Bernard W Futscher

PMID: 16652338;Abstract:

The characterization of complex DNA libraries by high-throughput sequencing technologies provides a powerful approach toward finding mutations and genetic variation in the human genome. However, the value of these analyses is highly dependent upon the quality of the DNA libraries themselves. For example, the sequence composition of libraries made using PCR-based procedures can be skewed due to biases in the amplification efficiency of individual library members. Here, we used CpG island microarrays to evaluate the biases incurred in PCR-based genome amplification using three different DNA polymerase mixtures designed to efficiently amplify problematic sequence tracts. Based on hybridization properties of dye-labeled DNA libraries to these microarrays, we quantified the overall and specific trends in the PCR efficiency of more than 1,400 sequences with high GC-content, which generally amplify with low efficiency using conventional PCR protocols. Overall, all three DNA polymerase mixtures produced libraries that show substantial increases in the representation of CpG island segments that poorly amplify with Taq DNA polymerase. However, the effects of these DNA polymerases were quite specific since they did not alter the relative representation of segments that efficiently amplify with Taq DNA polymerase. Furthermore, we demonstrate that DNA microarrays provide a robust platform for rapidly evaluating the ability of different PCR systems to amplify difficult genomic regions targeted for mutational, resequencing, and genotyping analyses.

PMID: 10954590;PMCID: PMC110706;Abstract:

BRCA1 expression is repressed by aberrant cytosine methylation in sporadic breast cancer. We hypothesized that aberrant cytosine methylation of the BRCA1 promoter was associated with the transcriptionally repressive effects of histone hypoacetylation and chromatin condensation. To address this question, we developed an in vitro model of study using normal cells and sporadic breast cancer cells with known levels of BRCA1 transcript to produce a 1.4 kb 5-methylcytosine map of the BRCA1 5' CpG island. While all cell types were densely methylated upstream of -728 relative to BRCA1 transcription start, all normal and BRCA1 expressing cells were non-methylated downstream of -728 suggesting that this region contains the functional BRCA1 5' regulatory region. In contrast, the non-BRCA1 expressing UACC3199 cells were completely methylated at all 75 CpGs. Chromatin immunoprecipitations showed that the UACC3199 cells were hypoacetylated at both histones H3 and H4 in the BRCA1 promoter compared to non-methylated BRCA1 expressing cells. The chromatin of the methylated UACC3199 BRCA1 promoter was inaccessible to DNA-protein interactions. These data indicate that the epigenetic effects of aberrant cytosine methylation, histone hypoacetylation and chromatin condensation act together in a discrete region of the BRCA1 5' CpG island to repress BRCA1 transcription in sporadic breast cancer.

PMID: 1387586;Abstract:

We have examined the effects of the nitrosoureas, streptozotocin (STZ) and 1,3-bis(chloroethyl)-1-nitrosourea (BCNU), on a human multiple myeloma cell line, RPMI 8226, and its drug-resistant variants. Cell lines selected for doxorubicin (DOX) resistance alone displayed a STZ and BCNU cytotoxicity profile similar to that of the parent cell line. In contrast, two of the drug-resistant variants selected with DOX plus verapamil, an agent which inhibits P-glycoprotein-mediated multidrug resistance, displayed a collateral sensitivity to STZ and BCNU. Verapamil was included in the selection protocol because it has been shown to inhibit the P-glycoprotein-mediated multidrug resistance phenotype and is now in clinical trials as a chemosensitizing agent. The collateral sensitivity to these nitrosoureas seen in the DOX plus verapamil-selected cell lines is due to the functional loss of a DNA repair molecule, O⁶-Methylguanine DNA methyltransferase (MGMT). The functional loss of MGMT is secondary to the loss of MGMT gene expression. The loss of MGMT gene expression is not due to loss or gross rearrangement of the MGMT-coding region. If this selection pressure applied in vitro reflects the in vivo situation, then new chemotherapeutic strategies may be devised to exploit this phenomenon. These cell lines will serve as useful models for delineating mechanisms which govern MGMT expression.

Immortality is an essential characteristic of human carcinoma cells. We recently developed an efficient, reproducible method that immortalizes human mammary epithelial cells (HMEC) in the absence of gross genomic changes by targeting 2 critical senescence barriers. Consistent transcriptomic changes associated with immortality were identified using microarray analysis of isogenic normal finite pre-stasis, abnormal finite post-stasis, and immortal HMECs from 4 individuals. A total of 277 genes consistently changed in cells that transitioned from post-stasis to immortal. Gene ontology analysis of affected genes revealed biological processes significantly altered in the immortalization process. These immortalization-associated changes showed striking similarity to the gene expression changes seen in The Cancer Genome Atlas (TCGA) clinical breast cancer data. The most dramatic change in gene expression seen during the immortalization step was the downregulation of an unnamed, incompletely annotated transcript that we called MORT, for mortality, since its expression was closely associated with the mortal, finite lifespan phenotype. We show here that MORT (ZNF667-AS1) is expressed in all normal finite lifespan human cells examined to date and is lost in immortalized HMEC. MORT gene silencing at the mortal/immortal boundary was due to DNA hypermethylation of its CpG island promoter. This epigenetic silencing is also seen in human breast cancer cell lines and in a majority of human breast tumor tissues. The functional importance of DNA hypermethylation in MORT gene silencing is supported by the ability of 5-aza-2'-deoxycytidine to reactivate MORT expression. Analysis of TCGA data revealed deregulation of MORT expression due to DNA hypermethylation in 15 out of the 17 most common human cancers. The epigenetic silencing of MORT in a large majority of the common human cancers suggests a potential fundamental role in cellular immortalization during human carcinogenesis.

PMID: 8062263;Abstract:

The multidrug resistance-associated protein (MRP) gene is a member of the ATP-binding cassette transporter gene superfamily and may be partially responsible for clinical drug resistance. Reverse transcriptase-polymerase chain reaction was used to measure MRP mRNA in normal hematopoietic cells from bone marrow and peripheral blood as well as patients with high risk acute myelocytic leukemia and multiple myeloma. All normal peripheral blood cells, regardless of cell lineage (CD4, CD8, CD14, CD15, CD19, CD56), expressed a similar basal level of MRP mRNA. Specimens from bone marrow containing mixed lineages also expressed a similar basal level of MRP expression. In patients with acute myelocytic leukemia, 10 of 12 (83%) of the specimens had detectable MRP mRNA, but the level of expression was similar to that of normal blood cells and low compared to a cell line known to overexpress MRP (H69/AR). All myeloma patients (12 of 12) had detectable MRP mRNA expression at levels comparable to normal peripheral blood and bone marrow cells. We conclude that MRP is commonly expressed in normal hematopoietic cells as well as certain hematopoietic malignancies. The therapeutic relevance of MRP expression is unknown, but these studies emphasize the importance of measuring MRP expression in normal cells as a point of reference and comparison for detection in malignant cells. We also recommend obtaining sequential specimens from patients, which may reveal an increased expression of MRP from baseline as the disease progresses and becomes resistant.