We performed single-molecule telomere length and telomere fusion analysis in patients at different stages of chronic lymphocytic leukemia (CLL). Our work identified the shortest telomeres ever recorded in primary human tissue, reinforcing the concept that there is significant cell division in CLL. Furthermore, we provide direct evidence that critical telomere shortening, dysfunction, and fusion contribute to disease progression. The frequency of short telomeres and fusion events increased with advanced disease, but importantly these were also found in a subset of early-stage patient samples, indicating that these events can precede disease progression. Sequence analysis of fusion events isolated from persons with the shortest telomeres revealed limited numbers of repeats at the breakpoint, subtelomeric deletion, and microhomology. Array-comparative genome hybridization analysis of persons displaying evidence of telomere dysfunction revealed large-scale genomic rearrangements that were concentrated in the telomeric regions; this was not observed in samples with longer telomeres. The telomere dynamics observed in CLL B cells were indistinguishable from that observed in cells undergoing crisis in culture after abrogation of the p53 pathway. Taken together, our data support the concept that telomere erosion and subsequent telomere fusion are critical in the progression of CLL and that this paradigm may extend to other malignancies. (Blood. 2010;116(11): 1899-1907) IntroductionNonreciprocal translocations (NRTs) are considered to be key mutational events that can drive many types of malignancy. 1 The underlying mechanisms that result in these types of events can include, among others, deficiencies in double-strand break repair, 2 mitotic checkpoints, 3,4 and telomere dysfunction. 5 Telomeres play a key role in upholding genomic integrity; in the context of DNA damage checkpoint defects, cells in culture undergo crisis and have extensive telomere erosion, chromosomal fusion, and genomic rearrangements. 6,7 NRTs, as well as localized gene amplification, 8 can arise as a consequence of cycles of anaphase-bridging, breakage, and fusion initiated by the formation of dicentric chromosomes after telomere fusion. 9 This paradigm is exemplified in vivo by telomerase knockout mice, where short telomeres appear to drive the formation of tumors containing NRTs. 5 However, evidence for this phenomenon in humans is circumstantial. Numerous malignancies, including breast, prostate, colorectal, and chronic lymphocytic leukemia (CLL), [10][11][12][13][14][15] have been documented to exhibit shorter telomeres compared with normal tissues. These data are consistent with the expected levels of cell division during the progression to malignancy but do not indicate that telomeres become short enough to lose their end-capping function. Telomere fusion, as well as other chromosomal defects, can lead to the formation of anaphase bridges; in situ data show an increase in anaphase bridges, often interpreted as a surrogate marker for telomere f...
To identify variants for multiple myeloma risk, we conducted a genome-wide association study with validation in additional series totaling 4,692 cases and 10,990 controls. We identified four risk loci at 3q26.2 (rs10936599, P=8.70x10-14), 6p21.33 (rs2285803, PSORS1C2; P= 9.67x10-11), 17p11.2 (rs4273077, TNFRSF13B; P=7.67x10-9) and 22q13.1 (rs877529, CBX7; P=7.63x10-16). These data provide further evidence for genetic susceptibility to this B-cell hematological malignancy and insight into the biological basis of predisposition.
) and 8q22.3 (rs2511714, P=2.90x10 -9 ). These findings provide further insights into the genetic and biological basis of inherited genetic susceptibility to CLL. Speedy et al 3Chronic lymphocytic leukemia (CLL) is the most common hematological malignancy in Western countries 1 and is characterized by a 8-fold increased risk in first-degree relatives 2 . Genome-wide association studies (GWASs) have so far identified common variants at 24 loci that contribute to the heritable risk of CLL [3][4][5][6] . Current projections for the number of independent regions harboring common variants associated with CLL suggest that additional risk loci conferring modest effects should be identified by expansion of discovery GWAS datasets.To identify additional novel susceptibility loci for CLL, we conducted an independent primary scan of CLL and performed a genome-wide meta-analysis with a previously published GWAS followed by analysis of the top single nucleotide polymorphisms (SNPs) in two separate case-control series.In the primary scan (UK-CLL-2), 1,271 CLL cases were genotyped using the Illumina Omni Express Figure 1). To harmonize the two GWAS datasets, we imputed UK-CLL-1 to recover untyped SNPs directly genotyped in UK-CLL-2, using data from the 1000 Genomes Project as reference. Using data on all cases and controls from each GWAS, we derived joint odds ratios (ORs) and confidence intervals (CIs) under a fixed effects model for each SNP and associated P-values, restricting analysis to SNPs with MAF >1%. After filtering on the basis of pre-specified quality-control measures Table 2). We also identified promising association signals (i.e. P<1.0×10−5 ) at 11 additional loci (Supplementary Table 2). We applied 1000 Genomes imputation to UK-CLL-1 and UK-CLL-2 at these loci to investigate if a statistically significant stronger SNP association could be identified, recovering an additional SNP which was significant at the genome-wide threshold (rs6858698; Supplementary Table 2). We performed replication genotyping of six SNPs selected on the basis of statistical significance (rs2236256, rs6062501, rs6858698) and gene centricity coupled with Table 4). While we found no evidence for a relationship between rs10936599, and telomere length in 246 CLL patients (Supplementary Table 5), carrier status for the rs10936599-C risk allele is previously been associated with significantly longer telomeres in leukocytes 10,11 .The third significant association was at rs6858698 on 4q26 (OR=1.31, 95% C.I. 1.20-1.44; P=3.07x10 linked to cis-platinum resistance by enhancing apoptosis. A recent GWAS of CLL has reported promising associations at 5p15.33 defined by rs10069690 and at 8q22.33 defined by rs2511714 6 . Combining the Pvalues for rs10069690 and rs2511714 obtained in our meta-analysis (P=1.0x10 -4 and 1.0x10respectively) with published data 6 provides robust evidence for both associations (combined P-values 1.10x10 -10 and 2.90x10 -9 respectively; Supplementary Figure 4). rs10069690 maps to intron 4 of TERT (telomerase reverse trans...
Alemtuzumab is a humanized anti-CD52 antibody licensed for refractory B-cell chronic lymphocytic leukemia (B-CLL), when given intravenously at 30 mg thrice weekly. However, the intravenous route is associated with infusion-related reactions and is inconvenient. We measured blood concentrations in 30 relapsed patients treated with intravenous alemtuzumab and in 20 patients from a previously untreated group who received similar doses subcutaneously. Highest trough samples in the intravenous group were less than 0.5 microg/mL to 18.3 microg/mL (mean 5.4 microg/mL). The cumulative dose required to reach 1.0 microg/mL was 13 mg to 316 mg (mean 90 mg). Higher blood concentrations correlated with the achievement of better clinical responses and minimal residual disease. The highest measured concentrations in the subcutaneous group were similar (0.6 microg/mL to 24.8 microg/mL, mean 5.4 microg/mL). However, the cumulative dose to reach 1.0 microg/mL was higher: 146 mg to 1106 mg (mean 551 mg). No antiglobulin responses were detected in 30 patients given intravenous alemtuzumab whereas 2 of 32 patients given subcutaneous alemtuzumab made substantial anti-idiotype responses. Thus, subcutaneous alemtuzumab achieved concentrations similar to those for intravenous alemtuzumab, although with slightly higher cumulative doses. Subcutaneous alemtuzumab is more convenient and better tolerated but may be associated with some patients forming anti-alemtuzumab antibodies, particularly those patients who were previously untreated.
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