TOR signalling regulates mitotic commitment through the stress MAP kinase pathway and the Polo and Cdc2 kinases

The coupling of growth to cell cycle progression allows eukaryotic cells to divide at particular sizes depending on nutrient availability. In fission yeast, this coupling involves the Spc1/Sty1 mitogen-activated protein kinase (MAPK) pathway working through Polo kinase recruitment to the spindle pole bodies (SPBs). Here we report that changes in nutrients influence TOR signalling, which modulates Spc1/Sty1 activity. Rapamycin-induced inhibition of TOR signalling advanced mitotic onset, mimicking the reduction in cell size at division seen after shifts to poor nitrogen sources. Gcn2, an effector of TOR signalling and modulator of translation, regulates the Pyp2 phosphatase that in turn modulates Spc1/Sty1 activity. Rapamycin- or nutrient-induced stimulation of Spc1/Sty1 activity promotes Polo kinase SPB recruitment and Cdc2 activation to advance mitotic onset. This advanced mitotic onset is abolished in cells depleted of Gcn2, Pyp2, or Spc1/Sty1 or on blockage of Spc1/Sty1-dependent Polo SPB recruitment. Therefore, TOR signalling modulates mitotic onset through the stress MAPK pathway via the Pyp2 phosphatase.     

Heat Stress Activates Fission Yeast Spc1/StyI MAPK by a MEKK-Independent Mechanism

Fission yeast Spc1/StyI MAPK is activated by many environmental insults including high osmolarity, oxidative stress, and heat shock. Spc1/StyI is activated by Wis1, a MAPK kinase (MEK), which is itself activated by Wik1/Wak1/Wis4, a MEK kinase (MEKK). Spc1/StyI is inactivated by the tyrosine phosphatases Pyp1 and Pyp2. Inhibition of Pyp1 was recently reported to play a crucial role in the oxidative stress and heat shock responses. These conclusions were based on three findings: 1) osmotic, oxidative, and heat stresses activate Spc1/StyI in wis4 cells; 2) oxidative stress and heat shock activate Spc1/StyI in cells that express Wis1AA, in which MEKK consensus phosphorylation sites were replaced with alanine; and 3) Spc1/StyI is maximally activated in Δpyp1 cells. Contrary to these findings, we report: 1) Spc1/StyI activation by osmotic stress is greatly reduced in wis4 cells; 2) wis1-AA and Δwis1 cells have identical phenotypes; and 3) all forms of stress activate Spc1/StyI in Δpyp1 cells. We also report that heat shock, but not osmotic or oxidative stress, activate Spc1 in wis1-DD cells, which express Wis1 protein that has the MEKK consensus phosphorylation sites replaced with aspartic acid. Thus osmotic and oxidative stress activate Spc1/StyI by a MEKK-dependent process, whereas heat shock activates Spc1/StyI by a novel mechanism that does not require MEKK activation or Pyp1 inhibition.     

Activation and regulation of the Spc1 stress-activated protein kinase in Schizosaccharomyces pombe.

Spc1, an osmotic-stress-stimulated mitogen-activated protein kinase (MAPK) homolog in the fission yeast Schizosaccharomyces pombe, is required for the induction of mitosis and survival in high-osmolarity conditions. Spc1, also known as Sty1, is activated by Wis1 MAPK kinase and inhibited by Pyp1 tyrosine phosphatase. Spc1 is most closely related to Saccharomyces cerevisiae Hog1 and mammalian p38 kinases. Whereas Hog1 is specifically responsive to osmotic stress, we report here that Spc1 is activated by multiple forms of stress, including high temperature and oxidative stress. In this regard Spc1 is more similar to mammalian p38. Activation of Spc1 is crucial for survival of various forms of stress. Spc1 regulates expression of genes encoding stress-related proteins such as glycerol-3-phosphate dehydrogenase (gpd1+) and trehalose-6-phosphate synthase (tps1+). Spc1 also promotes expression of pyp2+, which encodes a tyrosine phosphatase postulated as a negative regulator of Spc1. This proposal is supported by the finding that Spc1 associates with Pyp2 in vivo and that the amount of Spc1 tyrosine phosphorylation is lower in a Pyp2-overproducing strain than in the wild type. Moreover, the level of stress-stimulated gpd1+ expression is higher in delta pyp2 mutants than in the wild type. These findings demonstrate that Spc1 promotes expression of genes involved in stress survival and that of regulation may be commonly employed to modulate MAPK signal transduction pathways in eukaryotic species.     

Mcs4 mitotic catastrophe suppressor regulates the fission yeast cell cycle through the Wik1-Wis1-Spc1 kinase cascade.

Spc1 in Schizosaccharomyces pombe is a member of the stress-activated protein kinase family, an evolutionary conserved subfamily of mitogen-activated protein kinases (MAPKs). Spc1 is activated by a MAPK kinase homologue, Wis1, and negatively regulated by Pyp1 and Pyp2 tyrosine phosphatases. Mutations in the spc1+ and wis1+ genes cause a G2 cell cycle delay that is exacerbated during stress. Herein, we describe two upstream regulators of the Wis1-Spc1 cascade. wik1+ (Wis1 kinase) was identified from its homology to budding yeast SSK2, which encodes a MAPKK kinase that regulates the HOG1 osmosensing pathway. Delta wik1 cells are impaired in stress-induced activation of Spc1 and show a G2 cell cycle delay and osmosensitive growth. Moreover, overproduction of a constitutively active form of Wik1 induces hyperactivation of Spc1 in wis1(+)-dependent manner, suggesting that Wik1 regulates Spc1 through activation of Wis1. A mutation of mcs4+ (mitotic catastrophe suppressor) was originally isolated as a suppressor of the mitotic catastrophe phenotype of a cdc2-3w wee1-50 double mutant. We have found that mcs4- cells are defective at activation of Spc1 in response to various forms of stress. Epistasis analysis has placed Mcs4-upstream of Wik1 in the Spc1 activation cascade. These results indicate that Mcs4 is part of a sensor system for multiple environmental signals that modulates the timing of entry into mitosis by regulating the Wik1-Wis1-Spc1 kinase cascade. Inactivation of the sensor system delays the onset of mitosis and rescues lethal premature mitosis in cdc2-3w wee1-50 cells.     

Fission Yeast Scp3 Potentially Maintains Microtubule Orientation through Bundling

Microtubules play important roles in organelle transport, the maintenance of cell polarity and chromosome segregation and generally form bundles during these processes. The fission yeast gene scp3 ⁺ was identified as a multicopy suppressor of the cps3-81 mutant, which is hypersensitive to isopropyl N-3-chlorophenylcarbamate (CIPC), a poison that induces abnormal multipolar spindle formation in higher eukaryotes. In this study, we investigated the function of Scp3 along with the effect of CIPC in the fission yeast Schizosaccharomyces pombe. Microscopic observation revealed that treatment with CIPC, cps3-81 mutation and scp3 ⁺ gene deletion disturbed the orientation of microtubules in interphase cells. Overexpression of scp3 ⁺ suppressed the abnormal orientation of microtubules by promoting bundling. Functional analysis suggested that Scp3 functions independently from Ase1, a protein largely required for the bundling of the mitotic spindle. A strain lacking the ase1 ⁺ gene was more sensitive to CIPC, with the drug affecting the integrity of the mitotic spindle, indicating that CIPC has a mitotic target that has a role redundant with Ase1. These results suggested that multiple systems are independently involved to ensure microtubule orientation by bundling in fission yeast.     

BiP links TOR signaling to ER stress in Chlamydomonas

The highly conserved target of rapamycin (TOR) Ser/Thr kinase promotes protein synthesis under favorable growth conditions in all eukaryotes. Downregulation of TOR signaling in the model unicellular green alga Chlamydomonas reinhardtii has recently revealed a link between control of protein synthesis, endoplasmic reticulum (ER) stress and the reversible modification of the BiP chaperone by phosphorylation. Inhibition of protein synthesis by rapamycin or cycloheximide resulted in the phosphorylation of BiP on threonine residues while ER stress induced by tunicamycin or heat shock caused the fast dephosphorylation of the protein. Regulation of BiP function by phosphorylation/dephosphorylation events was proposed in early studies in mammalian cells although no connection to TOR signaling has been established so far. Here I will discuss about the coordinated regulation of BiP modification by TOR and ER stress signals in Chlamydomonas.     

Glucose Activates TORC2-Gad8 Protein via Positive Regulation of the cAMP/cAMP-dependent Protein Kinase A (PKA) Pathway and Negative Regulation of the Pmk1 Protein-Mitogen-activated Protein Kinase Pathway

The target of rapamycin (TOR) kinase belongs to the highly conserved eukaryotic family of phosphatidylinositol 3-kinase-related kinases. TOR proteins are found at the core of two evolutionary conserved complexes, known as TORC1 and TORC2. In fission yeast, TORC2 is dispensable for proliferation under optimal growth conditions but is required for starvation and stress responses. TORC2 has been implicated in a wide variety of functions; however, the signals that regulate TORC2 activity have so far remained obscure. TORC2 has one known direct substrate, the AGC kinase Gad8, which is related to AKT in human cells. Gad8 is phosphorylated by TORC2 at Ser-546 (equivalent to AKT Ser-473), leading to its activation. Here, we show that glucose is necessary and sufficient to induce Gad8 Ser-546 phosphorylation in vivo and Gad8 kinase activity in vitro. The glucose signal that activates TORC2-Gad8 is mediated via the cAMP/PKA pathway, a major glucose-sensing pathway. By contrast, Pmk1, similar to human extracellular signal-regulated kinases and a major stress-induced mitogen activated protein kinase (MAPK) in fission yeast, inhibits TORC2-dependent Gad8 phosphorylation and activation. Inhibition of TORC2-Gad8 also occurs in response to ionic or osmotic stress, in a manner dependent on the cAMP/PKA and Pmk1-MAPK signaling pathways. Our findings highlight the significance of glucose availability in regulation of TORC2-Gad8 and indicate a novel link between the cAMP/PKA, Pmk1/MAPK, and TORC2-Gad8 signaling.     

A TOR (target of rapamycin) and nutritional phosphoproteome of fission yeast reveals novel targets in networks conserved in humans

Fluctuations in TOR, AMPK and MAP-kinase signalling maintain cellular homeostasis and coordinate growth and division with environmental context. We have applied quantitative, SILAC mass spectrometry to map TOR and nutrient-controlled signalling in the fission yeast Schizosaccharomyces pombe. Phosphorylation levels at more than 1000 sites were altered following nitrogen stress or Torin1 inhibition of the TORC1 and TORC2 networks that comprise TOR signalling. One hundred and thirty of these sites were regulated by both perturbations, and the majority of these (119) new targets have not previously been linked to either nutritional or TOR control in either yeasts or humans. Elimination of AMPK inhibition of TORC1, by removal of AMPKα (ssp2::ura4⁺), identified phosphosites where nitrogen stress-induced changes were independent of TOR control. Using a yeast strain with an ATP analogue-sensitized Cdc2 kinase, we excluded sites that were changed as an indirect consequence of mitotic control modulation by nitrogen stress or TOR signalling. Nutritional control of gene expression was reflected in multiple targets in RNA metabolism, while significant modulation of actin cytoskeletal components points to adaptations in morphogenesis and cell integrity networks. Reduced phosphorylation of the MAPKK Byr1, at a site whose human equivalent controls docking between MEK and ERK, prevented sexual differentiation when resources were sparse but not eliminated.     

Molecular functions of the PP2A regulatory subunit Tap46 in plants

Tap42/α4 is a regulatory subunit of the protein phosphatase 2A (PP2A) family of phosphatases and plays a role in the target of rapamycin (TOR) pathway that regulates cell growth, ribosome biogenesis, translation and cell cycle progression in both yeast and mammals. We determined the cellular functions of Tap46, the plant homolog of Tap42/α4, in both Arabidopsis thaliana and Nicotiana benthamiana. Tap46 associated with the catalytic subunits of PP2A and the PP2A-like phosphatases PP4 and PP6 in vivo. Tap46 was phosphorylated by TOR in vitro, indicating that Tap46 is a direct substrate of TOR kinase. Tap46 deficiency caused cellular phenotypes that are similar to TOR-depletion phenotypes, including repression of global translation and activation of both autophagy and nitrogen recycling. Furthermore, Tap46 depletion regulated total PP2A activity in a time-dependent manner similar to TOR deficiency. These results suggest that Tap46 acts as a positive effector of the TOR signaling pathway in controlling diverse metabolic processes in plants. However, Tap46 silencing caused acute cell death, while TOR silencing only hastened senescence. Furthermore, mitotic cells with reduced Tap46 levels exhibited chromatin bridges at anaphase, while TOR depletion did not cause a similar defect. These findings suggest that Tap46 may have TOR-independent functions as well as functions related to TOR signaling in plants.Key words: acute cell death, autophagy, chromatin bridge, nitrogen mobilization, protein phosphatases, target of rapamycin (TOR)Yeast type 2A phosphatase-associated protein 42 kDa (Tap42) is a regulatory subunit that directly associates with catalytic subunits of the protein phosphatase 2A (PP2A) family of protein phosphatases to make a heterodimer and regulates the activity and substrate specificity of the intact enzyme complex.¹ Functions of Tap42 as a component of the target of rapamycin (TOR) signaling pathway have been well characterized in yeast.^1–3 Tap42-regulated phosphatase activities play a major role in signal transduction mediated by TOR. Accumulating evidence suggest that TOR regulates phosphorylation of target proteins by restraining PP2A activity through Tap42 phosphorylation.^1–3 Rapamycin inhibits TOR activity and also influences Tap42-mediated phosphatase regulation in yeast.^3–5α4, the mammalian homolog of Tap42, also associates with the catalytic subunits of PP2A, PP4 and PP6 to make a heterodimer.⁶ Rapamycin inhibits mammalian TOR (mTOR) activity, but it is not clear whether rapamycin prevents the formation of the α4/PP2Ac complex or whether α4 stimulates or represses PP2Ac activity.^7–9 Interestingly, loss of Tap42 function in Drosophila does not affect TOR-regulated activities, including cell growth, metabolism and S6 kinase activity, but results in mitotic arrest caused by spindle anomalies and subsequent activation of c-Jun N-terminal kinase signaling and apoptosis.¹⁰ Similarly, α4 deletion in mice leads to the rapid onset of apoptosis in both proliferating and differentiated cells, while rapamycin itself does not severely affect adult cells.¹¹ Furthermore, while TOR depletion causes developmental arrest and organ degeneration at the L3 stage in Caenorhabditis elegans, loss of α4 does not reproduce TOR deficiency phenotypes, but mainly leads to a fertility defect.¹² Taken together, these results suggest that the yeast Tap42/TOR paradigm is not completely conserved in higher eukaryotes and that Tap42/α4 functions may not be exclusively dependent on the Tor signaling pathway.In this study, we investigated the in vivo functions and phosphatase regulation of Tap46, the plant Tap42/α4 homolog, in relation to TOR in Nicotiana benthamiana, Arabidopsis and tobacco BY2 cells. Tap46 was shown to interact with the catalytic subunits of PP2A, PP4 and PP6 in vivo. Recombinant Tap46 protein was phosphorylated by immunoprecipitated TOR kinase and its deletion forms in vitro. Dexamethasone-induced RNAi of Tap46 caused dramatic repression of global translation and activation of both autophagy and nitrogen mobilization in the early stages of gene silencing. These phenotypes mimic those of TOR inactivation or TOR deficiency in Arabidopsis, yeast and mammals, indicating that Tap46 is a critical mediator of the Tor pathway in the regulation of these metabolic processes in plants. However, these early phenotypes of Tap46-deficient plants were soon followed by an acute and rapid programmed cell-death (PCD), while TOR silencing only led to growth retardation and premature senescence in Arabidopsis and N. benthamiana, confirming results from a previous study.¹³ The PCD caused by Tap46 deficiency is consistent with the apoptosis induced by loss of Tap42/α4 function in both Drosophila and mice.^10,11 Thus Tap42/α4/Tap46 appears to have a strong anti-apoptotic activity in higher eukaryotes. The underlying mechanisms of PCD activation caused by Tap46 depletion remain to be revealed, but it is possible that the inappropriate modulation of phosphatase activity and aberrant protein phosphorylation led to stress signaling and PCD activation.Another interesting phenotype of Tap46 deficiency is the formation of chromatin bridges in anaphase during mitosis, suggesting a role for Tap46 in plant cell mitotic progression. However, there have been no reports of anaphase bridge formation in tor mutants of any organisms. In Drosophila, loss of Tap42 function causes spindle disorganization and pre-anaphase arrest prior to the onset of apoptosis.¹⁰ In addition, Drosophila mutants with a defective regulatory subunit of PP2A exhibit an increased number of lagging chromosomes and chromatin bridges in anaphase.^14,15 Tap46 likely regulates the functions of PP2A family phosphatases during mitosis by direct association with their catalytic subunits, thereby modulating both the activity and specificity of the enzyme. Accumulating evidence reveals dynamic functions of PP2A during mitosis in both yeast and mammals: PP2A regulates kinetochore function, sister chromatid cohesion, spindle bipolarity and progression to anaphase.^15–17 Counteracting the activity of protein kinases, PP4 has also been implicated in both centrosome maturation and function during mitosis.¹⁸ Based on immunolabeling results, Tap46 was visualized as distinct spots around chromatin and mitotic spindles during mitosis in tobacco BY2 cells (Lee HS and Pai HS, unpublished results). Further studies will address the interacting partners and dynamic relocation of Tap46 during the cell cycle.Our results in this study demonstrated that Tap46 plays an important regulatory role in plant growth and metabolism; a major part of its function appears related to TOR signaling. However, we consistently observed certain phenotypic differences between Tap46-silenced and TOR-silenced Arabidopsis and N. benthamiana plants: an acute and rapid PCD occurred upon Tap46 silencing but not upon TOR silencing, despite a similar degree of gene silencing. Furthermore, we did not observe anaphase bridge formation in mitotic root-tip cells of ethanol-induced TOR RNAi Arabidopsis plants, while chromatin bridges were repeatedly observed in Tap46-silenced tobacco BY2 and Arabidopsis root-tip cells. Although an ancient Tap42/TOR paradigm observed in yeast appears to be conserved in plants, new TOR-independent functions of Tap46 might have evolved, the abrogation of which can cause massive PCD activation and anaphase bridge formation. Tap46 is a major regulator of cellular PP2A activity in plant cells by interacting with multiple phosphatase partners. Unraveling the molecular networks of Tap46 activity and interactions is essential for understanding its TOR-dependent and -independent functions in plants.     

Attenuation of TORC1 signaling delays replicative and oncogenic RAS-induced senescence

Numerous stimuli, including oncogenic signaling, DNA damage or eroded telomeres trigger proliferative arrest, termed cellular senescence. Accumulating evidence suggests that cellular senescence is a potent barrier to tumorigenesis in vivo, however oncogene induced senescence can also promote cellular transformation.^1,2 Several oncogenes, whose overexpression results in cellular senescence, converge on the TOR (target of rapamycin) pathway. We therefore examined whether attenuation of TOR results in delay or reversal of cellular senescence. By using primary human fibroblasts undergoing either replicative or oncogenic RAS-induced senescence, we demonstrated that senescence can be delayed, and some aspects of senescence can be reversed by inhibition of TOR, using either the TOR inhibitor rapamycin or by depletion of TORC1 (TOR Complex 1). Depletion of TORC2 fails to affect the course of replicative or RAS-induced senescence. Overexpression of REDD1 (Regulated in DNA Damage Response and Development), a negative regulator of TORC1, delays the onset of replicative senescence. These results indicate that TORC1 is an integral component of the signaling pathway that mediates cellular senescence.     

Growth Control Under Stress: mTOR Regulation through the REDD1-TSC Pathway

Dysregulated signaling by the checkpoint kinase TOR (target of rapamycin) has been linked to numerous human cancers. The tuberous sclerosis tumor suppressors TSC1 and TSC2 form a protein complex that integrates and transmits cellular growth factor and stress signals to negatively regulate TOR activity. Several recent reports have identified the stress response gene REDD1 as an essential regulator of TOR activity through the TSC1/2 complex in both Drosophila and mammalian cells. REDD1 is induced in response both to hypoxia and energy stress, and cells that lack REDD1 exhibit highly defective TOR regulation in response to either of these stress signals. While the precise mechanism of REDD1 function remains to be determined, the finding that REDD1-dependent TOR regulation contributes to cell growth/cell size control in flies and mammals suggests that abnormalities of REDD1-mediated signaling might disrupt energy homeostasis and/or promote tumorigenesis.     

Phosphorylation of the TOR ATP binding domain by AGC kinase constitutes a novel mode of TOR inhibition

TOR (target of rapamycin) signaling coordinates cell growth, metabolism, and cell division through tight control of signaling via two complexes, TORC1 and TORC2. Here, we show that fission yeast TOR kinases and mTOR are phosphorylated on an evolutionarily conserved residue of their ATP-binding domain. The Gad8 kinase (AKT homologue) phosphorylates fission yeast Tor1 at this threonine (T1972) to reduce activity. A T1972A mutation that blocked phosphorylation increased Tor1 activity and stress resistance. Nitrogen starvation of fission yeast inhibited TOR signaling to arrest cell cycle progression in G1 phase and promoted sexual differentiation. Starvation and a Gad8/T1972-dependent decrease in Tor1 (TORC2) activity was essential for efficient cell cycle arrest and differentiation. Experiments in human cell lines recapitulated these yeast observations, as mTOR was phosphorylated on T2173 in an AKT-dependent manner. In addition, a T2173A mutation increased mTOR activity. Thus, TOR kinase activity can be reduced through AGC kinase–controlled phosphorylation to generate physiologically significant changes in TOR signaling.     

TOR-mediated autophagy regulates cell death in Drosophila neurodegenerative disease

Target of rapamycin (TOR) signaling is a regulator of cell growth. TOR activity can also enhance cell death, and the TOR inhibitor rapamycin protects cells against proapoptotic stimuli. Autophagy, which can protect against cell death, is negatively regulated by TOR, and disruption of autophagy by mutation of Atg5 or Atg7 can lead to neurodegeneration. However, the implied functional connection between TOR signaling, autophagy, and cell death or degeneration has not been rigorously tested. Using the Drosophila melanogaster visual system, we show in this study that hyperactivation of TOR leads to photoreceptor cell death in an age- and light-dependent manner and that this is because of TOR''s ability to suppress autophagy. We also find that genetically inhibiting TOR or inducing autophagy suppresses cell death in Drosophila models of Huntington''s disease and phospholipase C (norpA)–mediated retinal degeneration. Thus, our data indicate that TOR induces cell death by suppressing autophagy and provide direct genetic evidence that autophagy alleviates cell death in several common types of neurodegenerative disease.     

Rapamycin and glucose-target of rapamycin (TOR) protein signaling in plants

Target of rapamycin (TOR) kinase is an evolutionarily conserved master regulator that integrates energy, nutrients, growth factors, and stress signals to promote survival and growth in all eukaryotes. The reported land plant resistance to rapamycin and the embryo lethality of the Arabidopsis tor mutants have hindered functional dissection of TOR signaling in plants. We developed sensitive cellular and seedling assays to monitor endogenous Arabidopsis TOR activity based on its conserved S6 kinase (S6K) phosphorylation. Surprisingly, rapamycin effectively inhibits Arabidopsis TOR-S6K1 signaling and retards glucose-mediated root and leaf growth, mimicking estradiol-inducible tor mutants. Rapamycin inhibition is relieved in transgenic plants deficient in Arabidopsis FK506-binding protein 12 (FKP12), whereas FKP12 overexpression dramatically enhances rapamycin sensitivity. The role of Arabidopsis FKP12 is highly specific as overexpression of seven closely related FKP proteins fails to increase rapamycin sensitivity. Rapamycin exerts TOR inhibition by inducing direct interaction between the TOR-FRB (FKP-rapamycin binding) domain and FKP12 in plant cells. We suggest that variable endogenous FKP12 protein levels may underlie the molecular explanation for longstanding enigmatic observations on inconsistent rapamycin resistance in plants and in various mammalian cell lines or diverse animal cell types. Integrative analyses with rapamycin and conditional tor and fkp12 mutants also reveal a central role of glucose-TOR signaling in root hair formation. Our studies demonstrate the power of chemical genetic approaches in the discovery of previously unknown and pivotal functions of glucose-TOR signaling in governing the growth of cotyledons, true leaves, petioles, and primary and secondary roots and root hairs.     

The TOR Pathway Modulates the Structure of Cell Walls in Arabidopsis

Plant cell growth is limited by the extension of cell walls, which requires both the synthesis and rearrangement of cell wall components in a controlled fashion. The target of rapamycin (TOR) pathway is a major regulator of cell growth in eukaryotes, and inhibition of this pathway by rapamycin reduces cell growth. Here, we show that in plants, the TOR pathway affects cell wall structures. LRR-extensin1 (LRX1) of Arabidopsis thaliana is an extracellular protein involved in cell wall formation in root hairs, and lrx1 mutants develop aberrant root hairs. rol5 (for repressor of lrx1) was identified as a suppressor of lrx1. The functionally similar ROL5 homolog in yeast, Ncs6p (needs Cla4 to survive 6), was previously found to affect TOR signaling. Inhibition of TOR signaling by rapamycin led to suppression of the lrx1 mutant phenotype and caused specific changes to galactan/rhamnogalacturonan-I and arabinogalactan protein components of cell walls that were similar to those observed in the rol5 mutant. The ROL5 protein accumulates in mitochondria, a target of the TOR pathway and major source of reactive oxygen species (ROS), and rol5 mutants show an altered response to ROS. This suggests that ROL5 might function as a mitochondrial component of the TOR pathway that influences the plant''s response to ROS.