Myotubularin-Related (MTMR) Phospholipid Phosphatase Proteins in the Peripheral Nervous System

Myotubularin-related proteins (MTMRs) constitute a broad family of ubiquitously expressed phosphatases with 14 members in humans, of which eight are catalytically active phosphatases, while six are catalytically inactive. Active MTMRs possess 3-phosphatase activity toward both PtdIns3P and PtdIns(3, 5)P ₂ poliphosphoinositides (PPIn), suggesting an involvement in intracellular trafficking and membrane homeostasis. Among MTMRs, catalytically active MTMR2 and inactive MTMR13 have a nonredundant function in nerve. Loss of either MTMR2 or MTMR13 causes Charcot–Marie–Tooth type 4B1 and B2 neuropathy, respectively, characterized by demyelination and redundant loops of myelin known as myelin outfoldings. In Mtmr2-null mouse nerves, these aberrant foldings occur at 3–4 weeks after birth, a time when myelination is established, and Schwann cells are still elongating to reach the final internodal length. Moreover, Mtmr2-specific ablation in Schwann cells is both sufficient and necessary to provoke CMT4B1 with myelin outfoldings. MTMR2 phospholipid phosphatase might regulate intracellular trafficking events and membrane homeostasis in Schwann cells during postnatal nerve development. In this review, we will discuss recent findings on the MTMR family with a major focus on MTMR2 and MTMR13 and their putative role in Schwann cell biology.     

Genetic interaction between MTMR2 and FIG4 phospholipid phosphatases involved in Charcot-Marie-Tooth neuropathies

We previously reported that autosomal recessive demyelinating Charcot-Marie-Tooth (CMT) type 4B1 neuropathy with myelin outfoldings is caused by loss of MTMR2 (Myotubularin-related 2) in humans, and we created a faithful mouse model of the disease. MTMR2 dephosphorylates both PtdIns3P and PtdIns(3,5)P(2), thereby regulating membrane trafficking. However, the function of MTMR2 and the role of the MTMR2 phospholipid phosphatase activity in vivo in the nerve still remain to be assessed. Mutations in FIG4 are associated with CMT4J neuropathy characterized by both axonal and myelin damage in peripheral nerve. Loss of Fig4 function in the plt (pale tremor) mouse produces spongiform degeneration of the brain and peripheral neuropathy. Since FIG4 has a role in generation of PtdIns(3,5)P(2) and MTMR2 catalyzes its dephosphorylation, these two phosphatases might be expected to have opposite effects in the control of PtdIns(3,5)P(2) homeostasis and their mutations might have compensatory effects in vivo. To explore the role of the MTMR2 phospholipid phosphatase activity in vivo, we generated and characterized the Mtmr2/Fig4 double null mutant mice. Here we provide strong evidence that Mtmr2 and Fig4 functionally interact in both Schwann cells and neurons, and we reveal for the first time a role of Mtmr2 in neurons in vivo. Our results also suggest that imbalance of PtdIns(3,5)P(2) is at the basis of altered longitudinal myelin growth and of myelin outfolding formation. Reduction of Fig4 by null heterozygosity and downregulation of PIKfyve both rescue Mtmr2-null myelin outfoldings in vivo and in vitro.     

The phosphoinositide-3-phosphatase MTMR2 associates with MTMR13, a membrane-associated pseudophosphatase also mutated in type 4B Charcot-Marie-Tooth disease

Charcot-Marie-Tooth disease type 4B (CMT4B) is a severe, demyelinating peripheral neuropathy characterized by distinctive, focally folded myelin sheaths. CMT4B is caused by recessively inherited mutations in either myotubularin-related 2 (MTMR2) or MTMR13 (also called SET-binding factor 2). MTMR2 encodes a member of the myotubularin family of phosphoinositide-3-phosphatases, which dephosphorylate phosphatidylinositol 3-phosphate (PI(3)P) and bisphosphate PI(3,5)P2. MTMR13 encodes a large, uncharacterized member of the myotubularin family. The MTMR13 phosphatase domain is catalytically inactive because the essential Cys and Arg residues are absent. Given the genetic association of both MTMR2 and MTMR13 with CMT4B, we investigated the biochemical relationship between these two proteins. We found that the endogenous MTMR2 and MTMR13 proteins are associated in human embryonic kidney 293 cells. MTMR2-MTMR13 association is mediated by coiled-coil sequences present in each protein. We also examined the cellular localization of MTMR2 and MTMR13 using fluorescence microscopy and subcellular fractionation. We found that (i) MTMR13 is a predominantly membrane-associated protein; (ii) MTMR2 and MTMR13 cofractionate in both a light membrane fraction and a cytosolic fraction; and (iii) MTMR13 membrane association is mediated by the segment of the protein which contains the pseudophosphatase domain. This work, which describes the first cellular or biochemical investigation of the MTMR13 pseudophosphatase protein, suggests that MTMR13 functions in association with MTMR2. Loss of MTMR13 function in CMT4B2 patients may lead to alterations in MTMR2 function and subsequent alterations in 3-phosphoinositide signaling. Such a mechanism would explain the strikingly similar phenotypes of patients with recessive mutations in either MTMR2 or MTMR13.     

Mutations in MTMR13, a new pseudophosphatase homologue of MTMR2 and Sbf1, in two families with an autosomal recessive demyelinating form of Charcot-Marie-Tooth disease associated with early-onset glaucoma

Charcot-Marie-Tooth disease (CMT) with autosomal recessive (AR) inheritance is a heterogeneous group of inherited motor and sensory neuropathies. In some families from Japan and Brazil, a demyelinating CMT, mainly characterized by the presence of myelin outfoldings on nerve biopsies, cosegregated as an autosomal recessive trait with early-onset glaucoma. We identified two such large consanguineous families from Tunisia and Morocco with ages at onset ranging from 2 to 15 years. We mapped this syndrome to chromosome 11p15, in a 4.6-cM region overlapping the locus for an isolated demyelinating ARCMT (CMT4B2). In these two families, we identified two different nonsense mutations in the myotubularin-related 13 gene, MTMR13. The MTMR protein family includes proteins with a phosphoinositide phosphatase activity, as well as proteins in which key catalytic residues are missing and that are thus called "pseudophosphatases." MTM1, the first identified member of this family, and MTMR2 are responsible for X-linked myotubular myopathy and Charcot-Marie-Tooth disease type 4B1, an isolated peripheral neuropathy with myelin outfoldings, respectively. Both encode active phosphatases. It is striking to note that mutations in MTMR13 also cause peripheral neuropathy with myelin outfoldings, although it belongs to a pseudophosphatase subgroup, since its closest homologue is MTMR5/Sbf1. This is the first human disease caused by mutation in a pseudophosphatase, emphasizing the important function of these putatively inactive enzymes. MTMR13 may be important for the development of both the peripheral nerves and the trabeculum meshwork, which permits the outflow of the aqueous humor. Both of these tissues have the same embryonic origin.     

Crystal structure of a phosphoinositide phosphatase, MTMR2: insights into myotubular myopathy and Charcot-Marie-Tooth syndrome

Myotubularin-related proteins are a large subfamily of protein tyrosine phosphatases (PTPs) that dephosphorylate D3-phosphorylated inositol lipids. Mutations in members of the myotubularin family cause the human neuromuscular disorders myotubular myopathy and type 4B Charcot-Marie-Tooth syndrome. The crystal structure of a representative member of this family, MTMR2, reveals a phosphatase domain that is structurally unique among PTPs. A series of mutants are described that exhibit altered enzymatic activity and provide insight into the specificity of myotubularin phosphatases toward phosphoinositide substrates. The structure also reveals that the GRAM domain, found in myotubularin family phosphatases and predicted to occur in approximately 180 proteins, is part of a larger motif with a pleckstrin homology (PH) domain fold. Finally, the MTMR2 structure will serve as a model for other members of the myotubularin family and provide a framework for understanding the mechanism whereby mutations in these proteins lead to disease.     

Phosphatidylinositol-5-phosphate activation and conserved substrate specificity of the myotubularin phosphatidylinositol 3-phosphatases

Phosphoinositides control many different processes required for normal cellular function. Myotubularins are a family of Phosphatidylinositol 3-phosphate (PtdIns3P) phosphatases identified by the positional cloning of the MTM1 gene in patients suffering from X-linked myotubular myopathy and the MTMR2 gene in patients suffering from the demyelinating neuropathy Charcot-Marie-Tooth disease type 4B. MTM1 is a phosphatidylinositol phosphatase with reported specificity toward PtdIns3P, while the related proteins MTMR2 and MTMR3 hydrolyze both PtdIns3P and PtdIns(3,5)P2. We have investigated MTM1 and MTMR6 and find that they use PtdIns(3,5)P2 in addition to PtdIns3P as a substrate in vitro. The product of PtdIns(3,5)P2 hydrolysis, PtdIns5P, causes MTM1 to form a heptameric ring that is 12.5 nm in diameter, and it is a specific allosteric activator of MTM1, MTMR3, and MTMR6. A disease-causing mutation at arginine 69 of MTM1 falling within a putative pleckstrin homology domain reduces the ability of the enzyme to respond to PtdIns5P. We propose that the myotubularin family of enzymes utilize both PtdIns3P and PtdIns(3,5)P2 as substrates, and that PtdIns5P functions in a positive feedback loop controlling their activity. These findings highlight the importance of regulated phosphatase activity for the control of phosphoinositide metabolism.     

Multiple disease-linked myotubularin mutations cause NFL assembly defects in cultured cells and disrupt myotubularin dimerization

Charcot-Marie-Tooth disease (CMT) is an inherited peripheral neuropathy that has been linked to mutations in multiple genes. Mutations in the neurofilament light ( NFL ) chain gene lead to the CMT2E form whereas mutations in the myotubularin-related protein 2 and 13 ( MTMR2 and MTMR13 ) genes lead to the CMT4B form. These two forms share characteristic pathological hallmarks on nerve biopsies including concentric sheaths ('onion bulbs') and, in at least one case, myelin loops. In addition, MTMR2 protein has been shown to interact physically with both NFL and MTMR13. Here, we present evidence that CMT-linked mutations of MTMR2 can cause NFL aggregation in a cell line devoid of endogenous intermediate filaments, SW13vim⁻. Mutations in the protein responsible for X-linked myotubular myopathy (myotubularin, MTM1) also induced NFL abnormalities in these cells. We also show that two MTMR2 mutant proteins, G103E and R283W, are unable to form dimers and undergo phosphorylation in vivo , implicating impaired complex formation in myotubularin-related pathology.     

Characterization of MTMR3. an inositol lipid 3-phosphatase with novel substrate specificity.

Inositol lipids play key roles in many fundamental cellular processes that include growth, cell survival, motility, and membrane trafficking. Recent studies on the PTEN and Myotubularin proteins have underscored the importance of inositol lipid 3-phosphatases in cell function. Inactivating mutations in the genes encoding PTEN and Myotubularin are key steps in the progression of some cancers and in the onset of X-linked myotubular myopathy, respectively. Myotubularin-related protein 3 (MTMR3) shows extensive homology to Myotubularin, including the catalytic domain, but additionally possesses a C-terminal extension that includes a FYVE domain. We show that MTMR3 is an inositol lipid 3-phosphatase, with a so-far-unique substrate specificity. It is able to hydrolyze PtdIns3P and PtdIns3,5P2, both in vitro and when heterologously expressed in S. cerevisiae, and to thereby provide the first clearly defined route for the cellular production of PtdIns5P. Overexpression of a catalytically dead MTMR3 (C413S) in mammalian cells induces a striking formation of vacuolar compartments that enclose membranous structures that are highly concentrated in mutant proteins.     

Loss of Catalytically Inactive Lipid Phosphatase Myotubularin-related Protein 12 Impairs Myotubularin Stability and Promotes Centronuclear Myopathy in Zebrafish

X-linked myotubular myopathy (XLMTM) is a congenital disorder caused by mutations of the myotubularin gene, MTM1. Myotubularin belongs to a large family of conserved lipid phosphatases that include both catalytically active and inactive myotubularin-related proteins (i.e., “MTMRs”). Biochemically, catalytically inactive MTMRs have been shown to form heteroligomers with active members within the myotubularin family through protein-protein interactions. However, the pathophysiological significance of catalytically inactive MTMRs remains unknown in muscle. By in vitro as well as in vivo studies, we have identified that catalytically inactive myotubularin-related protein 12 (MTMR12) binds to myotubularin in skeletal muscle. Knockdown of the mtmr12 gene in zebrafish resulted in skeletal muscle defects and impaired motor function. Analysis of mtmr12 morphant fish showed pathological changes with central nucleation, disorganized Triads, myofiber hypotrophy and whorled membrane structures similar to those seen in X-linked myotubular myopathy. Biochemical studies showed that deficiency of MTMR12 results in reduced levels of myotubularin protein in zebrafish and mammalian C2C12 cells. Loss of myotubularin also resulted in reduction of MTMR12 protein in C2C12 cells, mice and humans. Moreover, XLMTM mutations within the myotubularin interaction domain disrupted binding to MTMR12 in cell culture. Analysis of human XLMTM patient myotubes showed that mutations that disrupt the interaction between myotubularin and MTMR12 proteins result in reduction of both myotubularin and MTMR12. These studies strongly support the concept that interactions between myotubularin and MTMR12 are required for the stability of their functional protein complex in normal skeletal muscles. This work highlights an important physiological function of catalytically inactive phosphatases in the pathophysiology of myotubular myopathy and suggests a novel therapeutic approach through identification of drugs that could stabilize the myotubularin-MTMR12 complex and hence ameliorate this disorder.     

Disruption of Mtmr2 produces CMT4B1-like neuropathy with myelin outfolding and impaired spermatogenesis

Mutations in MTMR2, the myotubularin-related 2 gene, cause autosomal recessive Charcot-Marie-Tooth (CMT) type 4B1, a demyelinating neuropathy with myelin outfolding and azoospermia. MTMR2 encodes a ubiquitously expressed phosphatase whose preferred substrate is phosphatidylinositol (3,5)-biphosphate, a regulator of membrane homeostasis and vesicle transport. We generated Mtmr2-null mice, which develop progressive neuropathy characterized by myelin outfolding and recurrent loops, predominantly at paranodal myelin, and depletion of spermatids and spermatocytes from the seminiferous epithelium, which leads to azoospermia. Disruption of Mtmr2 in Schwann cells reproduces the myelin abnormalities. We also identified a novel physical interaction in Schwann cells, between Mtmr2 and discs large 1 (Dlg1)/synapse-associated protein 97, a scaffolding molecule that is enriched at the node/paranode region. Dlg1 homologues have been located in several types of cellular junctions and play roles in cell polarity and membrane addition. We propose that Schwann cell-autonomous loss of Mtmr2-Dlg1 interaction dysregulates membrane homeostasis in the paranodal region, thereby producing outfolding and recurrent loops of myelin.     

MTMR9 Increases MTMR6 Enzyme Activity, Stability, and Role in Apoptosis

Myotubularin-related protein 6 (MTMR6) is a catalytically active member of the myotubularin (MTM) family, which is composed of 14 proteins. Catalytically active myotubularins possess 3-phosphatase activity dephosphorylating phosphatidylinositol-3-phoshate and phosphatidylinositol-3,5-bisphosphate, and some members have been shown to form homomers or heteromeric complexes with catalytically inactive myotubularins. We demonstrate that human MTMR6 forms a heteromer with an enzymatically inactive member myotubularin-related protein 9 (MTMR9), both in vitro and in cells. MTMR9 increased the binding of MTMR6 to phospholipids without changing the lipid binding profile. MTMR9 increased the 3-phosphatase activity of MTMR6 up to 6-fold. We determined that MTMR6 is activated up to 28-fold in the presence of phosphatidylserine liposomes. Together, MTMR6 activity in the presence of MTMR9 and assayed in phosphatidylserine liposomes increased 84-fold. Moreover, the formation of this heteromer in cells resulted in increased protein levels of both MTMR6 and MTMR9, probably due to the inhibition of degradation of both proteins. Furthermore, co-expression of MTMR6 and MTMR9 decreased etoposide-induced apoptosis, whereas decreasing both MTMR6 and MTMR9 by RNA interference led to increased cell death in response to etoposide treatment when compared with that seen with RNA interference of MTMR6 alone. Thus, MTMR9 greatly enhances the functions of MTMR6.Myotubularin proteins are a family of 14 proteins with the canonical dual specificity protein tyrosine phosphatase active site CX₅R motif (1–3). Eight members of the myotubularin family possess catalytic activity, dephosphorylating phosphatidylinositol 3-phosphate (PtdIns-3-P)⁴ and phosphatidylinositol 3,5-bisphosphate (PtdIns-3,5-P₂) at the D-3 position, and six members are not catalytically active because they lack the conserved cysteine residue in the protein tyrosine phosphatase motif that is required for activity. Interest in this group of proteins originated from the genetic evidence linking myotubularin, the founding member of this family, to myotubular myopathy, an X-linked disorder characterized by severe hypotonia and generalized muscle weakness (4). Subsequently, mutations in MTMR2 and in its inactive binding partner MTMR13 were linked to a subset of Charcot-Marie-Tooth disease type 4B, a demyelinating neurodegenerative disorder (5, 6).Despite near identical substrate specificity, biochemical and genetic evidence supports the hypothesis that myotubularin proteins are not redundant and have unique functions within cells (2, 7–9). The mechanisms by which loss of function of myotubularin proteins produce diseases are not known. Current evidence supports the hypothesis that each myotubularin protein regulates a specific pool of PtdIns-3-P and/or PtdIns-3,5-P₂, which in turn regulates a variety of cellular functions. Differences in tissue expression and subcellular localization play a role in the specificity of different myotubularins (10–15).The functions of myotubularin proteins are altered by the formation of heteromers between catalytically active and inactive members of the family. The initial biochemical purification of MTM1 demonstrated the presence of MTM1 homodimers and MTM1-3-phosphatase adapter protein (3PAP) heteromers (16), which was later described as MTMR12 (15, 17). MTMR2 was found to form heteromers with MTMR5 (13) and MTMR13 (18), and MTMR7 formed heteromers with MTMR9 (19). In each case, a catalytically active myotubularin protein interacted with an inactive protein. Heteromerization generated two important effects: increased catalytic activity of the active component (13, 15, 19, 20) and targeting of the heteromer to specific subcellular locations (15). Mutations in the inactive member MTMR13 result in a similar phenotype in patients as the mutations in its catalytically active binding partner MTMR2, indicating an indispensable role for the catalytically inactive subunit (21).Myotubularin proteins can be grouped into subfamilies based on homology. Closely related MTMR6, MTMR7, and MTMR8 comprise such a subfamily. We have previously characterized the interaction between mouse MTMR7 and MTMR9 proteins (19). In this report, we characterize the interaction between human MTMR6 and MTMR9. MTMR6 and MTMR9 have been shown to form a heteromeric complex in mouse and Caenorhabditis elegans (19, 22). MTMR6 has been shown to inhibit the activity of a calcium-activated potassium channel (type KCa3.1) (23, 24). Two screening experiments implicate MTMR6 as a regulator of apoptosis. By RNA microarray analysis, increased MTMR6 expression was observed in B cell chronic lymphoid leukemia cells with increased resistance to irradiation-induced apoptosis (25), whereas in an RNA interference screen in HeLa cells, decreased MTMR6 expression promoted apoptosis (26).Here we show that MTMR6 interacts with MTMR9 in vitro and in human cells. This interaction increases the phospholipid binding and enzymatic activity of MTMR6 in vitro. Co-expression of either subunit in cells dramatically increased the protein levels of the individual binding partners, suggesting that heteromer formation increases the stability of the proteins. Finally, MTMR9 was found to potentiate the effects of MTMR6 on apoptosis.     

Myotubularin-related Proteins 3 and 4 Interact with Polo-like Kinase 1 and Centrosomal Protein of 55 kDa to Ensure Proper Abscission

The myotubularins are a family of phosphatases that dephosphorylate the phosphatidylinositols phosphatidylinositol-3-phosphate and phosphatidylinositol-3,5-phosphate. Several family members are mutated in disease, yet the biological functions of the majority of myotubularins remain unknown. To gain insight into the roles of the individual enzymes, we have used affinity purification coupled to mass spectrometry to identify protein–protein interactions for the myotubularins. The myotubularin interactome comprises 66 high confidence (false discovery rate ≤1%) interactions, including 18 pairwise interactions between individual myotubularins. The results reveal a number of potential signaling contexts for this family of enzymes, including an intriguing, novel role for myotubularin-related protein 3 and myotubularin-related protein 4 in the regulation of abscission, the final step of mitosis in which the membrane bridge remaining between two daughter cells is cleaved. Both depletion and overexpression of either myotubularin-related protein 3 or myotubularin-related protein 4 result in abnormal midbody morphology and cytokinesis failure. Interestingly, myotubularin-related protein 3 and myotubularin-related protein 4 do not exert their effects through lipid regulation at the midbody, but regulate abscission during early mitosis, by interacting with the mitotic kinase polo-like kinase 1, and with centrosomal protein of 55 kDa (CEP55), an important regulator of abscission. Structure-function analysis reveals that, consistent with known intramyotubularin interactions, myotubularin-related protein 3 and myotubularin-related protein 4 interact through their respective coiled coil domains. The interaction between myotubularin-related protein 3 and polo-like kinase 1 relies on the divergent, nonlipid binding Fab1, YOTB, Vac1, and EEA1 domain of myotubularin-related protein 3, and myotubularin-related protein 4 interacts with CEP55 through a short GPPXXXY motif, analogous to endosomal sorting complex required for transport-I components. Disruption of any of these interactions results in abscission failure, by disrupting the proper recruitment of CEP55, and subsequently, of endosomal sorting complex required for transport-I, to the midbody. Our data suggest that myotubularin-related protein 3 and myotubularin-related protein 4 may act as a bridge between CEP55 and polo-like kinase 1, ensuring proper CEP55 phosphorylation and regulating CEP55 recruitment to the midbody. This work provides a novel role for myotubularin-related protein 3/4 heterodimers, and highlights the temporal and spatial complexity of the regulation of cytokinesis.The myotubularins are a subfamily of protein tyrosine phosphatases (PTPs)¹, consisting of sixteen conserved proteins. Despite containing the conserved C(X)₅R catalytic motif found in all protein tyrosine phosphatases, myotubularins harbor active sites that do not dephosphorylate tyrosine, but instead catalyze the conversion of the phosphatidylinositol-type lipids phosphatylinositol 3 phosphate (PI3P) and phosphatylinositol 3,5 phosphate (PI3,5P) to phosphatidylinositol (PI) and phosphatylinositol 5 phosphate (PI5P), respectively (1). Phosphatidylinositols are important molecules in a variety of processes, and as enzymatic regulators, myotubularins may function in cell proliferation, differentiation, survival, and cytoskeletal and junctional dynamics (1, 2). Of the sixteen myotubularins, only nine are active enzymes (supplemental Fig. S1A), as several lack catalytic cysteine residues (3). Myotubularins interact extensively with each other, and interactions between active and inactive pairs are frequent (4). It is thought that inactive myotubularins regulate the activity, substrate binding, and/or localization of their active binding partners (2).Several myotubularins are linked to human disease. Myotubularin (MTM1), the first reported family member, is mutated in X-linked centronuclear myopathy (5), and Myotubularin related protein 14 (MTMR14) is mutated in autosomal centronuclear myopathy (6). Mutations in the active MTMR2 or its inactive binding partner, SET binding factor (SBF)2 (MTMR13), cause Charcot-Marie-Tooth diseases CMT4A and CMT4B, respectively (7–9). MTMR7 and MTMR9 have been associated with metabolic syndrome and obesity (MTMR9) (10, 11), epilepsy (MTMR7/9) (12), and Creutzfeldt-Jakob disease (MTMR7) (13). In addition, misregulation of the active phosphatase MTMR3 contributes to susceptibility to gastric and colon carcinomas (14), oral cancer (15), and lung cancer (16), and contributes to metastasis (15, 17). Aberrant expression of the inactive MTMR11 has been observed in acute myeloid leukemia (18), acute lymphocytic leukemia (19), and Her2-positive breast cancer (20). Generally, myotubularins are thought to integrate different cellular pathways, through both phosphatidylinositol regulation and protein–protein interactions (2). Despite their proposed involvement in a variety of cellular processes as well as disease states, many myotubularins remain poorly characterized, with their precise cellular functions not yet elucidated, and the pathological significance of those functions still unknown.To gain insight on the biological functions of myotubularin family phosphatases, we have used affinity purification coupled to mass spectrometry (AP-MS) to identify protein–protein interactions for each myotubularin. The results expand upon the known repertoire of intra-myotubularin interactions, and, critically, identify specific novel interactions for individual myotubularins, providing valuable clues toward their respective functions. Further investigation revealed an unexpected role for MTMR3 and MTMR4 in abscission (21), the fission event at the end of cytokinesis that severs the final membrane link between divided daughter cells. Future studies of additional identified protein–protein interactions will undoubtedly illuminate the cellular roles of myotubularin family phosphatases.     

RANKL induces NFATc1 acetylation and stability via histone acetyltransferases during osteoclast differentiation

The MTM (myotubularin)/MTMR (myotubularin-related) protein family is comprised of 15 lipid phosphatases, of which nine members are catalytically active. MTMs are known to play a fundamental role in human physiology as gene mutations can give rise to X-linked myotubular myopathy or Charcot-Marie-Tooth disease, which manifest in skeletal muscle or in peripheral neurons respectively. Interestingly, studies have shown MTMR2 and MTMR5, two MTM family members, to be highly expressed in the testis, particularly in Sertoli and germ cells, and knockout of either gene resulted in spermatogenic defects. Other studies have shown that MTMR2 functions in endocytosis and membrane trafficking. In the testis, MTMR2 interacts and co-localizes with c-Src/phospho-Src-(Tyr?1?), a non-receptor protein tyrosine kinase that regulates the phosphorylation state of proteins at the apical ES (ectoplasmic specialization), a unique type of cell junction found between Sertoli cells and elongating/elongated spermatids. In the present review, we highlight recent findings that have made a significant impact on our understanding of this protein family in normal cell function and in disease, with the emphasis on the role of MTMs and MTMRs in spermatogenesis. We also describe a working model to explain how MTMR2 interacts with other proteins such as c-Src, dynamin 2, EPS8 (growth factor receptor pathway substrate 8) and ARP2/3 (actin-related protein 2/3) at the apical ES and the apical TBC (tubulobulbar complex; tubular-like invaginations that function in the disassembly of the apical ES and in the recycling of its components) to regulate spermiation at late stage VIII of the seminiferous epithelial cycle.     

Endosomal phosphoinositides and human diseases

Phosphoinositides (PIs) are lipid second messengers implicated in signal transduction and membrane trafficking. Seven distinct PIs can be synthesized by phosphorylation of the inositol ring of phosphatidylinositol (PtdIns), and their metabolism is accurately regulated by PI kinases and phosphatases. Two of the PIs, PtdIns3 P and PtdIns(3,5) P ₂, are present on intracellular endosomal compartments, and several studies suggest that they have a role in membrane remodeling and trafficking. We refer to them as 'endosomal PIs'. An increasing number of human genetic diseases including myopathy and neuropathies are associated to mutations in enzymes regulating the turnover of these endosomal PIs. The PtdIns3 P and PtdIns(3,5) P ₂ 3-phosphatase myotubularin gene is mutated in X-linked centronuclear myopathy, whereas its homologs MTMR2 and MTMR13 and the PtdIns(3,5) P ₂ 5-phosphatase SAC3/FIG4 are implicated in Charcot–Marie–Tooth peripheral neuropathies. Mutations in the gene encoding the PtdIns3 P 5-kinase PIP5K3/PIKfyve have been found in patients affected with François–Neetens fleck corneal dystrophy. This review presents the roles of the endosomal PIs and their regulators and proposes defects of membrane remodeling as a common pathological mechanism for the corresponding diseases.     

The myotubularin family: novel phosphoinositide regulators

Phosphatidylinositol 3-phosphate [PtdIns(3)P] acts as a second messenger via the recruitment of diverse signalling proteins to various cellular compartments. Recent advances have highlighted the association of human diseases with mutations in phosphatases that regulate PtdIns(3)P levels. Myotubularin, the gene mutated in myotubular myopathy, functions as a lipid phosphatase with specificity for PtdIns(3)P. It is now apparent that there is an increasing family of proteins that are defined by their significant homology with myotubularin. The myotubularin-related gene family includes proteins that exhibit a lipid phosphatase catalytic motif, those that contain mutations of the critical catalytic residues, and at least one protein that functions as an adapter subunit for PtdIns(3)P-3-phosphatase activity. The present challenge is to understand how deregulation of phosphoinositide metabolism causes human disease.     

The CMT4B disease‐causing proteins MTMR2 and MTMR13/SBF2 regulate AKT signalling

Charcot‐Marie‐Tooth disease type 4B is caused by mutations in the genes encoding either the lipid phosphatase myotubularin‐related protein‐2 (MTMR2) or its regulatory binding partner MTMR13/SBF2. Mtmr2 dephosphorylates PI‐3‐P and PI‐3,5‐P2 to form phosphatidylinositol and PI‐5‐P, respectively, while Mtmr13/Sbf2 is an enzymatically inactive member of the myotubularin protein family. We have found altered levels of the critical signalling protein AKT in mouse mutants for Mtmr2 and Mtmr13/Sbf2. Thus, we analysed the influence of Mtmr2 and Mtmr13/Sbf2 on signalling processes. We found that overexpression of Mtmr2 prevents the degradation of the epidermal growth factor receptor (EGFR) and leads to sustained Akt activation whereas Erk activation is not affected. Mtmr13/Sbf2 counteracts the blockage of EGFR degradation without affecting prolonged Akt activation. Our data indicate that Mtmr2 and Mtmr13/Sbf2 play critical roles in the sorting and modulation of cellular signalling which are likely to be disturbed in CMT4B.     

Bioinformatic identification of novel protein phosphatases in the dog genome

Protein kinases and protein phosphatases constitute about 2-4% of the genes in a typical eukaryotic genome. Protein phosphatases are important players in many cellular processes such as proliferation, differentiation, cell adhesion, and motility. In this study, we identified, classified, and analyzed protein phosphatase complement of the dog genome. In this article, we report the identification of at least 178 putative protein phosphatases in dog which include 51 PSTPs, 112 PTPs, and 15 Asp-based protein phosphatases. Interestingly, we found at least five novel protein phosphatases in dog, namely DUSP5L, DUSP18L, MTMR9L, MTMR12L, and PPP6CL which are not present in human, mouse, rat, and cow. In addition, we found PTP4A1-rt, a retro-transposed copy of the PTP4A1 gene, in chromosome 27. Furthermore, we modeled three-dimensional structures of the catalytic domains of these putative protein phosphatases and aligned them to see the structural similarities between them. We docked PPP2CA with okadaic acid and calculated the value of affinity energy as -8.8?kcal/mol. Our nucleotide substitution rate study revealed that apparently none of the phosphatase family is under significantly higher evolutionary pressure.     

Receptor mediated endocytosis 8 is a novel PI(3)P binding protein regulated by myotubularin-related 2

Myotubularin related protein 2 (MTMR2) is a member of the myotubularin family of phosphoinositide lipid phosphatases. Although MTMR2 dephosphorylates the phosphoinositides PI(3)P and PI(3,5)P2, the phosphoinositide binding proteins that are regulated by MTMR2 are poorly characterized. In this study, phosphoinositide affinity chromatography coupled to mass spectrometry identified receptor mediated endocytosis 8 (RME-8) as a novel PI(3)P binding protein. RME-8 co-localized with the PI(3)P marker DsRed-FYVE, while the N-terminal region of RME-8 is required for PI(3)P and PI(3,5)P(2) binding in vitro. Depletion of PI(3)P by MTMR2 S58A or wortmannin treatment attenuated RME-8 endosomal localization and co-localization with EGFR on early endosomes. Our results suggest a model in which the localization of RME-8 to endosomal compartments is spatially mediated by PI(3)P binding and temporally regulated by MTMR2 activity.     

Identification of PtdIns(3,4)P2 effectors in human platelets using quantitative proteomics

After decades in PtdIns(3,4,5)P₃'s shadow, PtdIns(3,4)P₂ has now emerged as a bona fide regulator of important cellular events, including endocytosis and cell migration. New understanding of PtdIns(3,4)P₂'s cellular roles has been possible via novel approaches to observe and quantify cellular PtdIns(3,4)P₂ dynamics, alongside methods to target the kinases and phosphatases governing phosphoinositide turnover. Despite this, the mechanisms by which PtdIns(3,4)P₂ orchestrates its cellular roles remain more poorly understood, most notably because, to date, few PtdIns(3,4)P₂ effectors have been identified. Here, we develop and apply an affinity-proteomics strategy to conduct a global screen for PtdIns(3,4)P₂ interactors in human platelets; a primary cell type with striking PtdIns(3,4)P₂ accumulation. Through an integrated approach, coupling affinity capture of PtdIns(3,4)P₂-binding proteins to both label-free and isobaric tag-based quantitative proteomics, we identify a diverse PtdIns(3,4)P₂ interactome. Included are long-established PtdIns(3,4)P₂-binding proteins such as PLEKHA1, PLEKHA2, AKT and DAPP1, and a host of potentially novel effectors, including MTMR5, PNKD, RASA3 and GAB3. The PtdIns(3,4)P₂ interactome shows an enrichment of pleckstrin homology (PH) domain-containing proteins, and through bioinformatics and array analyses we characterise the PH domain of MTMR5 and define its phosphoinositide selectivity. The interactome is also diverse in function, including several proteins known to support protein trafficking and cytoskeletal mobilisation. Such proteins have the ability to drive key platelet events, and to fulfil recently-defined roles for PtdIns(3,4)P₂ in a wider range of cell types. Moreover, this study will serve as a valuable resource for the future characterisation of effector-driven PtdIns(3,4)P₂ function.