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The roles of integrin-like proteins, tyrosine phosphorylation and F-actin in hyphal tip growthChitcholtan, Kanueng January 2006 (has links)
Tip growth, the mechanism by which hyphae, pollen tubes, root hairs, and algal rhizoids extend, is a complex and dynamic process that is characterised by localised extension at the extreme apex of the cell and morphological polarity. Its complexity suggests that high degree of regulation is needed to ensure that the characteristics of a particular cell type are maintained during growth. Regulation is likely to come about through bidirectional interplay between the cell wall and cytoplasm, although the mechanisms by which such cross-talk might occur are unknown. Results of this thesis present immunocytochemical data that indicate the presence of, and a close association between β4 integrin subunit-like proteins and proteins containing phosphorylated tyrosine residues in the oomycete Achlya bisexualis. When hyphae were plasmolysed, these proteins were present in wall-membrane attachment sites where there was also F-actin. A combination of immunoblots, ELISA, and a coupled enzyme assay suggest that phosphorylation may occur by both autophosphorylation and through the possible action of a tyrosine kinase. Tyrphostins, which are inhibitors of tyrosine kinases, abolished the anti-phosphotyrosine staining, inhibited the kinase activity, slowed tip growth and affected the organisation of the actin cytoskeleton, in a dose-dependent manner. In addition, results show A. bisexualis contains proteins epitopically similar to the rod domain of animal talin. However, these proteins do not co-localise with F-actin, and mainly locate at the sub-apical region in hyphae. For comparative purposes, Saccharomyces cerevisiae was also used to investigate the presence of β4 integrin subunit-like proteins and tyrosine phosphorylation. Immunoblotting showed that S. cereviaise contains a protein, which is found in the microsomal pellet fraction, that cross reacts with anti-β4 integrin subunit antibody. Furthermore, there are a number of proteins containing phosphotyrosine residues. Immunocytochemistry shows that this anti-β4 integrin staining is at the cortical site but anti-phosphotyrosine residues are distributed throughout cells. On the basis of an ELISA and a coupled enzyme assay, it is suggested that a soluble fraction of S. cerevisiae contains tyrosine kinase activity. This activity is strongly inhibited by tyrphostins.
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The roles of integrin-like proteins, tyrosine phosphorylation and F-actin in hyphal tip growthChitcholtan, Kanueng January 2006 (has links)
Tip growth, the mechanism by which hyphae, pollen tubes, root hairs, and algal rhizoids extend, is a complex and dynamic process that is characterised by localised extension at the extreme apex of the cell and morphological polarity. Its complexity suggests that high degree of regulation is needed to ensure that the characteristics of a particular cell type are maintained during growth. Regulation is likely to come about through bidirectional interplay between the cell wall and cytoplasm, although the mechanisms by which such cross-talk might occur are unknown. Results of this thesis present immunocytochemical data that indicate the presence of, and a close association between β4 integrin subunit-like proteins and proteins containing phosphorylated tyrosine residues in the oomycete Achlya bisexualis. When hyphae were plasmolysed, these proteins were present in wall-membrane attachment sites where there was also F-actin. A combination of immunoblots, ELISA, and a coupled enzyme assay suggest that phosphorylation may occur by both autophosphorylation and through the possible action of a tyrosine kinase. Tyrphostins, which are inhibitors of tyrosine kinases, abolished the anti-phosphotyrosine staining, inhibited the kinase activity, slowed tip growth and affected the organisation of the actin cytoskeleton, in a dose-dependent manner. In addition, results show A. bisexualis contains proteins epitopically similar to the rod domain of animal talin. However, these proteins do not co-localise with F-actin, and mainly locate at the sub-apical region in hyphae. For comparative purposes, Saccharomyces cerevisiae was also used to investigate the presence of β4 integrin subunit-like proteins and tyrosine phosphorylation. Immunoblotting showed that S. cereviaise contains a protein, which is found in the microsomal pellet fraction, that cross reacts with anti-β4 integrin subunit antibody. Furthermore, there are a number of proteins containing phosphotyrosine residues. Immunocytochemistry shows that this anti-β4 integrin staining is at the cortical site but anti-phosphotyrosine residues are distributed throughout cells. On the basis of an ELISA and a coupled enzyme assay, it is suggested that a soluble fraction of S. cerevisiae contains tyrosine kinase activity. This activity is strongly inhibited by tyrphostins.
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F-actin and integrin like proteins in Phytophthora cinnamomiHarland, Chad S. January 2007 (has links)
Tip growth is the primary form of growth in hyphal organisms and some plant cells. Tip growth in hyphae is highly dependent on F-actin, which acts to regulate and support growth. One of the models suggested for tip growth, the amebae model of tip growth, suggests that F-actin may also be the primary source of protrusive force for tip growth in some conditions, and that proteins with a similar function to animal integrins would be present an involved in tip growth (Heath and Steinberg 1999). In this thesis we examine the role of F-actin in the growth of the oomycete Phytophthora cinnamomi and the effects on growth of the F-actin disrupting compound Latrunculin B. We demonstrate that F-actin plays a critical role in the tip growth of Phytophthora cinnamomi with it's disruption causing rapid cessation in directional growth, followed by significant subapical swelling. Further more we examine Phytophthora cinnamomi for the presence of an B4 integrin like protein that has been previously reported in the oomycete Achlya bisexualis (Chitcholtan & Garrill 2005) and show that the B4 integrin like protein is not present in Phytophthora cinnamomi. These experiments help further our understanding of tip growth in Phytophthora cinnamomi an economically important plant pathogen.
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The Role of Actin in Hyphal Tip GrowthSuei, Sandy H.Y. January 2008 (has links)
This thesis investigates whether there are alternative mechanisms of tip growth in invasive and non-invasive hyphae of the fungus Neurospora crassa. The cytoskeleton protein actin is thought to play a pivotal role in hyphal tip growth, performing a multitude of tasks, one of which may be the provision of a resistive force to counter turgor pressure.
An Actin depleted zone (ADZ) was the dominant feature of invasive hyphal tips, which was largely absent from non-invasive hyphae. The Spitzenkörper was slightly larger in invasive hyphae but this size difference alone was thought insufficient to account for the exclusion of filamentous actin (F-actin) from the tip. The actin nucleating protein formin was found at sites where actin nucleation is occurring, while cofilin, a protein that severs F-actin, was found to localise where F-actin disassembly was likely to be occurring. It is suggested that these proteins are likely to play a role in controlling a dynamic cytoskeleton, rearrangements of which are required for the two modes of growth. Invasive hyphae were found to generate a higher turgor than non-invasive hyphae.
These results suggest that the F-actin rearrangements facilitated by cofilin give an ADZ that may play a role in invasive hyphal tip growth; possibly through a reduction of tip resistance; thus enabling the provision of a greater protrusive force by turgor.
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F-actin and integrin like proteins in Phytophthora cinnamomiHarland, Chad S. January 2007 (has links)
Tip growth is the primary form of growth in hyphal organisms and some plant cells. Tip growth in hyphae is highly dependent on F-actin, which acts to regulate and support growth. One of the models suggested for tip growth, the amebae model of tip growth, suggests that F-actin may also be the primary source of protrusive force for tip growth in some conditions, and that proteins with a similar function to animal integrins would be present an involved in tip growth (Heath and Steinberg 1999). In this thesis we examine the role of F-actin in the growth of the oomycete Phytophthora cinnamomi and the effects on growth of the F-actin disrupting compound Latrunculin B. We demonstrate that F-actin plays a critical role in the tip growth of Phytophthora cinnamomi with it's disruption causing rapid cessation in directional growth, followed by significant subapical swelling. Further more we examine Phytophthora cinnamomi for the presence of an B4 integrin like protein that has been previously reported in the oomycete Achlya bisexualis (Chitcholtan & Garrill 2005) and show that the B4 integrin like protein is not present in Phytophthora cinnamomi. These experiments help further our understanding of tip growth in Phytophthora cinnamomi an economically important plant pathogen.
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The Role of Actin in Hyphal Tip GrowthSuei, Sandy H.Y. January 2008 (has links)
This thesis investigates whether there are alternative mechanisms of tip growth in invasive and non-invasive hyphae of the fungus Neurospora crassa. The cytoskeleton protein actin is thought to play a pivotal role in hyphal tip growth, performing a multitude of tasks, one of which may be the provision of a resistive force to counter turgor pressure. An Actin depleted zone (ADZ) was the dominant feature of invasive hyphal tips, which was largely absent from non-invasive hyphae. The Spitzenkörper was slightly larger in invasive hyphae but this size difference alone was thought insufficient to account for the exclusion of filamentous actin (F-actin) from the tip. The actin nucleating protein formin was found at sites where actin nucleation is occurring, while cofilin, a protein that severs F-actin, was found to localise where F-actin disassembly was likely to be occurring. It is suggested that these proteins are likely to play a role in controlling a dynamic cytoskeleton, rearrangements of which are required for the two modes of growth. Invasive hyphae were found to generate a higher turgor than non-invasive hyphae. These results suggest that the F-actin rearrangements facilitated by cofilin give an ADZ that may play a role in invasive hyphal tip growth; possibly through a reduction of tip resistance; thus enabling the provision of a greater protrusive force by turgor.
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In vivo Analysis and Modeling Reveals that Transient Interactions of Myosin XI, its Cargo, and Filamentous Actin Overcome Diffusion Limitations to Sustain Polarized Cell GrowthBibeau, Jeffrey Philippe 19 February 2018 (has links)
Tip growth is a ubiquitous process throughout the plant kingdom in which a single cell elongates in one direction in a self-similar manner. To sustain tip growth in plants, the cell must regulate the extensibility of the wall to promote growth and avoid turgor-induced rupture. This process is heavily dependent on the cytoskeleton, which is thought to coordinate the delivery and recycling of vesicles containing cell wall materials at the cell tip. Although significant work has been done to elucidate the various molecular players in this process, there remains a need for a more mechanistic understanding of the cytoskeletonÂ’s role in tip growth. For this reason, specific emphasis should be placed on understanding the dynamics of the cytoskeleton, its associated motors, and their cargo. Since the advent of fluorescence fusion technology, various quantitative fluorescence dynamics techniques have emerged. Among the most prominent of these techniques is fluorescence recovery after photobleaching (FRAP). Despite its prominence, it is unclear how to interpret fluorescence recoveries in confined cellular geometries such as tip-growing cells. Here we developed a digital confocal microscope simulation of FRAP in tip-growing cells. With this simulation, we determined that fluorescence recoveries are significantly influenced by cell boundaries. With this FRAP simulation, we then measured the diffusion of VAMP72-labeled vesicles in the moss Physcomitrella patens. Using finite element modeling of polarized cell growth, and the measured VAMP72-labeled vesicle diffusion coefficient, we were able to show that diffusion alone cannot support the required transport of wall materials to the cell tip. This indicates that an actin-based active transport system is necessary for vesicle clustering at the cell tip to support growth. This provides one essential function of the actin cytoskeleton in polarized cell growth. After establishing the requirement for actin-based transport, we then sought to characterize the in vivo binding interactions of myosin XI, vesicles, and filamentous actin. Particle tracking evidence from P. patens protoplasts suggests that myosin XI and VAMP72-labeled vesicles exhibit fast transient interactions. Hidden Markov modeling of particle tracking indicates that myosin XI and VAMP72- labeled vesicles move along actin filaments in short-lived linear trajectories. These fast transient interactions may be necessary to achieve the rapid dynamics of the apical actin, important for growth. This work advances the fieldÂ’s understanding of fluorescence dynamics, elucidates a necessary function of the actin cytoskeleton, and provides insight into how the components of the cytoskeleton interact in vivo.
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Reverse genetic and cell biological approaches to the study of developmental functions of Class XI myosin in Arabidopsis thalianaPark, Eunsook 01 March 2010 (has links)
Myosin proteins function as molecular motors that drive the ATP-dependent movement of cellular components along actin filaments. Vascular plants encode two different types of myosin, referred to as class VIII and class XI. Although class XI myosins have been suggested to function in organelle movement and cytoplasmic streaming, little is known about their cellular function in detail.
The Arabidopsis genome encodes 13 class XI myosin genes. The reasons for the relatively large number of myosin XI isoforms present within a single plant species are unknown. To investigate the function of these gene products in the cell, we determined the spatial and temporal gene expression patterns by constructing promoter-reporter plants. Myosin genes are expressed in a variety of tissues with substantial overlap between family members. To study the biological function more intensively, homozygous T-DNA insertion lines were isolated for all 13 genes. Interestingly, five mutants showed phenotypes related to root hairs. mya2, xi-b, and xi-k showed shorter root hairs than in wild type while xi-h and mya1 produced a higher density of root hairs on the epidermis. MYA1 and XI-K are the most similar isoforms among the 13 myosins and their double mutant showed an additive phenotype with extremely short root hairs suggesting that these two myosins have partially redundant functions. Interestingly organelle movements, especially those of peroxisomes, were reduced in mya1 xi-k.
Tip growth is the key growth mechanism in root hairs and pollen tubes. Many kinds of vesicles are trafficking toward (or backward from) the apical dome of root hairs to supply membrane and cell wall material as well as energy for growing tips. These movements along the shank of the hair occurred with velocities around 2 to 3 μm/s for Arabidopsis thaliana. In xi-k mutants, root hairs grew more slowly and terminated sooner than in wild type. Interestingly, this reduction of growth rate was correlated with a fluctuation of YFP-RAbA4b accumulation at the tip of growing root hairs. Other markers, including PI4P lipid and ER, as well as calcium and actin dynamics did not show significant differences. A YFP-XI-K construct driven by its native promoter could rescue the mutant phenotype and revealed accumulation of this myosin in the tip of growing root hairs. The distribution of YFP-XI-K in the root hair tip partially overlapped with CFP-RHD4-labeled vesicles at the subapex and YFP-RabA4b vesicles at the apex of root hairs, suggesting that myosin XI-K might be involved in the accumulation of unidentified vesicles in the tip of growing root hairs.
Characterization of two mutants that showed ectopic root hair growth in the epidermis, resulting in a higher density of root hairs than wild type, mya1 and xi-h, were initiated with two analyses. At first, staining pattern of promoter-reporter constructs of three key transcription factors, WER, EGL3, and GL2 were observed in mya1. Although variation in individual samples was too large to conclude, GL2 staining patterns in mya1 occasionally were unorganized. Increasing sample population and detail study is necessary. Secondly, effects of phosphate deficiency were observed with the mya1 and the xi-h in series of phosphate concentrations ranging from 1μM to 300μM. The xi-h mutant showed insensitivity on root hair production upon phosphate deficiency, suggesting a potential function of XI-H in the response to phosphate deficiency. Confirmation of these results and further study of the MYA1 and the XI-H is essential. In summary, this study established a systematic approach to investigate the biological function of class XI myosins in plant development and significantly increases our understanding of the function of XI-K myosin in root hair tip growth.
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F-actin rearrangements and analysis of physical environment of invasive hyphal growth.Rolston, Laura Elizabeth January 2009 (has links)
Invasive growth through a substrate requires a massive amount of penetrative force, and this is generated in the space of a few microns in a growing tip. This process is known to be critical in the root hair, pollen tube, rhizoids, and the topic of this thesis, hyphal growth. However defining the mechanisms underlying the tip growth remains a contentious issue. Shortcomings in control of direction and regulation of growth began to undermine early turgor-based theories, and the cytoskeletal protein actin, ubiquitous in nature and with crucial roles in structure and motility became a target for investigation. A major breakthrough came with the discovery that a characteristic actin depleted zone (ADZ) occurs at the growing tip of hyphae during invasive but not non-invasive hyphal growth. The ADZ is likely to have an important role in generating the greater protrusive force required for invasive growth. However, since its discovery, little has been determined about the characteristics of the ADZ. Uncertainty in the description of the physical environment the hyphae face adds a layer of complexity to interpretation of results.
This thesis aims to address this issue, studying the impact of increasing agarose substrate concentration on the presence and dimensions of the ADZ in the oomycete A. bisexualis. Furthermore, agarose is examined by compression and imaging to compare the physical characteristics of the agar samples over the range of concentrations, and determine whether increasing agarose concentration influences agarose gel structure.
Results suggest a difference in the number of ADZ observed in non-invasive compared with invasive samples, however no significant differences in the number or dimensions of ADZ were found amongst the 1-4% w/v agarose concentrations. The 0% sample showed 20.7 percent of hyphae exhibited depleted zones, while 1, 2, 3 and 4% samples showed 56.9%, 48.8%, 40.9% and 54.2% respectively. ADZ dimensions did not correlate with agarose concentration. The average ADZ area:hyphal diameter ratio was 0.634, 0.526, 0.430, 1.09, and 0.65 for 0-4% agarose concentrations respectively. Additionally, investigation of gel compression forces revealed gel strength increases with agarose
concentration. The force required to compress the agarose increased from 1.85 Psi in 1% agarose to 4.85, 7.09 and 12.22 Psi in 2, 3 and 4% agarose concentrations respectively. SEM imaging, however, suggests heterogeneity of the fibrous interconnected network of agarose gels at a microscopic scale with variable porous structure at all agarose concentrations. This scale is relevant to hyphal tip growth. In combination, these results suggest F-actin depletion may be a response mechanism to provide greater force for invasive growth. Additionally, this response is not dependent on the concentration of the agarose media, possibly due to the variability encountered within the media. These results contribute another important step forward in unraveling the elusive mechanism of tip growth.
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F-actin rearrangements and analysis of physical environment of invasive hyphal growth.Rolston, Laura Elizabeth January 2009 (has links)
Invasive growth through a substrate requires a massive amount of penetrative force, and this is generated in the space of a few microns in a growing tip. This process is known to be critical in the root hair, pollen tube, rhizoids, and the topic of this thesis, hyphal growth. However defining the mechanisms underlying the tip growth remains a contentious issue. Shortcomings in control of direction and regulation of growth began to undermine early turgor-based theories, and the cytoskeletal protein actin, ubiquitous in nature and with crucial roles in structure and motility became a target for investigation. A major breakthrough came with the discovery that a characteristic actin depleted zone (ADZ) occurs at the growing tip of hyphae during invasive but not non-invasive hyphal growth. The ADZ is likely to have an important role in generating the greater protrusive force required for invasive growth. However, since its discovery, little has been determined about the characteristics of the ADZ. Uncertainty in the description of the physical environment the hyphae face adds a layer of complexity to interpretation of results. This thesis aims to address this issue, studying the impact of increasing agarose substrate concentration on the presence and dimensions of the ADZ in the oomycete A. bisexualis. Furthermore, agarose is examined by compression and imaging to compare the physical characteristics of the agar samples over the range of concentrations, and determine whether increasing agarose concentration influences agarose gel structure. Results suggest a difference in the number of ADZ observed in non-invasive compared with invasive samples, however no significant differences in the number or dimensions of ADZ were found amongst the 1-4% w/v agarose concentrations. The 0% sample showed 20.7 percent of hyphae exhibited depleted zones, while 1, 2, 3 and 4% samples showed 56.9%, 48.8%, 40.9% and 54.2% respectively. ADZ dimensions did not correlate with agarose concentration. The average ADZ area:hyphal diameter ratio was 0.634, 0.526, 0.430, 1.09, and 0.65 for 0-4% agarose concentrations respectively. Additionally, investigation of gel compression forces revealed gel strength increases with agarose concentration. The force required to compress the agarose increased from 1.85 Psi in 1% agarose to 4.85, 7.09 and 12.22 Psi in 2, 3 and 4% agarose concentrations respectively. SEM imaging, however, suggests heterogeneity of the fibrous interconnected network of agarose gels at a microscopic scale with variable porous structure at all agarose concentrations. This scale is relevant to hyphal tip growth. In combination, these results suggest F-actin depletion may be a response mechanism to provide greater force for invasive growth. Additionally, this response is not dependent on the concentration of the agarose media, possibly due to the variability encountered within the media. These results contribute another important step forward in unraveling the elusive mechanism of tip growth.
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