Direct Regulation of Microtubule Dynamics by KIF17 Motor and Tail Domains

KIF17 is a kinesin-2 family motor that interacts with EB1 at microtubule (MT) plus-ends and contributes to MT stabilization in epithelial cells. The mechanism by which KIF17 affects MTs and how its activity is regulated are not yet known. Here, we show that EB1 and the KIF17 autoinhibitory tail domain (KIF17-Tail) interacted competitively with the KIF17 catalytic motor domain (K370). Both EB1 and KIF17-Tail decreased the K_0.5MT of K370, with opposing effects on MT-stimulated ATPase activity. Importantly, K370 had independent effects on MT dynamic instability, resulting in formation of long MTs without affecting polymerization rate or total polymer mass. K370 also inhibited MT depolymerization induced by dilution in vitro and by nocodazole in cells, suggesting that it acts by protecting MT plus-ends. Interestingly, KIF17-Tail bound MTs and tubulin dimers, delaying initial MT polymerization in vitro and MT regrowth in cells. However, neither EB1 nor KIF17-Tail affected K370-mediated MT polymerization or stabilization significantly in vitro, and EB1 was dispensable for MT stabilization by K370 in cells. Thus, although EB1 and KIF17-Tail may coordinate KIF17 catalytic activity, our data reveal a novel and direct role for KIF17 in regulating MT dynamics.     

Myosin-1A targets to microvilli using multiple membrane binding motifs in the tail homology 1 (TH1) domain

One of the most abundant components of the enterocyte brush border is the actin-based monomeric motor, myosin-1a (Myo1a). Within brush border microvilli, Myo1a carries out a number of critical functions at the interface between membrane and actin cytoskeleton. Proper physiological function of Myo1a depends on its ability to bind to microvillar membrane, an interaction mediated by a C-terminal tail homology 1 (TH1) domain. However, little is known about the mechanistic details of the Myo1a-TH1/membrane interaction. Structure-function analysis of Myo1a-TH1 targeting in epithelial cells revealed that an N-terminal motif conserved among class I myosins and a C-terminal motif unique to Myo1a-TH1 are both required for steady state microvillar enrichment. Purified Myo1a bound to liposomes composed of phosphatidylserine and phosphoinositol 4,5-bisphosphate, with moderate affinity in a charge-dependent manner. Additionally, peptides of the N- and C-terminal regions required for targeting were able to compete with Myo1a for binding to highly charged liposomes in vitro. Single molecule total internal reflection fluorescence microscopy showed that these motifs are also necessary for slowing the membrane detachment rate in cells. Finally, Myo1a-TH1 co-localized with both lactadherin-C2 (a phosphatidylserine-binding protein) and PLCδ1-PH (a phosphoinositol 4,5-bisphosphate-binding protein) in microvilli, but only lactaderin-C2 expression reduced brush border targeting of Myo1a-TH1. Together, our results suggest that Myo1a targeting to microvilli is driven by membrane binding potential that is distributed throughout TH1 rather than localized to a single motif. These data highlight the diversity of mechanisms that enable different class I myosins to target membranes in distinct biological contexts.     

Rap1 and Rap2 Antagonistically Control Endothelial Barrier Resistance

Rap1 and Rap2 are closely related proteins of the Ras family of small G-proteins. Rap1 is well known to regulate cell-cell adhesion. Here, we have analysed the effect of Rap-mediated signalling on endothelial permeability using electrical impedance measurements of HUVEC monolayers and subsequent determination of the barrier resistance, which is a measure for the ease with which ions can pass cell junctions. In line with its well-established effect on cell-cell junctions, depletion of Rap1 decreases, whereas activation of Rap1 increases barrier resistance. Despite its high sequence homology with Rap1, depletion of Rap2 has an opposite, enhancing, effect on barrier resistance. This effect can be mimicked by depletion of the Rap2 specific activator RasGEF1C and the Rap2 effector MAP4K4, establishing Rap2 signalling as an independent pathway controlling barrier resistance. As simultaneous depletion or activation of both Rap1 and Rap2 results in a barrier resistance comparable to control cells, Rap1 and Rap2 control barrier resistance in a reciprocal manner. This Rap1-antagonizing effect of Rap2 is established independent of junctional actin formation. These data establish that endothelial barrier resistance is determined by the combined antagonistic actions of Rap1 and Rap2.     

In Thermoanaerobacterium thermosulfurigenes EM1 S-Layer Homology Domains Do Not Attach to Peptidoglycan

Three exocellular enzymes of Thermoanaerobacterium thermosulfurigenes EM1 possess a C-terminal triplicated sequence related to a domain of bacterial cell surface proteins (S-layer proteins). At least one copy of this sequence, named the SLH (for S-layer homology) domain, is also present at the N terminus of the S-layer protein of this bacterium. The hypothesis that SLH domains serve to anchor proteins to the cell surface was investigated by using the SLH domain-containing xylanase. This enzyme was isolated from T. thermosulfurigenes EM1, and different forms with and without SLH domains were synthesized in Escherichia coli. The interaction of these proteins with isolated components of the cell envelope was determined to identify the attachment site in the cell wall. In addition, a polypeptide consisting of three SLH domains and the N terminus of the S-layer protein of T. thermosulfurigenes EM1 were included in these studies. The results indicate that SLH domains are necessary for the attachment of these proteins to peptidoglycan-containing sacculi. Extraction of the native sacculi with hydrofluoric acid led to the conclusion that not peptidoglycan but accessory cell wall polymers function as the adhesion component in the cell wall. Our results provide further evidence that attachment of proteins via their SLH domains represents an additional mode to display polypeptides on the cell surfaces of bacteria.     

Heterologous Src Homology 4 Domains Support Membrane Anchoring and Biological Activity of HIV-1 Nef

The HIV-1 pathogenicity factor Nef enhances viral replication by modulation of multiple host cell transport and signaling pathways. Nef associates with membranes via an N-terminal Src homology 4 (SH4) domain, and membrane association is believed to be essential for its biological functions. At which subcellular site(s) Nef exerts its different functions and how kinetics of membrane interactions contribute to its biological activity are unknown. To address how specific characteristics of Nef membrane association affect its biological properties, the SH4 domain of Nef was replaced by heterologous membrane targeting domains. The use of a panel of heterologous SH4 domains resulted in chimeric Nef proteins with distinct steady state subcellular localization, membrane association efficiency, and anterograde transport routes. Irrespective of these modifications, cardinal Nef functions affecting host cell vesicular transport and actin dynamics were fully preserved. In contrast, stable targeting of Nef to the surface of mitochondria, peroxisomes, or the Golgi apparatus, and thus prevention of plasma membrane delivery, caused potent and broad loss of Nef activity. These results support the concept that Nef adopts its active conformation in the membrane-associated state but exclude that membrane-associated Nef simply acts by recruiting soluble factors independently of its local microenvironment. Rather than its steady state subcellular localization or membrane affinity, the ability to undergo dynamic anterograde and internalization cycles appear to determine Nef function. These results reveal that functional membrane interactions of Nef underlie critical spatiotemporal regulation and suggest that delivery to distinct subcellular sites via such transport cycles provides the basis for the multifunctionality of Nef.     

Mutations in Drosophila Enabled and Rescue by Human Vasodilator-stimulated Phosphoprotein (VASP) Indicate Important Functional Roles for Ena/VASP Homology Domain 1 (EVH1) and EVH2 Domains

Drosophila Enabled (Ena) was initially identified as a dominant genetic suppressor of mutations in the Abelson tyrosine kinase and, more recently, as a member of the Ena/human vasodilator-stimulated phosphoprotein (VASP) family of proteins. We have used genetic, biochemical, and cell biological approaches to demonstrate the functional relationship between Ena and human VASP. In addition, we have defined the roles of Ena domains identified as essential for its activity in vivo. We have demonstrated that VASP rescues the embryonic lethality associated with loss of Ena function in Drosophila and have shown that Ena, like VASP, is associated with actin filaments and focal adhesions when expressed in cultured cells. To define sequences that are central to Ena function, we have characterized the molecular lesions present in two lethal ena mutant alleles that affected the Ena/VASP homology domain 1 (EVH1) and EVH2. A missense mutation that resulted in an amino acid substitution in the EVH1 domain eliminated in vitro binding of Ena to the cytoskeletal protein zyxin, a previously reported binding partner of VASP. A nonsense mutation that resulted in a C-terminally truncated Ena protein lacking the EVH2 domain failed to form multimeric complexes and exhibited reduced binding to zyxin and the Abelson Src homology 3 domain. Our analysis demonstrates that Ena and VASP are functionally homologous and defines the conserved EVH1 and EVH2 domains as central to the physiological activity of Ena.     

Structural Studies Reveal Unique Non-canonical Regulators of G Protein Signaling Homology (RH) Domains in Sorting Nexins

As a subgroup of sorting nexins (SNXs) that contain regulator of G protein signaling homology (RH) domain, SNX-RH proteins, including SNX13, SNX14 and SNX25, were proposed to play bifunctional roles in protein sorting and GPCR signaling regulation. However, mechanistic details of SNX-RH proteins functioning via RH domain remain to be illustrated. Here, we delineate crystal structures of the RH domains of SNX13 and SNX25, revealing a homodimer of SNX13 RH domain mediated by unique extended α4 and α5 helices, and a thiol modulated homodimer of SNX25-RH triggered by a unique cysteine on α6 helix. Further studies showed that RH domains of SNX-RH do not possess binding capacity toward Gα subunits, owing to the lack of critical residues for interaction. Thus, this study identifies a group of novel non-canonical RH domains that can act as a dimerization module in sorting nexins, which provides structural basis for mechanism studies on SNX-RH protein functions.     

Biochemical Activities of the Wiskott-Aldrich Syndrome Homology Region 2 Domains of Sarcomere Length Short (SALS) Protein

Drosophila melanogaster sarcomere length short (SALS) is a recently identified Wiskott-Aldrich syndrome protein homology 2 (WH2) domain protein involved in skeletal muscle thin filament regulation. SALS was shown to be important for the establishment of the proper length and organization of sarcomeric actin filaments. Here, we present the first detailed characterization of the biochemical activities of the tandem WH2 domains of SALS (SALS-WH2). Our results revealed that SALS-WH2 binds both monomeric and filamentous actin and shifts the monomer-filament equilibrium toward the monomeric actin. In addition, SALS-WH2 can bind to but fails to depolymerize phalloidin- or jasplakinolide-bound actin filaments. These interactions endow SALS-WH2 with the following two major activities in the regulation of actin dynamics: SALS-WH2 sequesters actin monomers into non-polymerizable complexes and enhances actin filament disassembly by severing, which is modulated by tropomyosin. We also show that profilin does not influence the activities of the WH2 domains of SALS in actin dynamics. In conclusion, the tandem WH2 domains of SALS are multifunctional regulators of actin dynamics. Our findings suggest that the activities of the WH2 domains do not reconstitute the presumed biological function of the full-length protein. Consequently, the interactions of the WH2 domains of SALS with actin must be tuned in the cellular context by other modules of the protein and/or sarcomeric components for its proper functioning.     

Differential effects of poly (Glu60, Phe40) (GPhe) on murine TH1 and TH2 cells.

The random amino acid copolymer (Glu60, Phe40)n (GPhe) was previously shown to augment antigen-dependent proliferation of the murine TH2 cell lines DCL-2 and D10.G4.1. In the present study, the addition of GPhe to (Glu36, Lys24, Ala40)n (GLA)-primed BALB/c primary lymph node (1 degree LN) T cell cultures, the source of DCL-2, resulted in significant suppression of both the proliferative and lymphokine response to GLA. Suppression by GPhe of the 1 degree LN response was subsequently shown to be neither antigen- nor haplotype restricted, and was inhibitable by polyclonal anti-GPhe antibodies. Studies were extended to a GLA-reactive T cell hybridoma clone (DL.4G6.1). where significant suppression by GPhe of GLA-stimulated lymphokine production was observed as measured by markedly decreased HT-2 stimulatory activity of the collected supernatants. Subsequent antibody blocking experiments employing the monoclonal anti-murine IL-4 antibody 11B11 revealed that BALB/c GLA-reactive 1 degree LN T cells and DL.4G6.1 did not produce detectable levels of IL-4 in their culture fluids when stimulated by GLA, which suggested that these cells, unlike DCL-2, were TH1-like in nature. The addition of GPhe to the TH1 clones 5.2 and 5.9 resulted in significant suppression of proliferation to homologous antigen (ovalbumin), in contrast to the augmentation observed with the TH2 cell lines DCL-2 and D10.G4.1. It was concluded from these data, that the addition of GPhe to various T cell cultures lead to unusual suppressive and augmenting activities specific for TH1 and TH2 cells, respectively. Although the mechanism for these dichotomous effects of GPhe is as yet undetermined, several possibilities are considered.     

Virus-Induced Chaperone-Enriched (VICE) Domains Function as Nuclear Protein Quality Control Centers during HSV-1 Infection

Virus-Induced Chaperone-Enriched (VICE) domains form adjacent to nuclear viral replication compartments (RC) during the early stages of HSV-1 infection. Between 2 and 3 hours post infection at a MOI of 10, host protein quality control machinery such as molecular chaperones (e.g. Hsc70), the 20S proteasome and ubiquitin are reorganized from a diffuse nuclear distribution pattern to sequestration in VICE domains. The observation that VICE domains contain putative misfolded proteins suggests that they may be similar to nuclear inclusion bodies that form under conditions in which the protein quality control machinery is overwhelmed by the presence of misfolded proteins. The detection of Hsc70 in VICE domains, but not in nuclear inclusion bodies, indicates that Hsc70 is specifically reorganized by HSV-1 infection. We hypothesize that HSV-1 infection induces the formation of nuclear protein quality control centers to remodel or degrade aberrant nuclear proteins that would otherwise interfere with productive infection. Detection of proteolytic activity in VICE domains suggests that substrates may be degraded by the 20S proteasome in VICE domains. FRAP analysis reveals that GFP-Hsc70 is dynamically associated with VICE domains, suggesting a role for Hsc70 in scanning the infected nucleus for misfolded proteins. During 42°C heat shock, Hsc70 is redistributed from VICE domains into RC perhaps to remodel viral replication and regulatory proteins that have become insoluble in these compartments. The experiments presented in this paper suggest that VICE domains are nuclear protein quality control centers that are modified by HSV-1 to promote productive infection.     

Homology Modeling and Molecular Dynamics Simulations of PBCV-1 Glycosylase Complexed with UV-damaged DNA

The UV-light damage specific DNA glycosylase from Chlorella virus strain PBCV-1 (pyrimidine dimer glycosylase; PDG) incises DNA at sites containing UV-induced thymidine dimers by catalyzing the breakage of the N-C-1 glycosyl bond. As the amino acid sequence of PDG is 41% identical to that of T4 endonuclease V (Endo V), and potential key active site residues are conserved, we used coordinates from a crystal structure of an Endo V complexed with DNA containing a cis-syn cyclobutane thymidine-dimer as a template to model a similar complex of PDG. Quantum mechanical calculations of the damaged base pair and the distance geometry based program DIAMOD were used to generate a PDG/DNA model whose backbone root mean square deviation (RMSD) to the Endo V/DNA structure was 0.5 Å, 0.5 Å, and 0.8 Å for DNA, protein, and the whole complex, respectively. To better understand structural details that could account for differences in activity of the two enzymes, molecular dynamics simulations were used to follow protein-DNA interactions in an aqueous environment. The simulations of the Endo V/DNA complex indicate new roles for Arg22 and Arg26 in the active site in recognizing irregular pairing and maintaining the strand separation needed for incision of the damaged bases. The model for the PDG/DNA complex and simulations thereof indicate a similar mechanism for DNA binding by this enzyme despite significant differences in residues maintaining the flipped-out adenine and strand separation in the area of damage. According to our model, PDGs increased affinity for substrate is probably due to a higher surface charge. Further, reduced packing density in the active site could account for PDGs activity on trans-syn II cyclobutane dimers.Electronic Supplementary Material available.     

N Terminus of Sos1 Ras Exchange Factor: Critical Roles for the Dbl and Pleckstrin Homology Domains

We have studied the functional importance of the N terminus of mouse Sos1 (mSos1), a ubiquitously expressed Ras-specific guanine nucleotide exchange factor whose C-terminal sequences bind Grb-2. Consistent with previous reports, addition of a myristoylation signal to mSos1 (MyrSos1) rendered it transforming for NIH 3T3 cells and deletion of the mSos C terminus (MyrSos1-ΔC) did not interfere with this activity. However, an N-terminally deleted myristoylated mSos1 protein (MyrSos1-ΔN) was transformation defective, although the protein was stable and localized to the membrane. Site-directed mutagenesis was used to examine the role of the Dbl and pleckstrin homology (PH) domains located in the N terminus. When mutations in the PH domain were introduced into two conserved amino acids either singly or together in MyrSos1 or MyrSos1-ΔC, the transforming activity was severely impaired. An analogous reduction in biological activity was seen when a cluster of point mutations was engineered into the Dbl domain. The mitogen-activation protein (MAP) kinase activities induced by the various Dbl and PH mutants of MyrSos1 correlated with their biological activities. When NIH 3T3 cells were transfected with a myristoylated Sos N terminus, their growth response to epidermal growth factor (EGF), platelet-derived growth factor, lysophosphatidic acid or serum was greatly impaired. The dominant inhibitory biological activity of the N terminus correlated with its ability to impair EGF-dependent activation of GTP-Ras and of MAP kinase, as well with the ability of endogenous Sos to form a stable complex with activated EGF receptors. The N terminus with mutations in the Dbl and PH domains was much less inhibitory in these biological and biochemical assays. In contrast to wild-type Sos1, nonmyristoylated versions of Sos1-ΔN and Sos1-ΔC did not form a stable complex with activated EGF receptors. We conclude that the Dbl and PH domains are critical for Sos function and that stable association of Sos with activated EGF receptors requires both the Sos N and C termini.     

The Pleckstrin Homology and Phosphotyrosine Binding Domains of Insulin Receptor Substrate 1 Mediate Inhibition of Apoptosis by Insulin

Insulin and insulin-like growth factor 1 (IGF-1) evoke diverse biological effects through receptor-mediated tyrosine phosphorylation of insulin receptor substrate (IRS) proteins. We investigated the elements of IRS-1 signaling that inhibit apoptosis of interleukin 3 (IL-3)-deprived 32D myeloid progenitor cells. 32D cells have few insulin receptors and no IRS proteins; therefore, insulin failed to inhibit apoptosis during IL-3 withdrawal. Insulin stimulated mitogen-activated protein kinase in 32D cells expressing insulin receptors (32D^IR) but failed to activate the phosphatidylinositol 3 (PI 3)-kinase cascade or to inhibit apoptosis. By contrast, insulin stimulated the PI 3-kinase cascade, inhibited apoptosis, and promoted replication of 32D^IR cells expressing IRS-1. As expected, insulin did not stimulate PI 3-kinase in 32D^IR cells, which expressed a truncated IRS-1 protein lacking the tail of tyrosine phosphorylation sites. However, this truncated IRS-1 protein, which retained the NH₂-terminal pleckstrin homology (PH) and phosphotyrosine binding (PTB) domains, mediated phosphorylation of PKB/akt, inhibition of apoptosis, and replication of 32D^IR cells during insulin stimulation. These results suggest that a phosphotyrosine-independent mechanism mediated by the PH and PTB domains promoted antiapoptotic and growth actions of insulin. Although PI 3-kinase was not activated, its phospholipid products were required, since LY294002 inhibited these responses. Without IRS-1, a chimeric insulin receptor containing a tail of tyrosine phosphorylation sites derived from IRS-1 activated the PI 3-kinase cascade but failed to inhibit apoptosis. Thus, phosphotyrosine-independent IRS-1-linked pathways may be critical for survival and growth of IL-3-deprived 32D cells during insulin stimulation.     

TH1 and TH2 cytokine inhibition by 3,5-bis(trifluoromethyl)pyrazoles,a novel class of immunomodulators

In order to discover novel immunomodulators for application in treating autoimmune diseases, a stable Jurkat transfectant was constructed in which luciferase reporter gene is driven by a full-length IL-2 promotor. A chemical library was screened to identify compounds that inhibited luciferase expression in Jurkat transfectants stimulated with PMA and ionomycin. A class of compounds (bis-trifluoromethyl pyrazole, BTPs) was identified from this screen. BTPs were shown to inhibit anti-CD3 and anti-CD28 antibody-induced IL-2 secretion, mixed lymphocyte reaction, and Con A-induced T cell proliferation in normal human peripheral blood T cells. In addition, mRNA levels of IL-4, IL-5, IL-9, IL-10, IL-13, IL-15, and IFN-gamma were markedly inhibited by BTPs in peripheral blood mononuclear cells stimulated by Con A as determined by multi-probe RNA protection assay. Furthermore, IL-2, IL-4, IL-5, and IFN-gamma secretion by Hut 78 cells or CD3(+) T cells stimulated with PMA plus ionomycin or anti-CD3 antibody plus PMA were inhibited in a concentration-dependent manner by BTPs. Therefore, BTPs inhibit a wide spectrum of cytokine production including TH1 and TH2 type cytokines. Taken together, these compounds may be useful for treating autoimmune diseases and organ transplant rejection.     

Caenorhabditits elegans LRK-1 and PINK-1 Act Antagonistically in Stress Response and Neurite Outgrowth

Mutations in two genes encoding the putative kinases LRRK2 and PINK1 have been associated with inherited variants of Parkinson disease. The physiological role of both proteins is not known at present, but studies in model organisms have linked their mutants to distinct aspects of mitochondrial dysfunction, increased vulnerability to oxidative and endoplasmic reticulum stress, and intracellular protein sorting. Here, we show that a mutation in the Caenorhabditits elegans homologue of the PTEN-induced kinase pink-1 gene resulted in reduced mitochondrial cristae length and increased paraquat sensitivity of the nematode. Moreover, the mutants also displayed defects in axonal outgrowth of a pair of canal-associated neurons. We demonstrate that in the absence of lrk-1, the C. elegans homologue of human LRRK2, all phenotypic aspects of pink-1 loss-of-function mutants were suppressed. Conversely, the hypersensitivity of lrk-1 mutant animals to the endoplasmic reticulum stressor tunicamycin was reduced in a pink-1 mutant background. These results provide the first evidence of an antagonistic role of PINK-1 and LRK-1. Due to the similarity of the C. elegans proteins to human LRRK2 and PINK1, we suggest a common role of both factors in cellular functions including stress response and regulation of neurite outgrowth. This study might help to link pink-1/PINK1 and lrk-1/LRRK2 function to the pathological processes resulting from Parkinson disease-related mutants in both genes, the first manifestations of which are cytoskeletal defects in affected neurons.Mutations in the Parkinson disease (PD)²-related gene PINK1 have been associated with increased sensitivity to oxidative stress and mitochondrial dysfunction (1–4). Although a series of reports support a localization of PINK1 only in mitochondria (5–7), recent studies have shown that a portion of endogenous PINK1 is also distributed to the cytoplasm (8–11). Notably, the cytoplasmic kinase activity and not the mitochondrial targeting of PINK1 seems to be prerequisite of its protective effects against mitochondrial stress (12).The GTPase-regulated kinase LRRK2, another gene associated with familial PD, has been linked to the biogenesis and regulation of vesicular transport (13, 14). In support of this notion, the C. elegans lrk-1, the LRRK2 homologue, has recently been shown to be involved in synaptobrevin-associated vesicular transport (15). Moreover, the Dictyostelium homologue of LRRK2/LRK-1 proteins, GbpC, a cGMP-binding protein is required for the normal phosphorylation and cytoskeletal assembly of myosin (16). Based on this data, it had been anticipated that PINK1/PINK-1 and LRRK2/LRK-1 might be involved in distinct cellular functions, whereas pathological mutations in both genes, leading either to loss-of-function (PINK1) or gain-of-function (LRRK2), result in a similar phenotype, the loss of dopaminergic neurons.In the present study, we found a functional connection between their Caenorhabditits elegans homologues pink-1 and lrk-1. We demonstrate that loss of C. elegans pink-1 results in oxidative stress sensitivity and neurite outgrowth defects. All aspects of pink-1 deficiency were suppressed in the absence of lrk-1 that, as a single mutant, displayed a profound hypersensitivity to the ER stressor tunicamycin. Because the latter phenotype was in turn suppressed by deleting pink-1, our results support an antagonistic role of pink-1 and lrk-1 in stress response and neuronal activities.     

Vaccinia Virus F1L Interacts with Bak Using Highly Divergent Bcl-2 Homology Domains and Replaces the Function of Mcl-1

The Bcl-2 family regulates induction of apoptosis at the mitochondria. Essential to this regulation are the interactions between Bcl-2 family members, which are mediated by Bcl-2 homology (BH) domains. Vaccinia virus F1L is a unique inhibitor of apoptosis that lacks significant sequence similarity with the Bcl-2 family and does not contain obvious BH domains. Despite this, F1L inhibits cytochrome c release from mitochondria by preventing Bak and Bax activation. Although F1L constitutively interacts with Bak to prevent Bak activation, the precise mechanism of this interaction remains elusive. We have identified highly divergent BH domains in F1L that were verified by the recent crystal structure of F1L (Kvansakul, M., Yang, H., Fairlie, W. D., Czabotar, P. E., Fischer, S. F., Perugini, M. A., Huang, D. C., and Colman, P. M. (2008) Cell Death Differ. 15, 1564–1571). Here we show that F1L required these BH domains to interact with ectopically expressed and endogenous Bak. The interaction between F1L and Bak was conserved across species, and both F1L and the cellular antiapoptotic protein Mcl-1 required the Bak BH3 domain for interaction. Moreover, F1L replaced Mcl-1 during infection, as the Bak·Mcl-1 complex was disrupted during vaccinia virus infection. In contrast to UV irradiation, vaccinia virus infection did not result in rapid degradation of Mcl-1, consistent with our observation that vaccinia virus did not initiate a DNA damage response. Additionally, Mcl-1 expression prevented Bak activation and apoptosis during infection with a proapoptotic vaccinia virus devoid of F1L. Our data suggest that F1L replaces the antiapoptotic activity of Mcl-1 during vaccinia virus infection by interacting with Bak using highly divergent BH domains.     

Myosin-1a is critical for normal brush border structure and composition

To develop our understanding of myosin-1a function in vivo, we have created a mouse line null for the myosin-1a gene. Myosin-1a knockout mice demonstrate no overt phenotypes at the whole animal level but exhibit significant perturbations and signs of stress at the cellular level. Among these are defects in microvillar membrane morphology, distinct changes in brush-border organization, loss of numerous cytoskeletal and membrane components from the brush border, and redistribution of intermediate filament proteins into the brush border. We also observed significant ectopic recruitment of another short-tailed class I motor, myosin-1c, into the brush border of knockout enterocytes. This latter finding, a clear demonstration of functional redundancy among vertebrate myosins-I, may account for the lack of a whole animal phenotype. Nevertheless, these results indicate that myosin-1a is a critical multifunctional component of the enterocyte, required for maintaining the normal composition and highly ordered structure of the brush border.