Toxicological Properties of 7-Methylguanine, and Preliminary Data on its Anticancer Activity.

7-Methylguanine (7-MG) competitively inhibits the DNA repair enzyme poly(ADP-ribose) polymerase (PARP) and RNA-modifying enzyme tRNA-guanine transglycosylase (TGT) and represents a potential anticancer drug candidate. Furthermore, as a natural compound, it could escape the serious side effects characteristic for approved synthetic PARP inhibitors. Here we present a comprehensive study of toxicological and carcinogenic properties of 7-MG. It was demonstrated that 7-MG does not induce mutations or structural chromosomal abnormalities, and has no blastomogenic activity. A treatment regimen with 7-MG has been established in mice (50 mg/kg per os, 3 times per week), exerting no adverse effects or changes in morphology. Preliminary data on the 7-MG anticancer activity obtained on transplantable tumor models support our conclusions that 7-MG can become a promising new component of chemotherapy.

First data on the structure of tubes formed by phoronids.

Phoronids are marine benthic animals that live in tubes in soft sediment or hard substrata; the phoronids form the tubes by digging or boring. Epidermal glands produce much of the material of the tube, which is completely imbedded in the soft sediment or hard substrata. The structure of phoronid tubes has not been previously studied in detail. In the current research, the morphology and microstructure of the tubes were studied by light microscopy, histology, and scanning electron microscopy for the following species: Phoronis ijimai, Phoronis svetlanae, Phoronis hipporcrepia, Phoronis australis, and Phoronopsis harmeri. In most of these species, the tube consists of an inner organic cylinder and an external layer. The inner organic cylinder is formed by three layers (inner, middle, and outer) of thin films. Each film is formed by fibers, whose thickness differs in different species. These fibers form a net, whose density is higher in digging phoronids than in boring phoronids. The middle layer is formed by highly compressed thin films. The outer layer is the densest portion of the inner cylinder and is associated with the external layer. The external layer is absent in some species (P. australis) but is well developed in digging phoronids. The differences in the organization of tube are consistent with the biology of each species and depend on the type of substrata and on the life style of the animal. Tube organization substantially differs between phoronids and sedentary annelids: the inner organic cylinder is much thicker in phoronid than in annelid tubes, and the fibers that form films are randomly oriented in phoronids but regularly oriented in annelids. In annelids but not in phoronids, inorganic particles in the external layer are usually surrounded and glued together by organic material. These differences may be used to distinguish phoronid tubes from annelid tubes in present-day benthic samples and also in fossil samples.

Novel isoenzyme of 2-oxoglutarate dehydrogenase is identified in brain, but not in heart.

2-Oxoglutarate dehydrogenase (OGDH) is the first and rate-limiting component of the multienzyme OGDH complex (OGDHC) whose malfunction is associated with neurodegeneration. The essential role of this complex in the degradation of glucose and glutamate, which have specific significance in brain, raises questions about the existence of brain-specific OGDHC isoenzyme(s). We purified OGDHC from extracts of brain or heart mitochondria using the same procedure of poly(ethylene glycol) fractionation, followed by size-exclusion chromatography. Chromatographic behavior and the insufficiency of mitochondrial disruption to solubilize OGDHC revealed functionally significant binding of the complex to membrane. Components of OGDHC from brain and heart were identified using nano-high performance liquid chromatography electrospray tandem mass spectrometry after trypsinolysis of the electrophoretically separated proteins. In contrast to the heart complex, where only the known OGDH was determined, the band corresponding to the brain OGDH component was found to also include the novel 2-oxoglutarate dehydrogenase-like (OGDHL) protein. The ratio of identified peptides characteristic of OGDH and OGDHL was preserved during purification and indicated comparable quantities of the two proteins in brain. Brain OGDHC also differed from the heart complex in the abundance of the components, lower apparent molecular mass and decreased stability upon size-exclusion chromatography. The functional competence of the novel brain isoenzyme and different regulation of OGDH and OGDHL by 2-oxoglutarate are inferred from the biphasic dependence of the overall reaction rate versus 2-oxoglutarate concentration. OGDHL may thus participate in brain-specific control of 2-oxoglutarate distribution between energy production and synthesis of the neurotransmitter glutamate.

Thermodynamic and kinetic stability of penicillin acylase from Escherichia coli.

Thermal denaturation of penicillin acylase (PA) from Escherichia coli has been studied by high-sensitivity differential scanning calorimetry as a function of heating rate, pH and urea concentration. It is shown to be irreversible and kinetically controlled. Upon decrease in the heating rate from 2 to 0.1 K min(-1) the denaturation temperature of PA at pH 6.0 decreases by about 6 degrees C, while the denaturation enthalpy does not change notably giving an average value of 31.6+/-2.1 J g(-1). The denaturation temperature of PA reaches a maximum value of 64.5 degrees C at pH 6.0 and decreases by about of 15 degrees C at pH 3.0 and 9.5. The pH induced changes in the denaturation enthalpy follow changes in the denaturation temperature. Increasing the urea concentration causes a decrease in both denaturation temperature and enthalpy of PA, where denaturation temperature obeys a linear relation. The heat capacity increment of PA is not sensitive to the heating rate, nor to pH, and neither to urea. Its average value is of 0.58+/-0.02 J g(-1) K(-1). The denaturation transition of PA is approximated by the Lumry-Eyring model. The first stage of the process is assumed to be a reversible unfolding of the alpha-subunit. It activates the second stage involving dissociation of two subunits and subsequent denaturation of the beta-subunit. This stage is irreversible and kinetically controlled. Using this model the temperature, enthalpy and free energy of unfolding of the alpha-subunit, and a rate constant of the irreversible stage are determined as a function of pH and urea concentration. Structural features of the folded and unfolded conformation of the alpha-subunit as well as of the transition state of the PA denaturation in aqueous and urea solutions are discussed.