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Highly Restricted Usage of Immunoglobulin Light Chain IGKV3-20 with Stereotyped Sequence in Primary Cold-Agglutinin Disease (CAD)

Malecka, Agnieszka ; Trøen, Gunhild ; Tierens, Anne ; [et al.]

American Society of Hematology ; 2015

In: Blood Vol. 126, No. 23 ( 2015-12-03), p. 4137-4137

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In: Blood, American Society of Hematology, Vol. 126, No. 23 ( 2015-12-03), p. 4137-4137

Abstract: Primary cold agglutinin disease (CAD) is a type of hemolytic anemia mediated by anti-I autoantibodies. Patients suffer from anemia as well as circulatory problems. However, the severity of disease differs greatly between patients. We recently demonstrated that primary CAD is caused by an underlying low grade B cell lymphoproliferative disease of the bone marrow with a typical histology that is different from lymphoplasmacytic lymphoma and, accordingly, does not display the MYD88 L265P mutation (Randen et al., Haematologica, 2013). The majority of patients display circulating monoclonal antibodies encoded by the immunoglobulin heavy chain gene IGHV4-34. The disease severity does not correlate with antibody titers, but seems to be determined by the thermal amplitude, i.e., the highest temperature at which the cold agglutinin binds to the antigen. The framework region 1 of IGHV4-34 encodes for a sequence that binds to I antigen. However, this does not explain the molecular basis of disease heterogeneity. We studied 27 patients with well-characterized primary CAD and sequenced immunoglobulin heavy as well as immunoglobulin light chains to find additional consensus regions that may determine anti-I reactivity. Bone marrow aspirates, or frozen bone marrow trephine biopsies and blood from 27 patients with well-documented primary CAD were collected. Monoclonal B cells were isolated by flow sorting (FACS Aria Ilu High speed sorter, Becton Dickinson). Viable cells were detected using the forward scatter versus side scatter dot plot. Subsequently, CD45 bright events with low side scatter features representing lymphocytes, were selected. Then, CD5 positive and CD19 negative events, i.e. T cells, were gated out using a CD5 versus CD19 dot plot leaving only B cells. Finally, monoclonal B cells were selected using the immunoglobulin light chain gate, either k or l. Clonally rearranged IGH genes were detected using the Somatic Hypermutation Assay v2.0 (Invivoscribe) and were then sequenced. Immunoglobulin light chain genes (IGL) were amplified by an in-house diagnostic protocol based on Biomed-2 primers (van Dongen et al., Leukemia, 2003). All sequences were analyzed using the IMGT database (www.imgt.org). Productive IGHV4-34 gene rearrangements were identified in 22/27 patients. In 4 patients, no productive rearrangement was identified, while in one patient a productive IGHV3-23 was seen. No significant homology of complementarity determining region 3 (CDR3) regions was found between IGHV sequences. The N-glycosylation sequence within the CDR2 region, affecting antigen-binding, was mutated in 8 patients whereas no mutations were present in 7 patients and mutations in flanking residues were seen in 6 patients. The latter mutations may modulate glycosylation efficacy. Clonal rearrangement of the IGKV3-20 was detected in 16/27 patients, clonal IGKV3-15 gene rearrangements were identified in 4/27 patients whereas other IGL genes were rearranged in 4/27 patients. No clonal IGL gene rearrangement was found in 3/27 patients. Of interest, 7 of the patients with IGKV3-20 rearrangement displayed highly homologous CDR3 regions. The latter was highly associated with an un-mutated N-glycosylation sequence of the respective IGHV4-34 sequence. In conclusion, our data show that in addition to IGHV, also IGLV usage is highly restricted in CAD. Furthermore, stereotyped IGLV sequences are seen that are mutually exclusive with mutated N-glycosylation sequences in the IGHV CDR2 sequence. These data indicate that multiple regions within the immunoglobulin heavy chain as well as immunoglobulin light chain contribute to I-antigen binding. The data suggest that subtle differences in these multiple binding sequences may contribute to the differences in thermal amplitude of I antigen binding of the antibody. The highly restricted usage of IGKV3-20 provides a rationale for vaccination with IGKV3-20 proteins, known to be immunogenic and being considered for treatment in other lymphoproliferative diseases (Martorelli et al., Clin Cancer Res, 2012). Disclosures No relevant conflicts of interest to declare.

Type of Medium: Online Resource

ISSN: 0006-4971 , 1528-0020

URL: Article

DOI: 10.1182/blood.V126.23.4137.4137

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Language: English

Publisher: American Society of Hematology

Publication Date: 2015

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Gene Expression Analysis Reveals Downregulation of Complement Receptor 1 in Cold Agglutinin Disease

Malecka, Agnieszka ; Ostlie, Ingunn ; Trøen, Gunhild ; [et al.]

American Society of Hematology ; 2022

In: Blood Vol. 140, No. Supplement 1 ( 2022-11-15), p. 6419-6420

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In: Blood, American Society of Hematology, Vol. 140, No. Supplement 1 ( 2022-11-15), p. 6419-6420

Type of Medium: Online Resource

ISSN: 0006-4971 , 1528-0020

URL: Article

DOI: 10.1182/blood-2022-156489

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Language: English

Publisher: American Society of Hematology

Publication Date: 2022

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Patients with high-risk DLBCL benefit from dose-dense immunochemotherapy combined with early systemic CNS prophylaxis

Leppä, Sirpa ; Jørgensen, Judit ; Tierens, Anne ; [et al.]

American Society of Hematology ; 2020

In: Blood Advances Vol. 4, No. 9 ( 2020-05-12), p. 1906-1915

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In: Blood Advances, American Society of Hematology, Vol. 4, No. 9 ( 2020-05-12), p. 1906-1915

Abstract: Survival of patients with high-risk diffuse large B-cell lymphoma (DLBCL) is suboptimal, and the risk of central nervous system (CNS) progression is relatively high. We conducted a phase 2 trial in 139 patients aged 18 to 64 years who had primary DLBCL with an age-adjusted International Prognostic Index (aaIPI) score of 2 to 3 or site-specific risk factors for CNS recurrence. The goal was to assess whether a dose-dense immunochemotherapy with early systemic CNS prophylaxis improves the outcome and reduces the incidence of CNS events. Treatment consisted of 2 courses of high-dose methotrexate in combination with biweekly rituximab (R), cyclophosphamide, doxorubicin, vincristine, and prednisone (R-CHOP-14), followed by 4 courses of R-CHOP-14 with etoposide (R-CHOEP) and 1 course of high-dose cytarabine with R. In addition, liposomal cytarabine was administered intrathecally at courses 1, 3, and 5. Coprimary endpoints were failure-free survival and CNS progression rates. Thirty-six (26%) patients experienced treatment failure. Progression occurred in 23 (16%) patients, including three (2.2%) CNS events. At 5 years of median follow-up, failure-free survival, overall survival, and CNS progression rates were 74%, 83%, and 2.3%, respectively. Treatment reduced the risk of progression compared with our previous trial, in which systemic CNS prophylaxis was given after 6 courses of biweekly R-CHOEP (hazard ratio, 0.49; 95% CI, 0.31-0.77; P = .002) and overcame the adverse impact of an aaIPI score of 3 on survival. In addition, outcome of the patients with BCL2/MYC double-hit lymphomas was comparable to the patients without the rearrangements. The results are encouraging, with a low toxic death rate, low number of CNS events, and favorable survival rates. This trial was registered at www.clinicaltrials.gov as #NCT01325194.

Type of Medium: Online Resource

ISSN: 2473-9529 , 2473-9537

URL: Article

DOI: 10.1182/bloodadvances.2020001518

Language: English

Publisher: American Society of Hematology

Publication Date: 2020

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Cold agglutinin–associated B-cell lymphoproliferative disease shows highly recurrent gains of chromosome 3 and 12 or 18

Małecka, Agnieszka ; Delabie, Jan ; Østlie, Ingunn ; [et al.]

American Society of Hematology ; 2020

In: Blood Advances Vol. 4, No. 6 ( 2020-03-24), p. 993-996

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In: Blood Advances, American Society of Hematology, Vol. 4, No. 6 ( 2020-03-24), p. 993-996

Type of Medium: Online Resource

ISSN: 2473-9529 , 2473-9537

URL: Article

DOI: 10.1182/bloodadvances.2020001608

Language: English

Publisher: American Society of Hematology

Publication Date: 2020

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The mutational landscape of cold agglutinin disease: CARD11 and CXCR4 mutations are correlated with lower hemoglobin levels

Małecka, Agnieszka ; Trøen, Gunhild ; Delabie, Jan ; [et al.]

Wiley ; 2021

In: American Journal of Hematology Vol. 96, No. 8 ( 2021-08)

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In: American Journal of Hematology, Wiley, Vol. 96, No. 8 ( 2021-08)

Type of Medium: Online Resource

ISSN: 0361-8609 , 1096-8652

URL: Issue

URL: Article

DOI: 10.1002/ajh.v96.8

DOI: 10.1002/ajh.26205

Language: English

Publisher: Wiley

Publication Date: 2021

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NEIL3-Dependent Regulation of Cardiac Fibroblast Proliferation Prevents Myocardial Rupture

Olsen, Maria B. ; Hildrestrand, Gunn A. ; Scheffler, Katja ; [et al.]

Elsevier BV ; 2017

In: Cell Reports Vol. 18, No. 1 ( 2017-01), p. 82-92

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In: Cell Reports, Elsevier BV, Vol. 18, No. 1 ( 2017-01), p. 82-92

Type of Medium: Online Resource

ISSN: 2211-1247

URL: Article

DOI: 10.1016/j.celrep.2016.12.009

Language: English

Publisher: Elsevier BV

Publication Date: 2017

detail.hit.zdb_id: 2649101-1

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The Mutational Landscape of Cold Agglutinin Disease

Malecka, Agnieszka ; Trøen, Gunhild ; Delabie, Jan ; [et al.]

American Society of Hematology ; 2020

In: Blood Vol. 136, No. Supplement 1 ( 2020-11-5), p. 14-15

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In: Blood, American Society of Hematology, Vol. 136, No. Supplement 1 ( 2020-11-5), p. 14-15

Abstract: Primary cold agglutinin disease (CAD) is a rare autoimmune hemolytic anemia mediated by monoclonal IgM autoantibodies directed against the I antigen on erythrocytes. CAD is due to a B-cell lymphoproliferative disorder of the bone marrow. We have previously reported recurrentKMT2DandCARD11mutations and trisomy 3 and 12 or 18 in CAD patients (Malecka et al., 2018 & 2020). In addition, we have revealed that the cold-reactive antibody is highly stereotyped (Malecka et al., 2016). In this study, we present new and detailed data on the mutation landscape of CAD patients. We have analyzed the bone marrow from 14 patients with CAD, included in a recent clinical trial (Berentsen et al., 2017), by whole exome sequencing. Clonal B cells and normal T cells (normal control) were acquired using fluorescence-activated cell sorting. The data from whole exome sequencing were aligned to the human genome hg38 and analyzed as described before (Malecka et al., 2020). Variant discovery and functional annotation were performed with the use of GATK4 tools: Mutect2 and Funcotator. Detected mutations were validated manually using IGV browser. The total amount of non-synonymous mutations detected in each CAD sample ranged from 13 to 62, while the total amount of all mutations in the exome regions ranged from 36 to 163 (Figure 1A). Four genes showed non-synonymous mutations in 3 or more cases, these are:KMT2D(8/14; 57%),IGLL5(5/14; 36%),CARD11(3/14; 21%),CXCR4(3/14; 21%) (Figure 1B and Table 1). Additionally, several genes showed non-synonymous mutations in 2 of the 14 cases (14%):PHLDB1, HIST1H1E, LPIN3, LTB, MACF1, NBEA, NEFH, PCNX2, RRAGC, TMPRSS7, ZNF618(Figure 1B). A majority of these genes are also found mutated in lymphoma. All patients with eitherCARD11orCXCR4mutations have concurrentKMT2Dmutations. One patient has bothCARD11andCXCR4mutations together withKMT2Dmutation. Recurrent mutations seem to cluster in some of the cases (Figure 1C). Almost all patients with aKMT2Dmutation (7/8, 87%) have at least 3 other recurrent mutations. Patients with aCARD11(3 cases) or aCXCR4(3 cases) mutation have at least 3 other recurrent mutations. KMT2Dmutations are found in many lymphomas and are associated with Kabuki syndrome. It is suggested thatKMT2Dis a tumor suppressor gene, andKMT2Dmutations might act as driver mutations in many lymphomas. In addition,CARD11mutations in our cases are located in coiled-coil domain in exon 6, and therefore it is expected to result in NF-kB activation (Malecka et al. 2018).IGLL5is located in the IG lambda locus. The function of theIGLL5gene is unknown, but it is homologues to theIGLL1gene known to be important in B cell development.IGLL5mutations are seen in lymphoma as well as other malignancies and might have some prognostic value in diseases like multiple myeloma.CXCR4has been implicated in the migration and trafficking of malignant B cells in several hematological malignancies.CXCR4mutations are frequently seen in lymphoplasmacytic lymphoma, and almost always in combination with aMYD88mutation. In our series, aCXCR4mutation always occurs in combination with aKMT2Dmutation.MYD88was not found to be mutated. Detected mutations in theCXCR4gene are of potential therapeutic interest, sinceCXCR4inhibitors exist. CAD patients with aKMT2Dmutation associated with other recurrent mutations (Figure 1C), show a trend to lower hemoglobin levels at diagnosis compared to patients with noKMT2Dmutation or patients withKMT2Dmutation without other recurrent mutations. We are currently working on sequencing clonal B cells from additional patients in order to confirm these findings. In conclusion, CAD-associated lymphoproliferative disease shows a relatively low mutation burden. but with recurrent gene mutations. The most common recurrent mutations are in genes known to be involved in lymphoma development. Our preliminary data suggest thatKMT2Dmutation associated with other recurrent mutations might determine severity of hemolysis. Disclosures Tierens: Amgen:Membership on an entity's Board of Directors or advisory committees;Jazz Pharmaceuticals:Membership on an entity's Board of Directors or advisory committees;Astellas Pharma:Membership on an entity's Board of Directors or advisory committees.Berentsen:Mundipharma:Research Funding;Apellis Pharmaceuticals:Consultancy, Other: lecture honoraria;Bioverativ:Consultancy, Other: lecture honoraria;Janssen-Cilag:Other: lecture honoraria;Momenta Pharmaceuticals:Consultancy;True North Therapeutics:Other: lecture honoraria;Alexion Pharmaceuticals, Inc,:Other: lecture honoraria.Tjønnfjord:Mundipharma:Other: A grant from Mundipharma to cover the expenses of bendamustine for the CAD5 study.

Type of Medium: Online Resource

ISSN: 0006-4971 , 1528-0020

URL: Article

DOI: 10.1182/blood-2020-133760

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Language: English

Publisher: American Society of Hematology

Publication Date: 2020

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Cold Agglutinin Disease Shows Highly Recurrent Gains of Chromosome 3, 12 and 18

Malecka, Agnieszka ; Delabie, Jan ; Ostlie, Ingunn ; [et al.]

American Society of Hematology ; 2019

In: Blood Vol. 134, No. Supplement_1 ( 2019-11-13), p. 1488-1488

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In: Blood, American Society of Hematology, Vol. 134, No. Supplement_1 ( 2019-11-13), p. 1488-1488

Abstract: Cold agglutinin disease (CAD) is a rare autoimmune hemolytic anemia, caused by a distinct type of B-cell lymphoproliferative disease of the bone marrow. Anemia is mediated by binding of monoclonal cold agglutinin antibodies to the erythrocyte surface I antigen at temperatures below central body temperature, followed by agglutination and complement activation. These antibodies are almost exclusively encoded by IGHV4-34. We recently found recurrent KMT2D and CARD11 gene mutations in CAD (Malecka, et al 2017). We analyzed 12 CAD samples from the CAD-5 study (NCT02689986) (Berentsen, et al 2017) using Affymetrix OncoScan CNV Plus Assay and exome sequencing data in order to detect chromosomal aberrations. All samples were sorted using fluorescence activated cell sorting prior to analysis. Complete or partial gain of chromosome 3 (+3 or +3q) was detected in all samples (Table 1). Additionally, most cases showed either gain of chromosome 12 or 18 (9/12) (Table 1). Additional small regions of recurrent gain or loss were also detected in other chromosomes. The recurrent changes in least 4 samples are: +1p36.31-p36.13, -8p21.3-p21.2, +9q34.2-q34.3, +11q13.1-q13.2, +17q25.3, +21q22.3, +22q13.31-q13.33. Gains and losses of large parts of chromosomes are clearly visible in both Affymetrix OncoScan CNV Plus Assay and exome sequencing data (Figure 1). In contrast smaller changes are often not visible in exome sequencing data and therefore could not be fully validated. Further validation will be required for smaller chromosomal changes. Gain of chromosome 3/3q was characteristic for all CAD cases analyzed. Gain of chromosome 3 in CAD has previously been reported in 9 of 26 patients (Gordon, et al 1990, Michaux, et al 1995). Gain of chromosome 3 is not a highly recurrent finding in most B-cell lymphomas with the exception of marginal zone lymphoma (MZL). Of interest, gain of chromosome 12 and 18, demonstrated in our study, is also a feature of MZL. These findings, together with our previous findings (Malecka, et al 2017), suggest that the CAD-associated lymphoproliferative disease, although exclusively present in the bone marrow, might be related to MZL. The CAD-5 study assessed the efficacy of bendamustine plus rituximab in CAD patients. We explored whether a correlation existed between presence or absence of trisomy 12 and 18 with response to therapy. Although the series is small, we found a trend towards poorer response in patients with trisomy 18 compared to patients with trisomy 12. Furthermore, both patients without trisomy 12 or 18 had the best responses (Table 1). Despite the limited number of cases the Pearson correlation was statistically significant (p=0.02). However, more samples need to be analyzed to confirm these results. A correlation between response to therapy and presence of trisomy 12 or 18 has previously been demonstrated for other B-cell lymphomas. Trisomy 12 is frequent in patients with small lymphocytic lymphoma (28-36%) and in chronic lymphocytic leukemia (10-25%) and in the latter +12 is associated with intermediate prognosis (Autore, et al 2018). Trisomy 3 and 18 are found to be correlated with advanced stage extranodal marginal zone lymphoma (Krugmann, et al 2005). There is evidence from previous studies that trisomy 18 may be associated with upregulation of BCL2, an anti-apoptotic gene located on chromosome 18. Whether BCL2 is upregulated in CAD with trisomy 18 and whether it might be the cause of therapy resistance, needs to be investigated. Such a study is of importance since BCL2 inhibitors might be considered to improve treatment responses. We conclude that gain of chromosome 3 is a highly recurrent finding in CAD-associated lymphoproliferative disease. Further gain of chromosome 12 and 18 might be predictors of therapy outcome. These genetic findings are similar to what has previously been demonstrated in nodal and extranodal MZL, suggesting that CAD-associated lymphoproliferative disease, a disease of the bone marrow, might be related to MZL. Disclosures Berentsen: Mundipharma: Research Funding; Apellis, Bioverativ (a Sanofi company), Momenta Pharmaceuticals, and True North Therapeutics: Consultancy; Alexion, Apellis, and Janssen-Cilag: Honoraria. Tjønnfjord:Mundipharma: Research Funding.

Type of Medium: Online Resource

ISSN: 0006-4971 , 1528-0020

URL: Article

DOI: 10.1182/blood-2019-121750

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Language: English

Publisher: American Society of Hematology

Publication Date: 2019

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High Frequency of Somatic Mutations of KMT2D and CARD11 Genes in Cold Agglutinin Disease

Malecka, Agnieszka ; Trøen, Gunhild ; Tierens, Anne ; [et al.]

American Society of Hematology ; 2016

In: Blood Vol. 128, No. 22 ( 2016-12-02), p. 2934-2934

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In: Blood, American Society of Hematology, Vol. 128, No. 22 ( 2016-12-02), p. 2934-2934

Abstract: Primary cold agglutinin disease (CAD) is a hemolytic anemia mediated by monoclonal anti-I autoantibodies. CAD is caused by an underlying low grade B-cell lymphoproliferative disease of the bone marrow with a typical histology that is different from lymphoplasmacytic lymphoma and, accordingly, does not display the MYD88 L265P mutation (Randen et al., Haematologica, 2014). Since CAD is a clonal lymphoproliferative disorder, we studied the mutational landscape to further characterize the disease and identify potential novel treatment approaches. We prospectively collected bone marrow samples of CAD patients, enrolled in a clinical trial (CAD5; www.clinicaltrials.gov, NCT02689986). Exome sequencing of six cases was performed and findings were confirmed in ten additional cases using targeted sequencing. For these analyses, clonal B cells and normal T cells, used as control, were purified from bone marrow samples using fluorescent activated cell sorting. All mutations were verified by Sanger sequencing. Whole-exome sequencing was performed at BGI Tech Solutions (Hongkong) using the Agilent SureSelect Human All Exon V4 Reagent Kit and Illumina HiSeq technology. The bioinformatics pipeline consistent of BWA alignment tool (aligned to hg19); Picard tools FixMateInformation and MarkDuplicates; the Genome Analysis Toolkit (GATK) IndelRealigner and BaseRecalibrator; somatic variant detection tools Strelka, MuTect and Pindel; the annotation tool SnpEff. Recurrent somatic mutations were found in KMT2D (11/16 cases, 69%) and CARD11 (5/16, 31%) (Table 1, Figure 1-2). 7/16 (44%) of KMT2D mutations were deemed high impact mutations by SnpEff and to result in inactive protein. 2/16 (12,5%) of KMT2D mutations are missense mutations and are predicted to impair SET domain function. 2/16 (12,5%) of KMT2D mutations are classified by SnpEff as low impact mutations of which functional tests are necessary to demonstrate potential consequences for protein function. Of interest, two additional patients showed rare germline KMT2D variants that have also been seen in Kabuki syndrome patients, although these patients do not have Kabuki syndrome. CARD11 was somatically mutated in 5/16 (31%) cases. Four of those patients had a concurrent KMT2D mutation. All CARD 11 mutations were classified as moderate impact mutations by SnpEff. Mutations were tightly clustered in a 20bp sequence of the coiled-coil domain sequence (Table 1, Figure 2). KMT2D is a histone lysine methyl transferase that represses B cell lymphoma development. Mono-allelic mutations of KMT2D seem to act in a dominant fashion and cause partial loss of protein expression with cell growth advantage. KMT2D is frequently mutated in follicular lymphoma, diffuse large B cell lymphoma and nodal marginal zone lymphoma. Mono-allelic constitutional mutations cause Kabuki syndrome, characterized by distinct facial characteristics and multiple organ malformations. Patients frequently develop immune-mediated thrombocytopenia as well as auto-immune hemolytic anemia. CARD11 coiled-coil domain mutations result in constitutive NF-kB activation and enhanced NF-kB activity upon antigen receptor stimulation. Mutations were previously detected in diffuse large B cell lymphomas of activated B cell origin. Mono-allelic CARD11 coiled coil mutations are not oncogenic per se in mice and humans, but result in B-cell proliferation and auto-antibody production. Since four CAD patients showed concurrent KMT2D and CARD11 mutations, it seems likely that the mutations act in concert with anti-I B-cell receptor stimulation to contribute to CAD-associated lymphoproliferative disease. In conclusion, we demonstrated a high frequency of KMT2D and CARD11 mutations in the bone marrow B cell lymphoproliferative disease of patients with CAD. These results confirm that CAD-associated B cell lymphoproliferative disease is a distinct disease different from other known B cell lymphoproliferative diseases of the bone marrow, most notably lymphoplasmacytic lymphoma. The identification of these recurrent mutations in CAD may allow the design of novel treatment modalities. Table 1 Mutations in KMT2D and CARD11 gene in CAD. Table 1. Mutations in KMT2D and CARD11 gene in CAD. Figure 1 Mutations within KMT2D gene and protein detected in CAD patients. Figure 1. Mutations within KMT2D gene and protein detected in CAD patients. Figure 2 Mutations within CARD11 protein detected in CAD patients. Figure 2. Mutations within CARD11 protein detected in CAD patients. Disclosures No relevant conflicts of interest to declare.

Type of Medium: Online Resource

ISSN: 0006-4971 , 1528-0020

URL: Article

DOI: 10.1182/blood.V128.22.2934.2934

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Language: English

Publisher: American Society of Hematology

Publication Date: 2016

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Dose-Dense Chemoimmunotherapy Including Early CNS Prophylaxis for High-Risk DLBCL. -Final Analysis from a Nordic Phase II Study (the CHIC trial)

Leppa, Sirpa ; Joergensen, Judit ; Tierens, Anne ; [et al.]

American Society of Hematology ; 2016

In: Blood Vol. 128, No. 22 ( 2016-12-02), p. 1854-1854

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In: Blood, American Society of Hematology, Vol. 128, No. 22 ( 2016-12-02), p. 1854-1854

Abstract: Introduction: Survival of patients with high-risk diffuse large B-cell lymphoma (DLBCL) is suboptimal, and the risk of early central nervous system (CNS) progression is high. Here we present the final results from a Nordic phase II study, where dose-dense chemoimmunotherapy including early systemic CNS prophylaxis with high dose methotrexate (HD-Mtx), further intensified by intrathecally (IT) administered liposomal cytosine arabinoside (AraC), was given. Patients and methods: Inclusion criteria were age 18-65 years, de novo DLBCL or grade 3B follicular lymphoma without clinical, radiological or cytological signs of CNS involvement, age adjusted IPI 2-3, WHO performance score 0-3, and/or anatomical sites related to increased risk for CNS recurrence (e.g. testis, facial sinuses, orbita). Treatment consisted of two courses of HD-Mtx in combination with R-CHOP14, followed by four courses of R-CHOEP14 and one course of R-HD-AraC. Liposomal AraC was administered IT at courses 1, 3 and 5 (omitted during a period of production halt). Primary end points were failure free survival (FFS; disease progression, discontinuation of protocolled therapy due to toxicity, death from any cause) and CNS progression rate at 18 months. Among the secondary endpoints were the identification of biological risk factors for high risk disease and prognostic role of cerebrospinal fluid (CSF) cytology-/flow cytometry (FC)+for CNS recurrence. Results: Of the accrued 143 patients, 140 met the inclusion criteria and were evaluable for baseline characteristics and primary endpoints. Of these, 132 had a complete set of treatment data. The male/female ratio was 1.7 and the median age 56 years (range 20-64). The majority of the patients had DLBCL (96%), advanced clinical stage (93%), elevated LDH (91%), more than one extranodal site (73%), and B-symptoms (64%). A bulky lesion ( 〉 10 cm) was present in 37% of the patients and 11 CSF samples (8%) were FC+. Most patients (n=127, 96%) received a full treatment schedule. Liposomal AraC was given to 81 (61%) and radiotherapy to 39 (30%) patients. Grade 4 infections were observed in 12% of the patients. The frequency of grade 3-4 mucositis as well as gastrointestinal toxicity was 20%, and of grade 3 arachnoiditis 2,5%. Three toxic deaths were observed. In addition, three patients developed AML/MDS and one PML. At the end of treatment, CR/CRu, PR and PD rates were 79%, 17% and 3%, respectively. Of the 120 patients who underwent PET-CT, 92 (77%) achieved a metabolic CR (Deauville score (DS) 1-3). Three patients had primary refractory disease. At a median follow-up of 30 months, additional 14 patients had relapsed, three of them in the CNS (only one had a pre-therapeutic FC+ CSF), and 15 had died. FFS, PFS, OS and CNS progression rates at 30 months were 80%, 83%, 90%, and 2.4%, respectively. PET positivity (DS 4-5) at the end of treatment (p=0.019) and BCL2 expression (p=0.049) were associated with increased risk of progression, whereas other factors, such as molecular subtype (GC versus non-GC), Ki-67 score (≥70%), aaIPI group (2 versus 3), number of extranodal sites, FC-based CSF positivity, and treatment with liposomal AraC did not seem to have significant impact on outcome. Conclusions: Safety profile and final outcome results of the Nordic CHIC trial indicate high response rates, favorable survival, low number of CNS recurrences and manageable toxicity as a result of this CNS targeted intensive therapy schedule. PET response at the end of therapy and selected biological factors identify patients at high risk of progression. Disclosures Leppa: Roche: Honoraria, Other: Travel expenses, Research Funding; Janssen: Research Funding; Bayer: Research Funding; Mundipharma: Research Funding; Amgen: Research Funding; Takeda: Honoraria, Other: Travel expenses; CTI Life Sciences: Honoraria; Merck: Other: Travel expenses. Joergensen:Amgen: Research Funding; Mundipharma: Research Funding. Mannisto:SOBI: Honoraria; Pfizer: Honoraria; Gilead: Other: Travel expenses; Celgene: Other: Travel expenses; Novartis: Other: Travel expenses; Amgen: Other: Travel expenses; Takeda: Honoraria, Other: Travel expenses; Roche: Honoraria, Other: Travel expenses. Jerkeman:Gilead: Research Funding; Celgene: Research Funding; Mundipharma: Research Funding; Amgen: Research Funding; Janssen: Research Funding. Holte:Amgen: Research Funding; Mundipharma: Research Funding.

Type of Medium: Online Resource

ISSN: 0006-4971 , 1528-0020

URL: Article

DOI: 10.1182/blood.V128.22.1854.1854

RVK:

XA 33000

RVK:

XA 10000

Language: English

Publisher: American Society of Hematology

Publication Date: 2016

detail.hit.zdb_id: 1468538-3

detail.hit.zdb_id: 80069-7

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