Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:3.1.4.1 (phosphodiesterase)
 18,767 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

We identify a new enzymatic activity underlying metastasis in breast cancer and describe its susceptibility to therapeutic inhibition. We show that human prune (h-prune), a phosphoesterase DHH family appertaining protein, has a hitherto unrecognized cyclic nucleotide phosphodiesterase activity effectively suppressed by dipyridamole, a phosphodiesterase inhibitor. h-prune physically interacts with nm23-H1, a metastasis suppressor gene. The h-prune PDE activity, suppressed by dipyridamole and enhanced by the interaction with nm23-H1, stimulates cellular motility and metastasis processes. Out of 59 metastatic breast cancer cases analyzed, 22 (37%) were found to overexpress h-prune, evidence that this novel enzymatic activity is involved in promoting cancer metastasis.
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PMID:Prune cAMP phosphodiesterase binds nm23-H1 and promotes cancer metastasis. 1499 90

H-prune, a new cyclic nucleotide phosphodiesterase, binds to nm23-H1, a metastasis suppressor protein. The overexpression of h-prune in the MDA-MB-435 breast carcinoma cell line causes a substantial decrease of cAMP, and an increase in cellular motility. This latest effect is correlated both to the h-prune phosphodiesterase activity and to the interaction between h-prune and nm23-H1 proteins. Understanding the molecular changes in tumor cells with an increased level of expression of h-prune might shed light on motility processes, which are the driving forces of the cells to move away from the primary tumor and to become metastatic. This report overview genes and pathways influenced by h-prune overexpression in a conventional breast cancer cellular model.
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PMID:Unraveling genes and pathways influenced by H-prune PDE overexpression: a model to study cellular motility. 1525 13

The combination of an increase in the cAMP-phosphodiesterase activity of h-prune and its interaction with nm23-H1 have been shown to be key steps in the induction of cellular motility in breast cancer cells. Here we present the molecular mechanisms of this interaction. The region of the nm23-h-prune interaction lies between S120 and S125 of nm23, where missense mutants show impaired binding; this region has been highly conserved throughout evolution, and can undergo serine phosphorylation by casein kinase I. Thus, the casein kinase I delta-epsilon specific inhibitor IC261 impairs the formation of the nm23-h-prune complex, which translates 'in vitro' into inhibition of cellular motility in a breast cancer cellular model. A competitive permeable peptide containing the region for phosphorylation by casein kinase I impairs cellular motility to the same extent as IC261. The identification of these two modes of inhibition of formation of the nm23-H1-h-prune protein complex pave the way toward new challenges, including translational studies using IC261 or this competitive peptide 'in vivo' to inhibit cellular motility induced by nm23-H1-h-prune complex formation during progression of breast cancer.
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PMID:Phosphorylation of nm23-H1 by CKI induces its complex formation with h-prune and promotes cell motility. 1790 97

The h-prune protein is a member of the DHH protein superfamily, and its overexpression in breast, colorectal and gastric cancers correlates with depth of invasion and degree of lymph-node metastasis. Taken together with the observation that h-prune is highly expressed in metastatic breast cancer, this suggests that h-prune can be used as a marker for the identification of subsets of cancer patients with highly aggressive tumours. H-prune possesses a phosphodiesterase (cAMP-PDE) activity, and inhibition of PDE activity with dipyridamole suppresses cell motility. H-prune interacts with nm23-H1, GSK-3beta and gelsolin. Although a correlation between an h-prune PDE activity and cellular motility has been shown, GSK-3beta does not affect the PDE activity of h-prune. Inhibition of the interactions between h-prune and GSK-3beta and nm23-H1 additively suppresses the migration of colon cancer and breast cancer cells, thus suggesting that h-prune regulates cell motility by two different means of action: through its PDE activity and in its interactions with protein partners. Therefore, the identification of highly specific inhibitors of h-prune should be useful in the development of drugs to treat cancer metastasis.
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PMID:Understanding h-prune biology in the fight against cancer. 1795 13

The DHH superfamily human protein h-prune, a binding partner of the metastasis suppressor nm23-H1, is frequently overexpressed in metastatic cancers. From an evolutionary perspective, h-prune is very close to eukaryotic exopolyphosphatases. Here, we show for the first time that h-prune efficiently hydrolyzes short-chain polyphosphates (k cat of 3-40 s (-1)), including inorganic tripoly- and tetrapolyphosphates and nucleoside 5'-tetraphosphates. Long-chain inorganic polyphosphates (>or=25 phosphate residues) are converted more slowly, whereas pyrophosphate and nucleoside triphosphates are not hydrolyzed. The reaction requires a divalent metal cofactor, such as Mg (2+), Co (2+), or Mn (2+), which activates both the enzyme and substrate. Notably, the exopolyphosphatase activity of h-prune is suppressed by nm23-H1, long-chain polyphosphates and pyrophosphate, which may be potential physiological regulators. Nucleoside triphosphates, diadenosine hexaphosphate, cAMP, and dipyridamole (inhibitor of phosphodiesterase) do not affect this activity. Mutation of seven single residues corresponding to those found in the active site of yeast exopolyphosphatase led to a severe decrease in h-prune activity, whereas one variant enzyme exhibited enhanced activity. Our results collectively suggest that prune is the missing exopolyphosphatase in animals and support the hypothesis that the metastatic effects of h-prune are modulated by inorganic polyphosphates, which are increasingly recognized as critical regulators in cells.
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PMID:Human metastasis regulator protein H-prune is a short-chain exopolyphosphatase. 1870 Jul 47