Browsing by Author "Kuhn, Jeffrey R."

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    Actin Filament Attachments for Sustained Motility In Vitro Are Maintained by Filament Bundling
    Hu, Xiaohua; Kuhn, Jeffrey R. (PLOS, 2012-02-16)
    We reconstructed cellular motility in vitro from individual proteins to investigate how actin filaments are organized at the leading edge. Using total internal reflection fluorescence microscopy of actin filaments, we tested how profilin, Arp2/3, and capping protein (CP) function together to propel thin glass nanofibers or beads coated with N-WASP WCA domains. Thin nanofibers produced wide comet tails that showed more structural variation in actin filament organization than did bead substrates. During sustained motility, physiological concentrations of Mg2+ generated actin filament bundles that processively attached to the nanofiber. Reduction of total Mg2+ abolished particle motility and actin attachment to the particle surface without affecting actin polymerization, Arp2/3 nucleation, or filament capping. Analysis of similar motility of microspheres showed that loss of filament bundling did not affect actin shell formation or symmetry breaking but eliminated sustained attachments between the comet tail and the particle surface. Addition of Mg2+, Lys-Lys2+, or fascin restored both comet tail attachment and sustained particle motility in low Mg2+ buffers. TIRF microscopic analysis of filaments captured by WCA-coated beads in the absence of Arp2/3, profilin, and CP showed that filament bundling by polycation or fascin addition increased barbed end capture by WCA domains. We propose a model in which CP directs barbed ends toward the leading edge and polycation-induced filament bundling sustains processive barbed end attachment to the leading edge.
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    Actin polymerization dynamics at the leading edge
    Hu, Xiaohua (Virginia Tech, 2012-10-05)
    Actin-based cell motility plays crucial role throughout the lifetime of an organism. While the dendritic nucleation model explains the initiation and organization of the actin network in lamellipodia, two questions need to be answered. In this study, I reconstructed cellular motility in vitro to investigate how actin filaments are organized to coordinate elongation and attachment to leading edge. Using total internal reflection fluorescence microscopy of actin filaments, we tested how profilin, Arp2/3, and capping protein (CP) function together to propel beads or thin glass nanofibers coated with N-WASP WCA domains. During sustained motility, physiological concentrations of Mg²⁺ generated actin filament bundles that processively attached to the nanofiber. Reduction of total Mg²⁺ abolished particle motility and actin attachment to the particle surface without affecting actin polymerization, Arp2/3 nucleation, filament capping, or actin shell formation. Addition of other types of crosslinkers restored both comet tail attachment and particle motility. We propose a model in which polycation-induced filament bundling sustains processive barbed end attachment to the leading edge. I lowered actin, profilin, Arp2/3, and CP concentrations to address the generation of actin filament orientation during the initiation of motility. In the absence of CP, Arp2/3 nucleates barbed ends that grow away from the nanofiber surface and branches remain stably attached to nanofiber. CP addition causes shedding of short branches and barbed end capture by the nanofiber. Barbed end retention by nanofibers is coupled with capping, indicating that WWCA and CP bind simultaneously to barbed ends. In pull-down assays, saturating CP addition only blocks WWCA binding to barbed end by half. Labeled WWCA bound to barbed ends with an affinity of 14 pM and unlabeled WWCA with an affinity of 75 pM. CP addition increased WWCA binding slightly at low CP concentrations and decreased WWCA binding to 50% at high CP concentrations. Molecular models of CP and WH2 domains bound respectively to the terminal and penultimate actin subunit showed no overlap and that CP orientation might blocks WWCA dissociation from the penultimate subunit. Simultaneous binding of CP and WWCA to barbed ends is essential to the establishment of filament orientation at the leading edge.
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    Biochemical and Microscopic Characterization of INFT-1: an Inverted Formin in C. elegans
    Li, Ying (Virginia Tech, 2011-03-14)
    Formins are potent regulators of actin dynamics that can remodel the actin cytoskeleton to control cell shape, cell cytokinesis, and cell morphogenesis. The defining feature of formins is the formin homology 2 (FH2) domain (Paul and Pollard, 2008), which promotes actin filament assembly while processively moving along the polymerizing filament barbed end. INFT-1 is one of six formin family members present in Caenorhabditis elegans (Hunt-Newbury et al., 2007) and is most closely related to vertebrate INF2, an inverted formin with regulatory domains in the C- rather than N-terminus. Nematode INFT-1 contains both formin homology 1 (FH1) and formin homology 2 (FH2) domains. However, it does not share the regulatory N-terminal Diaphanous Inhibitory Domain (DID) domain and C-terminal Diaphanous Autoregulatory Domain (DAD) domain found in mammalian INF2. In contrast to mammalian INF2, the sequence of INFT-1 starts immediately at FH1 domain and C-terminal region of INFT-1 shares little homology with INF2, suggesting that elegans INFT-1 is regulated by other mechanisms. We used fluorescence spectroscopy to determine the effect of INFT-1 FH1FH2 on actin assembly and total internal reflection fluorescence microscopy to investigate how INFT-1 formin homology 1 and formin homology 2 domains (FH1FH2) mediate filament nucleation and elongation. INFT-1 FH1FH2 nucleates actin filament and promote actin assembly. However, INFT-1 FH1FH2 reduces filament barbed-end elongation rates in the absence or presence of profilin. Evidences demonstrated that INFT-1 is non-processive, indicating a unique mechanism of nucleation. INFT-1 nucleation efficiency is similar to the efficiency of Arabidopsis FORMIN1 (AFH1), another non-processive formin. High phosphate affected the assembly activity of INFT-1 FH1FH2 in the absence or presence of profilin. INFT is thus the second example of a non-processive formin member and will allow a more detailed understanding of the mechanistic difference between processive and non-processive formins.
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    Cationic Glycopolymers for DNA Delivery: Cellular Internalization Mechanisms and Biological Characterization
    McLendon, Patrick Michael (Virginia Tech, 2009-10-20)
    Understanding the biological mechanisms of polymeric DNA delivery is essential to develop vehicles that perform optimally. In this work, the cellular internalization mechanisms of poly(glycoamidoamine) (PGAA) DNA delivery polymers were investigated. Polymer:DNA complexes interact with cell-surface glycosaminoglycans (GAGs) in a manner independent of electrostatic interactions. Desulfation and GAG removal leads to decreased uptake. Individual polyplexes appear to have differing affinities for specific GAGs, as polyplex dissociation occurs in a charge-independent manner, and may influence binding. Internalization occurs through close interactions with GAGs, as GAGs accumulate on polyplex surfaces, resulting in negatively-charged polyplexes and decompaction of intact polyplexes is observed upon interaction with GAG. PGAA polyplexes enter cells via a complex, multifaceted internalization route. Pharmacological inhibition of endocytosis and visualization by confocal microscopy reveal that internalization occurs primarily through an actin and dynamin-dependent mechanism. Caveolae/raft-mediated endocytosis appears to be the predominant internalization mechanism, with clathrin-mediated endocytosis also significantly involved. Internalization occurs to a smaller degree via macropinocytosis and direct membrane penetration. Caveolae-mediated, but not clathrin-mediated, internalization leads to transgene expression, suggesting a targeting opportunity based on uptake mechanisms. PEGylation of PGAA polyplexes was achieved to minimize polyplex aggregation in serum. Polyplex size increased in serum, but PEGylation prevented further polyplex growth over time compared to non-PEGylated polymers. Specific targeting of hepatocytes through end-modification of PEG with galactose was unsuccessful, likely due to inaccessibility of targeting groups. Further hepatocyte targeting efforts focused on malonate-based polymers with clickable linkages for facile linkage of targeting groups. Despite favorable surface presentation of galactose, receptor-specific internalization of polyplexes was unsuccessful, as competitive inhibition in HepG2 cells resulted in significant polyplex internalization derived from nonspecific membrane interactions. Chemical modification of vehicles allows systematic study of structure-function properties leading to efficient intracellular delivery. Increasing G4 molecular weight generally increases toxicity and decreases transgene expression in HeLa cells. Incorporating galactose into a lanthanide-chelating polymer facilitated efficient cellular internalization that was visualized by two-photon microscopy. Increased gene expression was observed that correlated to increasing galactose, suggesting that polymer degradation increases gene expression. Also studied were branched peptides targeted to HIV-1 TAR, which displayed high biocompatibility and favorable internalization profiles in mammalian cells.
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    Characterization of lin-42/period transcriptional regulation by the Ikaros/hunchback-family transcription factor ZTF-16 in Caenorhabditis elegans
    Meisel, Kacey Danielle (Virginia Tech, 2013-06-03)
    The gene lin-42 is an ortholog of the mammalian period gene, a component of the circadian pathway that converts environmental stimuli into behavioral and physiological outputs over 24 hours. Mammalian period also regulates adult stem cell differentiation, although this function is poorly understood. The structure, function and expression of lin-42 are all similar to period. Therefore, we are studying lin-42 regulation and function during C. elegans larval development as a model for understanding period control of mammalian stem/progenitor cell development. Previous work has shown that ZTF-16 is a regulator of lin-42 transcription. The lin-42 locus encodes three isoforms, and we have characterized lin-42 isoform specific regulation by ZTF-16 through phenotypic assays and analysis of transcriptional reporter strains. Our data show that ZTF-16 regulates the cyclic expression of lin-42A and lin-42B during larval development. However, ztf-16 is not expressed during the adult stage and does not regulate lin-42C, which is expressed only in adults and may be responsible for the circadian functions of lin-42. We also show that ztf-16 reduction-of-function mutations phenocopy loss-of- function phenotypes of the lin-42A/B isoforms. Finally, we have found that deletion of a putative ZTF-16 transcription factor binding site within the lin-42BC promoter abolishes tissue-specific expression patterns. Together, these data indicate that ZTF-16 is required to regulate the expression of lin-42A/B during C. elegans development, and may do this by direct binding to the lin-42BC promoter. Our  findings pave the way for testing the possible regulation of period expression by HIL-family transcription factors in mammalian tissues.
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    Characterization of Transcriptional and Post-transcriptional Regulation of lin-42/Period During Post-embryonic Development of C. elegans
    James, Tracy (Virginia Tech, 2012-09-11)
    Period, which is broadly conserved in metazoans, regulates circadian timing of neurophysiology as well as cell fate specification. Studies in mouse and humans indicate that period functions as a tumor suppressor and controls adult stem cell differentiation. However, regulation of period function in developmental pathways has not been characterized and appears to be different from its regulation and function in circadian pathways. lin-42 is the Caenorhabditis elegans ortholog of period and has both circadian and developmental timing functions. During post-embryonic larval development, cyclic expression and function of lin-42 controls stage-specific and reiterative cell fate choices of a subset of epidermal stem cells called seam cells. We are studying lin-42 regulation of seam cell fate during C. elegans larval development as a model for understanding the mechanisms of period regulation of adult stem cell fate in mammals. This dissertation describes the research undertaken to characterize the cis-regulatory elements and the trans-regulatory factors that control lin-42 expression. We used direct molecular interaction assays (Electrophoretic Mobility Shift Assay, EMSA) (Chapter 2) followed by an RNA interference (RNAi)-based genetic screen (Chapter 3) to identify lin-42 transcriptional regulators. Using the EMSA, we identified three 50 to 100 base pair regions (binding regions, BR1-3) in the lin-42 5â noncoding sequences that were bound with specificity by C. elegans nuclear proteins. These binding regions represent putative cis-regulatory elements that may serve as transcription factor binding sites (TFBSs). We attempted to identify by mass spectrometry the proteins that bind to the BR sequences. We also used Phylogenetic Footprinting and bioinformatics screens to identify candidate C. elegans transcription factors (TFs) that may bind to putative TFBSs within the BR sequences. Using an RNAi-based screen, we tested the candidate TF genes for potential genetic interactions with lin-42. We identified ZTF-16, a member of the Hunchback/Ikaros zinc-finger transcription factor family, as a potential lin-42 activator and, using quantitative real-time PCR, confirmed that ztf-16 mutation results in down-regulation and loss of cycling expression of lin-42. We further determined that loss of ztf-16 results in seam cell development defects that phenocopy lin-42 loss-of-function, thus validating ZTF-16 as a transcriptional activator of lin-42.
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    Control of sex myoblast migration in C. elegans
    Zhang, Sihui (Virginia Tech, 2013-08-01)
    Cell migration is critical in generating complex animal forms during development; misregulation of migration contributes to pathological conditions such as cancer metastasis. Thanks to its easily traceable cell lineages in a transparent body and a compact genome accessible to a wealth of genetic manipulations, the use of the nematode C. elegans as a model system has greatly advanced our understanding of mechanisms governing cell migration conserved through higher organisms. Among several migration processes in C. elegans, sex myoblast (SM) migration is an attractive system that has a simple and well-defined migratory route along the ventral side from the posterior to the precise center of the gonad. A multitude of guidance mechanisms control SM migration, many of which are likely to be conserved in other migratory processes. Similar to vertebrate systems, C. elegans uses Rho family small GTPases to regulate the engine of cell motility, the actin cytoskeleton, in response to guidance cues. The differential utilizations of Rho GTPases in distinct processes in vivo remain a central question in the study of Rho GTPases. I investigated how Rho GTPases regulate different aspects of SM migration, and found that Cdc-42/CDC42 functions in the anteroposterior migration, whereas MIG-2/RhoG and CED-10/Rac1 control ventral restriction independently of FGF and SLIT/Robo signaling. The relative difficulty in perturbing SM migration using constitutively active Rho GTPases compared to other migration processes illustrates the robustness of the mechanisms that control SM migration. On a technical aspect, I established a nematode larval cell culture system that allows access to postembryonic cells. Compared to the flourishing genetic researches in C. elegans, there are few studies of molecules that also extend to the subcellular level in postembryonic development, mainly due to the lack of a larval cell culture system. I developed a novel method combining SDS-DTT presensitization of larval cuticles and subsequent pronase E digestion. My method efficiently isolates both low- and high-abundance cell types from all larval stages. This technical advance will not only facilitate studies such as regulation of actin dynamics with high-resolution microscopy, but is beginning to be used by researchers to tackle cell-type specific questions through profiling methods as gene expression analysis.
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    The effect of spindle geometry on the establishment of merotelic kinetochore attachment and chromosome mis-segregation
    Silkworth, William Thomas (Virginia Tech, 2012-06-26)
    At any given time there are on the order of one hundred million cells undergoing mitosis in the human body. To accurately segregate chromosomes, the cell forms the bipolar mitotic spindle, a molecular machine that distributes chromosomes equally to the daughter cells. To this end, microtubules of the mitotic spindle must appropriately attach the kinetochores: protein structures that form on each chromatid of each mitotic chromosome. The majority of the time correct kinetochore microtubule attachments are formed. However, mis-attachments can and do form. Mis-attachments that are not corrected before chromosome segregation can give rise to aneuploidy, an incorrect number of chromosomes. Aneuploidy occurring in the germ line can cause both miscarriage and genetic diseases. Furthermore, aneuploidy is a major characteristic of cancer cells, and aneuploid cancer cells frequently mis-segregate chromosomes at high rates, a phenotype termed chromosomal instability (CIN). CIN has been correlated with both advanced tumorigenesis and poor patient prognosis and over the years there have been many hypotheses for what causes CIN. In this study, we identified two distinct mechanisms that are responsible for CIN. Both of these mechanisms cause a transient, abnormal geometric arrangement of the mitotic spindle. Specifically, cancer cells possess supernumerary centrosomes, which lead to the assembly of multipolar spindles during early mitosis when attachments between kinetochores and microtubules are forming. Supernumerary centrosomes facilitate the formation of merotelic attachments, in which a single kinetochore binds microtubules from more than one centrosome. As mitosis progresses the supernumerary centrosomes cluster, giving rise to a bipolar spindle by the time of chromosome segregation. However, the high rates of merotelic attachments formed during the transient multipolar stage result in high rates of chromosome mis-segregation. The second geometric defect characterized is caused by failure of centrosomes to separate before kinetochore-microtubule attachments begin to form. This mechanism, too, leads to high rates of kinetochore mis-attachment formation and high rates of chromosome mis-segregation. Finally, this study shows that the mechanisms characterized here are prevalent in human cancer cells from multiple organ sites, thus revealing that both mechanisms are a common cause of CIN.
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    Isolation and Culture of Larval Cells from C. elegans
    Zhang, Sihui; Banerjee, Diya; Kuhn, Jeffrey R. (PLOS, 2011-04-29)
    Cell culture is an essential tool to study cell function. In C. elegans the ability to isolate and culture cells has been limited to embryonically derived cells. However, cells or blastomeres isolated from mixed stage embryos terminally differentiate within 24 hours of culture, thus precluding post-embryonic stage cell culture. We have developed an efficient and technically simple method for large-scale isolation and primary culture of larval-stage cells. We have optimized the treatment to maximize cell number and minimize cell death for each of the four larval stages. We obtained up to 7.8×104 cells per microliter of packed larvae, and up to 97% of adherent cells isolated by this method were viable for at least 16 hours. Cultured larval cells showed stage-specific increases in both cell size and multinuclearity and expressed lineage- and cell type-specific reporters. The majority (81%) of larval cells isolated by our method were muscle cells that exhibited stage-specific phenotypes. L1 muscle cells developed 1 to 2 wide cytoplasmic processes, while L4 muscle cells developed 4 to 14 processes of various thicknesses. L4 muscle cells developed bands of myosin heavy chain A thick filaments at the cell center and spontaneously contracted ex vivo. Neurons constituted less than 10% of the isolated cells and the majority of neurons developed one or more long, microtubule-rich protrusions that terminated in actin-rich growth cones. In addition to cells such as muscle and neuron that are high abundance in vivo, we were also able to isolate M-lineage cells that constitute less than 0.2% of cells in vivo. Our novel method of cell isolation extends C. elegans cell culture to larval developmental stages, and allows use of the wealth of cell culture tools, such as cell sorting, electrophysiology, co-culture, and high-resolution imaging of subcellular dynamics, in investigation of post-embryonic development and physiology.
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    Processive Acceleration of Actin Barbed End Assembly by N-WASP
    Khanduja, Nimisha (Virginia Tech, 2014-02-03)
    Actin-based cell motility plays crucial roles throughout the lifetime of an organism. The dynamic rearrangement of the actin cytoskeleton triggers a plethora of cellular processes including cellular migration. Neural Wiskott Aldrich syndrome protein (N-WASP) is involved in transduction of signals from receptors on the cell surface to the actin cytoskeleton. N-WASP activated actin polymerization drives extension of invadopodia and podosomes into the basement layer. In addition to activating Arp2/3 complex, N-WASP binds actin filament barbed ends, and both N-WASP and barbed ends are tightly clustered in these invasive structures. We used nanofibers coated with N-WASP WWCA domains as model cell surfaces and single actin filament imaging to determine how clustered N-WASP affects Arp2/3-independent barbed end assembly. Individual barbed ends captured by WWCA domains of N-WASP grew at or below their diffusion limited assembly rate. At high filament densities, overlapping filaments formed buckles between their nanofiber tethers and myosin attachment points. These buckles grew 3.4-fold faster than the diffusion-limited rate of unattached barbed ends. N-WASP constructs with and without the native poly-proline (PP) region showed similar rate enhancements. Increasing polycationic Mg2+ or Spermine to enhance filament bundling increased the frequency of filament buckle formation, consistent with a requirement of accelerated assembly on barbed end bundling. Our preliminary data shows that tethered N-WASP construct containing one WH2 domain does not generate processive bundles or filament loops leading us to believe that tandem WH2 is required for processivity. We propose that this novel N-WASP assembly activity provides an Arp2/3-independent force that drives nascent filament bundles into the basement layer during cell invasion. Discovery of this bundle mediated unique pathway involved in invasion and metastasis will provide new targets for therapeutic development.