The study of the determinants controlling Arpp19 phosphatase-inhibitory activity reveals an Arpp19/PP2A-B55 feedback loop

Arpp19 is a potent PP2A-B55 inhibitor that regulates this phosphatase to ensure the stable phosphorylation of mitotic/meiotic substrates. At G2-M, Arpp19 is phosphorylated by the Greatwall kinase on S67. This phosphorylated Arpp19 form displays a high affinity to PP2A-B55 and a slow dephosphorylation rate, acting as a competitor of PP2A-B55 substrates. The molecular determinants conferring slow dephosphorylation kinetics to S67 are unknown. PKA also phosphorylates Arpp19. This phosphorylation performed on S109 is essential to maintain prophase I-arrest in Xenopus oocytes although the underlying signalling mechanism is elusive. Here, we characterize the molecular determinants conferring high affinity and slow dephosphorylation to S67 and controlling PP2A-B55 inhibitory activity of Arpp19. Moreover, we show that phospho-S109 restricts S67 phosphorylation by increasing its catalysis by PP2A-B55. Finally, we discover a double feed-back loop between these two phospho-sites essential to coordinate the temporal pattern of Arpp19-dependent PP2A-B55 inhibition and Cyclin B/Cdk1 activation during cell division.

The Greatwall kinase safeguards the genome integrity by affecting the kinome activity in mitosis

Progression through mitosis is balanced by the timely regulation of phosphorylation and dephosphorylation events ensuring the correct segregation of chromosomes before cytokinesis. This balance is regulated by the opposing actions of CDK1 and PP2A, as well as the Greatwall kinase/MASTL. MASTL is commonly overexpressed in cancer, which makes it a potential therapeutic anticancer target. Loss of Mastl induces multiple chromosomal errors that lead to the accumulation of micronuclei and multilobulated cells in mitosis. Our analyses revealed that loss of Mastl leads to chromosome breaks and abnormalities impairing correct segregation. Phospho-proteomic data for Mastl knockout cells revealed alterations in proteins implicated in multiple processes during mitosis including double-strand DNA damage repair. In silico prediction of the kinases with affected activity unveiled NEK2 to be regulated in the absence of Mastl. We uncovered that, RAD51AP1, involved in regulation of homologous recombination, is phosphorylated by NEK2 and CDK1 but also efficiently dephosphorylated by PP2A/B55. Our results suggest that MastlKO disturbs the equilibrium of the mitotic phosphoproteome that leads to the disruption of DNA damage repair and triggers an accumulation of chromosome breaks even in noncancerous cells.

Investigating the determinants of mammalian Mastl kinase activation

ABSTRACTMastl (Greatwall) kinase is an essential mitotic protein kinase. Mastl is an atypical member of AGC family with a unique long stretch of non-conserved middle region. The mechanism of its phosphorylation dependent activation has been studied in Xenopus egg extracts, revealing several phosphosites that were suggested to be crucial for kinase activation. These residues correspond to T193 and T206 in the activation loop, and S861 in the C-tail of mouse Mastl. By combining a chemically inducible knockout system to deplete the endogenous Mastl and a viral expression system to ectopically express the mutant variants, we obtained a viable knockout clone that expresses the S861A and S861D mutants. We observed that proliferation rates of the MastlS861A and MastlS861D clones were comparable. Our results have revealed that phosphorylation of the turn motif phosphosite (S861) is auxiliary and it is not indispensable for Mastl function.

Role of Protein Phosphatase-2A (PP-2A) in the Control of Mitosis and Meiosis.

A specific form of Protein Phosphatase-2A (PP-2A), namely PP2A-B55δ was proposed to occupy a central role in the control of mitosis entry and exit, and meiosis in Xenopus oocytes [1,3]. It was held that PP2A-B55δ is responsible for dephosphorylating substrates of cdc2/Cdk1 and that inhibition of PP2A-B55δ by Arpp-19 phosphorylated at serine 67 by Greatwall kinase triggers entry of both mitosis and meiosis in Xenopus oocytes. It was further declared that the phosphorylation of Arpp19 at serine 109 by PKA underlies the blockade of meiotic division and that dephosphorylation of serine 109 of Arpp19 triggers resumption of meiotic division in Xenopus oocytes [4]. Recently two groups have stated that PP2A-B55δ is the protein phosphatase that is responsible for dephosphorylating both serine 67 and serine 109 of Arpp19 [4,5] However, unfortunately for the authors concerned [1-5], no verifiable scientific evidence exists that shows that Arpp19 is a specific inhibitor of PP-2AB55ɗ when Arpp19 is phosphorylated at serine 67 by Greatwall kinase and that Arpp-19 phosphorylated at serine 67 and Arpp19 phosphorylated at 109 are both specifically dephosphorylated by PP-2AB55ɗ Arpp19. The idea that Arpp-19 phosphorylated at serine 67 is both an inhibitor and a substrate of PP-2AB55ɗ has more to do with science fiction than science. The role of other Protein Phosphatases, including, PP-2A-B'56ɗ and Protein Phosphatase-1 I (PP-1 I ) cannot be ignored. Evidenceis presented and discussed here..

Cyclin A triggers Mitosis either via Greatwall or Cyclin B

Two mitotic Cyclins, A and B, exist in higher eukaryotes, but their specialised functions in mitosis are poorly understood. Using degron tags we analyse how acute depletion of these proteins affects mitosis. Loss of Cyclin A in G2-phase prevents the initial activation of Cdk1. Cells lacking Cyclin B can enter mitosis and phosphorylate most mitotic proteins, because of parallel PP2A:B55 phos-phatase inactivation by Greatwall kinase. The final barrier to mitotic establishment corresponds to nuclear envelope breakdown that requires a decisive shift in the balance of Cdk1 and PP2A:B55 activity. Beyond this point Cyclin B/Cdk1 is essential to phosphorylate a distinct subset mitotic Cdk1 substrates that are essential to complete cell division. Our results identify how Cyclin A, B and Greatwall coordinate mitotic progression by increasing levels of Cdk1-dependent substrate phos-phorylation.

Reciprocal regulation of ARPP-16 by PKA and MAST3 kinases provides a cAMP-regulated switch in protein phosphatase 2A inhibition

ARPP-16, ARPP-19, and ENSA are inhibitors of protein phosphatase PP2A. ARPP-19 and ENSA phosphorylated by Greatwall kinase inhibit PP2A during mitosis. ARPP-16 is expressed in striatal neurons where basal phosphorylation by MAST3 kinase inhibits PP2A and regulates key components of striatal signaling. The ARPP-16/19 proteins were discovered as substrates for PKA, but the function of PKA phosphorylation is unknown. We find that phosphorylation by PKA or MAST3 mutually suppresses the ability of the other kinase to act on ARPP-16. Phosphorylation by PKA also acts to prevent inhibition of PP2A by ARPP-16 phosphorylated by MAST3. Moreover, PKA phosphorylates MAST3 at multiple sites resulting in its inhibition. Mathematical modeling highlights the role of these three regulatory interactions to create a switch-like response to cAMP. Together, the results suggest a complex antagonistic interplay between the control of ARPP-16 by MAST3 and PKA that creates a mechanism whereby cAMP mediates PP2A disinhibition.

Homeostatic control of START through negative feedback between Cln3-Cdk1 and Rim15/Greatwall kinase in budding yeast

How cells coordinate growth and division is key for size homeostasis. Phosphorylation by G1-CDK of Whi5/Rb inhibitors of SBF/E2F transcription factors triggers irreversible S-phase entry in yeast and metazoans, but why this occurs at a given cell size is not fully understood. We show that the yeast Rim15-Igo1,2 pathway, orthologous to Gwl-Arpp19/ENSA, is up-regulated in early G1 and helps promoting START by preventing PP2ACdc55 to dephosphorylate Whi5. RIM15 overexpression lowers cell size while IGO1,2 deletion delays START in cells with low CDK activity. Deletion of WHI5, CDC55 and ectopic CLN2 expression suppress the START delay of igo1,2∆ cells. Rim15 activity increases after cells switch from fermentation to respiration, where Igo1,2 contribute to chromosome maintenance. Interestingly Cln3-Cdk1 also inhibits Rim15 activity, which enables homeostatic control of Whi5 phosphorylation and cell cycle entry. We propose that Rim15/Gwl regulation of PP2A plays a hitherto unappreciated role in cell size homeostasis during metabolic rewiring of the cell cycle.