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NEOPLASIA
From the Oncology Institute of Southern Switzerland,
Division of Medical Oncology, Bellinzona, Switzerland; Department of
Experimental Haematology, St Bartholomew's and The Royal London School
of Medicine and Dentistry, London, United Kingdom; Istituto Cantonale
di Patologia, Locarno, Switzerland; Anatomia Patologica e Citologia,
Ospedali Riuniti Bergamo, Italy; Servizio di Ematologia,
Università Statale di Milano, Ospedale Maggiore IRCCS, Milan,
Italy; and Istituto di Anatomia e Istologia Patologica,
Università dell'Insubria, Varese, Italy.
Nodal marginal zone B-cell lymphoma (MZL) is a rare and not
extensively studied entity that accounts for approximately 2% of all
non-Hodgkin lymphomas. Complementarity-determining regions 2 and 3 (CDR2, CDR3) of the immunoglobulin heavy-chain variable region
(VH) genes were amplified by polymerase chain reaction (PCR), cloned, and sequenced in 8 patients with nodal MZL. All showed a
potentially functional VH rearrangement. The use of
VH gene families was unbiased and without
overrepresentation of any particular VH gene or gene
family. The presence of somatic VH mutations was detected,
with a deviation from the closest germ line sequence ranging from 4%
to 17% in 6 of 8 patients. In 3 mutations, the replacement-to-silent
mutation ratio suggested the presence of an antigen-selected process.
Sequencing different subclones of the same cloned PCR products allowed
the detection of intraclonal variability in 4 analyzed patients. The
observed pattern of VH mutations suggested that nodal MZL,
formerly deemed a malignancy of memory B cells, may arise from
different subsets of marginal zone B cells The entity traditionally designated as monocytoid
B-cell lymphoma is classified in the Revised European American
Classification of Lymphoid Neoplasms (REAL) and in World Health
Organization (WHO) Classification of Hematological Malignancies as
nodal marginal zone B-cell lymphoma (MZL).1,2 By
definition, in the WHO classification the term nodal is used to design
cases primarily involving lymph nodes, and it excludes any case with
prior or concurrent localization in an extranodal site other than bone marrow, liver, or spleen.3 Although nodal MZL shares many
histologic and immunologic features with extranodal MZL of MALT
type,1,2,4,5 clinical characteristics, natural history,
and prognosis suggest that nodal MZL should be considered a distinct
disease entity.6,7 Based on molecular findings, the
relation between the 2 entities is still
controversial.8,9
Generation of antigen receptors by somatic recombination of variable,
diversity, and joining segments is a unique feature of B and T cells,
occurring in an early phase of development. In B-cell ontogenesis,
after the successful construction of a functional, nonautoreactive
antigen receptor, naive B cells move to the germinal centers of
secondary lymphoid organs. In these structures, upon antigen encounter,
during T-cell-dependent B-cell development, the antibody expressed by
a B cell may be modified by class-switch recombination, somatic
hypermutation,10 and, according to some suggestions,
receptor editing.11 Somatic hypermutation, which
introduces predominantly point mutations into the immunoglobulin variable region genes, increases immunoglobulin diversity and can
modify the immunoglobulin affinity for antigen.12 Because somatic hypermutation appears to be restricted to B cells proliferating within the microenvironment of the germinal center,13
somatically mutated V-region genes are a hallmark of germinal center B
cells and their descendants. Thus, sequence analysis of the
immunoglobulin variable region genes of normal B cells and B-cell
lymphomas can be applied to determine either the ancestral derivation
from follicle center cells or the continued influence of the follicle
center microenvironment.14
The pattern of somatic mutations in the VH genes of most
B-cell non-Hodgkin lymphomas, with clustering of replacement mutations in complementarity-determining regions (CDRs), indicates that the tumor
cells or their precursors were selected for antigen-receptor expression
during the process of mutation.15 Furthermore, intraclonal nucleic acid sequence variation, suggestive of ongoing mutations, indicates that tumor B cells are still under the influence of a
mutation mechanism.15 Extranodal MZLs of MALT type are
thought to arise from post-germinal center B cells. In gastric MZL,
Helicobacter pylori-specific T cells drive the
proliferation of the neoplastic B cells.16 Immunoglobulin
VH genes show a pattern of somatic mutations consistent
with a selection by antigen, suggesting that continued exposure to
antigen may play a role in the persistence of
lymphoma.17,18 The specificity of extranodal MZL B cells for autoantigens and the characteristic growth of extranodal MZLs in
the background of autoimmune diseases represent important elements in
the comprehension of the pathogenesis of this lymphoma
entity.19,20
Analyses of immunoglobulin heavy-chain variable region genes in nodal
MZLs have been limited to a few series of patients.21-23 Usually the sequences analyzed showed the presence of somatic mutations, suggesting the derivation of the tumor population from post-follicular, antigen-experienced B cells. Based on these results and according to the immunophenotypical characteristics of the tumor
cells, nodal marginal zone B-cell lymphomas have been suggested to
represent malignancies of memory B cells.15 Nevertheless, in all these studies, the technical approach of amplifying rearranged variable region genes, followed by direct sequencing of the PCR products prevented the reliable detection of potential ongoing mutations within the tumor cells.
Our study was aimed at acquiring insight into the nature of the
immunoglobulin heavy-chain variable region sequences in nodal MZLs to
confirm the presence of somatic mutations and identify mutation
patterns reminiscent of antigen selection processes. In addition, the
study was devised to explore the presence of ongoing mutations by
cloning and sequencing the VH genes of 8 patients with
histologically reviewed nodal MZLs.
All molecular analyses were performed on tumor tissues collected
at diagnosis from patients with nodal MZL.
Pathology review
DNA extraction
PCR amplification and cloning A seminested strategy was used for the PCR amplification of the VH genes using the FR2A consensus primer, complementary to the conserved framework-2 segment of the variable region, and the LJH and VLJH consensus primers for the J region.24 Patient samples were analyzed together with DNA from the Raji cell line as positive control and with a negative reagent control containing all PCR reagents without any template DNA. PCR products were visualized on 7% nondenaturing polyacrylamide gels stained with ethidium bromide. Patients apparently lacking PCR products were assessed for the presence of amplifiable DNA: a 268-bp segment of the -globin gene was
amplified by PCR using specific primers (PCO4: 5'
CAACTTCATCCACGTTCACC 3'; GH20: 5' GAAGAGCCAAGGACAGGTAC 3').
Cloning of monoclonal cases was performed with the pGEM T-easy vector (Promega, Madison, WI) using DNA excised and purified with Sephacryl MicroSpin S-400 HR columns (Amersham Pharmacia Biotech, Uppsala, Sweden) from monoclonal bands in the polyacrylamide gels. Randomly picked recombinant clones showing the expected insert size were analyzed using fluorescence sequencing technology on a 377 automatic DNA sequencer (Applied Biosystems, Foster City, CA) using the ABI Prism Big Dye Terminator Kit (PerkinElmer, Foster City, CA) as recommended by the manufacturer. All clones were sequenced in both directions. Sequence analysis Tumor-related VH genes were identified based on the presence of analogous CDR3 sequences. DNA sequences were analyzed for homologies in the GenBank database using the Basic Local Alignment Search Tool (BLAST) software, available at the National Center for Biotechnology Information (NCBI). Homology with germ line VH, DH, and JH genes was identified using the V-Base database44 and the IgBlast software of the NCBI.45 The ability to code for functional heavy chains was determined by translation of DNA sequences into amino acids.Analysis of intraclonal heterogeneity To evaluate the presence of ongoing mutations in nodal MZLs, at least 7 clones from each specimen were sequenced. For evaluation of intraclonal heterogeneity, the following definitions were used: unconfirmed mutation a substitution mutation observed in
only one of the VH gene molecular clones from the same
tumor specimen; confirmed mutationa mutation observed in
more than one of the VH gene molecular clones from the same
tumor specimen. Only the confirmed mutations were considered as
evidence of intraclonal heterogeneity; the unconfirmed mutations were
instead ascribed to Taq polymerase error.25
Antigen selection To determine the pattern of somatic mutations compatible with antigen selection, 2 different methods were applied.26 First, the ratio of replacement-to-silent mutations (R/S) in the CDR2 and FW3 regions was studied. A sequence was considered to be antigen selected when the R/S ratio in the CDR2 was higher than 2.9 and the R/S ratio in the FW3 region was lower than 1.5. Second, only the R/S ratio of the somatic mutations in the FW3 region was considered. A sequence was regarded as antigen selected when the R/S ratio was less than 1.6.
Assessment of clonality CDR2 and CDR3 of the immunoglobulin heavy-chain variable region (VH) genes were amplified in 10 patients with nodal MZL. Eight patients, characterized by a single band on polyacrylamide gel electrophoresis indicating a monoclonal rearrangement, underwent cloning and sequencing procedures and are the subjects of the present study.Patients' clinical characteristics Most patients showed advanced stage at presentation. In all of them prominent and disseminated nodal involvement was present; peripheral blood involvement was not detected in any of them. Moderate spleen enlargement, not pathologically investigated, was reported in 3 patients, none of whom had regional lymphadenopathy. No patient had a history of previous or concurrent autoimmune disease. The main clinical characteristics at diagnosis are summarized in Table 1.
Immunohistochemistry Table 2 shows immunohistochemical features of the patients analyzed.
Usage of VH, DH, and JH genes Table 3 shows the number of tumor-derived clones identified among the total number of clones sequenced for each sample. Sequences not related differed individually and were likely derived from contaminating normal B cells. In Table 3, the VH gene used by each tumor and its homology with the germ line counterpart are also reported. In 4 patients, VH gene segments were derived from the VH3 family, in 3 patients they were derived from the VH4 family, and in one patient they were derived from the VH2 family. No bias with respect to the previously reported27 preferential use of the segments VH 4-34 and VH 1-69 was observed. Assignment of D gene segments was based on the homology between CDR3 sequences and the germ line D genes. Adopting the rules proposed by Corbett et al,28 which require at least 10 consecutive nucleotides of identity to assign a D segment, a D gene was identified in only 3 patients (patients 2, 3, 7). In 4 patients (patients 4-6, 8), the assignment was based on less stringent rules29: minimal homology of 6 matches in a row or 7 matches interrupted by one mismatch. Priority was given to the homology with a D segment when both D and JH homologous regions overlapped (only in patients 7 and 8). In patient 1, no rule could support D-segment assignment. JH4 was used in 2 patients, whereas in 2 patients sequence homology was found with the JH6 segment. JH4 is the most commonly used JH gene segment at all stages of ontogeny,30 but the small number of patients with an assignable germ line JH segment did not allow us to make any conclusion about the relative frequency of this usage. No JH segment could be assigned to patients 2 and 4. CDR3s did not show remarkable similarities in lengths or sequence.
Somatic hypermutations in tumor-related VH genes Table 3 summarizes mutation patterns of the VH region. In all but 2 patients, the sequences analyzed contained somatic mutations with respect to the closest germ line sequences. The percentage of sequence homology ranged from 83% to 96% (Figure 1). Most hypermutation events consisted of single base changes, but double and triple substitutions also frequently occurred, mostly in the same codon. In addition to point mutations, patient 5 displayed a multiple-base segment insertion (Figure 1) in the presence of a maintained open-reading frame, an event believed to be linked to the hypermutation process.31 The demonstration of this finding in our small sample, according to the value found in normal germinal center B cells,30 further suggests the relevance of the hypermutation process in this patient. Two patients (patients 3 and 6), as stated before, showed no somatic mutations with respect to the germ line VH segment.
Antigen selection and coding capacity As already stated, 2 methods were applied for the estimation of antigen selection in the mutated B cells. The 2 methods agreed in identifying antigen selection criteria in one patient (patient 5). Two other patients (patients 2 and 4) only satisfied the second method criteria. On the contrary, the 3 remaining patients with mutations lacked signs of antigen selection considering both methods. All patients analyzed showed a functional VH rearrangement, devoid of stop codons.Intraclonal nucleotide sequence variation Extensive molecular cloning was applied to search for intraclonal heterogeneity. In 2 patients (patients 2 and 7), the extensively mutated clonal VH gene isolates did not show intraclonal heterogeneity. In patient 7, the analyses were applied to DNA extracted from both lymph node and peripheral blood of the patient, but no confirmed mutation was assessed.In all 4 remaining patients bearing somatic mutations (patients 1, 4, 5, 8), intraclonal variability was documented according to the stringent criteria applied. In patient 4, the investigations were extended to genomic DNA extracted from lymph node and bone marrow samples. This approach allowed us to detect intraclonal variations.
Analyses of antigen-receptor genes in human lymphoma may represent a useful tool in understanding their pathogenesis and clonal history, and it may also produce clinically relevant information.32,33 The present study was undertaken to better define the somatic mutation pattern of immunoglobulin VH genes in nodal MZLs to identify the possible progenitor cells of this tumor. The rare and controversial nature of this entity suggests the need for
stringent diagnostic criteria. In our patients, diagnoses were made
according to the REAL/WHO classification, taking into account (Figure
2) the morphologic (a typical marginal
zone pattern assessed in all patients), immunophenotypical, and
clinical features.
Seven of 8 patients had an immunophenotype clearly consistent with the diagnosis of nodal MZL. The remaining patient (patient 6) exhibited an atypical pattern with concomitant slight CD5 and immunoglobulin D (IgD) expression. However, CD5+ MZLs have already been described,7,34 and the concurrent IgD expression has also been reported in the nodal MZL, although it is more frequent in splenic MZL.35 The main clinical characteristics at diagnosis, including the rate of bone marrow involvement, were consistent with those reported in the literature.36-39 Based on the analysis of the VH gene rearrangements in our
series, nodal MZLs appear as a heterogeneous entity with respect to the
histogenetic derivation. Indeed, MZL seems to arise from different
subsets of marginal zone B cells Previous studies devoted to the genetic analysis of the antigen receptor in nodal MZL have failed to show any intraclonal variability, probably because the approach of amplifying the VH genes from cell populations, followed by direct sequencing of the PCR products, likely prevented the detection of potential ongoing mutations within the tumor cells.21-23 Whether the subsets of nodal MZLs showing intraclonal heterogeneity or homogeneous somatic mutations originate from germinal center cells and post-germinal center cells, respectively, or whether the transforming events may render the cell independent of the influence of germinal center microenvironment is unclear. Because neither nodal MZLs nor extranodal MZLs of MALT type display immunophenotypical characteristics of germinal center cells, it could be speculated that the tumor cells located in the direct vicinity of germinal centers might be affected by the mutation machinery active in these neighboring germinal centers. Analysis of mutations in VH genes can provide insight concerning the role of antigen before or during lymphoma clonal outgrowth.10 All our patients showed a potentially functional VH rearrangement. Six patients had characteristics of the presence of somatic mutations. In one patient, as previously described in normal B cells and in follicular lymphoma,42 insertion events have been observed at the coding region of the VH genes. In one patient bearing somatic mutations, there was evidence of positive selection as demonstrated by analysis of R/S ratios in CDR2 and FW3; the low rate of R mutations in FRW3 also suggested the negative selection of nonfunctional immunoglobulin in this tumor. In 2 other cases the pattern of somatic mutation in FW3 is consistent with the structural conservation of the antigen receptor. These findings represent the prerequisites for the identification of an antigen-driven process in that prolonged exposure to an antigen may play a role in the pathogenesis of the lymphoma. A major question is, what is the responsible antigen. Together with follicular center, diffuse, large B-cell lymphoma and extranodal MZL, monocytoid B-cell lymphoma was most frequently associated with hepatitis C virus (HCV) infection.27,43 Our small series of patients, characterized by low prevalence of HCV infection, cannot give biologic insights into this subject. Several lines of evidence suggest the role of an autoimmune process in the pathogenesis of extranodal MZL,19,20 but no significant data support the role of autoantigens in the growth and persistence of the nodal MZL. In our series, no homologies with known autoantibody sequences were detected, nor was there a preferential usage of the specific VH segments previously involved in autoimmune processes and described in HCV-negative nodal MZLs.27 The heterogeneous pattern of VH gene somatic mutations observed in our series seems to reflect the heterogeneity described in the immunophenotypic profile of primary nodal MZLs, with some cases resembling splenic MZL.35 Interestingly, patient 6, one of the few to lack evidence of somatic mutations, expressed surface IgD. The identification of different subsets of nodal MZLs with respect to the VH mutational status seems to indicate that heterogeneous entities may fall under the definition of nodal MZLs, as already suggested on the basis of the immunophenotypic findings.35 The possible clinical implications of these different geno-phenotypic patterns are still not ascertained and warrant further investigation.
We thank Miss Michela Gisi for her expert technical assistance, Dr Claudio Realini for helpful discussion, Dr Andrea Rossi for help with clinical data, and Dr Lewis Rowett for reviewing the manuscript.
Submitted June 14, 2000; accepted March 15, 2001.
Supported in part by the Fondazione Ticinese per la Ricerca sul Cancro and by the Fondazione "San Salvatore." A.C. is supported by an ESMO Fellowship grant.
The publication costs of this article were defrayed in part by page charge payment. Therefore, and solely to indicate this fact, this article is hereby marked "advertisement" in accordance with 18 U.S.C. section 1734.
Reprints: Emanuele Zucca, Division of Medical Oncology, Oncology Institute of Southern Switzerland, Ospedale San Giovanni, 6500 Bellinzona, Switzerland; e-mail: ielsg{at}ticino.com.
1.
Harris NL, Jaffe ES, Diebold J, et al.
The World Health Organization classification of neoplastic diseases of the hematopoietic and lymphoid tissues: report of the Clinical Advisory Committee meeting, Airlie House, Virginia, November, 1997.
Ann Oncol.
1999;10:1419-1432
2.
Harris NL, Jaffe ES, Stein H, et al.
A revised European-American classification of lymphoid neoplasms: a proposal from International Lymphoma Study Group.
Blood.
1994;84:1361-1392 3. Nathwani BN, Drachenberg MR, Hernandez AM, Levine AM, Sheibani K. Nodal monocytoid B-cell lymphoma (nodal marginal-zone B-cell lymphoma). Semin Hematol. 1999;36:128-138[Medline] [Order article via Infotrieve]. 4. De Wolf-Peeters C, Pittaluga S, Dierlamm J, Wlodarska I, Van Den Berghe H. Marginal zone B-cell lymphomas including mucosa-associated lymphoid tissue type lymphoma (MALT), monocytoid B-cell lymphoma and splenic marginal zone cell lymphoma and their relation to the reactive marginal zone. Leuk Lymphoma. 1997;26:467-478[Medline] [Order article via Infotrieve]. 5. Ortiz-Hidalgo C, Wright DH. The morphological spectrum of monocytoid B-cell lymphoma and its relationship to lymphoma of mucosa-associated lymphoid tissue. Histopathology. 1992;21:555-561[Medline] [Order article via Infotrieve].
6.
Nathwani BN, Anderson JR, Armitage JO, et al.
Marginal zone B-cell lymphoma: a clinical comparison of nodal and mucosa-associated lymphoid tissue types.
J Clin Oncol.
1999;17:2486-2492
7.
Berger F, Felman P, Thieblemont C, et al.
Non-MALT marginal zone B-cell lymphomas: a description of clinical presentation and outcome in 124 patients.
Blood.
2000;95:1950-1956
8.
Dierlamm J, Pittaluga S, Wlodarska I, et al.
Marginal zone B-cell lymphomas of different sites share similar cytogenetic and morphologic features.
Blood.
1996;87:299-307
9.
Rosenwald A, Ott G, Stilgenbauer S, et al.
Exclusive detection of the t(11;18)(q21;q21) in extranodal marginal zone B-cell lymphomas (MZBL) of MALT type in contrast to other MZBL and extranodal large B cell lymphomas.
Am J Pathol.
1999;155:1817-1821 10. Rajewsky K. Clonal selection and learning in the antibody system. Nature. 1996;381:751-758[CrossRef][Medline] [Order article via Infotrieve].
11.
Meffre E, Papavasiliou F, Cohen P, et al.
Antigen receptor engagement turns off the V(D)J recombination machinery in human tonsil B cells.
J Exp Med.
1998;188:765-772 12. Spencer J, Dunn-Walters DK. Somatic hypermutation and B-cell malignancies. J Pathol. 1999;187:158-163[CrossRef][Medline] [Order article via Infotrieve]. 13. Kuppers R, Zhao M, Hansman ML, Rajewsky K. Tracing B-cell development in human germinal centres by molecular analysis of single cells picked from histological sections. EMBO J. 1993;12:4955-4967[Medline] [Order article via Infotrieve].
14.
Kuppers R, Klein U, Hansmann ML, Rajewsky K.
Cellular origin of human B-cell lymphomas.
N Engl J Med.
1999;341:1520-1529 15. Klein U, Goossens X, Fischer M, et al. Somatic hypermutation in normal and transformed human B cells. Immunol Rev. 1998;162:261-280[CrossRef][Medline] [Order article via Infotrieve]. 16. Hussel T, Isaacson PG, Crabtree JE, Spencer J. The response of cells from low-grade B-cell gastric lymphoma of mucosa associated lymphoid tissue to Helicobacter pylori. Lancet. 1993;342:571-574[CrossRef][Medline] [Order article via Infotrieve].
17.
Qin Y, Greiner A, Trunk MJ, Schaumausser B, Ott MM, Müller-Hermelink HK.
Somatic hypermutation in low-grade mucosa associated lymphoid tissue-type B-cell lymphoma.
Blood.
1995;86:3528-3534 18. Du M, Diss TC, Xu C, Peng H, Isaacson PG, Pan L. Ongoing mutation in MALT lymphoma immunoglobulin gene suggests that antigen stimulation plays a role in the clonal expansion. Leukemia. 1996;10:1190-1197[Medline] [Order article via Infotrieve]. 19. Zucca E, Bertoni F, Roggero E, et al. Autoreactive B cell clones in marginal-zone B cell lymphoma (MALT lymphoma) of the stomach. Leukemia. 1998;12:247-253[CrossRef][Medline] [Order article via Infotrieve]. 20. Isaacson PG. Mucosa associated lymphoid tissue lymphoma. Semin Oncol. 1999;36:139-147. 21. Küppers R, Hajadi M, Plank L, Rajewsky K, Hansmann ML. Molecular Ig gene analysis reveals that monocytoid B cell lymphoma is a malignancy of mature B cells carrying somatically mutated V region genes and suggests that rearrangement of the kappa-deleting element (resulting in deletion of the Ig kappa enhancers) abolishes somatic hypermutation in the human. Eur J Immunol. 1996;26:1794-1800[Medline] [Order article via Infotrieve].
22.
Tierens A, Delabie J, Pittaluga S, Driessen A, De Wolf-Peeters.
Mutation analysis of the rearranged immunoglobulin heavy chain genes of marginal zone cell lymphomas indicates an origin from different marginal zone B lymphocytes subsets.
Blood.
1998;91:2381-2386 23. Miranda RN, Cousar JB, Hammer RD, Collins RD, Vnencak-Jones CL. Somatic mutation analysis of IgH variable regions reveals that tumor cells of most parafollicular (monocytoid) B-cell lymphoma, splenic marginal zone B-cell lymphoma, and some hairy cell leukemia are composed of memory B lymphocytes. Hum Pathol. 1999;30:306-312[CrossRef][Medline] [Order article via Infotrieve]. 24. Diss TC, Peng H, Wotherspoon AC, Isaacson PG, Pan L. Detection of monoclonality in low-grade B-cell lymphomas using the polymerase chain reaction is dependent on primer selection and lymphoma type. J Pathol. 1993;169:291-295[CrossRef][Medline] [Order article via Infotrieve].
25.
Lossos IS, Okada CY, Tibshirani R, et al.
Molecular analysis of immunoglobulin genes in diffuse large B-cell lymphomas.
Blood.
2000;95:1797-1803
26.
Stein K, Hummel M, Korbjuhn P, et al.
Monocytoid B cells are distinct from splenic marginal zone cells and commonly derive from unmutated naive B cells and less frequently from postgerminal center B cells by polyclonal transformation.
Blood.
1999;94:2800-2808 27. Luppi M, Marasca R, Longo G, et al. Clinico-pathologic features of HCV-related B NHL [abstract 26]. Proceedings of the NIH Workshop: Cells of the Marginal Zone: Origins, Function and Neoplasia; April 17-18, 2000; Bethesda, MD. 28. Corbett SJ, Tomlinson IM, Sonnhammer ELL, Buck D, Winter G. Sequence of the human immunoglobulin diversity (D) segment locus: a systematic analysis provides no evidence for the use of DIR segments, inverted D segments, "minor" D segments or D-D recombination. J Mol Biol. 1997;270:587-597[CrossRef][Medline] [Order article via Infotrieve]. 29. Bertoni F, Cazzaniga G, Bosshard G, et al. Immunoglobulin heavy chain diversity genes rearrangement pattern indicates that MALT-type gastric lymphoma B-cells have undergone an antigen selection process. Br J Haematol. 1997;97:830-836[CrossRef][Medline] [Order article via Infotrieve].
30.
Brezinschek HP, Foster SJ, Brezinschek RI, et al.
Analysis of the human VH gene repertoire: differential effects of selection and somatic hypermutation on human peripheral CD5(+)/IgM+ and CD5(
31.
Goossens T, Klein U, Küppers R.
Frequent occurrence of deletions and duplications during somatic hypermutation: implications for oncogene translocations and heavy chain disease.
Proc Natl Acad Sci U S A.
1998;95:2463-2468
32.
Hamblin TJ, Davis Z, Gardiner A, Oscier DG, Stevenson FK.
Unmutated Ig V(H) genes are associated with a more aggressive form of chronic lymphocytic leukemia.
Blood.
1999;94:1848-1854
33.
Damle RN, Wasil T, Fais F, et al.
IgV gene mutation status and CD38 expression as novel prognostic indicators in chronic lymphocytic leukemia.
Blood.
1999;94:1840-1847 34. Ballesteros E, Osborne BM, Matsushima AY. CD5+ low-grade marginal zone B-cell lymphomas with localized presentation. Am J Surg Pathol. 1998;22:201-207[CrossRef][Medline] [Order article via Infotrieve]. 35. Campo E, Miquel R, Krenacs L, Sorbara L, Raffeld M, Jaffe ES. Primary nodal marginal zone lymphomas of splenic and MALT type. Am J Surg Pathol. 1999;23:59-68[CrossRef][Medline] [Order article via Infotrieve]. 36. Nodal and splenic marginal zone B-cell lymphomas. In: Armitage JO,Cavalli F,Longo DL, eds. Text Atlas of Lymphomas. London, UK: Martin Dunitz; 1999:123-131.
37.
Cogliatti SB, Lennert K, Hansmann ML, Zwingers TL.
Monocytoid B cell lymphoma: clinical and prognostic features of 21 patients.
J Clin Pathol.
1990;43:619-625
38.
Non-Hodgkin's Lymphoma Classification Project.
A clinical evaluation of the International Lymphoma Study Group classification of non-Hodgkin's lymphoma.
Blood.
1997;89:3909-3918
39.
Fisher RI, Dahlberg S, Nathwani BN, Banks PM, Miller TP, Grogan TM.
A clinical analysis of two indolent lymphoma entities: mantle cell lymphoma and marginal zone lymphoma (including the mucosa-associated lymphoid tissue and monocytoid B-cell subcategories): a Southwest Oncology Group Study.
Blood.
1995;85:1075-1082
40.
Tierens A, Delabie J, Michiels L, Vandenberghe P, De Wolf-Peeters C.
Marginal-zone B cells in the human lymph node and spleen show somatic hypermutations and display clonal expansion.
Blood.
1999;93:226-234 41. Garcia De Vinuesa C, Hsieh SP, Cook M, MacLennan I. Three pathways of recruitment of B cells into the marginal zone [abstract 11]. Proceedings of the NIH Workshop: Cells of the Marginal Zone: Origins, Function and Neoplasia; April 17-18, 2000; Bethesda, MD. 42. Noppe SM, Heirman C, Bakkus MH, et al. The genetic variability of VH genes in follicular lymphoma: the impact of the hypermutation mechanism. Br J Haematol. 1999;107:625-640[CrossRef][Medline] [Order article via Infotrieve].
43.
Zuckerman E, Zuckerman T, Levine AM, et al.
Hepatitis C virus infection in patients with B-cell non-Hodgkin lymphoma.
Ann Intern Med.
1997;127:423-428 44. V-Base database. Available at: http://www.mrc-cpe.cam.ac.uk/imt-doc/public. Accessed May 2000.
45. IgBlast. National Center for Biotechnology Information Web site.
Available at: http://www.ncbi.
© 2001 by The American Society of Hematology.
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  M. E. Salama, I. S. Lossos, R. A. Warnke, and Y. Natkunam Immunoarchitectural Patterns in Nodal Marginal Zone B-Cell Lymphoma: A Study of 51 Cases Am J Clin Pathol, July 1, 2009; 132(1): 39 - 49. [Abstract] [Full Text] [PDF]
|
|
|
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 |
|
 B. Kahl and D. Yang Marginal Zone Lymphomas: Management of Nodal, Splenic, and MALT NHL Hematology, January 1, 2008; 2008(1): 359 - 364. [Abstract] [Full Text] [PDF]
|
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|
|
 |
|
 Y. Natkunam, I. S. Lossos, B. Taidi, S. Zhao, X. Lu, F. Ding, A. S. Hammer, T. Marafioti, G. E. Byrne Jr, S. Levy, et al. Expression of the human germinal center-associated lymphoma (HGAL) protein, a new marker of germinal center B-cell derivation Blood, May 15, 2005; 105(10): 3979 - 3986. [Abstract] [Full Text] [PDF]
|
|
|
|
 |
|
 M. Kojima, S. Nakamura, T. Murase, T. Motoori, K. Murayama, M. Iijima, H. Itoh, N. Sakata, and N. Masawa Follicular Colonization of Nodal Marginal-Zone B-Cell Lymphoma Resembling Follicular Lymphoma: Report of 6 Cases International Journal of Surgical Pathology, January 1, 2005; 13(1): 73 - 78. [Abstract] [PDF]
|
|
|
|
 |
|
 S. A. Pileri, P. L. Zinzani, P. Went, A. Pileri Jr, and M. Bendandi Indolent lymphoma: the pathologist's viewpoint Ann. Onc., January 1, 2004; 15(1): 12 - 18. [Abstract] [Full Text] [PDF]
|
|
|
|
 |
|
 A. Tierens, J. Delabie, A. Malecka, J. Wang, A. Gruszka-Westwood, D. Catovsky, and E. Matutes Splenic Marginal Zone Lymphoma with Villous Lymphocytes Shows On-Going Immunoglobulin Gene Mutations Am. J. Pathol., February 1, 2003; 162(2): 681 - 689. [Abstract] [Full Text] [PDF]
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F. Bertoni, A. Conconi, C. Capella, T. Motta, R. Giardini, M. Ponzoni, E. Pedrinis, D. Novero, P. Rinaldi, G. Cazzaniga, et al. Molecular follow-up in gastric mucosa-associated lymphoid tissue lymphomas: early analysis of the LY03 cooperative trial Blood, April 1, 2002; 99(7): 2541 - 2544. [Abstract] [Full Text] [PDF]
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Abstract
Introduction
)/IgM+ B cells.
J Clin Invest.
1997;99:2488-2501