Preparation of Mica Supported Lipid Bilayers for High Resolution Optical Microscopy Imaging

Supported lipid bilayers (SLBs) are widely used as a model for studying membrane properties (phase separation, clustering, dynamics) and its interaction with other compounds, such as drugs or peptides. However SLB characteristics differ depending on the support used. Commonly used techniques for SLB imaging and measurements are single molecule fluorescence microscopy, FCS and atomic force microscopy (AFM). Because most optical imaging studies are carried out on a glass support, while AFM requires an extremely flat surface (generally mica), results from these techniques cannot be compared directly, since the charge and smoothness properties of these materials strongly influence diffusion. Unfortunately, the high level of manual dexterity required for the cutting and gluing thin slices of mica to the glass slide presents a hurdle to routine use of mica for SLB preparation. Although this would be the method of choice, such prepared mica surfaces often end up being uneven (wavy) and difficult to image, especially with small working distance, high numerical aperture lenses. Here we present a simple and reproducible method for preparing thin, flat mica surfaces for lipid vesicle deposition and SLB preparation. Additionally, our custom made chamber requires only very small volumes of vesicles for SLB formation. The overall procedure results in the efficient, simple and inexpensive production of high quality lipid bilayer surfaces that are directly comparable to those used in AFM studies.     

The measurement of Bacillus mycoides spore adhesion using atomic force microscopy,simple counting methods,and a spinning disk technique

An atomic force microscope has been used to study the adhesion of Bacillus mycoides spores to a hydrophilic glass surface and a hydrophobic-coated glass surface. AFM images of spores attached to the hydrophobic-coated mica surface allowed the measurement of spore dimensions in an aqueous environment without desiccation. The spore exosporium was observed to be flexible and to promote the adhesion of the spore by increasing the area of spore contact with the surface. Results from counting procedures using light microscopy matched the density of spores observed on the hydrophobic-coated glass surface with AFM. However, no spores were observed on the hydrophilic glass surface with AFM, a consequence of the weaker adhesion of the spores at this surface. AFM was also used to quantify directly the interactions of B. mycoides spores at the two surfaces in an aqueous environment. The measurements used "spore probes" constructed by immobilizing a single spore at the apex of a tipless AFM cantilever. The data showed that stretching and sequential bond breaking occurred as the spores were retracted from the hydrophilic glass surface. The greatest spore adhesion was measured at the hydrophobic-coated glass surface. An attractive force on the spores was measured as the spores approached the hydrophobic-coated surface. At the hydrophilic glass surface, only repulsive forces were measured during the approach of the spores. The AFM force measurements were in qualitative agreement with the results of a hydrodynamic shear adhesion assay that used a spinning disk technique. Quantitatively, AFM measurements of adhesive force were up to 4 x 10(3) times larger than the estimates made using the spinning disk data. This is a consequence of the different types of forces applied to the spore in the different adhesion assays. AFM has provided some unique insights into the interactions of spores with surfaces. No other instrument can make such direct measurements for single microbiological cells.     

Hepatitis C virus NS4B targets lipid droplets through hydrophobic residues in the amphipathic helices

Lipid droplets (LD) are dynamic storage organelles that are involved in lipid homeostasis. Hepatitis C virus (HCV) is closely associated with LDs. HCV Core and nonstructural (NS) proteins colocalize with LDs and presumably are involved in virion formation at that site. We demonstrated that HCV NS4B, an integral membrane protein in endoplasmic reticulum (ER), strongly targeted LDs. Confocal imaging studies showed that NS4B localized at the margins of LDs. Biochemical fractionation of HCV-replicating cells suggested that NS4B existed in membranes associated with LDs rather than on the LD surface membrane itself. The N- and C-terminal cytosolic domains of NS4B showed targeting of LDs, with the former being much stronger. In both domains, activity was present in the region containing an amphipathic α-helix, in which 10 hydrophobic residues were identified as putative determinants for targeting LDs. JFH1 mutants with alanine substitutions for the hydrophobic residues were defective for virus replication. W43A mutant with a single alanine substitution showed loss of association of NS4B with LDs and severely reduced release of infectious virions compared with wild-type JFH1. NS4B plays a crucial role in virus replication at the site of virion formation, namely, the microenvironment associated with LDs.     

Interfacial phenomena governing adhesion of chlorella to glass surfaces

Interfacial phenomena are directly involved in the adhesion of a strain of Chlorella, a unicellular alga, to glass surfaces in simple ionic solutions. The principal mechanisms governing the adhesion appear to be electrostatic interaction between electrical double layers and various specific surface interactions resulting from surface heterogeneity and ion adsorption. Under most conditions the algal cells and glass surfaces have negative zeta potentials, and adhesion to glass will not occur; but if, for example, FeCl₃ is added to an algal–glass system immersed in 0.05M NaCl, the algal and glass surfaces will possess very different zeta potentials, and adhesion will be strongest under those conditions which produce the greatest, difference in zeta poentials. Prior pretreatment and usage of glass apparatus greatly affect the glass zeta potentials and the adhesion of algal cells to glass. An apparatus for measuring a relative set of numbers representing the force of adhesion of algal cells is described.     

Yeast cell adhesion on oligopeptide modified surfaces

Self-assembling oligopeptides are novel materials with potential bioengineering applications; this paper explores the use of one of these oligopeptides, EAK 16 II, for modifying the surface properties of cell-supporting substrates. To characterize the surface properties, thermodynamic measurements of liquid contact angle and surface free energy were correlated to atomic force microscopy (AFM) observations. A critical concentration of 0.1 mg/ml was found necessary to completely modify the surface properties of the substrate with EAK 16 II. Adhesion of a yeast cell, Candida utilis, was modified by the coating of EAK 16 II on both hydrophobic (plastic) and hydrophilic (glass) surfaces: Cell coverage was slightly enhanced on the glass substrate, but decreased significantly on the plastic substrate. This indicates that the yeast cell adhesion was mainly determined via hydrophobic interactions between the substrate and the cell wall. However, on the EAK 16 II modified glass substrate, surface roughness might be a factor in causing a slightly larger cell adhesion than that on bare glass. The morphology of adhered cells was also obtained with AFM imaging, showing a depression at the center of the cell on all substrates. Small depressions on the oligopeptide-coated surfaces and plastic substrate may indicate good water-retaining ability by the cell. There was no apparent difference in cell adhesion and morphology among cells obtained from lag, exponential and stationary growth phases.     

Presence of actin in oncornaviruses

A 43K protein present in avian myeloblastosis virus has been identified as actin by 2D gel electrophoresis and peptide mapping proteolysis. Electron microscopy of chicken embryo fibroblasts infected with different pseudotypes of oncornaviruses treated with anti-actin antibody showed positive staining at the level of the virions especially on buds.Our results indicate that this actin is unlikely to have been artefactually absorbed at the virion surface during its preparation. It may therefore play a possible role in the budding of enveloped virions.     

Vaccinia virus penetration requires cholesterol and results in specific viral envelope proteins associated with lipid rafts

Vaccinia virus infects a wide variety of mammalian cells from different hosts, but the mechanism of virus entry is not clearly defined. The mature intracellular vaccinia virus contains several envelope proteins mediating virion adsorption to cell surface glycosaminoglycans; however, it is not known how the bound virions initiate virion penetration into cells. For this study, we investigated the importance of plasma membrane lipid rafts in the mature intracellular vaccinia virus infection process by using biochemical and fluorescence imaging techniques. A raft-disrupting drug, methyl-beta-cyclodextrin, inhibited vaccinia virus uncoating without affecting virion attachment, indicating that cholesterol-containing lipid rafts are essential for virion penetration into mammalian cells. To provide direct evidence of a virus and lipid raft association, we isolated detergent-insoluble glycolipid-enriched membranes from cells immediately after virus infection and demonstrated that several viral envelope proteins, A14, A17L, and D8L, were present in the cell membrane lipid raft fractions, whereas the envelope H3L protein was not. Such an association did not occur after virions attached to cells at 4 degrees C and was only observed when virion penetration occurred at 37 degrees C. Immunofluorescence microscopy also revealed that cell surface staining of viral envelope proteins was colocalized with GM1, a lipid raft marker on the plasma membrane, consistent with biochemical analyses. Finally, mutant viruses lacking the H3L, D8L, or A27L protein remained associated with lipid rafts, indicating that the initial attachment of vaccinia virions through glycosaminoglycans is not required for lipid raft formation.     

Atomic force microscopy investigation of human immunodeficiency virus (HIV) and HIV-infected lymphocytes

Isolated human immunodeficiency virus (HIV) and HIV-infected human lymphocytes in culture have been imaged for the first time by atomic force microscopy (AFM). Purified virus particles spread on glass substrates are roughly spherical, reasonably uniform, though pleomorphic in appearance, and have diameters of about 120 nm. Similar particles are also seen on infected cell surfaces, but morphologies and sizes are considerably more varied, possibly a reflection of the budding process. The surfaces of HIV particles exhibit "tufts" of protein, presumably gp120, which do not physically resemble spikes. The protein tufts, which number about 100 per particle, have average diameters of about 200 A, but with a large variance. They likely consist of arbitrary associations of small numbers of gp120 monomers on the surface. In examining several hundred virus particles, we found no evidence that the gp120 monomers form threefold symmetric trimers. Although >95% of HIV-infected H9 lymphocytic cells were producing HIV antigens by immunofluorescent assay, most lymphocytes displayed few or no virus on their surfaces, while others were almost covered by a hundred or more viruses, suggesting a dependence on cell cycle or physiology. HIV-infected cells treated with a viral protease inhibitor and their progeny viruses were also imaged by AFM and were indistinguishable from untreated virions. Isolated HIV virions were disrupted by exposure to mild neutral detergents (Tween 20 and CHAPS) at concentrations from 0.25 to 2.0%. Among the products observed were intact virions, the remnants of completely degraded virions, and partially disrupted particles that lacked sectors of surface proteins as well as virions that were split or broken open to reveal their empty interiors. Capsids containing nucleic acid were not seen, suggesting that the capsids were even more fragile than the envelope and were totally degraded and lost. From these images, a good estimate of the thickness of the envelope protein-membrane-matrix protein outer shell of the virion was obtained. Treatment with even low concentrations (<0.1%) of sodium dodecyl sulfate completely destroyed all virions but produced many interesting products, including aggregates of viral proteins with strands of nucleic acid.     

Electron Microscopic Characterization of the Defectiveness of a Temperature-Sensitive Mutant of Moloney Murine Leukemia Virus Restricted in Assembly

The effect of temperature shiftdown on the assembly of ts3 virions was investigated by both scanning (SEM) and transmission (TEM) electron microscopy. Ts3 is a spontaneous temperature-sensitive mutant of Moloney murine leukemia virus (Mo-MuLV) which previous studies indicated to be defective in assembly or release of the virions. In the present study, both SEM and TEM revealed the following: (i) there were more cell-associated virions in ts3-infected cells grown at the nonpermissive temperature (39 degrees C) than either in cells grown at the permissive temperature (34 degrees C) or in wild-type MuLV-infected cells grown at 39 degrees C; (ii) there were more normal single particles than multiploids (virions with two or more pieces of genomic RNA) in ts3-infected cells grown at the nonpermissive temperature; (iii) there were more multiploids in ts3-infected cells grown at the nonpermissive temperature than either in cells grown at the permissive temperature or in wild-type MuLV-infected cells grown at the nonpermissive temperature; (iv) upon temperature shift from 39 to 34 degrees C, about 90% of the cell-associated virions dissociated from the cell surface. TEM studies also indicated that upon temperature shiftdown, virion assembly rapidly occurred. The above observations suggest that faulty assembly, which results in the production of multiploids, may not be the reason why ts3 virions accumulate on the cell surface at the nonpermissive temperature. The relatively higher proportion of multiploids found in ts3-infected cells grown at 39 degrees C compared with those grown at 34 degrees C may be due to the higher density of budding virions at the cell surface at the nonpermissive temperature, which increases the possibility of two or more particles assembling close to one another. The accumulation of ts3 virions in all stages of assembly at the nonpermissive temperature, together with the fact that rapid assembly and release of ts3 virions occurred on temperature shiftdown, indicates that virion assembly is restricted after it has been initiated. The probable role of altered glycoprotein(s) in restricting virion assembly is discussed.     

Quantitation of the glycoprotein spike area on the surface of enveloped viruses

The density of glycoprotein (GP) distribution on the virion surface substantially influences the virus infectivity and pathogenicity. A method to quantitatively determine the area occupied by surface GP spikes was proposed for influenza virus (Flu) strain A/PR/8/34 on the basis of data of tritium bombardment and dynamic light scattering. The latter was used to measure the diameter of intact virions and subviral particles (Flu virions lacking GP spikes after bromelain digestion). Intact virions and subviral particles were bombarded with a hot tritium atom flux, and the specific radioactivity of the matrix M1 protein was analyzed. The tritium label was incorporated into the amino acid residues of a thin exposed protein layer and partly penetrated through the lipid bilayer of the viral envelope, labeling M1, located under the lipid bilayer. The tritium label distribution among different amino acid residues was the same in M1 isolated from subviral particles and M1 isolated from intact virions, demonstrating that the M1 spatial structure remained unchanged during proteolysis of GP spikes. The difference in specific radioactivity between the M1 proteins isolated from intact virions and subviral particles was used to calculate the GP-free portion of the viral surface. Approximating the Flu virion as a sphere, the GP-covered area was estimated at 1.4 × 10⁴ nm², about 40% of the total virion surface. This was consistent with the cryoelectron tomography data published for Flu strain A/X-31. The approach can be applied for other enveloped high pathogenic viruses, such as HIV and the Ebola virus.     

Cross-linking of a polyomavirus attachment protein to its mouse kidney cell receptor.

We used photoaffinity cross-linking with the heterobifunctional cross-linker N-hydroxysuccinimidyl 4-azidobenzoate (HSAB) to covalently link polyomavirus to a mouse kidney cell surface component. The virus-HSAB combination was adsorbed to the cells and then cross-linked and isolated in monopinocytotic vesicles from the cells after endocytosis. The cross-linked product was identified on sodium dodecyl sulfate-polyacrylamide gels by the presence of a new band carrying 125I-labeled virion protein with a higher molecular mass than the normal virion protein bands. A single new band, with an apparent molecular mass of 120 kilodaltons (120 kDa), was identified by this procedure. This band was formed only in the presence of the HSAB cross-linker when virions were bound to the cells. The band also copurified with cross-linked virions when virion-containing vesicles were treated with detergent to remove the cell membrane. Antibody treatments that blocked up to 100% of virus binding and internalization also blocked cross-linking, as measured by the formation of the 120-kDa band. The 120-kDa band was characterized by preparation of antibody against the excised band from the gel. This antibody was shown to have the expected dual specificity for polyomavirus VP1 sequences and plasma membrane proteins, as analyzed on Western blots. The anti-120-kDa antibody was also shown by immunofluorescence to bind to the surface of mouse kidney cells. These data have demonstrated that molecules of possible biological significance in the binding of polyomavirus to mouse kidney cells have been cross-linked and that cell surface molecules have been identified that may be characterized further for possible receptor function in polyomavirus attachment.     

Electrical properties of the foot-and-mouth disease virus

It has been shown that the electron microscopy method can be used for characteristics of the electric properties of foot-and-mouth disease virus. The appearance of simultaneous positive and negative staining during the negative staining of virus preparations with 3-4% PTV solution shows the presence of full virions of constant poles designated as positively and negatively stained areas of protein coat surface. The lateral orientation of virions on the film at routine conditions of preparation and the possibility of virion orientation on the film in the external electrical field allow to characterize the full virions as electric dipoles. It has been suggested that there is a relationship between a virus structure and the character of its electric properties.     

Fusion of a single influenza virion particle with BLM

One of the key stages of cell infection with influenza virus is the enveloped virus fusion with the cell endosome membrane. To study fusion of single fluorescently-labeled influenza virions with a model bilayer membrane (BLM), a special model system was developed. A small patch of BLM with several adsorbed virions was localized upon a contact with a glass micropipette. Low pH of solution inside the pipette triggered fusion that could be registered by a change in the conductance and integral fluorescence of the BLM patch. It has been shown that the fusion initiation is followed by an increase of fluorescence signal due to the probe redistribution from the virus membrane to the BLM fragment. The increase in fluorescence was accompanied by changes in conductance. Usually, from two to five periods of the channel activity were observed, each of which probably corresponded to fusion of a single virion. It has been found that electric activity was completely inhibited by amantadine known as a blocking agent of M2 channels. This allows one to suggest that the observed changes in conductance are connected with the activity of M2 channels in the virus membrane, whose electric accessibility was the result of fusion of single virions with BLM.     

Surface Physicochemistry and Ionic Strength Affects eDNA’s Role in Bacterial Adhesion to Abiotic Surfaces

Extracellular DNA (eDNA) is an important structural component of biofilms formed by many bacteria, but few reports have focused on its role in initial cell adhesion. The aim of this study was to investigate the role of eDNA in bacterial adhesion to abiotic surfaces, and determine to which extent eDNA-mediated adhesion depends on the physicochemical properties of the surface and surrounding liquid. We investigated eDNA alteration of cell surface hydrophobicity and zeta potential, and subsequently quantified the effect of eDNA on the adhesion of Staphylococcus xylosus to glass surfaces functionalised with different chemistries resulting in variable hydrophobicity and charge. Cell adhesion experiments were carried out at three different ionic strengths. Removal of eDNA from S. xylosus cells by DNase treatment did not alter the zeta potential, but rendered the cells more hydrophilic. DNase treatment impaired adhesion of cells to glass surfaces, but the adhesive properties of S. xylosus were regained within 30 minutes if DNase was not continuously present, implying a continuous release of eDNA in the culture. Removal of eDNA lowered the adhesion of S. xylosus to all surfaces chemistries tested, but not at all ionic strengths. No effect was seen on glass surfaces and carboxyl-functionalised surfaces at high ionic strength, and a reverse effect occurred on amine-functionalised surfaces at low ionic strength. However, eDNA promoted adhesion of cells to hydrophobic surfaces irrespective of the ionic strength. The adhesive properties of eDNA in mediating initial adhesion of S. xylosus is thus highly versatile, but also dependent on the physicochemical properties of the surface and ionic strength of the surrounding medium.     

Urokinase plasminogen activator inhibits HIV virion release from macrophage-differentiated chronically infected cells via activation of RhoA and PKCε

Background

HIV replication in mononuclear phagocytes is a multi-step process regulated by viral and cellular proteins with the peculiar feature of virion budding and accumulation in intra-cytoplasmic vesicles. Interaction of urokinase-type plasminogen activator (uPA) with its cell surface receptor (uPAR) has been shown to favor virion accumulation in such sub-cellular compartment in primary monocyte-derived macrophages and chronically infected promonocytic U1 cells differentiated into macrophage-like cells by stimulation with phorbol myristate acetate (PMA). By adopting this latter model system, we have here investigated which intracellular signaling pathways were triggered by uPA/uPAR interaction leading the redirection of virion accumulation in intra-cytoplasmic vesicles.

Results

uPA induced activation of RhoA, PKCδ and PKCε in PMA-differentiated U1 cells. In the same conditions, RhoA, PKCδ and PKCε modulated uPA-induced cell adhesion and polarization, whereas only RhoA and PKCε were also responsible for the redirection of virions in intracellular vesicles. Distribution of G and F actin revealed that uPA reorganized the cytoskeleton in both adherent and polarized cells. The role of G and F actin isoforms was unveiled by the use of cytochalasin D, a cell-permeable fungal toxin that prevents F actin polymerization. Receptor-independent cytoskeleton remodeling by Cytochalasin D resulted in cell adhesion, polarization and intracellular accumulation of HIV virions similar to the effects gained with uPA.

Conclusions

These findings illustrate the potential contribution of the uPA/uPAR system in the generation and/or maintenance of intra-cytoplasmic vesicles that actively accumulate virions, thus sustaining the presence of HIV reservoirs of macrophage origin. In addition, our observations also provide evidences that pathways controlling cytoskeleton remodeling and activation of PKCε bear relevance for the design of new antiviral strategies aimed at interfering with the partitioning of virion budding between intra-cytoplasmic vesicles and plasma membrane in infected human macrophages.     

Non-polar distribution of green fluorescent protein on the surface of Autographa californica nucleopolyhedrovirus using a heterologous membrane anchor

Heterogeneous proteins can be displayed on the surface of the budded form of Autographa californica nucleopolyhedrovirus (AcMNPV) after fusion of the display protein to the AcMNPV major envelope glycoprotein, gp64. However, display is restricted to the poles of the virion and is relatively low level. To investigate the use of alternative membrane anchor sequences that would be compatible with virus surface display, we have constructed a display vector containing the gp64 signal peptide and a membrane anchor from the vesicular stomatitis virus (VSV) G glycoprotein. Introduction of a gene encoding green fluorescent protein (GFP) between these signals led to abundant display of GFP on the surface of insect cells and on recombinant budded virions. In addition, and in contrast to gp64 based fusion proteins, GFP was localized to the lateral virion surfaces.     

Structural homology among four nodaviruses as deduced by sequencing and X-ray crystallography

The genomic RNA2s of nodaviruses encode a single gene, that of protein alpha, the precursor of virion proteins beta and gamma. We compared the sequences of the RNA2s of the nodaviruses, black beetle virus (BBV), flock house virus, boolarra virus and nodamura virus, with the objective of identifying homologies in the primary and secondary structure of these RNAs and in the structure of their encoded protein. The sequences of the four RNAs were found to be similar, so that homologous regions relating to translation and RNA replication were readily identified. However, the overall, secondary structures in solution, deduced from calculations of optimal Watson-Crick base-pairing configurations, were very different for the four RNAs. We conclude that a particular, overall, secondary structure in solution within host cells is not required for virus viability. The partially refined X-ray structure of BBV (R = 26.4% for the current model) was used as a framework for comparing the structure of the encoded proteins of the four viruses. Mapping of the four protein sequences onto the BBV capsid showed many amino acid differences on the outer surface, indicating that the exteriors of the four virions are substantially different. Mapping in the beta-barrel region showed an intermediate level of differences, indicating that some freedom in choice of amino acid residues is possible there although the basic framework of the capsids is evidently conserved. Mapping onto the interior surface of the BBV capsid showed a high degree of conservation of amino acid residues, particularly near the protein cleavage site, implying that that region is nearly identical in all four virions and has an essential role in virion maturation, and also suggests that all four capsid interior surfaces have similar surfaces exposed to the viral RNA. Apart from a small portion of the C promoter, the amino terminus of the BBV protein (residues 1 to 60) is crystallographically disordered and the amino acid residues in that region are not well conserved. The disordered portion of the BBV protein clearly projects from the capsid inner surface into the interior of the virion, the region occupied by the viral RNA. In all four viruses, residues 1 to 60 had a high proportion of basic residues, suggesting a virus-specific interaction of the amino terminus with the virion RNA.     

The Design of Simple Bacterial Microarrays: Development towards Immobilizing Single Living Bacteria on Predefined Micro-Sized Spots on Patterned Surfaces

In this paper we demonstrate a procedure for preparing bacterial arrays that is fast, easy, and applicable in a standard molecular biology laboratory. Microcontact printing is used to deposit chemicals promoting bacterial adherence in predefined positions on glass surfaces coated with polymers known for their resistance to bacterial adhesion. Highly ordered arrays of immobilized bacteria were obtained using microcontact printed islands of polydopamine (PD) on glass surfaces coated with the antiadhesive polymer polyethylene glycol (PEG). On such PEG-coated glass surfaces, bacteria were attached to 97 to 100% of the PD islands, 21 to 62% of which were occupied by a single bacterium. A viability test revealed that 99% of the bacteria were alive following immobilization onto patterned surfaces. Time series imaging of bacteria on such arrays revealed that the attached bacteria both divided and expressed green fluorescent protein, both of which indicates that this method of patterning of bacteria is a suitable method for single-cell analysis.     

The role of exopolymers in the attachment of sphingomonas paucimobilis

The importance of exopolymers in the adhesion of Sphingomonas paucimobilis was established by studying the attachment to glass of three mutants with defective gellan production. The attachment assays were performed in either phosphate buffered saline (controls) or in the exopolymeric solutions produced by the mutants. The exopolymer was found to have surface active properties, changing the glass surface from hydrophilic to hydrophobic, making adhesion thermodynamically favourable. Only the cells that had a substantial polymeric layer surrounding their walls were able to significantly colonise glass coated with the exopolymer. It is hypothesised that the exopolymer bound to the glass and the exopolymer present at the surface of the bacteria bound together, overcoming the energy barrier created by the negative charge of both surfaces. It is concluded that the exopolymer from S. paucimobilis has a dual role in the process of adhesion by both coating the surface thereby strengthening adhesion and by enhancing adhesion through the establishment of polymeric bridges.     

Adhesion forces measured at the level of a terminal plate of the fly's seta

The attachment pads of fly legs are covered with setae, each ending in small terminal plates coated with secretory fluid. A cluster of these terminal plates contacting a substrate surface generates strong attractive forces that hold the insect on smooth surfaces. Previous research assumed that cohesive forces and molecular adhesion were involved in the fly attachment mechanism. The main elements that contribute to the overall attachment force, however, remained unknown. Multiple local force-volume measurements were performed on individual terminal plates by using atomic force microscopy. It was shown that the geometry of a single terminal plate had a higher border and considerably lower centre. Local adhesion was approximately twice as strong in the centre of the plate as on its border. Adhesion of fly footprints on a glass surface, recorded within 20 min after preparation, was similar to adhesion in the centre of a single attachment pad. Adhesion strongly decreased with decreasing volume of footprint fluid, indicating that the layer of pad secretion covering the terminal plates is crucial for the generation of a strong attractive force. Our data provide the first direct evidence that, in addition to Van der Waals and Coulomb forces, attractive capillary forces, mediated by pad secretion, are a critical factor in the fly's attachment mechanism.