Measuring Phospholipid Flippase Activity by NBD-Lipid Uptake in Living Yeast Cells.

Phospholipid flippases in the P4-ATPase family are essential for establishing membrane asymmetry. These ATP-powered pumps translocate specific lipids from the exofacial leaflet to the cytosolic leaflet of the plasma membrane, thereby concentrating substrate lipids, such as phosphatidylserine, in the cytosolic leaflet while non-substrate lipids populate the exofacial leaflet. Here, we describe a method for measuring P4-ATPase transport activity in the yeast plasma membrane by using flow cytometry to quantify the uptake of lipids derivatized with a fluorescent [7-nitro-2-1,3-benzoxadiazol-4-yl)amino] (NBD) group on a short (C6) fatty acyl chain.

P4-ATPase endosomal recycling relies on multiple retromer-dependent localization signals.

Type IV P-type ATPases (P4-ATPases) are lipid flippases that generate an asymmetric membrane organization essential for cell viability. The five budding yeast P4-ATPases traffic between the Golgi complex, plasma membrane, and endosomes but how they are recycled from the endolysosomal system to the Golgi complex is poorly understood. In this study, we find that P4-ATPase endosomal recycling is primarily driven by the retromer complex and the F-box protein Rcy1.

Structural insight into an Arl1-ArfGEF complex involved in Golgi recruitment of a GRIP-domain golgin.

Arl1 is an Arf-like (Arl) GTP-binding protein that interacts with the guanine nucleotide exchange factor Gea2 to recruit the golgin Imh1 to the Golgi. The Arl1-Gea2 complex also binds and activates the phosphatidylserine flippase Drs2 and these functions may be related, although the underlying molecular mechanism is unclear. Here we report high-resolution cryo-EM structures of the full-length Gea2 and the Arl1-Gea2 complex.

Flipping the script: Advances in understanding how and why P4-ATPases flip lipid across membranes.

Type IV P-type ATPases (P4-ATPases) are a family of transmembrane enzymes that translocate lipid substrates from the outer to the inner leaflet of biological membranes and thus create an asymmetrical distribution of lipids within membranes. On the cellular level, this asymmetry is essential for maintaining the integrity and functionality of biological membranes, creating platforms for signaling events and facilitating vesicular trafficking. On the organismal level, this asymmetry has been shown to be important in maintaining blood homeostasis, liver metabolism, neural development, and the immune response.

Visualizing Reversible Cisternal Stacking in Budding Yeast Pichia pastoris.

Cisternal stacking is reversible, initiated at the "cis" side of the Golgi, and gets undone at the "trans" side in a continuous cycle in tune with the cisternal maturation. TGN peeling is a hallmark of such reversible cisternal stacking, but its visualization is challenging. In wild-type cells, TGN peeling of Golgi stack happens at a lower frequency, but the event itself occurs very rapidly, making it difficult to detect by microscopy.

Lipid Transport by Dnf2 Is Required for Hyphal Growth and Virulence.

Candida albicans is a common cause of human mucosal yeast infections, and invasive candidiasis can be fatal. Antifungal medications are limited, but those targeting the pathogen cell wall or plasma membrane have been effective. Therefore, virulence factors controlling membrane biogenesis are potential targets for drug development.

ER exit sites (ERES) and ER-mitochondria encounter structures (ERMES) often localize proximally.

To understand the potential interplay between vesicular trafficking and direct membrane contact sites-mediated transport, we selected the endoplasmic reticulum (ER), which participates in both modes of inter-organelle transport. ER-mitochondria encounter structures (ERMES) are direct membrane contact junctions that mediate macromolecule exchange, while the secretory pathway originates at ER exit sites (ERES). Using the budding yeast Pichia pastoris, we documented that ERMES resident proteins are often juxtaposed with ERES markers.

Structural basis of the P4B ATPase lipid flippase activity.

P4 ATPases are lipid flippases that are phylogenetically grouped into P4A, P4B and P4C clades. The P4A ATPases are heterodimers composed of a catalytic α-subunit and accessory β-subunit, and the structures of several heterodimeric flippases have been reported. The S.

Transport mechanism of P4 ATPase phosphatidylcholine flippases.

The P4 ATPases use ATP hydrolysis to transport large lipid substrates across lipid bilayers. The structures of the endosome- and Golgi-localized phosphatidylserine flippases-such as the yeast Drs2 and human ATP8A1-have recently been reported. However, a substrate-binding site on the cytosolic side has not been found, and the transport mechanisms of P4 ATPases with other substrates are unknown.

Exofacial membrane composition and lipid metabolism regulates plasma membrane P4-ATPase substrate specificity.

The plasma membrane of a cell is characterized by an asymmetric distribution of lipid species across the exofacial and cytofacial aspects of the bilayer. Regulation of membrane asymmetry is a fundamental characteristic of membrane biology and is crucial for signal transduction, vesicle transport, and cell division. The type IV family of P-ATPases, or P4-ATPases, establishes membrane asymmetry by selection and transfer of a subset of membrane lipids from the lumenal or exofacial leaflet to the cytofacial aspect of the bilayer.

ER arrival sites associate with ER exit sites to create bidirectional transport portals.

COPI vesicles mediate Golgi-to-ER recycling, but COPI vesicle arrival sites at the ER have been poorly defined. We explored this issue using the yeast Pichia pastoris. ER arrival sites (ERAS) can be visualized by labeling COPI vesicle tethers such as Tip20.

The golgin Imh1 mediates reversible cisternal stacking in the Golgi of the budding yeast .

The adhesive force for cisternal stacking of Golgi needs to be reversible - to be initiated and undone in a continuous cycle to keep up with the cisternal maturation. Microscopic evidence in support of such a reversible nature of stacking, in the form of 'TGN peeling,' has been reported in various species, suggesting a potential evolutionarily conserved mechanism. However, knowledge of such mechanism has remained sketchy.

Vps74p controls Golgi size in an Arf1-dependent manner.

The oncogene GOLPH3 is implicated in Golgi size regulation, a function yet to be experimentally linked to its PI4P effector function or the Golgi cisternal maturation in general. Moreover, its yeast homolog, Vps74p is not yet implicated in Golgi size regulation. Our results indicate that VPS74 deletion increases the late Golgi cisternal size and the cisternal maturation frequencies, and destabilizes the Golgi PI4P gradient in budding yeast.

Identification and characterization of GRIP domain Golgin PpImh1 from Pichia pastoris.

Budding yeast Pichia pastoris has highly advanced secretory pathways resembling mammalian systems, an advantage that makes it a suitable model system to study vesicular trafficking. Golgins are large Golgi-resident proteins, primarily reported to play role in cargo vesicle capture, but details of such mechanisms are yet to be deciphered. Golgins that localize to the Golgi via their GRIP domain, a C-terminal Golgi anchoring domain, are known as GRIP domain Golgins.

Perturbation of nucleo-cytoplasmic transport affects size of nucleus and nucleolus in human cells.

Size regulation of human cell nucleus and nucleolus are poorly understood subjects. 3D reconstruction of live image shows that the karyoplasmic ratio (KR) increases by 30-80% in transformed cell lines compared to their immortalized counterpart. The attenuation of nucleo-cytoplasmic transport causes the KR value to increase by 30-50% in immortalized cell lines.

Golgi enlargement in Arf-depleted yeast cells is due to altered dynamics of cisternal maturation.

Regulation of the size and abundance of membrane compartments is a fundamental cellular activity. In Saccharomyces cerevisiae, disruption of the ADP-ribosylation factor 1 (ARF1) gene yields larger and fewer Golgi cisternae by partially depleting the Arf GTPase. We observed a similar phenotype with a thermosensitive mutation in Nmt1, which myristoylates and activates Arf.