Richard Williams scite author profile

Colorectal tumors that are wild-type (WT) for KRAS are often sensitive to EGFR blockade, but almost always develop resistance within several months of initiating therapy1,2. The mechanisms underlying this acquired resistance to anti-EGFR antibodies are largely unknown. This situation stands in marked contrast to that of small molecule targeted agents, such as inhibitors of ABL, EGFR, BRAF, and MEK, in which mutations in the genes encoding the protein targets render the tumors resistant to the effects of the drugs3–6. The simplest hypothesis to account for the development of resistance to EGFR blockade are that rare cells with KRAS mutations pre-exist at low levels in tumors with ostensibly WT KRAS genes. Though this hypothesis would seem readily testable, there is no evidence in pre-clinical models to support it, nor is there data from patients. To test this hypothesis, we determined whether mutant KRAS DNA could be detected in the circulation of 28 patients receiving monotherapy with panitumumab, a therapeutic anti-EGFR antibody. We found that nine of 24 (38%) patients whose tumors were initially KRAS WT developed detectable mutations in KRAS in their sera, three of which developed multiple different KRAS mutations. The appearance of these mutations was very consistent, generally occurring between five to six months following treatment. Mathematical modeling indicated that the mutations were present in expanded subclones prior to the initiation of panitumumab. These results suggest that the emergence of KRAS mutations is a mediator of acquired resistance to EGFR blockade and that these mutations can be detected in a non-invasive manner. Moreover, they explain why solid tumors develop resistance to targeted therapies in a highly reproducible fashion.

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Rearrangement of CRLF2 in B-progenitor– and Down syndrome–associated acute lymphoblastic leukemia

Mullighan

et al. 2009

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AUTHOR CONTRIBUTIONSCGM designed and coordinated the study, designed assays, performed experiments, analyzed data and wrote the manuscript JRC-U generated retroviral vectors and performed Ba/F3 assays LAAP performed JAK sequencing and quantitative PCR assays MLL performed PAR1 deletion genomic PCR WL performed statistical analysis JZ analyzed sequencing data Jing Ma analyzed microarray data EC-S performed flow cytometry and analyzed data RCH and CLW developed FISH assays Julia Meyer performed experiments and analyzed data FMM, AJC and NAH performed FISH assays and analyzed cytogenetic data RTW provided luciferase vectors JC designed subcloning vectors GB and AP provided patient samples SCR performed cytogenetic analysis SPH coordinated studies and sample collection JRD provided patient samples WLC provided patient samples, performed experiments and analyzed data KRR provided samples, performed experiments and analyzed data NIH Public Access Author ManuscriptNat Genet. Author manuscript; available in PMC 2010 May 1. Published in final edited form as:Nat Genet. SUMMARYAneuploidy and translocations are hallmarks of B-progenitor acute lymphoblastic leukemia (ALL), but many patients lack a recurring chromosomal alteration. Here we report a recurring interstitial deletion of the pseudoautosomal region 1 of chromosomes X and Y in B-progenitor ALL that juxtaposes the first, non-coding exon of P2RY8 to the coding region of CRLF2 (which encodes cytokine receptor like factor 2, or thymic stromal lymphopoietin receptor). The P2RY8-CRLF2 fusion was identified in 7% of B-progenitor ALL cases, and was identified in over 50% of ALL cases arising in patients with Down syndrome (53% of 75 cases). CRLF2 alteration was associated with the presence of activating JAK mutations, and expression of P2RY8-CRLF2 together with JAK2 mutants resulted in constitutive Jak-Stat activation and cytokine-independent growth of Ba/F3-IL7R cells, indicating that these two genetic lesions together contribute to leukemogenesis in B-progenitor ALL.Chromosomal alterations are a hallmark of acute lymphoblastic leukemia (ALL), the commonest malignancy of childhood, and include aneuploidy (hyperdiploidy and hypodiploidy) and recurring chromosomal translocations, such as t(12;21) [ETV6-RUNX1], t (1;19) [TCF3-PBX1], t(9;22) [BCR-ABL1] and rearrangement of MLL 1 . These alterations are important events in leukemogenesis and influence response to therapy. However, up to onequarter of childhood ALL cases lack a recurring chromosomal alteration, and the genetic basis of these cases is poorly understood.To identify submicroscopic genetic alterations contributing to the pathogenesis of ALL, we previously performed high resolution profiling of DNA copy number alterations and loss of heterozygosity (LOH) using single nucleotide polymorphism (SNP) microarrays, and identified multiple recurring genetic alterations targeting key cellular pathways including lymphoid development, cell cycle regulation and tumor suppression2 , 3. These alterations included a novel deletio...

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Self-Trapped Excitons

Song¹,

Williams²

1996

378

512

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Self-Trapped Excitons

Song¹,

Williams²

1993

430

357

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