Timothy R. Schwartz scite author profile

Three-hundred ninety-two adult Dermacentor variabilis were collected from six Maryland counties during the spring, summer, and fall of 2002. Infection prevalence for spotted fever group Rickettsia was 3.8%, as determined by polymerase chain reaction. Single strand conformational polymorphism (SSCP) analysis followed by sequencing indicated that all infections represented a single rickettsial taxon, Rickettsia montanensis .

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Recovery of cell cycle delay following targeted gene repair by oligonucleotides

Ferrara

Engstrom

Schwartz

et al. 2007

DNA Repair

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We have previously shown that activation of the homologous recombinational repair pathway leads to a block of cell division in corrected cells, possibly through the activity of checkpoint proteins Chk1 and Chk2. In this study, we examine the long term impact of this stalling on the growth of cells that have enabled gene repair events. Using a mutated eGFP gene as an episomal reporter, we show that corrected (eGFP positive) cells contain only a few active replication templates two weeks after electroporation, yet do not display an apoptotic or senescent phenotype. By six weeks after electroporation, cells resume active replication with a cell cycle profile that is comparable to that of the non-corrected (eGFP negative) population. These results indicate that the initial stalling is transient and eGFP positive cells eventually resume a normal phenotypic growth pattern, allowing for passaging and expansion in vitro.

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G-Rich Oligonucleotides Alter Cell Cycle Progression and Induce Apoptosis Specifically in OE19 Esophageal Tumor Cells

et al. 2008

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Short synthetic oligonucleotides (ODNs) can be used to block cellular processes involved in cell growth and proliferation. Often acting as aptamers, these molecules interact with critical proteins that regulate the induction of apoptosis or necrosis. We have used a specialized class of ODNs that contain a monomeric sequence of guanosine to induce apoptosis specifically in the malignant esophageal cell line, OE19, in cell culture, and in a NODscid mouse model. OE19 cells were grown in culture and treated with a stable G-rich oligonucleotide (GRO). Cells were processed and apoptosis was measured by FACS analyses, caspase activity, and Hoescht staining. Circular dichroism (CD) was used to define the structure and stability of various GROs. The GRO works by first inducing retardation in the progression of the cell cycle and then by creating a sub-G1 population of apoptotic cells. The reaction is dose dependent, and appears to rely on the capacity of the G-rich ODN to adopt a G-quartet conformation. Apoptosis was measured by determining caspase 3/7 levels and by staining for nuclear fragmentation using the Hoechst dye. Importantly, nonmalignant esophageal cells or normal human lung fibroblasts are not impeded in their cell cycle progression when incubated with the G-rich ODNs. These results suggest that a selective killing of esophageal tumor cells is directed by G-rich ODNs. Selective killing was demonstrated in the unique activity of the GRO compared to other ODNs of different sequences as well as the response of oncogenic cells compared to nononcogenic cells.

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