MDI 301 suppresses myeloid leukemia cell growth in vitro and in vivo without the toxicity associated with all-trans retinoic acid therapy.

MDI 301 is a novel 9-cis retinoic acid derivative in which the terminal carboxylic acid group has been replaced by a picolinate ester. MDI 301, a retinoic acid receptor-α - agonist, suppressed the growth of several human myeloid leukemia cell lines (HL60, NB4, OCI-M2, and K562) in vitro and induced cell-substrate adhesion in conjunction with upregulation of CD11b. Tumor growth in HL60-injected athymic nude mice was reduced. In vitro, MDI 301 was comparable to all-trans retinoic acid (ATRA) whereas in vivo, MDI 301 was slightly more efficacious than ATRA. Most importantly, unlike what was found with ATRA treatment, MDI 301 did not induce a cytokine response in the treated animals and the severe inflammatory changes and systemic toxicity seen with ATRA did not occur. A retinoid with these characteristics might be valuable in the treatment of promyelocytic leukemia, or, perhaps, other forms of myeloid leukemia.

Comprehensive analysis of copy number and allele status identifies multiple chromosome defects underlying follicular lymphoma pathogenesis.

PURPOSE: Follicular lymphoma (FL) constitutes the second most common non-Hodgkin's lymphoma in the Western world. The clinical course is variable and only in part explained by known tumor-intrinsic or -extrinsic factors. FL carries the hallmark chromosomal translocation t(14;18), deregulating the expression of Bcl-2, but this is not sufficient to explain either FL biology or clinical behavior. EXPERIMENTAL DESIGN: We have employed high-density genomic profiling technology using the Affymetrix 50K-XbaI oligonucleotide single nucleotide polymorphism-chip platform to interrogate the genomes of 58 fluorescence-activated cell-sorted (FACS) FL specimens for chromosomal copy number changes and 46 specimens for loss of heterozygosity (LOH). RESULTS: We report (a) previously unknown high-frequency copy-neutral LOH (uniparental disomy) in FL on chromosomes 1p (approximately 50%) and 6p (approximately 30%); (b) that del6q is complex, as reported, with at least two regions of minimal common loss at 6q13-15 and 6q23-24, and that in addition, approximately 8% of FL specimens contain a homozygous deletion at 6q23.3-24.1 that spans the negative NFkappaB regulator A20 and the p53 apoptosis effector PERP; (c) that combined analysis of chromosome 17p for LOH, copy number, and p53 mutations shows that most p53 mutations in FL do not involve del17p. Finally, we map high-frequency LOH with and without copy loss on chromosomes 9p, 10q, and 16p and genomic gains on 2p15-16 and 8q24.22-24.3. CONCLUSIONS: This comprehensive description of the pathologic anatomy of the FL genome uncovers novel genetic lesions and should aid with identification of genes relevant to FL biology and clinical behavior.

Analysis of acquired genomic copy number aberrations and regions of loss of heterozygosity in acute myelogenous leukemia genomes using Affymetrix SNP 6.0 arrays and supporting software tools.

The application of SNP array technology to the analysis of cancer genomes has greatly advanced our knowledge of the incidence and functional consequences of acquired genomic copy number aberrations (aCNA) and LOH in various malignancies. The major challenges of using SNP arrays are accurately identifying acquired genomic DNA aberrations in the raw array data with very high sensitivity and specificity and meaningfully assessing the associations between these aberrations and biological characteristics or patient outcomes. Critical to the success and valid interpretation of data derived from SNP array profiling are (1) the purity of cells used as a source of template DNA; (2) the analysis of paired DNA samples (tumor and normal); (3) use of validated software tools for data analysis; (4) access to an acceptable gold standard for aCNA and LOH, including FISH data, cytogenetic results, and Q-PCR data; and (5) statistical support to employ or develop algorithmic approaches to SNP array data analysis. Overcalling of lesions including lack of validation and undercalling of lesions that display low fractional allelic representations are common problems. This guide should help the reader establish this powerful technology in the laboratory and aims to stimulate transition of SNP array profiling into clinical applications.