Browsing by Subject "Actin"

Mutations in myosin VIIa (MyoVIIa), an unconventional myosin, have been shown to cause Usher Syndrome Type 1B in humans. Usher Syndrome Type 1B is characterized by congenital sensorineural deafness, vestibular dysfunction and pre-pubertal onset of retinitis pigmentosa. Mouse model studies show that sensorineural deafness and vestibular dysfunction in MyoVIIa mutants is caused by disruption in the structure of microvilli-like projections (stereocilia) of hair cells in the cochlea and vestibular organ. MyoVIIa has also been shown to affect adaptation of mechanoelectrical transduction channels in stereocilia.

In Drosophila melanogaster mutations in MyoVIIa encoded by crinkled (ck) cause defects in hair and bristle morphogenesis and deafness. Here we study the formation of bristles and hairs in Drosophila melanogaster to investigate the molecular basis of ck/MyoVIIa function and its regulation. We use live time-lapse confocal microscopy and genetic manipulations to investigate the requirement of ck/MyoVIIa function in various steps of morphogenesis of hairs and bristles. Here we show that null or near null mutations in ck/MyoVIIa lead to the formation of 8-10 short and thin hairs (split hairs) per epithelial cell that are likely the result of the failure of association of hair-actin bundles that in wild-type cells come together to form a single hair.

The myosin super family of motor proteins is divided into 17 classes by virtue of differences in the sequence of their motor domain, which presumably affect their physiological functions. In addition, substantial variety in the overall structure of their tail plays an important role in the differential regulation of myosin function. In this study we show that ck/MyoVIIa, that has two MyTH4 FERM domains in its tail separated by an SH3 domain, requires both MyTH4 FERM repeats for efficient association of hair-actin bundles to form hairs. We also show that the "multiple hair" phenotype of over-expression of ck/MyoVIIa requires both MyTH4 FERM domain function but not the tail-SH3 domain. We further demonstrate that the tail-SH3 domain of ck/MyoVIIa plays a role in keeping actin bundles, which run parallel to the length of the growing bristle, separate from each other. Our data also suggests that the tail-SH3 domain plays a role in the association of the actin filament bundles with the membrane and regulates F-actin levels in bristles.

We further demonstrate that over-expression of Quail (villin) can rescue the hair elongation defects seen in ck/MyoVIIa null or near null mutants but does not rescue the split hair defects. We show that over-expression of Alpha-actinin-GFP, another actin bundling protein, phenocopies the multiple hair phenotype of ck/MyoVIIa over-expression. Over-expression of Alpha-actinin-GFP in a ck/MyoVIIa null or near null background shows that Alpha-actinin-GFP cannot rescue the split or short hair phenotype of ck/MyoVIIa loss-of-function. However, cells over-expressing Alpha-actinin-GFP in a ck/MyoVIIa null or near null background have more than the normal 8-10 split hairs, suggesting that Alpha-actinin-GFP over-expression causes the formation of more than the normal complement of hair-actin bundles per cell, resulting in a multiple hair phenotype. We show that Twinfilin, an actin monomer sequestering protein implicated in negatively regulating F-actin bundle elongation in stereocilia in a MyoVIIa-dependent manner, is required for F-actin bundle stability.

In addition, we use yeast two-hybrid strategies to identify Slam as a protein that directly binds to ck/MyoVIIa. We show that Slam, a novel membrane-associated protein, likely functions to regulate ck/MyoVIIa function during hair and bristle morphogenesis. We show that over-expression of Slam and loss-of-function mutations in Slam phenocopy ck/MyoVIIa loss-of-function split and short hair phenotype. We also show that disruption of Slam and RhoGEF2 association causes split hair defects similar to ck/MyoVIIa loss-of-function phenotype suggesting that Slam probably regulates ck/MyoVIIa function via RhoGEF2.

Together our results show that ck/MyoVIIa plays an important role in regulating the actin cytoskeleton that underlies actin-based cellular protrusions like hairs and bristles.

Establishing an axis of cell polarity is central to cell motility, tissue morphogenesis, and cell proliferation. A highly conserved group of polarity regulators is responsible for organizing a wide variety of polarized morphologies. One of the most widely expressed polarity regulators is the Rho-type GTPase Cdc42. In response to cell cycle cues the budding yeast Saccharomyces cerevisiae polarizes Cdc42p to a discrete site on the cell periphery. GTP-Cdc42p recruits a number of effectors that aid in the organization of a polarized actin cytoskeleton. The polarized actin cytoskeleton acts as tracks to facilitate the delivery of the secretory vesicles that will grow the bud, an essential process for an organism that proliferates by budding. We have employed treatment with the actin depolymerizing drugs Latrunculin A and B as well as high-speed timelapse microscopy of fluorescently labeled polarity proteins to characterize the assembly of the incipient bud site.

Often, ensuring that only a single axis of polarity is established is as important as generating asymmetry in the cell. Even in the absence of positional cues dictating the direction of polarization, many cells are still able to self-organize and establish one, and only one, polarity axis through a process termed symmetry breaking. Symmetry breaking is thought to employ positive feedback to amplify stochastic fluctuations in protein concentration into a larger asymmetry. To test whether singularity could be guaranteed by the amplification mechanism we re-wired yeast to employ a synthetic positive feedback mechanism. The re-wired cells could establish polarity, however they occasionally made two buds simultaneously, suggesting that singularity is guaranteed by the amplification mechanism.

Synapses – the delicate connections between our neurons – adjust and refine their strength to shape our brains, our thoughts, and our memories. Proteomic and genetic techniques have revealed that this process, known as synaptic plasticity, is tightly controlled by signaling cascades that ultimately expand or contract actin networks within postsynaptic sites. In this dissertation, I advance the field of synaptic plasticity by focusing on presynaptic terminals, which are equal partners with their postsynaptic counterparts. To date, the study of presynaptic plasticity has been difficult due to the limited number of presynaptic signaling molecules currently identified (particularly those regulating the cytoskeleton), as well as the lack of tools to manipulate these molecules specifically within presynaptic terminals. I therefore developed new experimental approaches to tackle both of these hurdles. After mapping presynaptic cytoskeletal signaling pathways in the mouse brain, I discovered a new mechanism of presynaptic plasticity that is driven by action potential-coupled actin remodeling.

Presynaptic terminals cannot be biochemically purified away from postsynaptic sites. This has restricted previous presynaptic proteomic studies to isolated synaptic vesicles or other fractions, which have only identified a few actin signaling molecules. I thus turned to a new proteomic method called in vivo BioID. This approach is based on proximity-based biotinylation, which labels proteins in a compartment of interest as defined by a bait protein. My choice of presynaptic bait worked beautifully, leading to the mass spectrometry-based identification of 54 cytoskeletal regulators, most of which were previously not known to be presynaptic. The networks of presynaptic actin signaling molecules turn out to be just as richly diverse as those of the postsynapse. Many proteins also converge on a Rac1-Arp2/3 signaling pathway that leads to the de novo nucleation of branched actin filaments. This reveals that the presynaptic cytoskeleton consists of a dynamic, branched actin network.

This finding was unexpected because Rac1 and Arp2/3 have long-established roles in the development and plasticity of the postsynapse. This also makes it difficult to isolate the presynaptic functions of these proteins. I thus created optogenetic tools and electrophysiological strategies to acutely and bidirectionally manipulate their activity specifically within presynaptic terminals. I showed that presynaptic Rac1 and Arp2/3 negatively regulate the recycling of synaptic vesicles, thereby driving a form of plasticity known as short-term depression. I also showed that this mechanism is conserved between excitatory and inhibitory synapses, demonstrating it is a fundamental aspect of presynaptic function. Finally, I conducted a series of experiments using two-photon fluorescence lifetime imaging (2pFLIM) with a FRET-based biosensor of Rac1 activity. I discovered that calcium entry during action potential firing activates Rac1 within presynaptic terminals. This establishes a new mechanism of short-term depression that is driven by an action potential-coupled signal to the presynaptic cytoskeleton.

This dissertation thus combines proteomics, optogenetics, electrophysiology, and 2pFLIM-FRET to gain new insights into presynaptic plasticity. These findings have three significant implications. First, they challenge the prevailing view that the Rac1-Arp2/3 pathway functions largely at excitatory postsynaptic sites. This compels re-evaluation of how mutations in Rac1 and Arp2/3 cause neurological diseases such as intellectual disability and schizophrenia. Second, the genetic and optogenetic tools I developed are the first way to specifically modulate short-term depression, finally allowing for the exact functions of this form of plasticity to be determined in vivo. This has particular relevance for working memory, which has been theorized to be controlled by short-term presynaptic plasticity. Finally, this study provides a proteomic framework and blueprint of experimental strategies to conduct a systematic genetic analysis of the presynaptic cytoskeleton, which may finally unify the controversial theories about presynaptic actin function. In sum, the experimental strategies and resources that I developed highlight the multifaceted, sophisticated signaling that occurs in presynaptic terminals. This may yet shed light on how we remember our experiences, and why we are who we are.

The actin cytoskeleton is a fundamental component of the cell and is involved in many processes, including cell division, cell migration, vesicle trafficking and cell polarity. The actin cytoskeleton has a very important role in embryogenesis as the cells within developing tissues proliferate, migrate, interpret extracellular cues, and shape complex tissues. The molecules that help the cell to interpret their environment and turn those cues into morphological changes are of great interest. One protein which may be involved in this manner is Cordon-bleu (Cobl).

In mouse embryos, Cobl's expression pattern resembles that of important developmental genes, is restricted to distinct domains, and changes dynamically throughout development as tissues are formed. While it is known that Cobl expression is regulated by developmental signaling pathways such as Shh and BMP, its molecular function at the cellular level remains elusive. In this study, we have identified molecular functions of Cobl. Cobl has C-terminal Wasp Homology-2 (WH2) domains which bind actin and nucleate new actin filaments in in vitro polymerization assays. Using cultured cells, we have determined that Cobl is involved in cytoskeletal remodeling during neurite branching and epithelial cell migration. We also demonstrate that Cobl interacts with the Syndapin family of adaptor proteins that link endocytosis and vesicle trafficking. Cobl colocalizes with Sdp2 in cultured epithelial cells and similarly localizes with Sdp1 and Sdp2 in developing mouse embryos. The localization of Cobl or Sdp2 in cultured epithelial cells is dependent on the other, as demonstrated using shRNA knockdown.

Previous studies demonstrated that a hypomorphic allele of Cobl interacts genetically with Looptail, in midbrain neurulation. Looptail mutants are deficient in the gene Vangl2, a member of the planar cell polarity pathway that coordinates the morphogenesis of a sheet of cells. To discover other roles for Cobl in the developing mouse, we have generated a conditionally null allele of Cobl. We find that outbred Cobl homozygous mutants are viable, but that they have inner ear defects. Together, our studies demonstrate that Cobl is a tissue-specific actin nucleator whose localization is regulated by its interaction with Syndapins and which functions in the development of sensory epithelia.

Essential and diverse biological processes such as cell division, morphogenesis and migration are regulated by a family of molecular switches called Rho GTPases. These proteins cycle between active, GTP-bound states and inactive, GDP-bound state and this cycle is regulated by families of proteins called Rho GEFs and GAPs. GAPs are proteins that stimulate the intrinsic GTPase activity of Rho-family proteins, potentiating the active to inactive transition. GAPs target specific spatiotemporal pools of GTPases by responding to cellular cues and utilizing protein-protein interactions. By dissecting these interactions and pathways, we can infer and then decipher the biological functions of these GAPs.

This work focuses on the characterization of a novel Rho-family GAP called srGAP2. In this study, we identify that srGAP2 is a Rac-specific GAP that binds a Formin-family member, Formin-like 1 (FMNL1). FMNL1 is activated by Rac and polymerizes, bundles and severs actin filaments. srGAP2 specifically inhibits the actin severing of active FMNL1, and the assembly of an srGAP2-FMNL1 complex is regulated by Rac. Work on FMNL1 shows that it plays important roles in regulating phagocytosis and adhesion in macrophages. To learn more about srGAP2 and its role in regulating FMNL1, we studied macrophages isolated from an srGAP2 KO mouse we have recently generated. This has proven quite fruitful: loss of srGAP2 decreases the ability for macrophages to invade through extracellular matrix but increases phagocytosis. These results suggest that these two processes might be coordinated in vivo by srGAP2 and that srGAP2 might be a critical regulator of the innate immune system.

Chlamydia trachomatis is the most common sexually transmitted bacterial pathogen and is the leading cause of preventable blindness worldwide. Chlamydia is particularly intriguing from the perspective of cell biology because it is an obligate intracellular pathogen that manipulates host cellular pathways to ensure its proliferation and survival. This is achieved through a significant remodeling of the host cell’s internal architecture from within a membrane-bound vacuole, termed the inclusion. However, given a previous lack of tools to perform genetic analysis, the mechanisms by which Chlamydia induces host cellular changes remained unclear. Here I present genetic and molecular mechanisms of chlamydial manipulation of the host cytoskeleton and organelles. Using a forward genetics screen, InaC was identified as a necessary factor for the assembly of an F-actin structure surrounding the inclusion. InaC associated with the vacuolar membrane where it recruited Golgi-specific ARF-family GTPases. Actin dynamics and ARF GTPases regulate Golgi morphology and positioning within cells, and InaC acted to redistribute the Golgi to surround the Chlamydia inclusion. These findings suggest that Chlamydia places InaC at the inclusion-cytosolic interface to recruit host ARF GTPases and F-actin to form a platform for rearranging intracellular organelles around the inclusion. The inclusion is also surrounded by the intermediate filament vimentin and the chlamydial protease CPAF cleaves vimentin in vitro. CPAF-dependent remodeling of vimentin occurred selectively in late stages of the infection. In living cells, this cleavage occurred only after a loss of inclusion membrane integrity, suggesting that CPAF cleaves intermediate filaments specifically during chlamydial exit of host cells. In summary, I have implemented recent forward and reverse genetic approaches in Chlamydia to reveal how it employs effector proteins to manipulate the internal organization of cells in novel ways.

Excitatory synapse formation during development involves the complex orchestration of both structural and functional alterations at the postsynaptic side, beginning with the formation of transient dendritic filopodia. Abnormalities in synapse development are linked to developmental brain disorders such as autism spectrum disorders, schizophrenia, and intellectual disability. However, the molecular mechanisms that underlie excitatory synaptogenesis remain elusive, in part because the internal machinery of developing synapses is largely unknown. Unlike mature excitatory synapses, there is currently no way to biochemically isolate the dendritic filopodia of nascent synapses. This lack of understanding is a critical barrier to our grasp of synapse development as well as the etiology of many neurodevelopmental disorders. This dissertation work focuses on the detection and analysis of proteins which localize to and are critical for spinogenesis and synaptogenesis. Using state-of-the-art in vivo proteomics, we identified a network of proteins which localize to the receiving end of the developing excitatory synapse, the dendritic filopodia. We then used the CRISPR/Cas9 system to identify candidates which drive the formation and maturation of dendritic filopodia. We finally did careful functional analysis of CARMIL3 and the Arp2/3 complex to identify their critical and diverse roles in synaptogenesis.

In our analysis, we found that CARMIL3 is expressed in the brain predominately during synaptogenesis, localizes to developing dendritic protrusions, and is important for the morphological and functional maturation of synapses, likely through its role in recruiting capping protein to maturing synapses. Loss of CARMIL3 leads to structurally and functionally immature synapses that are capping protein deficient. Further, we found that the Arp2/3 complex, a critical regulator of the actin cytoskeleton which creates branched actin networks, is required for both the functional and morphological maturation of dendritic spines. In the absence of the Arp2/3 complex, dendritic protrusions make presynaptic contact, recruit key proteins such as MAGUKs, and recruit certain receptors such as NMDA receptors, but lack AMPA receptors which are required for synapse unsilencing.

Together, this work demonstrates that the actin cytoskeleton controls the functional maturation of synapses by altering the cytoskeletal dynamics towards the creation of a branched actin network. CARMIL3 contributes to this process by providing capping protein, which biases actin nucleation towards branched actin networks. Arp2/3 creates the branched actin network. Without this network, there is not a sufficient framework to dock AMPA receptors in the post-synaptic density, and without AMPA receptors, dendritic protrusions remain functionally silent. Together, this work shows that the dynamics of the actin cytoskeleton drive synapse unsilencing.

Tip growth in fungi involves highly polarized secretion and modification of the cell wall at the growing tip. The genetic requirements for initiating polarized growth are perhaps best understood for the model budding yeast, Saccharomyces cerevisiae. Once the cell is committed to enter the cell cycle by activation of G1 cyclin/cyclin-dependent kinase (CDK) complexes, the polarity regulator Cdc42 becomes concentrated at the presumptive bud site, actin cables are oriented towards that site, and septin filaments assemble into a ring around the polarity site. Several minutes later, the bud emerges. Here, we investigated the mechanisms that regulate the timing of these events at the single cell level and the role of polarisome during pheromone-induced polarized growth. We employed genetics and live cell microscopy to characterize cellular events. Septin recruitment was delayed relative to polarity establishment, and our findings suggest that a CDK-dependent septin “priming” facilitates septin recruitment by Cdc42. Bud emergence was delayed relative to the initiation of polarized secretion, and our findings suggest that the delay reflects the time needed to weaken the cell wall sufficiently to bud. Rho1 activation by Rom2 occurred at around the time of bud emergence, perhaps in response to local cell wall weakening. This report reveals regulatory mechanisms underlying the morphogenetic events in the budding yeast.

Many microbial pathogens have evolved to replicate within host cells. While a number of these pathogens reside within vacuolar compartments, others escape from host endosomal pathways to replicate intracytosolically. To counter microbial invasion, host cells employ numerous defense proteins to limit microbial growth and mediate pathogen destruction. Among these host defense proteins are a number of dynamin-like GTPases expressed in response to the cytokine Interferon-gamma, including the p65 Guanylate Binding Proteins (GBPs). Murine GBPs have previously been shown to target both vacuolar and cytosolic pathogens to mediate pathogen destruction and potentiate host inflammatory responses via both the canonical (caspase-1) and noncanonical (caspase-11) inflammasomes. However, whether these functions are conserved among the human orthologs of murine GBPs has remained unclear.

To determine whether the ability to physically target pathogens is conserved among the human GBPs, I monitored the localization of all seven human GBPs within cells infected with the cytosol-resident Gram-negative bacterium Shigella flexneri, the causative agent of bacillary dysentery. Among the human GBP paralogs, I identified the unique ability of GBP1 to physically associate with S. flexneri, and showed that GBP1-targeting extends to a second cytosolic Gram-negative bacterium, Burkholderia thailandensis, but not to the cytosolic Gram-positive bacterium Listeria monocytogenes. Using mutational analysis, I determine that GBP1 targeting is directed by a C-terminal Polybasic Motif (PBM) centered around three arginine residues, and further relies on a lipidated CaaX motif and protein oligomerization via the GBP1 Large GTPase domain. Among the human GBP paralogs, the combination of a PBM and CaaX motif is unique to GBP1. Furthermore, I found that rough lipopolysaccharide (LPS) mutants of S. flexneri co-localize with GBP1 less frequently than wildtype S. flexneri, suggesting that host recognition of O-antigen promotes GBP1 targeting to Gram-negative bacteria. GBP1-targeting to S. flexneri led to co-recruitment of four additional human GBP paralogs (GBP2, GBP3, GBP4, and GBP6).

S. flexneri and a number of other cytosolic bacteria promote bacterial dissemination by hijacking host actin cytoskeleton machinery to form actin comet tails which emanate from one pole of the bacterium and provide mechanical force to propel bacterium-containing extensions into neighboring cells. I found that while GBP1-targeted bacteria remain viable, they replicate within intracellular aggregates and fail to form actin comet tails. Accordingly, wildtype but not a PBM-deficient GBP1 mutant restricts S. flexneri cell-to-cell spread in plaque assays. I also found that S. flexneri counters GBP1-mediated host defenses using a secreted effector, IpaH9.8. Accordingly, human-adapted S. flexneri, through the action of IpaH9.8, is more resistant to GBP1 targeting than the non-human-adapted bacillus B. thailandensis.

Finally, I examined the role of human GBP1 in shaping the host cell transcriptional response in S. flexneri infected cells, and found that GBP1 promotes the expression of several chemokines, including CXCL1, CXCL9, CXCL10, and CCL2, which act as chemoattractants for professional immune cells. This role in chemokine expression was independent of the GBP1 PBM and CaaX motif necessary for bacterial targeting, and extended not only to B. thailandensis, but also L. monocytogenes, which is untargeted by GBP1. Furthermore, GBP2 could functionally substitute for GBP1 to support expression of CXCL10, implicating other GBPs in the process.

Together, the work encompassed in this dissertation sheds light on the role of the human GBPs in host cell defense against intracellular pathogens, and identifies previously unknown roles for the GBPs in precluding bacterial actin-based motility and shaping the host transcriptional response to pathogens.

Epithelial sheet morphogenesis is characterized by dynamic tissue movements, resulting in the recognition and adhesion of cells to generate a seamless epithelium. Each step is mediated by carefully organized, cellular actin structures, including contractile purse strings, cellular protrusions, and dynamic medioapical arrays. I used live, 4D imaging to observe Drosophila dorsal closure, a model of epithelial sheet morphogenesis. I compared four fluorescently tagged F-actin probes widely used by Drosophila researchers to determine which was optimal for imaging dorsal closure. I observed differences in the intensity of the probes and the viability of the stocks that carry them. I quantified the rate of closure and the oscillatory behavior of amnioserosa cells when embryos expressed each F-actin probe. My findings demonstrated that each probe can be used to image F-actin during dorsal closure, and that the effects of probe expression make one probe more or less suitable than another for answering specific questions. I investigated the structure, kinematics and location of medioapical, actomyosin arrays during dorsal closure. I resolved medioapical arrays in vivo at the level of individual cytoskeletal components using total internal reflection structured illumination microscopy (TIRF-SIM). In concert with lattice light-sheet images, I show that when amnioserosa cells are relaxed, actin and myosin form a loose, domed meshwork that protrudes apically from the cellular junctions to which they are anchored. As the amnioserosa cells contract, this meshwork condenses, rearranges and is drawn basally towards the plane of the junctional belts. As the cells relax, so too does the actin and myosin meshwork in a new configuration. The medioapical arrays are juxtaposed to the plasma membrane and continuous with the extending lamellipodia and filopodia. Thus, medioapical arrays are modified cell cortex.