Naweed I. Naqvi

Rng2p, a protein required for cytokinesis in fission yeast, is a component of the actomyosin ring and the spindle pole body

BACKGROUND An actomyosin-based contractile ring plays a pivotal role in cytokinesis. Despite the identification of many components of the ring, the steps involved in its assembly are unknown. The fission yeast Schizosaccharomyces pombe is an attractive organism in which to study cytokinesis because its cell cycle has been well characterized; it divides by medial fission using an actomyosin ring; and a number of S. pombe mutants defective in actomyosin ring assembly have been isolated. Here, we have characterized one such mutant, rng2. RESULTS Temperature-sensitive rng2 mutants accumulated F-actin cables in the medial region of the cell but failed to organize the cables into a ring. In rng2-null mutants, only a spot-like structure containing F-actin was detected. The rng2+ gene encodes a protein related to human IQGAP1, a protein that binds actin and calmodulin and is a potential effector for the Rho family of GTPases. Rng2p localized to the actomyosin ring and to the spindle pole body (SPB) of interphase and mitotic cells. Localization of Rng2p to the actomyosin ring but not the SPB required F-actin. Rng2p interacted with calmodulin, a component of the SPB and the actomyosin ring. The rng2 gene showed genetic interactions with three other actomyosin ring assembly mutants, cdc4, cdc12, and rng5. CONCLUSIONS The S. pombe IQGAP-related protein Rng2p is a component of the actomyosin ring and the SPB and is required for actomyosin ring construction following assembly of F-actin at the division site.

Woronin Body Function in Magnaporthe grisea Is Essential for Efficient Pathogenesis and for Survival during Nitrogen Starvation Stress

The Woronin body is a peroxisome-derived dense-core vesicle that is specific to several genera of filamentous ascomycetes, where it has been shown to seal septal pores in response to cellular damage. The Hexagonal peroxisome (Hex1) protein was recently identified as a major constituent of the Woronin body and shown to be responsible for self-assembly of the dense core of this organelle. Using a mutation in the Magnaporthe grisea HEX1 ortholog, we define a dual and essential function for Woronin bodies during the pathogenic phase of the rice blast fungus. We show that the Woronin body is initially required for proper development and function of appressoria (infection structures) and subsequently necessary for survival of infectious fungal hyphae during invasive growth and host colonization. Fungal mycelia lacking HEX1 function were unable to survive nitrogen starvation in vitro, suggesting that in planta growth defects are a consequence of the mutants inability to cope with nutritional stress. Thus, Woronin body function provides the blast fungus with an important defense against the antagonistic and nutrient-limiting environment encountered within the host plant.

Evidence for F-actin-dependent and -independent mechanisms involved in assembly and stability of the medial actomyosin ring in fission yeast.

Cell division in a number of eukaryotes, including the fission yeast Schizosaccharomyces pombe, is achieved through a medially placed actomyosin‐based contractile ring. Although several components of the actomyosin ring have been identified, the mechanisms regulating ring assembly are still not understood. Here, we show by biochemical and mutational studies that the S.pombe actomyosin ring component Cdc4p is a light chain associated with Myo2p, a myosin II heavy chain. Localization of Myo2p to the medial ring depended on Cdc4p function, whereas localization of Cdc4p at the division site was independent of Myo2p. Interestingly, the actin‐binding and motor domains of Myo2p are not required for its accumulation at the division site although the motor activity of Myo2p is essential for assembly of a normal actomyosin ring. The initial assembly of Myo2p and Cdc4p at the division site requires a functional F‐actin cytoskeleton. Once established, however, F‐actin is not required for the maintenance of Cdc4p and Myo2p medial rings, suggesting that the attachment of Cdc4p and Myo2p to the division site involves proteins other than actin itself.

Rgs1 regulates multiple Gα subunits in Magnaporthe pathogenesis, asexual growth and thigmotropism

Regulators of G‐protein signaling (RGS proteins) negatively regulate heterotrimeric G‐protein cascades that enable eukaryotic cells to perceive and respond to external stimuli. The rice‐blast fungus Magnaporthe grisea forms specialized infection structures called appressoria in response to inductive surface cues. We isolated Magnaporthe RGS1 in a screen for mutants that form precocious appressoria on non‐inductive surfaces. We report that a thigmotropic cue is necessary for initiating appressoria and for accumulating cAMP. Similar to an RGS1‐deletion strain, magAG187S (RGS‐insensitive Gαs) and magAQ208L (GTPase‐dead) mutants accumulated excessive cAMP and elaborated appressoria on non‐inductive surfaces, suggesting that Rgs1 regulates MagA during pathogenesis. Rgs1 was also found to negatively regulate the Gαi subunit MagB during asexual development. Deficiency of MAGB suppressed the hyper‐conidiation defect in RGS1‐deletion strain, whereas magBG183S and magBQ204L mutants produced more conidia, similar to the RGS1‐deletion strain. Rgs1 physically interacted with GDP·AlF4−‐activated forms of MagA, MagB and MagC (a GαII subunit). Thus, Rgs1 serves as a negative regulator of all Gα subunits in Magnaporthe and controls important developmental events during asexual and pathogenic development.

Host invasion during rice‐blast disease requires carnitine‐dependent transport of peroxisomal acetyl‐CoA

In lower eukaryotes, beta‐oxidation of fatty acids is restricted primarily to the peroxisomes and the resultant acetyl‐CoA molecules (and the chain‐shortened fatty acids) are transported via the cytosol into the mitochondria for further breakdown and usage. Using a loss‐of‐function mutation in the Magnaporthe grisea PEROXIN6 orthologue, we define an essential role for peroxisomal acetyl‐CoA during the host invasion step of the rice‐blast disease. We show that an Mgpex6Δ strain lacks functional peroxisomes and is incapable of β‐oxidation of long‐chain fatty acids. The Mgpex6Δ mutant lacked appressorial melanin and host penetration, and was completely non‐pathogenic. We further show that a peroxisome‐associated carnitine acetyl‐transferase (Crat1) activity is essential for such appressorial function in Magnaporthe. CRAT1‐minus appressoria showed reduced melanization, but were surprisingly incapable of elaborating penetration pegs or infection hyphae. Exogenous addition of excess glucose during infection stage caused partial remediation of the pathogenicity defects in the crat1Δ strain. Moreover, Mgpex6Δ and crat1Δ mycelia showed increased sensitivity to Calcofluor white, suggesting that weakened cell wall biosynthesis in a glucose‐deficient environment leads to appressorial dysfunction in these mutants. Interestingly, CRAT1 was itself essential for growth on acetate and long‐chain fatty acids. Thus, carnitine‐dependent metabolic activities associated with the peroxisomes, cooperatively facilitate the appressorial function of host invasion during rice‐blast infections.

Type II myosin regulatory light chain relieves auto-inhibition of myosin-heavy-chain function.

The F-actin based motor protein myosin II has a key role in cytokinesis. Here we show that the Schizosaccharomyces pombe regulatory light chain (RLC) protein Rlc1p binds to Myo2p in manner that is dependent on the IQ sequence motif (the RLC-binding site), and that Rlc1p is a component of the actomyosin ring. Rlc1p is important for cytokinesis at all growth temperatures and is essential for this process at lower temperatures. Interestingly, all deleterious phenotypes associated with the loss of Rlc1p function are suppressed by deletion of the RLC binding site on Myo2p. We conclude that the sole essential function of RLCs in fission yeast is to relieve the auto-inhibition of myosin II function, which is mediated by the RLC-binding site, on the myosin heavy chain (MHC).

A multidrug resistance transporter in Magnaporthe is required for host penetration and for survival during oxidative stress.

In prokaryotes and eukaryotes, multidrug resistance (MDR) transporters use energy-dependent efflux action to regulate the intracellular levels of antibiotic or xenobiotic compounds. Using mutational analysis of ABC3, we define an important role for such MDR-based efflux during the host penetration step of Magnaporthe grisea pathogenesis. Mutants lacking ABC3 were completely nonpathogenic but were surprisingly capable of penetrating thin cellophane membranes to some extent. The inability of abc3Δ to penetrate the host surface was most likely a consequence of excessive buildup of peroxide and accumulation of an inhibitory metabolite(s) within the mutant appressoria. Treatment with antioxidants partially suppressed the host penetration defects in the abc3Δ mutant. abc3Δ was highly sensitive to oxidative stress and was unable to survive the host environment and invasive growth conditions. ABC3 transcript levels were redox-regulated, and on host surfaces, the activation of ABC3 occurred during initial stages of blast disease establishment. An Abc3-green fluorescent protein fusion localized to the plasma membrane in early appressoria (and in penetration hyphae) but became predominantly vacuolar during appressorial maturity. We propose that ABC3 function helps Magnaporthe to cope with cytotoxicity and oxidative stress within the appressoria during early stages of infection-related morphogenesis and likely imparts defense against certain antagonistic and xenobiotic conditions encountered during pathogenic development.

Autophagy-assisted glycogen catabolism regulates asexual differentiation in Magnaporthe oryzae

Autophagy, a conserved pathway for bulk cellular degradation and recycling in eukaryotes, regulates proper turnover of organelles, membranes and certain proteins. Such regulated degradation is important for cell growth and development particularly during environmental stress conditions, which act as key inducers of autophagy. We found that autophagy and MoATG8 were significantly induced during asexual development in Magnaporthe oryzae. An RFP-tagged MoAtg8 showed specific localization and enrichment in aerial hyphae, conidiophores and conidia. We confirmed that loss of MoATG8 results in dramatically reduced ability to form conidia, the asexual spores that propagate rice-blast disease. Exogenous supply of glucose or sucrose significantly suppressed the conidiation defects in a MoATG8-deletion mutant. Comparative proteomics based identification and characterization of Gph1, a glycogen phosphorylase that catalyzes glycogen breakdown, indicated that autophagy-assisted glycogen homeostasis is likely important for proper aerial growth and conidiation in Magnaporthe. Loss of Gph1, or addition of G6P significantly restored conidiation in the Moatg8Δ mutant. Overproduction of Gph1 led to reduced conidiation in wild-type Magnaporthe strain. We propose that glycogen autophagy actively responds to and regulates carbon utilization required for cell growth and differentiation during asexual development in Magnaporthe.

IQGAP-Related Rng2p Organizes Cortical Nodes and Ensures Position of Cell Division in Fission Yeast

Correct positioning of the cell division machinery is crucial for genomic stability and cell fate determination. The fission yeast Schizosaccharomyces pombe, like animal cells, divides using an actomyosin ring and is an attractive model to study eukaryotic cytokinesis. In S. pombe, positioning of the actomyosin ring depends on the anillin-related protein Mid1p. Mid1p arrives first at the medial cortex and recruits actomyosin ring components to node-like structures, although how this is achieved is unknown. Here we show that the IQGAP-related protein Rng2p, an essential component of the actomyosin ring, is a key element downstream of Mid1p. Rng2p physically interacts with Mid1p and is required for the organization of other actomyosin ring components into cortical nodes. Failure of localization of Rng2p to the nodes prevents medial retention of Mid1p and leads to actomyosin ring assembly in a node-independent manner at nonmedial locations. We conclude that Mid1p recruits Rng2p to cortical nodes at the division site and that Rng2p, in turn, recruits other components of the actomyosin ring to cortical nodes, thereby ensuring correct placement of the division site.

PdeH, a High-Affinity cAMP Phosphodiesterase, Is a Key Regulator of Asexual and Pathogenic Differentiation in Magnaporthe oryzae

Cyclic AMP-dependent pathways mediate the communication between external stimuli and the intracellular signaling machinery, thereby influencing important aspects of cellular growth, morphogenesis and differentiation. Crucial to proper function and robustness of these signaling cascades is the strict regulation and maintenance of intracellular levels of cAMP through a fine balance between biosynthesis (by adenylate cyclases) and hydrolysis (by cAMP phosphodiesterases). We functionally characterized gene-deletion mutants of a high-affinity (PdeH) and a low-affinity (PdeL) cAMP phosphodiesterase in order to gain insights into the spatial and temporal regulation of cAMP signaling in the rice-blast fungus Magnaporthe oryzae. In contrast to the expendable PdeL function, the PdeH activity was found to be a key regulator of asexual and pathogenic development in M. oryzae. Loss of PdeH led to increased accumulation of intracellular cAMP during vegetative and infectious growth. Furthermore, the pdeHΔ showed enhanced conidiation (2–3 fold), precocious appressorial development, loss of surface dependency during pathogenesis, and highly reduced in planta growth and host colonization. A pdeHΔ pdeLΔ mutant showed reduced conidiation, exhibited dramatically increased (∼10 fold) cAMP levels relative to the wild type, and was completely defective in virulence. Exogenous addition of 8-Br-cAMP to the wild type simulated the pdeHΔ defects in conidiation as well as in planta growth and development. While a fully functional GFP-PdeH was cytosolic but associated dynamically with the plasma membrane and vesicular compartments, the GFP-PdeL localized predominantly to the nucleus. Based on data from cAMP measurements and Real-Time RTPCR, we uncover a PdeH-dependent biphasic regulation of cAMP levels during early and late stages of appressorial development in M. oryzae. We propose that PdeH-mediated sustenance and dynamic regulation of cAMP signaling during M. oryzae development is crucial for successful establishment and spread of the blast disease in rice.