Somatic hypermutation (SHM) features in a series of 1967 immunoglobulin heavy chain gene (IGH) rearrangements obtained from patients with chronic lymphocytic leukemia (CLL) were examined and compared with IGH sequences from non-CLL B cells available in public databases. SHM analysis was performed for all 1290 CLL sequences in this cohort with less than 100% identity to germ line. At the cohort level, SHM patterns were typical of a canonical SHM process. However, important differences emerged from the analysis of certain subgroups of CLL sequences defined by: (1) IGHV gene usage, (2) presence of stereotyped heavy chain complementarity-determining region 3 (HCDR3) sequences, and (3) mutational load. Recurrent, "stereotyped" amino acid changes occurred across the entire IGHV region in CLL subsets carrying stereotyped HCDR3 sequences, especially those expressing the IGHV3-21 and IGHV4-34 genes. These mutations are underrepresented among non-CLL sequences and thus can be considered as CLL-biased. Furthermore, it was shown that even a low level of mutations may be functionally relevant, given that stereotyped amino acid changes can be found in subsets of minimally mutated cases. IntroductionDeveloping B cells generate a vast repertoire of antibody specificities through somatic recombination of distinct variable (V), diversity (D) (heavy chain only), and joining (J) genes to form the variable domain exons of immunoglobulins (IG). 1 Unlike heavy chain complementarity determining regions (HCDR) 1 and 2, which are entirely encoded by the IGHV gene, HCDR3 is created de novo by the VDJ recombination process. 1 The skewing of diversity to the HCDR3 implies that HCDR3 sequences are the principal determinants of specificity, at least in the primary repertoire. 2,3 However, HCDR3 diversity is not enough to realize the full potential of antibody diversity. 4 Furthermore, unconventional antigens, such as B-cell superantigens, may be recognized not via the CDRs but rather via the framework regions (FRs). 5 Somatic hypermutation (SHM) of IG variable genes forms a second round of diversification after somatic recombination which increases antibody diversity. 6 SHM has long been thought to occur mainly in the germinal centers (GCs) after antigen stimulation and in a manner dependent on T-cell help. 7 Recent reports, however, suggest that SHM can be T-cell independent and may also occur outside classic GCs. [8][9][10][11][12][13] In recent years, the mutational status of IGHV genes has been established as one of the most important molecular genetic markers in defining prognostic subgroups of chronic lymphocytic leukemia (CLL). CLL patients who carry IGHV genes with 98% identity or more to the closest germ line gene ("unmutated") follow a more aggressive clinical course and have strikingly shorter survival than patients carrying IGHV genes with less than 98% identity to germ line ("mutated"). 14,15 The 98% cutoff was chosen as a shortcut to exclude potential polymorphic variants [16][17][18][19] and has been used by the majority of st...
Mounting evidence indicates that grouping of chronic lymphocytic leukemia (CLL) into distinct subsets with stereotypedBCRs is functionally and prognostically relevant. However, several issues need revisiting, including the criteria for identification of BCR stereotypy and its actual frequency as well as the identification of "CLL-biased" features in BCR Ig stereotypes. To this end, we examined 7596 Ig VH (IGHV-IGHD-IGHJ) sequences from 7424 CLL patients, 3 times the size of the largest published series, with an updated version of our purpose-built clustering algorithm. We document that CLL may be subdivided into 2 distinct categories: one with stereotyped and the other with nonstereotyped BCRs, at an approximate ratio of 1:2, and provide evidence suggesting a different ontogeny for these 2 categories. We also show that subset-defining sequence patterns in CLL differ from those underlying BCR stereotypy in other B-cell malignancies. Notably, 19 major subsets contained from 20 to 213 sequences each, collectively accounting for 943 sequences or one-eighth of the cohort. Hence, this compartmentalized examination of VH sequences may pave the way toward a molecular classification of CLL with implications for targeted therapeutic interventions, applicable to a significant number of patients assigned to the same subset. (Blood. 2012;119(19):4467-4475) IntroductionThe analysis of the Ig genes in chronic lymphocytic leukemia (CLL) has contributed significantly toward deciphering the molecular pathogenesis of the disease. Studies from the 1990s provided the first indications for a possible role of Ag(s) in selecting the CLL progenitor cells, through the discovery of a biased Ig heavy variable (IGHV) gene repertoire, different from that of normal B cells, as well as distinctive Ag-binding sites among unrelated cases. [1][2][3][4][5] By the late 1990s, it emerged that the mutational status of the rearranged IGHV genes directly correlated with patient survival. In particular, patients with unmutated IGHV genes were found to follow a more aggressive clinical course and have significantly shorter survival than patients carrying mutated IGHV genes. 6,7 Yet, there were exceptions to this rule: cases using the IGHV3-21 gene, although mostly expressing mutated Ig, had a survival similar to that of unmutated cases. 8 Intriguingly, approximately half of the IGHV3-21 cases were found to display restricted and, in some instances, essentially identical variable heavy complementarity determining region 3 (VH CDR3) sequences and identical light chains, strongly suggesting recognition of a common antigenic determinant. 9 Soon thereafter, the study of Ig sequences in CLL by groups in both Europe and the United States led to the identification of several other subsets of cases carrying highly similar BCR Igs among both mutated and unmutated cases (stereotyped BCR). [10][11][12][13][14] The identification of stereotypy among unrelated and geographically distant cases was widely accepted as evidence for the Submitted November 26, 2011; accepte...
Chronic lymphocytic leukemia (CLL) is uniquely characterized by the existence of subsets of cases with quasi-identical, 'stereotyped' B-cell receptors (BCRs). Herein we investigate this stereotypy in 2662 patients with CLL, the largest series yet, using purpose-built bioinformatics methods based on sequence pattern discovery. Besides improving the identification of 'stereotyped' cases, we demonstrate that CLL actually consists of two different categories, based on the BCR repertoire, with important biological and ontogenetic differences. The first ( approximately 30% of cases) shows a very restricted repertoire and is characterized by BCR stereotypy (clustered cases), whereas the second includes cases with heterogeneous BCRs (nonclustered cases). Eleven major CLL clusters were identified with antigen-binding sites defined by just a few critically positioned residues, regardless of the actual immunoglobulin (IG) variable gene used. This situation is closely reminiscent of the receptors expressed by cells participating in innate immune responses. On these grounds, we argue that whereas CLL cases with heterogeneous BCRs likely derive from the conventional B-cell pool, cases with stereotyped BCRs could derive from progenitor cells evolutionarily adapted to particular antigenic challenges, perhaps intermediate between a true innate immune system and the conventional adaptive B-cell immune system, functionally similar to what has been suggested previously for mouse B1 cells.
We examined 807 productive IGHV-IGHD-IGHJ gene rearrangements from mantle cell lymphoma (MCL) cases, by far the largest series to date. The IGHV gene repertoire was remarkably biased, with IGHV3-21, IGHV4-34, IGHV1-8, and IGHV3-23 accounting for 46.3% of the cohort. Eightyfour of 807 (10.4%) cases, mainly using the IGHV3-21 and IGHV4-34 genes, were found to bear stereotyped heavy complementaritydetermining region 3 (VH CDR3) sequences and were placed in 38 clusters. Notably, the MCL stereotypes were distinct from those reported for chronic lymphocytic leukemia. Based on somatic hypermutation (SHM) status, 238/807 sequences (29.5%) carried IGHV genes with 100% germ line identity; the remainder (569/807; 70.5%) exhibited different SHM impact, ranging from minimal (in most cases) to pronounced. Shared replacement mutations across the IGHV gene were identified for certain subgroups, especially those using IGHV3-21, IGHV1-8, and IGHV3-23.Comparison with other entities, in particular CLL, revealed that several of these mutations were "MCL-biased." In conclusion, MCL is characterized by a highly restricted immunoglobulin gene repertoire with stereotyped VH CDR3s and very precise SHM targeting, strongly implying a role for antigen-driven selection of the clonogenic progenitors. Hence, an antigen-driven origin of MCL could be envisaged, at least for subsets of cases. (Blood. 2011; 118(11):3088-3095) IntroductionMantle cell lymphoma (MCL) is an aggressive B-cell malignancy that represents 5%-10% of non-Hodgkin lymphomas. The median overall survival is 3-5 years, and at present, conventional treatment is not curative and long-term remission is rare. However, subsets of MCL patients follow a more indolent clinical course without disease progression for a relatively long period. 1 The cytogenetic hallmark of MCL is the chromosomal translocation t(11;14)(q13;q32). This aberration leads to the juxtaposition of the CCDN1 locus on chromosome 11 to the immunoglobulin heavy chain (IGH) locus on chromosome 14. As a consequence, cyclin D1 is constitutively overexpressed, causing gross cell cycle deregulation. 2 In addition to the primary t(11;14), several secondary genomic aberrations can be identified in most MCL cases, 2,3 supporting early findings that cyclin D1 overexpression must be accompanied by other genetic abnormalities to promote lymphomagenesis. 2,4 Various gene expression changes that may cooperate with cyclin D1 deregulation also have been described in MCL, mainly involved in DNA repair pathways and the control of cell cycle and apoptosis. 4,5 That notwithstanding, alterations in the local tumor microenvironment also may play an important role in regulating the growth and survival of MCL neoplastic cells. 2,5,6 In B-cell malignancies, immunogenetic analysis of the clonogenic B-cell receptors (BcRs) offers valuable insight into both the ontogenetic derivation and the possible involvement of antigen selection. In particular, a biased repertoire of immunoglobulin heavy variable (IGHV) genes is generally considered as evid...
Plant glutathione transferase-mediated stress tolerance: functions and biotechnological applications
Plant glutathione transferases (EC 2.5.1.18, GSTs) are an ancient, multimember and diverse enzyme class. Plant GSTs have diverse roles in plant development, endogenous metabolism, stress tolerance, and xenobiotic detoxification. Their study embodies both fundamental aspects and agricultural interest, because of their ability to confer tolerance against biotic and abiotic stresses and to detoxify herbicides. Here we review the biotechnological applications of GSTs towards developing plants that are resistant to biotic and abiotic stresses. We integrate recent discoveries, highlight, and critically discuss the underlying biochemical and molecular pathways involved. We elaborate that the functions of GSTs in abiotic and biotic stress adaptation are potentially a result of both catalytic and non-catalytic functions. These include conjugation of reactive electrophile species with glutathione and the modulation of cellular redox status, biosynthesis, binding, and transport of secondary metabolites and hormones. Their major universal functions under stress underline the potential in developing climate-resilient cultivars through a combination of molecular and conventional breeding programs. We propose that future GST engineering efforts through rational and combinatorial approaches, would lead to the design of improved isoenzymes with purpose-designed catalytic activities and novel functional properties. Concurrent GST-GSH metabolic engineering can incrementally increase the effectiveness of GST biotechnological deployment.
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