Yorick Sandberg

BIOMED-2 multiplex immunoglobulin/T-cell receptor polymerase chain reaction protocols can reliably replace Southern blot analysis in routine clonality diagnostics

To establish the most sensitive and efficient strategy of clonality diagnostics via immunoglobulin and T-cell receptor gene rearrangement studies in suspected lymphoproliferative disorders, we evaluated 300 samples (from 218 patients) submitted consecutively for routine diagnostics. All samples were studied using the BIOMED-2 multiplex polymerase chain reaction (PCR) protocol. In 176 samples, Southern blot (SB) data were also available, and the two types of molecular results were compared. Results of PCR and SB analysis of both T-cell receptor and immunoglobulin loci were concordant in 85% of samples. For discordant results, PCR results were more consistent with the final diagnosis in 73% of samples. No false-negative results were obtained by PCR analysis. In contrast, SB analysis failed to detect clonality in a relatively high number of samples, mainly in cases of low tumor burden. We conclude that the novel BIOMED-2 multiplex PCR strategy is of great value in diagnosing patients with suspected B- and T-cell proliferations. Because of its higher speed, efficiency, and sensitivity, it can reliably replace SB analysis in clonality diagnostics in a routine laboratory setting. Just as with SB results, PCR results should always be interpreted in the context of clinical, immunophenotypical, and histopathological data.

Clinical effect of stereotyped B-cell receptor immunoglobulins in chronic lymphocytic leukaemia: a retrospective multicentre study

BACKGROUND About 30% of cases of chronic lymphocytic leukaemia (CLL) carry quasi-identical B-cell receptor immunoglobulins and can be assigned to distinct stereotyped subsets. Although preliminary evidence suggests that B-cell receptor immunoglobulin stereotypy is relevant from a clinical viewpoint, this aspect has never been explored in a systematic manner or in a cohort of adequate size that would enable clinical conclusions to be drawn. METHODS For this retrospective, multicentre study, we analysed 8593 patients with CLL for whom immunogenetic data were available. These patients were followed up in 15 academic institutions throughout Europe (in Czech Republic, Denmark, France, Greece, Italy, Netherlands, Sweden, and the UK) and the USA, and data were collected between June 1, 2012, and June 7, 2013. We retrospectively assessed the clinical implications of CLL B-cell receptor immunoglobulin stereotypy, with a particular focus on 14 major stereotyped subsets comprising cases expressing unmutated (U-CLL) or mutated (M-CLL) immunoglobulin heavy chain variable genes. The primary outcome of our analysis was time to first treatment, defined as the time between diagnosis and date of first treatment. FINDINGS 2878 patients were assigned to a stereotyped subset, of which 1122 patients belonged to one of 14 major subsets. Stereotyped subsets showed significant differences in terms of age, sex, disease burden at diagnosis, CD38 expression, and cytogenetic aberrations of prognostic significance. Patients within a specific subset generally followed the same clinical course, whereas patients in different stereotyped subsets-despite having the same immunoglobulin heavy variable gene and displaying similar immunoglobulin mutational status-showed substantially different times to first treatment. By integrating B-cell receptor immunoglobulin stereotypy (for subsets 1, 2, and 4) into the well established Döhner cytogenetic prognostic model, we showed these, which collectively account for around 7% of all cases of CLL and represent both U-CLL and M-CLL, constituted separate clinical entities, ranging from very indolent (subset 4) to aggressive disease (subsets 1 and 2). INTERPRETATION The molecular classification of chronic lymphocytic leukaemia based on B-cell receptor immunoglobulin stereotypy improves the Döhner hierarchical model and refines prognostication beyond immunoglobulin mutational status, with potential implications for clinical decision making, especially within prospective clinical trials. FUNDING European Union; General Secretariat for Research and Technology of Greece; AIRC; Italian Ministry of Health; AIRC Regional Project with Fondazione CARIPARO and CARIVERONA; Regione Veneto on Chronic Lymphocytic Leukemia; Nordic Cancer Union; Swedish Cancer Society; Swedish Research Council; and National Cancer Institute (NIH).

TCRγδ+ large granular lymphocyte leukemias reflect the spectrum of normal antigen-selected TCRγδ+ T-cells

T-cell large granular lymphocytes (LGL) proliferations range from reactive expansions of activated T cells to T-cell leukemias and show variable clinical presentation and disease course. The vast majority of T-LGL proliferations express TCRαβ. Much less is known about the characteristics and pathogenesis of TCRγδ+ cases. We evaluated 44 patients with clonal TCRγδ+ T-LGL proliferations with respect to clinical data, immunophenotype and TCR gene rearrangement pattern. TCRγδ+ T-LGL leukemia patients had similar clinical presentations as TCRαβ+ T-LGL leukemia patients. Their course was indolent and 61% of patients were symptomatic. The most common clinical manifestations were chronic cytopenias – neutropenia (48%), anemia (23%), thrombocytopenia (9%), pancytopenia (2%) – and to a lesser extent splenomegaly (18%). Also multiple associated autoimmune (34%) and hematological (14%) disorders were found. Leukemic LGLs were predominantly positive for CD2, CD5, CD7, CD8, and CD57, whereas variable expression was seen for CD16, CD56, CD11b, and CD11c. The Vγ9/Vδ2 immunophenotype was found in 48% of cases and 43% of cases was positive for Vδ1, reflecting the TCR-spectrum of normal TCRγδ+ T-cells in adult PB. Identification of the well-defined post-thymic Vδ2-Jδ1 selection determinant in all evaluable Vγ9+/Vδ2+ patients, is suggestive of common (super)antigen involvement in the pathogenesis of these TCRγδ+ T-LGL leukemia patients.

Not all IGHV3-21 chronic lymphocytic leukemias are equal: Prognostic considerations

An unresolved issue in chronic lymphocytic leukemia (CLL) is whether IGHV3-21 gene usage, in general, or the expression of stereotyped B-cell receptor immunoglobulin defining subset #2 (IGHV3-21/IGLV3-21), in particular, determines outcome for IGHV3-21-utilizing cases. We reappraised this issue in 8593 CLL patients of whom 437 (5%) used the IGHV3-21 gene with 254/437 (58%) classified as subset #2. Within subset #2, immunoglobulin heavy variable (IGHV)-mutated cases predominated, whereas non-subset #2/IGHV3-21 was enriched for IGHV-unmutated cases (P = .002). Subset #2 exhibited significantly shorter time-to-first-treatment (TTFT) compared with non-subset #2/IGHV3-21 (22 vs 60 months, P = .001). No such difference was observed between non-subset #2/IGHV3-21 vs the remaining CLL with similar IGHV mutational status. In conclusion, IGHV3-21 CLL should not be axiomatically considered a homogeneous entity with adverse prognosis, given that only subset #2 emerges as uniformly aggressive, contrasting non-subset #2/IGVH3-21 patients whose prognosis depends on IGHV mutational status as the remaining CLL.

Human T-cell lines with well-defined T-cell receptor gene rearrangements as controls for the BIOMED-2 multiplex polymerase chain reaction tubes

The BIOMED-2 multiplex polymerase chain reaction (PCR) tubes for analysis of immunoglobulin and T-cell receptor (TCR) gene rearrangements have recently been introduced as a reliable and easy tool for clonality diagnostics in suspected lymphoproliferations. Quality and performance assessment of PCR-based clonality diagnostics is generally performed using human leukemia/lymphoma cell lines as controls. We evaluated the utility of 30 well-defined human T-cell lines for quality performance testing of the BIOMED-2 PCR primers and protocols. The PCR analyses of the TCR loci were backed up by Southern blot analysis. The clonal TCRB, TCRG and TCRD gene rearrangements were analyzed for gene segment usage and for the size and composition of their junctional regions. In 29 out of 30 cell lines, unique clonal TCR gene rearrangements could be easily detected. Besides their usefulness in molecular clonality diagnostics, these cell lines can now be authenticated based on their TCR gene rearrangement profile. This enables their correct use in molecular clonality diagnostics and in other cancer research studies.

Spectrum of T-large granular lymphocyte lymphoproliferations: ranging from expanded activated effector T cells to T-cell leukaemia

Lymphoproliferations of large granular lymphocytes (LGL) are generally divided into CD3 T-LGL and CD3 CD16 natural killer (NK)-LGL types (Semenzato et al, 1997). Contrary to NK-LGL leukaemia, which shows a rather aggressive clinical course, T-LGL leukaemia is generally considered to be an indolent disease (Semenzato et al, 1997). Clinical symptoms typically consist of neutropenia and autoimmune characteristics and the lymphocytosis is often limited (Semenzato et al, 1997). Detection of a monoclonal LGL cell population is an important criterion for the diagnosis of T-LGL leukaemia (Semenzato et al, 1997). In the World Health Organization classification, LGL cell counts of >5 · 10/l and certainly >10 · 10/l are considered a sign of leukaemia, although it is suggested that LGL counts of >2 · 10/l can be consistent with a diagnosis of T-LGL leukaemia as well (Jaffe et al, 2001). On the contrary, LGL cell expansions <0Æ5 · 10/l and <40% of T lymphocytes can be found in healthy controls and thus represent true reactive proliferations (Semenzato et al, 1997; Van den Beemd et al, 2000). However, the clinical importance of LGL proliferations ranging from 0Æ5 · 10/l to 2–5 · 10/l, which can also be clonal in nature, is often less clear. These are sometimes termed T-cell clonopathy of undetermined significance (TCUS) in analogy to monoclonal gammopathy of undetermined significance (Dhodapkar et al, 1994). Recently, it was shown that T-LGL leukaemia cells in patients are indistinguishable from the small (oligo)clonal CD8 LGL effector cell expansions in asymptomatic individuals, given the common CD3 CD8 CD57 phenotype and the expression of FasL, granzyme and activating CD94/NKG2 molecules (Bigouret et al, 2003). Antigen stimulation of LGL effector cells and triggering of effector molecules may dysregulate immune mechanisms and thereby cause clinical problems (Bigouret et al, 2003). In line with the idea of antigen-activated cytotoxic effector cells, we have previously shown that T-LGL proliferations often display a polyclonal to oligoclonal Vb repertoire, with many cases showing one or more dominant clones with restricted Vb usage or even clear monoclonal Vb usage (Langerak et al, 2001). We strongly believe that this clonal heterogeneity reflects a continuous spectrum of T-LGL proliferations from reactive to clinically malignant (Fig 1). To further illustrate this spectrum, we describe three representative patients showing LGL proliferations (see also legend to Fig 1): (i) patient 1, presenting with seropositive rheumatoid arthritis and neutropenia, and finally diagnosed as having Felty syndrome, only showed 0Æ1 · 10/l reactive LGL effector cells; (ii) patient 2 showed anemia, disturbed erythropoiesis, and a limited LGL clone and was diagnosed with TCUS; and (iii) patient 3 presented with arthritis, but developed T-LGL leukaemia with a high cell count. These patients fit into a continuous spectrum of T-LGL proliferations ranging from limited or relatively mild lymphocytoses to cases that show a large monoclonal expansion and display signs of clinically malignant behaviour, justifying the term leukaemia.

Lack of common TCRA and TCRB clonotypes in CD8+/ TCRαβ+ T-cell large granular lymphocyte leukemia: A review on the role of antigenic selection in the immunopathogenesis of CD8+ T-LGL

Clonal CD8+/T-cell receptor (TCR)αβ+ T-cell large granular lymphocyte (T-LGL) proliferations constitute the most common subtype of T-LGL leukemia. Although the etiology of T-LGL leukemia is largely unknown, it has been hypothesized that chronic antigenic stimulation contributes to the pathogenesis of this disorder. In the present study, we explored the association between expanded TCR-Vβ and TCR-Vα clonotypes in a cohort of 26 CD8+/TCRαβ+ T-LGL leukemia patients, in conjunction with the HLA-ABC genotype, to find indications for common antigenic stimuli. In addition, we applied purpose-built sophisticated computational tools for an in-depth evaluation of clustering of TCRβ (TCRB) complementarity determining region 3 (CDR3) amino-acid LGL clonotypes. We observed a lack of clear TCRA and TCRB CDR3 homology in CD8+/TCRαβ+ T-LGL, with only low level similarity between small numbers of cases. This is in strong contrast to the homology that is seen in CD4+/TCRαβ+ T-LGL and TCRγδ+ T-LGL and thus underlines the idea that the LGL types have different etiopathogenesis. The heterogeneity of clonal CD8+/TCRαβ+ T-LGL proliferations might in fact suggest that multiple pathogens or autoantigens are involved.

Clonal T- and natural killer-cell large granular lymphocyte proliferations in a single patient established by array-based comparative genomic hybridization analysis.

Clonal T- and natural killer-cell large granular lymphocyte proliferations in a single patient established by array-based comparative genomic hybridization analysis

Dysregulated signaling, proliferation and apoptosis impact on the pathogenesis of TCRγδ+ T cell large granular lymphocyte leukemia

TCRγδ+ T-LGL leukemia is a rare form of chronic mature T cell disorders in elderly, which is generally characterized by a persistently enlarged CD3+CD57+TCRγδ+ large granular lymphocyte population in the peripheral blood with a monoclonal phenotype. Clinically, the disease is heterogeneous, most patients being largely asymptomatic, although neutropenia, fatigue and B symptoms and underlying diseases such as autoimmune diseases or malignancies are also often observed. The etiology of TCRγδ+ T-LGL proliferations is largely unknown. Here, we aimed to investigate underlying molecular mechanisms of these rare proliferations by performing gene expression profiling of TCRγδ+ T-LGL versus normal TCRγδ+ T cell subsets. From our initial microarray dataset we observed that TCRγδ+ T-LGL leukemia forms a separate group when compared with different healthy control TCRγδ+ T cell subsets, correlating best with the healthy TemRA subset. The lowest correlation was seen with the naive subset. Based on specific comparison between healthy control cells and TCRγδ+ T-LGL leukemia cells we observed up-regulation of survival, proliferation and hematopoietic system related genes, with a remarkable down-regulation of apoptotic pathway genes. RQ-PCR validation of important genes representative for the dataset, including apoptosis (XIAP, CASP1, BCLAF1 and CFLAR), proliferation/development (ID3) and inflammation (CD28, CCR7, CX3CR1 and IFNG) processes largely confirmed the dysregulation in proliferation and apoptosis. Based on these expression data we conclude that TCRγδ+ T-LGL leukemia is likely the result of an underlying aberrant molecular mechanisms leading to increased proliferation and reduced apoptosis.

Evaluation of functional single nucleotide polymorphisms of different genes coding for the immunoregulatory molecules in patients with monoclonal large granular lymphocyte lymphocytosis

TCR alpha beta+/CD4+ T-large granular lymphocyte (LGL) lymphocytosis is a subgroup of monoclonal T-LGL lymphoproliferative disorders that are different from the CD8+ TCR alpha beta T-LGL. An increasing evidence supports the involvement of a common antigen-driven mechanism in the etiology of TCR alpha beta+/CD4+ T-LGL. In this study, we tested several polymorphic markers associated with chronic viral infections and autoimmune diseases, including cytotoxic T-lymphocyte antigen-4 (CTLA-4), tumor necrosis factor-alpha (TNF-alpha), interleukin-10 (IL-10), interferon-gamma (IFN-gamma), RANTES, IL-1 alpha, FAS, FAS-ligand (FASL), and NKG2D, to investigate the potential association of these immunogenetic factors with the development of T-LGL. Overall, 38 patients with CD4+ T-LGL were analyzed and compared with a group of both CD8+/TCR alpha beta+ T-LGL patients (n = 43) and a group of control subjects (n = 176). Our results did not show any clear association between the different single nucleotide polymorphisms (SNPs) analyzed and the development of CD4+/TCR alpha beta T-LGL. An increase in the frequency of -380 (AA/GA) TNF-alpha genotype associated with a greater production of this cytokine was found among CD8+ T LGL patients in comparison to the CD4+LGL patients and the control group. Our results suggest that the frequency of SNP of the genes coding for the studied immunoregulatory molecules are not associated with the development of CD4+/TCR alpha beta+ T-LGL.