Equivalencies: 0 | Classes: 0 | Children: 0 | Explore

Appears in Networks 3

In-Edges 12

complex(a(GO:"protein phosphatase type 2A complex"), p(HGNC:PPME1)) increases act(p(HGNC:PPME1)) View Subject | View Object

Thus, PME-1 appears to exist in an inactive conformation in the absence of PP2A binding. PubMed:19277525

a(CHEBI:"microcystin-LR") decreases act(p(HGNC:PPME1)) View Subject | View Object

The structural feature that PME-1 binds directly to the PP2A active site, overlapping the binding sites for OA and MCLR, also explains why these phosphatase inhibitors blocked the methylesterase activity of PME-1 PubMed:19277525

a(CHEBI:"okadaic acid") decreases act(p(HGNC:PPME1)) View Subject | View Object

The structural feature that PME-1 binds directly to the PP2A active site, overlapping the binding sites for OA and MCLR, also explains why these phosphatase inhibitors blocked the methylesterase activity of PME-1 PubMed:19277525

complex(a(GO:"protein phosphatase type 2A complex"), p(HGNC:PPME1)) increases act(p(HGNC:PPME1)) View Subject | View Object

Structural analysis of the heterotrimeric PME-1-PP2A complex showed that PME-1 is only activated upon binding to PP2A (Figure 4, left panel). PubMed:19277525

complex(a(GO:"protein phosphatase type 2A complex"), p(HGNC:PPME1)) increases act(p(HGNC:PPME1)) View Subject | View Object

Interestingly, although PME-1 is activated by PP2A binding, the catalytic subunit of PP2A is inactivated in this process, not just through demethylation but also by loss of the catalytic metal ions PubMed:19277525

act(p(HGNC:LCMT1)) negativeCorrelation act(p(HGNC:PPME1)) View Subject | View Object

PME-1 catalyzes removal of the methyl group, thus reversing the activity of LCMT1 PubMed:19277525

act(complex(GO:"protein phosphatase type 2A complex")) negativeCorrelation p(HGNC:PPME1) View Subject | View Object

For example, PME-1 stabilizes a nuclear pool of inactive PP2A enzymes (Longin et al., 2008), while methylation by LCMT1 influences the amounts of PP2A enzymes bound to plasma membrane microdomains (Sontag et al.,2013). PubMed:24653673

act(p(HGNC:GSK3B)) increases act(p(HGNC:PPME1)) View Subject | View Object

For instance, activated GSK3β has been reported to induce PP2A inactivation via several mechanisms: phosphorylation of PP2A on Tyr307 (Yao et al.,2011); demethylation of PP2A on Leu309 through inhibition of LCMT1 and up-regulation of PME1 (Yao et al.,2012); and accumulation of I2 PP2A (Liu et al.,2008a). PubMed:24653673

Out-Edges 12

p(HGNC:PPME1) decreases p(HGNC:PPP2CA, pmod(Me, Leu, 309)) View Subject | View Object

Reversible methylation of PP2A is catalyzed by two highly conserved and PP2A-specific enzymes, leucine carboxyl methyltransferase (LCMT1)[21,33] and PP2A methylesterase (PME-1)[17] (Figure 1). PubMed:19277525

p(HGNC:PPME1) decreases p(HGNC:PPP2CA, pmod(Me, Leu, 309)) View Subject | View Object

PME-1 catalyzes removal of the methyl group, thus reversing the activity of LCMT1 PubMed:19277525

p(HGNC:PPME1) decreases p(HGNC:PPP2CA, pmod(Me, Leu, 309)) View Subject | View Object

Recent evidence suggests a broader role for PME-1 than just being a demethylating enzyme for the catalytic subunit of PP2A PubMed:19277525

act(p(HGNC:PPME1)) negativeCorrelation act(p(HGNC:LCMT1)) View Subject | View Object

PME-1 catalyzes removal of the methyl group, thus reversing the activity of LCMT1 PubMed:19277525

p(HGNC:PPME1) increases complex(a(GO:"protein phosphatase type 2A complex"), p(HGNC:PPME1)) View Subject | View Object

A portion of cellular PP2A stably associated with PME-1 and was catalytically inactive [80]; intriguingly, this inactive portion of PP2A could be re-activated by PP2A phosphatase activator (PTPA), but not by LCMT1, ruling out the possibility that inactivation was solely caused by demethylation PubMed:19277525

p(HGNC:PPME1) directlyIncreases complex(a(GO:"protein phosphatase type 2A complex"), p(HGNC:PPME1)) View Subject | View Object

The structural feature that PME-1 binds directly to the PP2A active site, overlapping the binding sites for OA and MCLR, also explains why these phosphatase inhibitors blocked the methylesterase activity of PME-1 PubMed:19277525

p(HGNC:PPME1) decreases act(complex(GO:"protein phosphatase type 2A complex")) View Subject | View Object

Structural observations clearly indicate that PME-1 inactivates the phosphatase activity of PP2A PubMed:19277525

p(HGNC:PPME1) increases complex(p(HGNC:PPME1), p(HGNC:PPP2CA)) View Subject | View Object

Conversely, the PP2A-specific methylesterase PME-1 can directly bind to the active site of the catalytic subunit, remove the methyl group and inactivate PP2A by evicting manganese ions required for phosphatase activity (Xing et al.,2008). PubMed:24653673

p(HGNC:PPME1) increases complex(p(HGNC:PPME1), p(HGNC:PPP2CB)) View Subject | View Object

Conversely, the PP2A-specific methylesterase PME-1 can directly bind to the active site of the catalytic subunit, remove the methyl group and inactivate PP2A by evicting manganese ions required for phosphatase activity (Xing et al.,2008). PubMed:24653673

p(HGNC:PPME1) negativeCorrelation act(complex(GO:"protein phosphatase type 2A complex")) View Subject | View Object

For example, PME-1 stabilizes a nuclear pool of inactive PP2A enzymes (Longin et al., 2008), while methylation by LCMT1 influences the amounts of PP2A enzymes bound to plasma membrane microdomains (Sontag et al.,2013). PubMed:24653673

act(p(HGNC:PPME1)) decreases p(HGNC:PPP2CA, pmod(Me, Leu, 309)) View Subject | View Object

For instance, activated GSK3β has been reported to induce PP2A inactivation via several mechanisms: phosphorylation of PP2A on Tyr307 (Yao et al.,2011); demethylation of PP2A on Leu309 through inhibition of LCMT1 and up-regulation of PME1 (Yao et al.,2012); and accumulation of I2 PP2A (Liu et al.,2008a). PubMed:24653673

p(HGNC:PPME1) decreases p(FPLX:PPP2C, pmod(Me)) View Subject | View Object

Car- boxyl methylation of the catalytic subunit is required for efficient in vivo assembly of the trimer C, A, and B [63-65]; a process that is balanced by the opposite actions of methyl- transferase type IV (PPMT) and the methylesterase PME-1 [66-70]. PubMed:22299660

About

BEL Commons is developed and maintained in an academic capacity by Charles Tapley Hoyt and Daniel Domingo-Fernández at the Fraunhofer SCAI Department of Bioinformatics with support from the IMI project, AETIONOMY. It is built on top of PyBEL, an open source project. Please feel free to contact us here to give us feedback or report any issues. Also, see our Publishing Notes and Data Protection information.

If you find BEL Commons useful in your work, please consider citing: Hoyt, C. T., Domingo-Fernández, D., & Hofmann-Apitius, M. (2018). BEL Commons: an environment for exploration and analysis of networks encoded in Biological Expression Language. Database, 2018(3), 1–11.