Traditional and novel techniques were tested and compared for their usefulness in evaluating biodegradability claims made for newly formulated "degradable" plastic film products. Photosensitized polyethylene (PE), starch-PE, extensively plasticized polyvinyl chloride (PVC), and polypropylene (PP) films were incorporated into aerobic soil. Biodegradation was measured for 3 months under generally favorable conditions. Carbon dioxide evolution, residual weight recovery, and loss of tensile strength measurements were supplemented, for some films, by gas chromatographic measurements of plasticizer loss and gel permeation chromatographic (GPC) measurement of polymer molecular size distribution. Six-and 12-week sunlight exposures of photosensitized PE films resulted in extensive photochemical damage that failed to promote subsequent mineralization in soil. An 8% starch-PE film and the plasticized PVC film evolved significant amounts of CO2 in biodegradation tests and lost residual weight and tensile strength, but GPC measurements demonstrated that all these changes were confined to the additives and the PE and PVC polymers were not degraded. Carbon dioxide evolution was found to be a useful screening tool for plastic film biodegradation, but for films with additives, polymer biodegradation needs to be confirmed by GPC. Photochemical cross-linking of polymer strands reduces solubility and may interfere with GPC measurements of polymer degradation.
The Cdc7/Dbf4 kinase is required for initiation of DNA replication and also plays a role in checkpoint function in response to replication stress. Exactly how Cdc7/Dbf4 mediates those activities remains to be elucidated. Cdc7/Dbf4 physically interacts with and phosphorylates the minichromosome maintenance complex (MCM), such as MCM2, MCM4 and MCM6. Cdc7/Dbf4 activity is required for association of Cdc45 followed by recruitment of DNA polymerase on the chromatin. Using high resolution mass spectrometry, we identified six phosphorylation sites on MCM2, two of them have not been described before. We provide evidence that Cdc7/Dbf4 mediates phosphorylation on serine 108 and serine 40 on human MCM2 in vitro and in vivo in cancer cells in the absence of DNA damage. Antibodies specific to pS108 or pS40 confirmed the sites and established useful read-outs for inhibition of Cdc7/Dbf4. This report demonstrates the utility of an in vitro to in vivo workflow utilizing immunoprecipitation and mass spectrometry to map phosphorylation sites on endogenous kinase substrates. The approach can be readily generalized to identify target modulation read-outs for other potential kinase cancer targets.
Pseudomonas pickettii YH105 was isolated for its ability to utilize p-nitrobenzoate as the sole source of carbon, nitrogen, and energy. Degradation of p-nitrobenzoate by this strain proceeds through a reductive route as evidenced by the accumulation of ammonia in the culture medium during growth on p-nitrobenzoate. Enzyme assays and high-performance liquid chromatography (HPLC) analysis of culture supernatants indicate that p-nitrobenzoate is degraded through p-hydroxylaminobenzoate and protocatechuate. In order to clone the genes responsible for the initial steps in the catabolic pathway, a cosmid library was constructed with P. pickettii YH105 genomic DNA. The library was screened for clones capable of transforming p-nitrobenzoate to protocatechuate, using a plate assay specific for diphenolic compounds. HPLC analysis of culture supernatants confirmed that the cosmid clones did indeed produce protocatechuate from p-nitrobenzoate. Five positive cosmid clones that possessed this activity were identified. Restriction digests of the cosmid clones indicated that all of the clones had two EcoRI fragments in common (3.9 and 1.0 kb). One of these cosmid clones, designated pGJZ1601, was chosen for further analysis. Subcloning and activity assay experiments localized the genes responsible for the conversion of p-nitrobenzoate to protocatechuate to a 1.4-kb SalI-SphI DNA fragment. Further subcloning experiments localized the gene coding for p-nitrobenzoate reductase, responsible for the first enzymatic step in the catabolic pathway, to a 0.8-kb SalI-ApaI DNA fragment. The gene for the second step in the catabolic pathway, coding for hydroxylaminolyase, was located adjacent to the gene for the p-nitrobenzoate reductase.
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