ABSTRACT
Multiple DNases were identified from Haemonchus contortus intestine based on previous studies. The DNases detected at 34, 36 and 38.5 kDa had diverse characteristics. Some of them had characteristics similar to those of mammalians and others had unusual characteristics. This study was carried out to fractionate worm intestinal DNases from other proteins using phenyl Sepharose chromatographic methods. All DNases detected from Haemonchus contortus intestine were fractionated in the flowthrough of phenyl Sepharose, indicating the worm DNases are hydrophilic. The DNases were enriched five-fold in the flowthrough fraction while additional steps are required for isolation of the worm DNases. Thus, fractionation with phenyl Sepharose could be used as a good initial step to enrich and separate DNases from other proteins.
Subject(s)
Chromatography , Deoxyribonucleases , Haemonchus , Intestines , Proteins , SepharoseABSTRACT
Multiple DNases were identified from Haemonchus contortus intestine based on previous studies. The DNases detected at 34, 36 and 38.5 kDa had diverse characteristics. Some of them had characteristics similar to those of mammalians and others had unusual characteristics. This study was carried out to fractionate worm intestinal DNases from other proteins using phenyl Sepharose chromatographic methods. All DNases detected from Haemonchus contortus intestine were fractionated in the flowthrough of phenyl Sepharose, indicating the worm DNases are hydrophilic. The DNases were enriched five-fold in the flowthrough fraction while additional steps are required for isolation of the worm DNases. Thus, fractionation with phenyl Sepharose could be used as a good initial step to enrich and separate DNases from other proteins.
Subject(s)
Chromatography , Deoxyribonucleases , Haemonchus , Intestines , Proteins , SepharoseABSTRACT
Hydroxyurea, when injected intraperitoneally at a dose of 1 mg/g body weight, inhibited thymidine kinase activity in developing rat cerebrum (16-day-embryonic) and cerebellum (7-day-postnatal) within a few hours of administration. The inhibition was timedependent and both cytosolic and mitochondrial thymidine kinases were affected. Under the same conditions, the activities of certain other enzymes concerned with DNA metabolism, viz., DNA polymerase, and acid and alkaline DNases were not inhibited. Further, the addition of hydroxyurea in vitro had no effect on the activity of any of the enzymes studied. However, similar treatment given to 2-year-old rat failed to exert any inhibition on either the mitochondrial or soluble thymidine kinase activities in grey and white matter regions of cerebrum and cerebellum. It is inferred that hydroxyurea, apart from its already known effect on ribonucleotide reductase of replicating cells, also affects thymidine kinase.
ABSTRACT
The effect of early postnatal undernutrition and subsequent rehabilitation on wet weight, DNA, RNA, protein and the activities of acid and alkaline DNases in the cerebellar region of rat brain was studied. The cerebellar region was found to be affected significantly during early undernutrition. Further, earlier the initiation of nutritional rehabilitation the better was the recovery and in some cases timely nutritional rehabilitation resulted in better than normal biochemical composition of the brain. The specific activities of acid and alkaline DNases were not affected by early undernutrition. However, the total activities of these enzymes were significantly low in undernourished rats (R15 and R21) Rehabilitation of these deprived groups upto 150 days resulted in higher amounts of these enzymes as compared to those of age-matched controls. It is concluded that the two DNases, are synthesized in a preferential manner during rehabilitation, It is further concluded that cerebellar region, in terms of development schedule and response to imposed calorie restriction, is intermediary between grey and white matter regions.
ABSTRACT
The content of DNA, RNA and protein in cerebellum at different stages of the life span of rat as well as the ratios of protein to DNA, showed-that in this region extensive cell proliferation occurs between the 1st and 7th day after birth and once again between the ages of 225 and 750 days. The putative DNA degrading enzymes, acid and alkaline DNases, showed a positive correlation with the rapid DNA accretion noticed during developmental stages as well as during old age. From these results, it could be presumed that there was a second bout of glial cell multiplication in aging cerebellum and that DNases must be playing some important role in the process.