicts the response of stage I(E) tumors, for which clinical staging has little prognostic value.

METHODS

A total of 111 patients with H. pylori-positive gastric MALT lymphoma treated with antibiotics were studied. Clinical staging was undertaken before therapy. The response of lymphoma to H. pylori eradication was determined by histologic examination of gastric biopsy specimens. Diagnostic biopsy specimens were analyzed for t(11;18)(q21;q21) by reverse-transcription polymerase chain reaction of the API2-MALT1 transcript.

RESULTS

Forty-seven of the 48 patients who showed complete regression had lymphoma at stage I(E), whereas 43 of the 63 nonresponsive cases were at stage I(E) and the remaining cases at stage II(E) or above. t(11;18)(q21;q21) was detected in 2 of 48 complete-regression cases, and these positive cases showed relapse of lymphoma in the absence of H. pylori reinfection. In contrast, the translocation was present in 42 of the 63 nonresponsive cases, including 26 of 43 (60%) at stage I(E).

CONCLUSIONS

t(11;18)(q21;q21)-positive gastric MALT lymphomas, including those at stage I(E), do not respond to H. pylori eradication. Detection of the translocation should help the clinical management of patients with gastric MALT lymphoma.

BCL10 mutation does not represent an important pathogenic mechanism in gastric MALT-type lymphoma, and the presence of the API2-MLT fusion is associated with aberrant nuclear BCL10 expression

Two recurrent translocations have been associated with mucosa-associated lymphoid tissue (MALT)-type lymphoma, t(11;18)(q21;q21) and t(1;14)(p22;q32). The first, t(11;18)(q21;q21), results in the fusion protein API2-MLT (API2-MALT1). Through t(1;14)(p22;q32), the BCL10 gene is entirely transferred to the IgH gene, resulting in its overexpression. Wild-type BCL10 is implicated in apoptosis, and it has been suggested that mutated forms gain oncogenic activity. The occurrence of genomic BCL10 mutations in 35 gastric MALT-type lymphomas with or without t(11;18)(q21;q21) (10 and 25 cases, respectively) was investigated. DNA extracted from either whole tissue sections or microdissected clusters of tumor cells was used. Five polymerase chain reactions amplifying the coding exons were performed and were followed by direct sequencing of the products. Twenty differences with the published BCL10 sequence, all single nucleotide substitutions, were detected in 16 cases. Of these, 12 represented known polymorphisms, either at codon 8, 213, or 5. Of the remaining 8 substitutions, 2 were silent and 6 resulted in amino acid substitutions. Mutation analysis results were correlated with the BCL10 expression pattern. Aberrant nuclear BCL10 expression was detected in 14 cases. No association could be demonstrated between the latter and the presence of BCL10 mutations. In contrast, all 10 cases carrying t(11;18)(q21;q21) showed nuclear expression, whereas this staining pattern was absent in 21 of 25 cases without t(11;18)(q21;q21). These results demonstrate that BCL10 mutations are rare in gastric MALT-type lymphoma and are not related to the aberrant nuclear expression of BCL10. In contrast, they indicate that the presence of the API2-MLT fusion protein is associated with aberrant nuclear BCL10 expression.

Gastric MALT lymphoma: from aetiology to treatment

The development of gastric mucosa-associated lymphoid tissue (MALT) lymphoma is dependent on Helicobacter pylori infection. Bacterial colonisation of the gastric mucosa triggers lymphoid infiltration and the formation of acquired MALT. The bacterial infection induces and sustains an actively proliferating B-cell population through direct (autoantigen) and indirect (intratumoral T cells specific for H. pylori) immunological stimulation. Moreover, the bacterial infection provokes a neutrophilic response, which causes the release of oxygen free radicals. These reactive species may promote the acquisition of genetic abnormalities and malignant transformation of reactive B cells. A transformed clone carrying the translocation t(1;18)(q21;q21) forms a MALT lymphoma, the growth of which is independent of H. pylori and will not respond to bacterial eradication. Malignant clones without t(11;18)(q21;q21), but with other genetic abnormalities, such as trisomy 3 or microsatellite instability, depend critically on immune stimulation mediated by H. pylori for their clonal expansion. In the early stages, the tumour can be successfully treated by eradication of the bacterium, whereas at later stages the tumour may escape its growth dependency through acquisition of additional genetic abnormalities such as t(1;14)(p22;q32) and t(1;2)(p22,p12) involving the BCL-10 gene. Finally, further genetic abnormalities, such as inactivation of the tumour suppressor genes, p53 and p16, can lead to high-grade transformation. Detection of these abnormalities may help with the clinical management of patients with gastric MALT lymphoma.

Mucosa-associated lymphoid tissue lymphoma

Since the first description of mucosa-associated lymphoid tissue (MALT) lymphoma in 1983 rapid advances have been made in the understanding of the pathogenesis and underlying molecular events associated with the development of this tumor. Lymphoma arises at extranodal sites in which a pre-existing inflammatory response has provoked the acquisition of organized lymphoid tissue. Specific molecular events have been associated with the development of MALT lymphoma including t(11;18) and alterations in Bcl-10 protein expression, and these appear to be interlinked. In gastric MALT lymphoma Helicobacter pylori is the most common stimulus for the acquisition of lymphoid tissue. Eradication of this organism has been shown to result in regression of the tumor in many cases, but there are a few that will not respond to this approach. Predicting those cases unlikely to respond to H pylori eradication alone has been investigated in a number of ways. An underlying t(11;18) within the tumor cells appears to predict for a lack of response. Clinical measurement of the depth of infiltration of the wall by gastric MALT lymphoma as measured by endoscopic ultrasound has been less clear. More superficial tumors are more likely to respond, but regression has been reported even in cases with local lymph node involvement. For superficial lymphomas at other sites alternatives to radiotherapy, chemotherapy, or surgery have been sought. Local injections of interferon (IF) alpha have been successful in treating conjunctival lymphoma, and this approach may be of use for other superficial lesions.