Attempts to detect transgenic and endogenous plant DNA and transgenic protein in muscle from broilers fed YieldGard Corn Borer Corn.

Questions regarding the digestive fate of DNA and protein from transgenic grain have been raised in regard to human consumption and trade of animal products (e.g., meat, milk, and eggs) from farm animals fed transgenic crops. Using highly sensitive, fully characterized analytical methods, fragments of transgenic and endogenous plant DNA, as well as transgenic protein, were not detected in chicken breast muscle samples from animals fed YieldGard Corn Borer Corn event MON 810 (YG). Total DNA was extracted from breast muscle samples from chickens fed for 42 d with a diet including either 55 to 60% YG grain or 55 to 60% conventional corn grain. DNA preparations were analyzed by PCR followed by Southern blot hybridization for the presence of a 211-bp fragment of the Bacillus thuringiensis (Bt) cry1Ab gene and a 213-bp fragment of the endogenous corn gene sh2 (encoding ADP glucose pyrophosphorylase). By using 1 microg of input DNA per reaction, none of the extracted samples was positive for cry1Ab or sh2 at the limit of detection for these PCR assays. A 396-bp fragment of the chicken ovalbumin (ov) gene, used as a positive control, was amplified from all samples showing that the DNA preparations were amenable to PCR amplification. By using a competitive immunoassay with a limit of detection of approximately 60 ng of CrylAb protein per gram of chicken muscle, neither the CrylAb protein nor immunoreactive peptide fragments were detectable in the breast muscle homogenates from chickens fed YG grain.

Cell cycle-coupled variation in topoisomerase IIalpha mRNA is regulated by the 3'-untranslated region. Possible role of redox-sensitive protein binding in mRNA accumulation.

Mammalian topoisomerase IIalpha (Topo II) is a highly regulated enzyme essential for many cellular processes including the G(2) cell cycle checkpoint. Because Topo II gene expression is regulated posttranscriptionally during the cell cycle, we investigated the possible role of the 3'-untranslated region (3'-UTR) in controlling Topo II mRNA accumulation. Reporter assays in stably transfected cells demonstrated that, similar to endogenous Topo II mRNA levels, the mRNA levels of reporter genes containing the Topo II 3'-UTR varied during the cell cycle and were maximal in S and G(2)/M relative to G(1). Topo II 3'-UTR sequence analysis and RNA-protein binding assays identified a 177-nucleotide (base pairs 4772-4949) region containing an AUUUUUA motif sufficient for protein binding. Multiple proteins (84, 70, 44, and 37 kDa) bound this region, and the binding of 84- and 37-kDa (tentatively identified as the adenosine- or uridine-rich element-binding factor AUF1) proteins was enhanced in G(1), correlating with decreased Topo II mRNA levels. The binding activity was enhanced in cellular extracts or cells treated with thiol-reducing agents, and increased binding correlated with decreased Topo II mRNA levels. These results support the hypothesis that cell cycle-coupled Topo II gene expression is regulated by interaction of the 3'-UTR with redox-sensitive protein complexes.

Proto-oncogene mRNA levels and activities of multiple transcription factors in C3H 10T 1/2 murine embryonic fibroblasts exposed to 835.62 and 847.74 MHz cellular phone communication frequency radiation.

This study was designed to determine whether two differently modulated radiofrequencies of the type generally used in cellular phone communications could elicit a general stress response in a biological system. The two modulations and frequencies studied were a frequency-modulated continuous wave (FMCW) with a carrier frequency of 835.62 MHz and a code division multiple-access (CDMA) modulation centered on 847.74 MHz. Changes in proto-oncogene expression, determined by measuring Fos, Jun, and Myc mRNA levels as well as by the DNA-binding activity of the AP1, AP2 and NF-kappaB transcription factors, were used as indicators of a general stress response. The effect of radiofrequency exposure on proto-oncogene expression was assessed (1) in exponentially growing C3H 10T 1/2 mouse embryo fibroblasts during their transition to plateau phase and (2) during transition of serum-deprived cells to the proliferation cycle after serum stimulation. Exposure of serum-deprived cells to 835.62 MHz FMCW or 847.74 MHz CDMA microwaves (at an average specific absorption rate, SAR, of 0.6 W/kg) did not significantly change the kinetics of proto-oncogene expression after serum stimulation. Similarly, these exposures did not affect either the Jun and Myc mRNA levels or the DNA-binding activity of AP1, AP2 and NF-kappaB in exponential cells during transit to plateau-phase growth. Therefore, these results suggest that the radiofrequency exposure is unlikely to elicit a general stress response in cells of this cell line under these conditions. However, statistically significant increases (approximately 2-fold, P = 0.001) in Fos mRNA levels were detected in exponential cells in transit to the plateau phase and in plateau-phase cells exposed to 835.62 MHz FMCW microwaves. For 847.74 MHz CDMA exposure, the increase was 1.4-fold (P = 0.04). This increase in Fos expression suggests that expression of specific genes could be affected by radiofrequency exposure.

Regulation of transcriptional activation of mdm2 gene by p53 in response to UV radiation.

The mdm2 oncogene is expressed at elevated levels in a variety of human tumors, and its product inactivates the p53 tumor suppressor protein. MDM2 forms an autoregulatory loop with p53, because the mdm2 gene contains a promoter that is responsive to p53. Synthesis of MDM2 protein increases in a p53-dependent manner in response to DNA-damaging agents such as UV light. Although this increase likely results from enhanced transcription, the amount of MDM2 protein does not correspond to the amount of p53 protein in cells exposed to UV light. Here we show that the p53-specific internal promoter in the mdm2 gene is induced after exposure to UV light, whereas the upstream constitutive promoter is not induced. The amount of the mdm2 transcript does not parallel the ability of p53 to bind DNA, indicating that transcription is regulated at a step distinct from activation of the DNA-binding function of p53.

A polymerase chain reaction assay for simultaneous detection and quantitation of proto-oncogene and GAPD mRNAs in different cell growth rates.

A reverse transcriptase followed by a polymerase chain-reaction (RT-PCR) assay was developed for the simultaneous detection and quantitation of proto-oncogene (c-fos and c-myc) mRNAs using an internal standard mRNA glyceraldehyde-6-phosphate dehydrogenase (GAPD). Total cellular RNA was reverse transcribed and PCR amplified with oligonucleotide primers specific to GAPD and either c-fos or c-myc genes. In contrast to Northern blot analysis, the RT-PCR assay is rapid and sensitive enough to quantitate specific proto-oncogene levels from as little as 12-25 ng of total cellular RNA. The reliability of the assay was tested by measuring c-fos and c-myc expression in C3H 10T1/2 mouse embryo fibroblast cells under two different growth states: (a) quiescent cell entry into the proliferative cycle, and (b) plateau phase. Furthermore, the assay was used in measuring variations in c-fos or c-myc expression in HA-1 hamster cells following exposure to the cellular stressing agent, nitric oxide. In serum-stimulated cells, the RT-PCR measurements of transient increase in c-fos (16-fold at 30 min) and c-myc (10-fold at 1 h) mRNA levels were comparable to previously reported results in the literature using a Northern blotting assay. In addition, a two- to fivefold increase in c-fos mRNA levels was observed in plateau phase cells when compared to log phase growth. Furthermore, a transient increase in c-fos mRNA levels (threefold at 2 h) was also observed following cells' exposure to the stressing agent nitric oxide. These results suggest that the multiplex RT-PCR assay represents a significant improvement over current methods to quantitate specific cellular mRNAs under different growth conditions or following environmental insults.