Gene/Protein
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Target Concepts:
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Query: EC:2.7.1.21 (
thymidine kinase
)
7,561
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
BOT
-2 cells (human breast tumor origin) have an impaired ability to utilize exogenous thymidine. Previous studies revealed this deficiency to be the permeation event rather than phosphorylation, since the cells have active
thymidine kinase
. Chromosome-mediated gene transfer was used to transfer genetic information in the form of metaphase chromosomes, from HeLa-65 cells to the
BOT
-2 cells, correcting the permease deficiency. Poly-L-ornithine or lipochromes were used for facilitation of chromosome uptake. After selection on HAT medium, transferant clones were isolated at a frequency of 4 x 10(-5) and 1 x 10(-5), respectively. Transferants MGP-1 and MGL-1 are stable after 18 months and have been characterized on the bases of purine and pyrimidine nucleoside uptake, relative
thymidine kinase
activities, alkaline phosphatase activities, and hydrocortisone-induced alkaline phosphatase activity. MGP-1 demonstrates positive thymidine uptake and incorporates radiolabeled thymidine into DNA. MGL-1 remains thymidine transport-deficient and surveys on HAT by increasing endogenous dihydrofolate reductase activity. Alkaline phosphatase activity in MGL-1 is similar to HeLa-65, 2% of that in
BOT
-2, and in addition, is inducible 25-30-fold by 3 micro M hydrocortisone. We have separated, genetically, a thymidine permease function from phosphorylation in cells of human origin and have transferred genetic information for the regulation of alkaline phosphatase.
...
PMID:Alteration of human breast tumor cell membrane functions by chromosome-mediated gene transfer. 23 36
Plants adjust their sink-organ growth rates, development and distribution of dry matter in response to whole-plant photosynthate status. To advance understanding of these processes, potato (Solanum tuberosum L.) plants were subjected to CO(2) and light flux treatments, and early tuber growth was assessed. Atmospheric CO(2) (700 or 350 micro mol mol(-1)) and light flux (shade and control illumination) treatments were imposed at two growth stages: tuber initiation (TI) and tuber bulking (TB). Elevated CO(2) increased accumulation of total net biomass when imposed at both stages, and increased tuber growth rate by about 36 %, but did not increase the number of tubers. Elevated CO(2) increased the number of cells in tubers at both TI and TB stages, whereas shade substantially decreased the number of cells at both stages. Generally, treatments did not affect cell volume or the proportion of nuclei endoreduplicating (repeated nuclear DNA replication in the absence of cell division), but the shade treatment led to a decrease in cell volume at TB and a decrease in endoreduplication at TI. Elevated CO(2) increased, and shade decreased, glucose concentration and soluble invertase activity in the cambial zones at both TI and TB, whereas sucrose concentration and activities of glucokinase, fructokinase, cell-wall-bound invertase and
thymidine kinase
were unaffected. Modulation of tuber cell division was responsible for much of the growth response to whole-plant photosynthate status, and treatments affected cambial-zone glucose and soluble invertase in a pattern suggesting involvement of a glucose signalling pathway.
Ann
Bot
2003 Feb
PMID:Response of potato tuber cell division and growth to shade and elevated CO2. 1254 90
A fluoroorotic acid (FOA)-resistant mutant of Arabidopsis thaliana was isolated by screening M2 populations of ethyl methane sulphonate (EMS)-mutagenized Columbia seed. FOA resistance was due to a nuclear recessive gene, for1-1, which locates to a 519 kb region in chromosome 5. Assays of key regulatory enzymes in de novo pyrimidine synthesis (uridine monophosphate synthase) and salvage biochemistry (
thymidine kinase
) confirmed that FOA resistance in for1-1/for1-1 plants was not due to altered enzymatic activities. Uptake studies using radiolabelled purines, pyrimidines, and [14C]FOA reveal that for1-1/for1-1 plants were specifically defective in the uptake of uracil or uracil-like bases. To confirm such specificity, genetic crosses show that FOR1 is a distinct locus from FUR1 which encodes a deoxyuridine nucleoside transporter. In addition, for1-1/for1-1 plants were restored to FOA sensitivity by transformation with the Escherichia coli uracil transporter gene uraA driven by the cauliflower mosaic virus (CaMV) 35S promoter. Molecular mapping studies reveal that FOR1 does not correspond to loci belonging to any of the six known nucleobase transporter families identified in the Arabidopsis genome. Moreover, FOR1 does not appear to regulate the transcript levels of either uracil transporter-encoding loci At2g03590 or At2g03530. The above results strongly suggest that the for1-1 mutant allele affects a transport mechanism that is specific for the uptake of uracil.
J Exp
Bot
2006
PMID:A fluoroorotic acid-resistant mutant of Arabidopsis defective in the uptake of uracil. 1696 82
