S100A10‐Mediated Translocation of Annexin‐A2 to SNARE Proteins in Adrenergic Chromaffin Cells Undergoing Exocytosis

In neuroendocrine cells, annexin‐A2 is implicated as a promoter of monosialotetrahexosylganglioside (GM1)‐containing lipid microdomains that are required for calcium‐regulated exocytosis. As soluble N‐ethylmaleimide‐sensitive factor attachment protein receptors (SNAREs) require a specific lipid environment to mediate granule docking and fusion, we investigated whether annexin‐A2‐induced lipid microdomains might be linked to the SNAREs present at the plasma membrane. Stimulation of adrenergic chromaffin cells induces the translocation of cytosolic annexin‐A2 to the plasma membrane, where it colocalizes with SNAP‐25 and S100A10. Cross‐linking experiments performed in stimulated chromaffin cells indicate that annexin‐A2 directly interacts with S100A10 to form a tetramer at the plasma membrane. Here, we demonstrate that S100A10 can interact with vesicle‐associated membrane protein 2 (VAMP2) and show that VAMP2 is present at the plasma membrane in resting adrenergic chromaffin cells. Tetanus toxin that cleaves VAMP2 solubilizes S100A10 from the plasma membrane and inhibits the translocation of annexin‐A2 to the plasma membrane. Immunogold labelling of plasma membrane sheets combined with spatial point pattern analysis confirmed that S100A10 is present in VAMP2 microdomains at the plasma membrane and that annexin‐A2 is observed close to S100A10 and to syntaxin in stimulated chromaffin cells. In addition, these results showed that the formation of phosphatidylinositol (4,5)‐bisphosphate (PIP₂) microdomains colocalized with S100A10 in the vicinity of docked granules, suggesting a functional interplay between annexin‐A2‐mediated lipid microdomains and SNAREs during exocytosis.     

Characterization of VAMP‐2 in the lung: implication in lung surfactant secretion

Lung surfactant is crucial for reducing the surface tension of alveolar space, thus preventing the alveoli from collapse. Lung surfactant is synthesized in alveolar epithelial type II cells and stored in lamellar bodies before being released via the fusion of lamellar bodies with the apical plasma membrane. SNAREs (soluble N‐ethylmaleimide‐sensitive fusion protein‐attachment protein receptors) play an essential role in membrane fusion. We have previously demonstrated the requirement of t‐SNARE (target SNARE) proteins, syntaxin 2 and SNAP‐23 (N‐ethylmaleimide‐sensitive factor‐attachment protein 23), in regulated surfactant secretion. Here, we characterized the distribution of VAMPs (vesicle‐associated membrane proteins) in rat lung and alveolar type II cells. VAMP‐2, ?3 and ?8 are shown in type II cells at both mRNA and protein levels. VAMP‐2 and ?8 were enriched in LB (lamellar body) fraction. Immunochemistry studies indicated that VAMP‐2 was co‐localized with the LB marker protein, LB‐180. Functionally, the cytoplasmic domain of VAMP‐2, but not VAMP‐8 inhibited surfactant secretion in type II cells. We suggest that VAMP‐2 is the v‐SNARE (vesicle SNARE) involved in regulated surfactant secretion.     

Role of Varp,a Rab21 exchange factor and TI‐VAMP/VAMP7 partner,in neurite growth

The vesicular soluble N‐ethylmaleimide‐sensitive factor attachment protein receptor (SNARE) tetanus neurotoxin‐insensitive vesicle‐associated membrane protein (TI‐VAMP/VAMP7) was previously shown to mediate an exocytic pathway involved in neurite growth, but its regulation is still largely unknown. Here we show that TI‐VAMP interacts with the Vps9 domain and ankyrin‐repeat‐containing protein (Varp), a guanine nucleotide exchange factor (GEF) of the small GTPase Rab21, through a specific domain herein called the interacting domain (ID). Varp, TI‐VAMP and Rab21 co‐localize in the perinuclear region of differentiating hippocampal neurons and transiently in transport vesicles in the shaft of neurites. Silencing the expression of Varp by RNA interference or expressing ID or a form of Varp deprived of its Vps9 domain impairs neurite growth. Furthermore, the mutant form of Rab21, defective in GTP hydrolysis, enhances neurite growth. We conclude that Varp is a positive regulator of neurite growth through both its GEF activity and its interaction with TI‐VAMP.     

Host microtubule plus‐end binding protein CLASP1 influences sequential steps in the Trypanosoma cruzi infection process

Mammalian cell invasion by the protozoan parasite Trypanosoma cruzi involves host cell microtubule dynamics. Microtubules support kinesin‐dependent anterograde trafficking of host lysosomes to the cell periphery where targeted lysosome exocytosis elicits remodelling of the plasma membrane and parasite invasion. Here, a novel role for microtubule plus‐end tracking proteins (+TIPs) in the co‐ordination of T. cruzi trypomastigote internalization and post‐entry events is reported. Acute silencing of CLASP1, a +TIP that participates in microtubule stabilization at the cell periphery, impairs trypomastigote internalization without diminishing the capacity for calcium‐regulated lysosome exocytosis. Subsequent fusion of the T. cruzi vacuole with host lysosomes and its juxtanuclear positioning are also delayed in CLASP1‐depleted cells. These post‐entry phenotypes correlate with a generalized impairment of minus‐end directed transport of lysosomes in CLASP1 knock‐down cells and mimic the effects ofdynactin disruption. Consistent with GSK3β acting as a negative regulator of CLASP function, inhibition of GSK3β activity enhances T. cruzi entry in a CLASP1‐dependent manner and expression of constitutively active GSK3β dampens infection. This study provides novel molecular insights into the T. cruzi infection process, emphasizing functional links between parasite‐elicited signalling, host microtubule plus‐end tracking proteins and dynein‐based retrograde transport. Highlighted in this work is a previously unrecognized role for CLASPs in dynamic lysosome positioning, an important aspect of the nutrient sensing response in mammalian cells.     

Bioluminescence imaging of chronic Trypanosoma cruzi infections reveals tissue‐specific parasite dynamics and heart disease in the absence of locally persistent infection

Chronic Trypanosoma cruzi infections lead to cardiomyopathy in 20–30% of cases. A causal link between cardiac infection and pathology has been difficult to establish because of a lack of robust methods to detect scarce, focally distributed parasites within tissues. We developed a highly sensitive bioluminescence imaging system based on T. cruzi expressing a novel luciferase that emits tissue‐penetrating orange‐red light. This enabled long‐term serial evaluation of parasite burdens in individual mice with an in vivo limit of detection of significantly less than 1000 parasites. Parasite distributions during chronic infections were highly focal and spatiotemporally dynamic, but did not localize to the heart. End‐point ex vivo bioluminescence imaging allowed tissue‐specific quantification of parasite loads with minimal sampling bias. During chronic infections, the gastro‐intestinal tract, specifically the colon and stomach, was the only site where T. cruzi infection was consistently observed. Quantitative PCR‐inferred parasite loads correlated with ex vivo bioluminescence and confirmed the gut as the parasite reservoir. Chronically infected mice developed myocarditis and cardiac fibrosis, despite the absence of locally persistent parasites. These data identify the gut as a permissive niche for long‐term T. cruzi infection and show that canonical features of Chagas disease can occur without continual myocardium‐specific infection.     

Phosphatidic Acid Sequesters Sec18p from cis‐SNARE Complexes to Inhibit Priming

Yeast vacuole fusion requires the activation of cis‐SNARE complexes through priming carried out by Sec18p/N‐ethylmaleimide sensitive factor and Sec17p/α‐SNAP. The association of Sec18p with vacuolar cis‐SNAREs is regulated in part by phosphatidic acid (PA) phosphatase production of diacylglycerol (DAG). Inhibition of PA phosphatase activity blocks the transfer of membrane‐associated Sec18p to SNAREs. Thus, we hypothesized that Sec18p associates with PA‐rich membrane microdomains before transferring to cis‐SNARE complexes upon PA phosphatase activity. Here, we examined the direct binding of Sec18p to liposomes containing PA or DAG. We found that Sec18p preferentially bound to liposomes containing PA compared with those containing DAG by approximately fivefold. Additionally, using a specific PA‐binding domain blocked Sec18p binding to PA‐liposomes and displaced endogenous Sec18p from isolated vacuoles. Moreover, the direct addition of excess PA blocked the priming activity of isolated vacuoles in a manner similar to chemically inhibiting PA phosphatase activity. These data suggest that the conversion of PA to DAG facilitates the recruitment of Sec18p to cis‐SNAREs. Purified vacuoles from yeast lacking the PA phosphatase Pah1p showed reduced Sec18p association with cis‐SNAREs and complementation with plasmid‐encoded PAH1 or recombinant Pah1p restored the interaction. Taken together, this demonstrates that regulating PA concentrations by Pah1p activity controls SNARE priming by Sec18p.      

A Dynamin Homolog Promotes the Transition from Hemifusion to Content Mixing in Intracellular Membrane Fusion

The convergence of the antagonistic reactions of membrane fusion and fission at the hemifusion/hemifission intermediate has generated a captivating enigma of whether Soluble N‐ethylmaleimide sensitive factor Attachment Protein Receptor (SNAREs) and dynamin have unusual counter‐functions in fission and fusion, respectively. SNARE‐mediated fusion and dynamin‐driven fission are fundamental membrane flux reactions known to occur during ubiquitous cellular communication events such as exocytosis, endocytosis and vesicle transport. Here we demonstrate the influence of the dynamin homolog Vps1 (Vacuolar protein sorting 1) on lipid mixing and content mixing properties of yeast vacuoles, and on the incorporation of SNAREs into fusogenic complexes. We propose a novel concept that Vps1, through its oligomerization and SNARE domain binding, promotes the hemifusion‐content mixing transition in yeast vacuole fusion by increasing the number of trans‐SNAREs .      

Legionella pneumophila Promotes Functional Interactions between Plasma Membrane Syntaxins and Sec22b

Biogenesis of a specialized organelle that supports intracellular replication of Legionella pneumophila involves the fusion of secretory vesicles exiting the endoplasmic reticulum (ER) with phagosomes containing this bacterial pathogen. Here, we investigated host plasma membrane SNARE proteins to determine whether they play a role in trafficking of vacuoles containing L. pneumophila. Depletion of plasma membrane syntaxins by RNA interference resulted in delayed acquisition of the resident ER protein calnexin and enhanced retention of Rab1 on phagosomes containing virulent L. pneumophila, suggesting that these SNARE proteins are involved in vacuole biogenesis. Plasma membrane‐localized SNARE proteins syntaxin 2, syntaxin 3, syntaxin 4 and SNAP23 localized to vacuoles containing L. pneumophila. The ER‐localized SNARE protein Sec22b was found to interact with plasma membrane SNAREs on vacuoles containing virulent L. pneumophila, but not on vacuoles containing avirulent mutants of L. pneumophila. The addition of α‐SNAP and N‐ethylmaleimide‐sensitive factor (NSF) to the plasma membrane SNARE complexes formed by virulent L. pneumophila resulted in the dissociation of Sec22b, indicating functional pairing between these SNAREs. Thus, L. pneumophila stimulates the non‐canonical pairing of plasma membrane t‐SNAREs with the v‐SNARE Sec22b to promote fusion of the phagosome with ER‐derived vesicles. The mechanism by which L. pneumophila promotes pairing of plasma membrane syntaxins and Sec22b could provide unique insight into how the secretory vesicles could provide an additional membrane reserve subverted during phagosome maturation.     

SNARE and regulatory proteins induce local membrane protrusions to prime docked vesicles for fast calcium‐triggered fusion

Synaptic vesicles fuse with the plasma membrane in response to Ca²⁺ influx, thereby releasing neurotransmitters into the synaptic cleft. The protein machinery that mediates this process, consisting of soluble N‐ethylmaleimide‐sensitive factor attachment protein receptors (SNAREs) and regulatory proteins, is well known, but the mechanisms by which these proteins prime synaptic membranes for fusion are debated. In this study, we applied large‐scale, automated cryo‐electron tomography to image an in vitro system that reconstitutes synaptic fusion. Our findings suggest that upon docking and priming of vesicles for fast Ca²⁺‐triggered fusion, SNARE proteins act in concert with regulatory proteins to induce a local protrusion in the plasma membrane, directed towards the primed vesicle. The SNAREs and regulatory proteins thereby stabilize the membrane in a high‐energy state from which the activation energy for fusion is profoundly reduced, allowing synchronous and instantaneous fusion upon release of the complexin clamp.     

SNARE protein analog‐mediated membrane fusion

Fusion of lipid membranes to form a single bilayer is an essential process for life and provides important biological functions including neurotransmitter release. Membrane fusion proteins facilitate approximation of interacting membranes to overcome the energy barrier. In case of synaptic transmission, proteins involved are known as soluble N‐ethylmaleimide‐sensitive‐factor attachment receptor (SNARE) proteins. The SNAREs from synaptic vesicles interact with the SNAREs from the target membrane to form a coiled‐coil bundle of four helices, thus pulling the membranes tightly together and initiating fusion. However, it remains unclear how these proteins function at molecular level. Natural systems are often too complex to obtain unambiguous results. Simple model systems mimicking natural proteins in synthetic lipid bilayers are powerful tools for obtaining insights into this essential biological process. An important advantage of such systems is their well‐defined composition, which can be systematically varied in order to fully understand events at molecular level. In this review, selected model systems are presented based upon specific interactions between recognition units embedded in separate lipid bilayers mimicking native SNARE protein‐mediated membrane fusion. Copyright © 2015 European Peptide Society and John Wiley & Sons, Ltd.     

Steric hindrance of SNARE transmembrane domain organization impairs the hemifusion‐to‐fusion transition

SNAREs fuse membranes in several steps. Trans‐SNARE complexes juxtapose membranes, induce hemifused stalk structures, and open the fusion pore. A recent penetration model of fusion proposed that SNAREs force the hydrophilic C‐termini of their transmembrane domains through the hydrophobic core of the membrane(s). In contrast, the indentation model suggests that the C‐termini open the pore by locally compressing and deforming the stalk. Here we test these models in the context of yeast vacuole fusion. Addition of small hydrophilic tags renders bilayer penetration by the C‐termini energetically unlikely. It preserves fusion activity, however, arguing against the penetration model. Addition of large protein tags to the C‐termini permits SNARE activation, trans‐SNARE pairing, and hemifusion but abolishes pore opening. Fusion proceeds if the tags are detached from the membrane by a hydrophilic spacer or if only one side of the trans‐SNARE complex carries a protein tag. Thus, both sides of a trans‐SNARE complex can drive pore opening. Our results are consistent with an indentation model in which multiple SNARE C‐termini cooperate in opening the fusion pore by locally deforming the inner leaflets.     

Plasmodium berghei sporozoites in nonreplicative vacuole are eliminated by a PI3P‐mediated autophagy‐independent pathway

The protozoan parasite Plasmodium, causative agent of malaria, invades hepatocytes by invaginating the host cell plasma membrane and forming a parasitophorous vacuole membrane (PVM). Surrounded by this PVM, the parasite undergoes extensive replication. Parasites inside a PVM provoke the Plasmodium‐associated autophagy‐related (PAAR) response. This is characterised by a long‐lasting association of the autophagy marker protein LC3 with the PVM, which is not preceded by phosphatidylinositol 3‐phosphate (PI3P)‐labelling. Prior to productive invasion, sporozoites transmigrate several cells and here we describe that a proportion of traversing sporozoites become trapped in a transient traversal vacuole, provoking a host cell response that clearly differs from the PAAR response. These trapped sporozoites provoke PI3P‐labelling of the surrounding vacuolar membrane immediately after cell entry, followed by transient LC3‐labelling and elimination of the parasite by lysosomal acidification. Our data suggest that this PI3P response is not only restricted to sporozoites trapped during transmigration but also affects invaded parasites residing in a compromised vacuole. Thus, host cells can employ a pathway distinct from the previously described PAAR response to efficiently recognise and eliminate Plasmodium parasites.     

Shared elements of host‐targeting pathways among apicomplexan parasites of differing lifestyles

Apicomplexans are a diverse group of obligate parasites occupying different intracellular niches that require modification to meet the needs of the parasite. To efficiently manipulate their environment, apicomplexans translocate numerous parasite proteins into the host cell. Whereas some parasites remain contained within a parasitophorous vacuole membrane (PVM) throughout their developmental cycle, others do not, a difference that affects the machinery needed for protein export. A signal‐mediated pathway for protein export into the host cell has been characterized in Plasmodium parasites, which maintain the PVM. Here, we functionally demonstrate an analogous host‐targeting pathway involving organellar staging prior to secretion in the related bovine parasite, Babesia bovis, a parasite that destroys the PVM shortly after invasion. Taking into account recent identification of a similar signal‐mediated pathway in the coccidian parasite Toxoplasma gondii, we suggest a model in which this conserved pathway has evolved in multiple steps from signal‐mediated trafficking to specific secretory organelles for controlled secretion to a complex protein translocation process across the PVM.     

The autophagic pathway is a key component in the lysosomal dependent entry of Trypanosoma cruzi into the host cell

The etiologic agent of Chagas disease, Trypanosoma cruzi, infects mammalian cells activating a signal transduction cascade that leads to the formation of its parasitophorous vacuole. Previous works have demonstrated the crucial role of lysosomes in the establishment of T. cruzi infection. In this work we have studied the possible relationship between this parasite and the host cell autophagy. We show, for the first time, that the vacuole containing T. cruzi (TcPV) is decorated by the host cell autophagic protein LC3. Furthermore, live cell imaging experiments indicate that autolysosomes are recruited to parasite entry sites. Interestingly, starvation or pharmacological induction of autophagy before infection significantly increased the number of infected cells whereas inhibitors of this pathway reduced the invasion. In addition, the absence of Atg5 or the reduced expression of Beclin1, two proteins required at the initial steps of autophagosome formation, limited parasite entry and reduced the association between TcPV and the classical lysosomal marker Lamp-1. These results indicate that mammalian autophagy is a key process that favors the colonization of T. cruzi in the host cell.     

Trypanosoma cruzi utilizes the host low density lipoprotein receptor in invasion

Background

Trypanosoma cruzi, an intracellular protozoan parasite that infects humans and other mammalian hosts, is the etiologic agent in Chagas disease. This parasite can invade a wide variety of mammalian cells. The mechanism(s) by which T. cruzi invades its host cell is not completely understood. The activation of many signaling receptors during invasion has been reported; however, the exact mechanism by which parasites cross the host cell membrane barrier and trigger fusion of the parasitophorous vacuole with lysosomes is not understood.

Methodology/Principal Findings

In order to explore the role of the Low Density Lipoprotein receptor (LDLr) in T. cruzi invasion, we evaluated LDLr parasite interactions using immunoblot and immunofluorescence (IFA) techniques. These experiments demonstrated that T. cruzi infection increases LDLr levels in infected host cells, inhibition or disruption of LDLr reduces parasite load in infected cells, T. cruzi directly binds recombinant LDLr, and LDLr-dependent T. cruzi invasion requires PIP2/3. qPCR analysis demonstrated a massive increase in LDLr mRNA (8000 fold) in the heart of T. cruzi infected mice, which is observed as early as 15 days after infection. IFA shows a co-localization of both LDL and LDLr with parasites in infected heart.

Conclusions/Significance

These data highlight, for the first time, that LDLr is involved in host cell invasion by this parasite and the subsequent fusion of the parasitophorous vacuole with the host cell lysosomal compartment. The model suggested by this study unifies previous models of host cell invasion for this pathogenic protozoon. Overall, these data indicate that T. cruzi targets LDLr and its family members during invasion. Binding to LDL likely facilitates parasite entry into host cells. The observations in this report suggest that therapeutic strategies based on the interaction of T. cruzi and the LDLr pathway should be pursued as possible targets to modify the pathogenesis of disease following infection.     

Mechanisms of interferon‐beta‐induced inhibition of Toxoplasma gondii growth in murine macrophages and embryonic fibroblasts: role of immunity‐related GTPase M1

The apical complex of Toxoplasma gondii enables it to invade virtually all nucleated cells in warm‐blooded animals, including humans, making it a parasite of global importance. Anti‐T. gondii cellular defence mechanisms depend largely on interferon (IFN)‐γ production by immune cells. However, the molecular mechanism of IFN‐β‐mediated defence remains largely unclear. Here, mouse peritoneal macrophages and murine embryonic fibroblasts (MEFs) primed with recombinant IFN‐β and IFN‐γ showed different pathways of activation. Treatment of these cells with IFN‐β or IFN‐γ inhibited T. gondii (type II PLK strain) growth. Priming macrophages with IFN‐β had no effect on inflammatory cytokine expression, inducible nitric oxide synthase or indoleamine 2,3‐dioxygenase, nor did it have an effect on their metabolites, nitric oxide and kynurenine respectively. In contrast, IFN‐γ stimulation was characterized by classical macrophage activation and T. gondii elimination. IFN‐β activation recruited the immunity‐related GTPase M1 (IRGM1) to the parasitophorous vacuole in the macrophages and MEFs. Anti‐toxoplasma activities induced by IFN‐β were significantly reduced after IRGM1 knockdown in murine macrophages and in IRGM1‐deficient MEFs. Thus, this study unravels an alternative pathway of macrophage activation by IFN‐β and provides a mechanistic explanation for the contribution of IRGM1 induced by IFN‐β to the elimination of T. gondii.     

Developmentally-Regulated Virulence Factors of Trypanosoma cruzi and Their Relationship to Evasion of Host Defences1

ABSTRACT. Developmental preadaptation of virulent stages of Trypanosoma cruzi correlates with their ability to survive and establish infection in mammalian hosts. Infective trypomastigote stages must first preadapt to survival in the extracellular milieu and then to the rigors of establishing an intracellular infection. Selected phenotypic variations in evading host defences have been correlated with expression of stage-specific proteins or functions. Resistance of trypomastigotes to complement-mediated killing correlates with the presence of a stage-specific molecule that exhibits an analogous function to mammalian decay-accelerating factor, and with the presence of a neuraminidase/trans-sialidase that transfers sialic acid moieties to the parasite surface, thereby enabling it to avoid complement activation. Trypomastigotes enter cells by a mechanism that involves sorting of cell surface receptors and avoids eliciting a respiratory burst. Once within a membrane-bound vacuole, which undergoes acidification, the neuraminidase/trans-sialidase and an acid-active, transmembrane pore-forming protein are released by the parasite and are capable of acting together to accelerate rupture of the vacuolar membrane and the parasite's escape into the cytoplasm of the host cell. Escape from the parasitophorous vacuole allows virulent stages of T. cruzi to avoid compartmental, non-oxidative killing mechanisms such as degradation by lysosomal hydrolases.     

A perforin‐like protein mediates disruption of the erythrocyte membrane during egress of Plasmodium berghei male gametocytes

Successful gametogenesis of the malaria parasite depends on egress of the gametocytes from the erythrocytes within which they developed. Egress entails rupture of both the parasitophorous vacuole membrane and the erythrocyte plasma membrane, and precedes the formation of the motile flagellated male gametes in a process called exflagellation. We show here that egress of the male gametocyte depends on the function of a perforin‐like protein, PPLP2. A mutant of Plasmodium berghei lacking PPLP2 displayed abnormal exflagellation; instead of each male gametocyte forming eight flagellated gametes, it produced gametocytes with only one, shared thicker flagellum. Using immunofluorescence and transmission electron microscopy analysis, and phenotype rescue with saponin or a pore‐forming toxin, we conclude that rupture of the erythrocyte membraneis blocked in the mutant. The parasitophorous vacuole membrane, on the other hand, is ruptured normally. Some mutant parasites are still able to develop in the mosquito, possibly because the vigorous motility of the flagellated gametes eventually leads to escape from the persisting erythrocyte membrane. This is the first example of a perforin‐like protein in Plasmodium parasites having a role in egress from the host cell and the first parasite protein shown to be specifically required for erythrocyte membrane disruption during egress.     

Multimodal analysis of Plasmodium knowlesi‐infected erythrocytes reveals large invaginations,swelling of the host cell,and rheological defects

The simian parasite Plasmodium knowlesi causes severe and fatal malaria infections in humans, but the process of host cell remodelling that underpins the pathology of this zoonotic parasite is only poorly understood. We have used serial block‐face scanning electron microscopy to explore the topography of P. knowlesi‐infected red blood cells (RBCs) at different stages of asexual development. The parasite elaborates large flattened cisternae (Sinton Mulligan's clefts) and tubular vesicles in the host cell cytoplasm, as well as parasitophorous vacuole membrane bulges and blebs, and caveolar structures at the RBC membrane. Large invaginations of host RBC cytoplasm are formed early in development, both from classical cytostomal structures and from larger stabilised pores. Although degradation of haemoglobin is observed in multiple disconnected digestive vacuoles, the persistence of large invaginations during development suggests inefficient consumption of the host cell cytoplasm. The parasite eventually occupies ~40% of the host RBC volume, inducing a 20% increase in volume of the host RBC and an 11% decrease in the surface area to volume ratio, which collectively decreases the ability of the P. knowlesi‐infected RBCs to enter small capillaries of a human erythrocyte microchannel analyser. Ektacytometry reveals a markedly decreased deformability, whereas correlative light microscopy/scanning electron microscopy and python‐based skeleton analysis (Skan) reveal modifications to the surface of infected RBCs that underpin these physical changes. We show that P. knowlesi‐infected RBCs are refractory to treatment with sorbitol lysis but are hypersensitive to hypotonic lysis. The observed physical changes in the host RBCs may underpin the pathology observed in patients infected with P. knowlesi.     

Coiled‐coil interactions are required for post‐Golgi R‐SNARE trafficking

The sorting of post‐Golgi R‐SNAREs (vesicle‐associated membrane protein (VAMP)1, 2, 3, 4, 7 and 8) is still poorly understood. To address this, we developed a system to investigate their localization, trafficking and cell‐surface levels. Here, we show that the distribution and internalization of VAMPs 3 and 8 are determined solely through a new conserved mechanism that uses coiled‐coil interactions, and that VAMP4 does not require these interactions for its trafficking. We propose that VAMPs 3 and 8 are trafficked while in a complex with Q‐SNAREs. We also show that the dileucine motif of VAMP4 is required for both its internalization and retrieval to the trans‐Golgi network. However, when the dileucine motif is mutated, the construct can still be internalized potentially through coiled‐coil interactions with Q‐SNAREs.