Using macrophages overexpressing or reducing SNAP-23, this study shows that SNAP-23 is implicated in phagosome formation and maturation, presumably by mediating SNARE-based membrane traffic. Indeed, a conformational change in SNAP-23 structure based on FRET signal is observed on the phagosome membrane of cells overexpressing the lysosomal SNARE VAMP7.
Molecular imaging employing fluorescent proteins has been widely used to highlight specific reactions or processes in various fields of the life sciences. Despite extensive improvements of the fluorescent tag, this technology is still limited in the study of molecular events in the extracellular milieu. This is partly due to the presence of cysteine in the fluorescent proteins. These proteins almost cotranslationally form disulfide bonded oligomers when expressed in the endoplasmic reticulum (ER). Although single molecule photobleaching analysis showed that these oligomers were not fluorescent, the fluorescent monomer form often showed aberrant behavior in folding and motion, particularly when fused to cysteine-containing cargo. Therefore we investigated whether it was possible to eliminate the cysteine without losing the brightness. By site-saturated mutagenesis, we found that the cysteine residues in fluorescent proteins could be replaced with specific alternatives while still retaining their brightness. cf(cysteine-free)SGFP2 showed significantly reduced restriction of free diffusion in the ER and marked improvement of maturation when fused to the prion protein. We further applied this approach to TagRFP family proteins and found a set of mutations that obtains the same level of brightness as the cysteine-containing proteins. The approach used in this study to generate new cysteine-free fluorescent tags should expand the application of molecular imaging to the extracellular milieu and facilitate its usage in medicine and biotechnology.
The endoplasmic reticulum (ER) is proposed to be a membrane donor for phagosome formation. In support of this, we have previously shown that the expression level of syntaxin 18, an ER-localized SNARE protein, correlates with phagocytosis activity. To obtain further insights into the involvement of the ER in phagocytosis we focused on Sec22b, another ER-localized SNARE protein that is also found on phagosomal membranes. In marked contrast to the effects of syntaxin 18, we report here that phagocytosis was nearly abolished in J774 macrophages stably expressing mVenus-tagged Sec22b, without affecting the cell surface expression of the Fc receptor or other membrane proteins related to phagocytosis. Conversely, the capacity of the parental J774 cells for phagocytosis was increased when endogenous Sec22b expression was suppressed. Domain analyses of Sec22b revealed that the R-SNARE motif, a selective domain for forming a SNARE complex with syntaxin18 and/or D12, was responsible for the inhibition of phagocytosis. These results strongly support the ER-mediated phagocytosis model and indicate that Sec22b is a negative regulator of phagocytosis in macrophages, most likely by regulating the level of free syntaxin 18 and/or D12 at the site of phagocytosis.
A yeast class V myosin Myo2 transports the Golgi into the bud during its inheritance. However, the mechanism that links the Golgi to Myo2 is unknown. Here, we report that Ypt11, a Rab GTPase that reportedly interacts with Myo2, binds to Ret2, a subunit of the coatomer complex. When Ypt11 is overproduced, Ret2 and the Golgi markers, Och1 and Sft2, are accumulated in the growing bud and are lost in the mother cell. In a ret2 mutant that produces the Ret2 protein with reduced affinity to Ypt11, no such accumulation is observed upon overproduction of Ypt11. At a certain stage of budding, it is known that the late Golgi cisternae labeled with Sec7-GFP show polarized distribution in the bud. We find that this polarization of late Golgi cisternae is not observed in the ypt11Delta mutant. Indeed, analyses of Sec7-GFP dynamics with spatio-temporal image correlation spectroscopy (STICS) and fluorescence loss in photobleaching (FLIP) reveals that Ypt11 is required for the vectorial actin-dependent movement of the late Golgi from the mother cell toward the emerging bud. These results indicate that the Ypt11 and Ret2 are components of a Myo2 receptor complex that functions during the Golgi inheritance into the growing bud.
Sphingolipids,includingsphingomyelin(SM)andglucosylceramide (GlcCer), are generated by the addition of a polar head group to ceramide (Cer). Sphingomyelin synthase 1 (SMS1) and glucosylceramide synthase (GCS) are key enzymes that catalyze the conversion of Cer to SM and GlcCer, respectively. GlcCer synthesis has been postulated to occur mainly in cis-Golgi, and SM synthesis is thought to occur in medial/trans-Golgi; however, SMS1 and GCS are known to partially co-localize in cisternae, especially in medial/trans-Golgi. Here, we report that SMS1 and GCS can form a heteromeric complex, in which the N terminus of SMS1 and the C terminus of GCS are in close proximity. Deletion of the N-terminal sterile ␣-motif of SMS1 reduced the stability of the SMS1-GCS complex, resulting in a significant reduction in SM synthesis in vivo. In contrast, chemical-induced heterodimerization augmented SMS1 activity, depending on an increase in the amount and stability of the complex. Fusion of the SMS1 N terminus to the GCS C terminus via linkers of different lengths increased SM synthesis and decreased GlcCer synthesis in vivo. These results suggest that formation of the SMS1-GCS heteromeric complex increases SM synthesis and decreases GlcCer synthesis. Importantly, this regulation of relative Cer levels by the SMS1-GCS complex was confirmed by CRISPR/Cas9 -mediated knockout of SMS1 or GCS combined with pharmacological inhibition of Cer transport protein in HEK293T cells. Our findings suggest that complex formation between SMS1 and GCS is part of a critical mechanism controlling the metabolic fate of Cer in the Golgi.Sphingolipids, including sphingomyelin (SM) 2 and glucosylceramide (GlcCer), are generated by the addition of a polar head group to ceramide (Cer); the head group is phosphocholine in SM and glucose in GlcCer. GlcCer serves as the core structure of more than 300 glycosphingolipids (GSLs), which are generated by the step-by-step addition of a sugar chain to GlcCer. In contrast, further extension of the polar head group does not occur in SM production. SM and GSLs mainly localize in the external leaflet of the plasma membrane and interact with cholesterol to form lipid microdomains, which play important roles in various cellular functions (1). Given that SMrich microdomains in the plasma membrane are spatially and functionally distinct from GSL-rich microdomains (2), SM and GlcCer might have different biological functions.Two enzymes, SM synthase (SMS) and GlcCer synthase (GCS; also termed GlcT-1, UGCG, or CGT) are involved in this metabolic branch point. SMS catalyzes the transfer of phosphocholine from phosphatidylcholine to Cer. SMS has two isoforms in mammals; SMS1 is localized in the Golgi apparatus, whereas SMS2 occurs in both the Golgi apparatus and plasma membranes (3). SMS1 is mainly responsible for the de novo synthesis of SM (4, 5), whereas SMS2 participates in the maintenance of the SM level in the plasma membrane (5,6) and modulates the interaction between signaling proteins (7, 8). In contrast, only one GCS ha...
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