The epidermal growth factor (EGF) receptor is a transmembrane polypeptide of 170 000 daltons (Da) with a cytoplasmically facing protein kinase domain. The regulation of the tyrosine kinase activity of the EGF receptor by added EGF and by receptor association state was studied in an in vitro system. The rate of autophosphorylation of the solubilized and purified EGF receptor was found to be independent of receptor concentration. To determine whether the zero-order kinetics observed point to intrapeptide phosphorylation, we measured the sedimentation characteristics of the undenatured solubilized receptor. The receptor was found to exist in two association-dissociation states-a monomeric 7.7S form and a dimeric 12S form. The 7.7S form is an active tyrosine kinase; it has high basal activity, and the activity is not further stimulated by EGF; it appears to be an EGF-independent form of the receptor kinase. The 12S form is devoid of catalytic activity, but in the presence of EGF it dissociates into the active monomeric form. Freshly purified receptor preparations contain mainly the monomeric receptor, have high basal kinase activity, and show low EGF stimulatability (less than 1.3-fold). Aging of the receptor results in progressive dimerization and decay of EGF-independent kinase activity (and increase in EGF stimulatability). All of these processes are reversed in the presence of EGF or dithiothreitol.(ABSTRACT TRUNCATED AT 250 WORDS)
The epidermal growth factor (EGF) receptor and other growth factor receptors have been shown to possess tyrosine-specific protein kinase activity. Before the demonstration of kinase activity in growth factor receptors, tyrosine kinases of molecular weight (MW) 60,000 (60K) were found to be encoded by the src oncogene and other oncogenes related to src. Our earlier work on intracellular processing of the EGF receptor, a 170,000-MW polypeptide, provided evidence for proteolytic separation of well defined structural domains, and suggested to us the possibility of separating functional domains by limited proteolysis. The isolation of such kinase domains should facilitate comparison of the receptor/kinase with other well characterized kinases including those of oncogene origin. We report here the identification of a catalytically functional 42K kinase derived proteolytically from the isolated human EGF receptor. This fragment, comparable in size to pp60src, carries the kinase ATP-binding site, and functions catalytically even after detachment from the EGF-binding site and the major autophosphorylation region.
Intact spermatozoa from rat cauda epididymis possess a Mg2+-dependent ATPase activity that hydrolyses externally added [gamma-32P]ATP. The ATPase reaction was linear with time for approx. 6 min and there was no detectable uptake of ATP by these cells. The ATPase activity of the whole spermatozoa was not due to leakage of the intracellular enzymic activity, contamination of the broken cells or any possible cell damage during incubation and isolation of spermatozoa. The activity of the enzyme was strongly inhibited (approx. 85%) by p-chloromercuribenzenesulphonic acid (50 microM) or the diazonium salt of sulphanilic acid (50 microM), which are believed not to enter the cells, whereas ouabain (0.5 mM), NaF (10 mM), NaN3 (2.5 mM) and oligomycin (5 microM) had no appreciable effect on the activity of the spermatozoal APTase. There was little loss of ATPase activity from the cells when washed with 0.5 mM-EDTA and an iso-osmotic or hyperosmotic medium. These data are consistent with the view that the observed ATPase activity is located on the external surface of spermatozoa. The sperm ecto-ATPase activity is resistant to the action of proteinases (50 micrograms/ml), namely trypsin, chymotrypsin and Pronase. Studies with various unlabelled phosphate esters indicate that the sperm ecto-ATPase is not a non-specific phosphatase and it has high degree of substrate specificity for ATP.
In West Bengal, India, although more than 6 million people are exposed to arsenic through drinking water, only 15-20% showed arsenic-induced skin lesions, including premalignant hyperkeratosis. This indicates toward some factors that confer susceptibility to arsenic-induced carcinogenicity. In this work, we wanted to explore whether differences in DNA repair capacity could impart arsenic-induced carcinogenicity, through Comet assay, chromosomal aberration (CA) assay and challenge assay. Sixty arsenic exposed (30 individuals with arsenic-induced premalignant hyperkeratosis and 30 without skin lesion, but drinking similar arsenic contaminated water) and 30 arsenic unexposed individuals were recruited as study participants. Alkaline comet assay, and challenge assay were carried out in whole blood and CA study in lymphocytes to find out the DNA damage and DNA repair capacity in both hyperkeratotic and without skin lesion individuals. DNA damage as well as CA were found to be significantly higher in the arsenic-exposed individuals compared to unexposed individuals (p < 0.001). Within the exposed group, there was no significant difference as far as the level of DNA damage is concerned (p > 0.05), but CA was significantly higher in exposed individuals with hyperkeratosis than exposed individuals without hyperkeratosis (p < 0.01). Challenge assay showed that upon induction of DNA damage, the repair capacity in the exposed individuals with premalignant hyperkeratosis is significantly less (p < 0.001) than that of individuals without skin lesion, although the basal level of DNA damage was similar in both. Thus, the deficiency in DNA repair capacities in the hyperkeratotic individuals emerges as a prime contender for arsenic carcinogenicity. ' 2008 Wiley-Liss, Inc.Key words: arsenic susceptibility; premalignant hyperkeratosis; challenge assay; DNA damage; DNA repair In West Bengal, India, ground water of 9 districts is contaminated with arsenic, concentrations ranging from 52-1055 lg/l, much higher than the current permissible maximum contamination level.1,2 More than 6 million people are exposed to arsenic in these districts. This is considered as the greatest arsenic calamity in the world. Long-term exposure to arsenic-contaminated drinking water causes a wide array of adverse health effects, principally, characteristic dermatological symptoms like raindrop pigmentation, palmo-plantar hyperkeratosis and hypo and hyperpigmentation and might ultimately lead to cancer of skin, lung and/or bladder.3 Hyperkeratosis of skin is considered as a precursor of arsenic-induced skin cancer, 4,5 as skin cancers often appear at the sites of existing hyperkeratosis. 6 A strong relationship between arsenic levels in water with the prevalence of hyperkeratosis in the exposed individuals has been reported earlier.7 Additionally, chronic arsenic exposure might also cause vascular diseases, conjunctivitis in the eyes, neuropathy, lung diseases and nonmelanocytic cancer of skin and different internal organs.7 Anomalously enough, of the huge...
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