Samuel W. Straight

Polarity Proteins Control Ciliogenesis via Kinesin Motor Interactions

BACKGROUND Cilia are specialized organelles that play a fundamental role in several mammalian processes including left-right axis determination, sperm motility, and photoreceptor maintenance. Mutations in cilia-localized proteins have been linked to human diseases including cystic kidney disease and retinitis pigmentosa. Retinitis pigmentosa can be caused by loss-of-function mutations in the polarity protein Crumbs1 (CRB1), but the exact role of CRB1 in retinal function is unclear. RESULTS Here we show that CRB3, a CRB1-related protein found in epithelia, is localized to cilia and required for proper cilia formation. We also find that the Crumbs-associated Par3/Par6/aPKC polarity cassette localizes to cilia and regulates ciliogenesis. In addition, there appears to be an important role for the polarity-regulating 14-3-3 proteins in this process. Finally, we can demonstrate association of these polarity proteins with microtubules and the microtubular motor KIF3/Kinesin-II. CONCLUSIONS Our findings point to a heretofore unappreciated role for polarity proteins in cilia formation and provide a potentially unique insight into the pathogenesis of human kidney and retinal disease.

A Novel and Conserved Protein-Protein Interaction Domain of Mammalian Lin-2/CASK Binds and Recruits SAP97 to the Lateral Surface of Epithelia

ABSTRACT Mammalian Lin-2 (mLin-2)/CASK is a membrane-associated guanylate kinase (MAGUK) and contains multidomain modules that mediate protein-protein interactions important for the establishment and maintenance of neuronal and epithelial cell polarization. The importance of mLin-2/CASK in mammalian development is demonstrated by the fact that mutations in mLin-2/CASK or SAP97, another MAGUK protein, lead to cleft palate in mice. We recently identified a new protein-protein interaction domain, called the L27 domain, which is present twice in mLin-2/CASK. In this report, we further define the binding of the L27C domain of mLin-2/CASK to the L27 domain of mLin-7 and identify the binding partner for L27N of mLin-2/CASK. Biochemical analysis reveals that this L27N domain binds to the N terminus of SAP97, a region that was previously reported to be essential for the lateral membrane recruitment of SAP97 in epithelia. Our colocalization studies, using dominant-negative mLin-2/CASK, show that the association with mLin-2/CASK is crucial for lateral localization of SAP97 in MDCK cells. We also report the identification of a novel isoform of Discs Large, a Drosophila melanogaster orthologue of SAP97, which contains a region highly related to the SAP97 N terminus and which binds Camguk, a Drosophila orthologue of mLin-2/CASK. Our data identify evolutionarily conserved protein-protein interaction domains that link mLin-2/CASK to SAP97 and account for their common phenotype when mutated in mice.

Multicellular Bacteria Deploy the Type VI Secretion System to Preemptively Strike Neighboring Cells

The Type VI Secretion System (T6SS) functions in bacteria as a contractile nanomachine that punctures and delivers lethal effectors to a target cell. Virtually nothing is known about the lifestyle or physiology that dictates when bacteria normally produce their T6SS, which prevents a clear understanding of how bacteria benefit from its action in their natural habitat. Proteus mirabilis undergoes a characteristic developmental process to coordinate a multicellular swarming behavior and will discriminate itself from another Proteus isolate during swarming, resulting in a visible boundary termed a Dienes line. Using transposon mutagenesis, we discovered that this recognition phenomenon requires the lethal action of the T6SS. All mutants identified in the genetic screen had insertions within a single 33.5-kb region that encodes a T6SS and cognate Hcp-VrgG-linked effectors. The identified T6SS and primary effector operons were characterized by killing assays, by construction of additional mutants, by complementation, and by examining the activity of the type VI secretion system in real-time using live-cell microscopy on opposing swarms. We show that lethal T6SS-dependent activity occurs when a dominant strain infiltrates deeply beyond the boundary of the two swarms. Using this multicellular model, we found that social recognition in bacteria, underlying killing, and immunity to killing all require cell-cell contact, can be assigned to specific genes, and are dependent on the T6SS. The ability to survive a lethal T6SS attack equates to “recognition”. In contrast to the current model of T6SS being an offensive or defensive weapon our findings support a preemptive mechanism by which an entire population indiscriminately uses the T6SS for contact-dependent delivery of effectors during its cooperative mode of growth.

Mammalian Lin-7 Stabilizes Polarity Protein Complexes

Mammalian Lin-7 forms a complex with several proteins, including PALS1, that have a role in polarity determination in epithelial cells. In this study we have found that loss of Lin-7 protein from the polarized epithelial cell line Madin-Darby canine kidney II by small hairpin RNA results in defects in tight junction formation as indicated by lowered transepithelial electrical resistance and mislocalization of the tight junction protein ZO-1 after calcium switch. The knock down of Lin-7 also resulted in the loss of expression of several Lin-7 binding partners, including PALS1 and the polarity protein PATJ. The effects of Lin-7 knock down were rescued by the exogenous expression of murine Lin-7 constructs that contained the L27 domain, but not the PDZ domain alone. Furthermore, exogenously expressed PALS1, but not other Lin-7 binding partners, also rescued the effects of Lin-7 knock down, including the restoration of PATJ protein in rescued cell lines. Finally, the effects of Lin-7 knock down appeared to be due to instability of PALS1 protein in the absence of Lin-7, as indicated by an increased rate of PALS1 protein degradation. Taken together, these results indicate that Lin-7 functions in tight junction formation by stabilizing its membrane-associated guanylate kinase binding partner PALS1.

N-Way FRET Microscopy of Multiple Protein-Protein Interactions in Live Cells

Fluorescence Resonance Energy Transfer (FRET) microscopy has emerged as a powerful tool to visualize nanoscale protein-protein interactions while capturing their microscale organization and millisecond dynamics. Recently, FRET microscopy was extended to imaging of multiple donor-acceptor pairs, thereby enabling visualization of multiple biochemical events within a single living cell. These methods require numerous equations that must be defined on a case-by-case basis. Here, we present a universal multispectral microscopy method (N-Way FRET) to enable quantitative imaging for any number of interacting and non-interacting FRET pairs. This approach redefines linear unmixing to incorporate the excitation and emission couplings created by FRET, which cannot be accounted for in conventional linear unmixing. Experiments on a three-fluorophore system using blue, yellow and red fluorescent proteins validate the method in living cells. In addition, we propose a simple linear algebra scheme for error propagation from input data to estimate the uncertainty in the computed FRET images. We demonstrate the strength of this approach by monitoring the oligomerization of three FP-tagged HIV Gag proteins whose tight association in the viral capsid is readily observed. Replacement of one FP-Gag molecule with a lipid raft-targeted FP allowed direct observation of Gag oligomerization with no association between FP-Gag and raft-targeted FP. The N-Way FRET method provides a new toolbox for capturing multiple molecular processes with high spatial and temporal resolution in living cells.

Coordination of the Rab5 Cycle on Macropinosomes

The GTPase Rab5a regulates the homotypic and heterotypic fusion of membranous organelles during the early stages of endocytosis. Many of the molecules which regulate the Rab5a cycle of association with membranes, activation, deactivation and dissociation are known. However, the extent to which these molecular scale activities are coordinated on membranes to affect the behavior of individual organelles has not been determined. This study used novel Förster resonance energy transfer (FRET) microscopic methods to analyze the Rab5a cycle on macropinosomes, which are large endocytic vesicles that form in ruffled regions of cell membranes. In Cos‐7 cells and mouse macrophages stimulated with growth factors, Rab5a activation followed immediately after its recruitment to newly formed macropinosomes. Rab5a activity increased continuously and uniformly over macropinosome membranes then decreased continuously, with Rab5a deactivation preceding dissociation by 1–12 min. Although the maximal levels of Rab5a activity were independent of organelle size, Rab5a cycles were longer on larger macropinosomes, consistent with an integrative activity governing Rab5a dynamics on individual organelles. The Rab5a cycle was destabilized by microtubule depolymerization and by bafilomycin A1. Overexpression of activating and inhibitory proteins indicated that active Rab5a stabilized macropinosomes. Thus, overall Rab5a activity on macropinosomes is coordinated by macropinosome structure and physiology.

Transient Increase in Cyclic AMP Localized to Macrophage Phagosomes

Cyclic AMP (cAMP) regulates many biological processes and cellular functions. The importance of spatially localized intracellular gradients of cAMP is increasingly appreciated. Previous work in macrophages has shown that cAMP is produced during phagocytosis and that elevated cAMP levels suppress host defense functions, including generation of proinflammatory mediators, phagocytosis and killing. However, the spatial and kinetic characteristics of cAMP generation in phagocytosing macrophages have yet to be examined. Using a Förster resonance energy transfer (FRET)-based cAMP biosensor, we measured the generation of cAMP in live macrophages. We detected no difference in bulk intracellular cAMP levels between resting cells and cells actively phagocytosing IgG-opsonized particles. However, analysis with the biosensor revealed a rapid decrease in FRET signal corresponding to a transient burst of cAMP production localized to the forming phagosome. cAMP levels returned to baseline after the particle was internalized. These studies indicate that localized increases in cAMP accompany phagosome formation and provide a framework for a more complete understanding of how cAMP regulates macrophage host defense functions.

Pulse shaping multiphoton FRET microscopy

Fluorescence Resonance Energy Transfer (FRET) microscopy is a commonly-used technique to study problems in biophysics that range from uncovering cellular signaling pathways to detecting conformational changes in single biomolecules. Unfortunately, excitation and emission spectral overlap between the fluorophores create challenges in quantitative FRET studies. It has been shown previously that quantitative FRET stoichiometry can be performed by selective excitation of donor and acceptor fluorophores. Extending this approach to two-photon FRET applications is difficult when conventional femtosecond laser sources are used due to their limited bandwidth and slow tuning response time. Extremely broadband titanium:sapphire lasers enable the simultaneous excitation of both donor and acceptor for two-photon FRET, but do so without selectivity. Here we present a novel two-photon FRET microscopy technique that employs pulse-shaping to perform selective excitation of fluorophores in live cells and detect FRET between them. Pulse-shaping via multiphoton intrapulse interference can tailor the excitation pulses to achieve selective excitation. This technique overcomes the limitation of conventional femtosecond lasers to allow rapid switching between selective excitation of the donor and acceptor fluorophores. We apply the method to live cells expressing the fluorescent proteins mCerulean and mCherry, demonstrating selective excitation of fluorophores via pulse-shaping and the detection of twophoton FRET. This work paves the way for two-photon FRET stoichiometry.

Abstract 295: PKCε phosphorylates and modulates the cell membrane translocation of RhoA

Proceedings: AACR 101st Annual Meeting 2010‐‐ Apr 17‐21, 2010; Washington, DC Accumulating evidence has clearly defined the importance of PKCe and small Rho GTPases in tumor metastasis. Previous studies in our laboratory have demonstrated that PKCe signals through RhoA to modulate tumor cell invasion and motility in head and neck squamous cell carcinoma. In this study, we further delineated the link between PKCe and RhoA. Recombinant PKCe directly phosphorylated recombinant RhoA using an in vitro kinase assay. Phosphopeptide mapping with LC-MSE identified T127 and S188 as confident phosphorylation sites and T19 and S26 as tentative phosphorylation sites on RhoA. Interestingly, recombinant PKCe was able to bind to recombinant RhoA in the absence of PKC activators and ATP. This observation demonstrates that the binding interaction between PKCe and RhoA does not require an active PKCe conformation and thus, the interaction between these proteins may be more complex than a typical substrate-kinase event. N-terminus fluorophore-tagged PKCe (CherryFP or CFP) and RhoA (GFP or YFP) were co-expressed in HEK293 cells to examine the interaction between these two proteins in live-cells. Live-cell fluorescence microscopy followed by FRET stoichiometric analysis confirmed the interaction between PKCe and RhoA in the cytoplasm of non-stimulated cells. Stimulation of the cells with PMA to activate PKCe resulted in the translocation of PKCe and RhoA from the cytoplasm to the cell membrane and increased the binding of PKCe to RhoA at the cell membrane by three-fold as measured by FRET. Taken together, our results demonstrate, for the first time, that PKCe phosphorylates, co-localizes, and regulates the cell membrane translocation of RhoA. Citation Format: {Authors}. {Abstract title} [abstract]. In: Proceedings of the 101st Annual Meeting of the American Association for Cancer Research; 2010 Apr 17-21; Washington, DC. Philadelphia (PA): AACR; Cancer Res 2010;70(8 Suppl):Abstract nr 295.

PKCε Phosphorylates and Mediates the Cell Membrane Localization of RhoA

Protein kinase Cε (PKCε) signals through RhoA to modulate cell invasion and motility. In this study, the multifaceted interaction between PKCε and RhoA was defined. Phosphopeptide mapping revealed that PKCε phosphorylates RhoA at T127 and S188. Recombinant PKCε bound to recombinant RhoA in the absence of ATP indicating that the association between PKCε and RhoA does not require an active ATP-docked PKCε conformation. Activation of PKCε resulted in a dramatic coordinated translocation of PKCε and RhoA from the cytoplasm to the cell membrane using time-lapse fluorescence microscopy. Stoichiometric FRET analysis revealed that the molecular interaction between PKCε and RhoA is a biphasic event, an initial peak at the cytoplasm and a gradual prolonged increase at the cell membrane for the entire time-course (12.5 minutes). These results suggest that the PKCε-RhoA complex is assembled in the cytoplasm and subsequently recruited to the cell membrane. Kinase inactive (K437R) PKCε is able to recruit RhoA to the cell membrane indicating that the association between PKCε and RhoA is proximal to the active catalytic site and perhaps independent of a PKCε-RhoA phosphorylation event. This work demonstrates, for the first time, that PKCε phosphorylates and modulates the cell membrane translocation of RhoA.