Natalie Hager scite author profile

Protein composition at the plasma membrane is tightly regulated, with rapid protein internalization and selective targeting to the cell surface occurring in response to environmental changes. For example, ion channels are dynamically relocalized to or from the plasma membrane in response to physiological alterations, allowing cells and organisms to maintain osmotic and salt homeostasis. To identify additional factors that regulate the selective trafficking of a specific ion channel, we used a yeast model for a mammalian potassium channel, the K inward rectifying channel Kir2.1. Kir2.1 maintains potassium homeostasis in heart muscle cells, and Kir2.1 defects lead to human disease. By examining the ability of Kir2.1 to rescue the growth of yeast cells lacking endogenous potassium channels, we discovered that specific α-arrestins regulate Kir2.1 localization. Specifically, we found that the Ldb19/Art1, Aly1/Art6, and Aly2/Art3 α-arrestin adaptor proteins promote Kir2.1 trafficking to the cell surface, increase Kir2.1 activity at the plasma membrane, and raise intracellular potassium levels. To better quantify the intracellular and cell-surface populations of Kir2.1, we created fluorogen-activating protein fusions and for the first time used this technique to measure the cell-surface residency of a plasma membrane protein in yeast. Our experiments revealed that two α-arrestin effectors also control Kir2.1 localization. In particular, both the Rsp5 ubiquitin ligase and the protein phosphatase calcineurin facilitated the α-arrestin-mediated trafficking of Kir2.1. Together, our findings implicate α-arrestins in regulating an additional class of plasma membrane proteins and establish a new tool for dissecting the trafficking itinerary of any membrane protein in yeast.

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A metabolic puzzle: Consumption of C1 compounds and thiosulfate in Hyphomicrobium denitrificans XT

Koch

Flegler

et al. 2023

Biochimica et Biophysica Acta (BBA) - Bioenergetics

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Inwardly Rectifying Potassium Channel Kir2.1 and its “Kir-ious” Regulation by Protein Trafficking and Roles in Development and Disease

Hager

McAtee

Lesko

et al. 2022

Front. Cell Dev. Biol.

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Potassium (K+) homeostasis is tightly regulated for optimal cell and organismal health. Failure to control potassium balance results in disease, including cardiac arrythmias and developmental disorders. A family of inwardly rectifying potassium (Kir) channels helps cells maintain K+ levels. Encoded by KCNJ genes, Kir channels are comprised of a tetramer of Kir subunits, each of which contains two-transmembrane domains. The assembled Kir channel generates an ion selectivity filter for K+ at the monomer interface, which allows for K+ transit. Kir channels are found in many cell types and influence K+ homeostasis across the organism, impacting muscle, nerve and immune function. Kir2.1 is one of the best studied family members with well-defined roles in regulating heart rhythm, muscle contraction and bone development. Due to their expansive roles, it is not surprising that Kir mutations lead to disease, including cardiomyopathies, and neurological and metabolic disorders. Kir malfunction is linked to developmental defects, including underdeveloped skeletal systems and cerebellar abnormalities. Mutations in Kir2.1 cause the periodic paralysis, cardiac arrythmia, and developmental deficits associated with Andersen-Tawil Syndrome. Here we review the roles of Kir family member Kir2.1 in maintaining K+ balance with a specific focus on our understanding of Kir2.1 channel trafficking and emerging roles in development and disease. We provide a synopsis of the vital work focused on understanding the trafficking of Kir2.1 and its role in development.

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Fluorogen‐Activating Proteins as a powerful new imaging tool for quantitative protein trafficking studies in yeast

et al. 2021

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Recent advantages of genetically encoded fluorescent probes have led to the development of fluorogen‐activating proteins (FAPs). This technology has two components: a non‐fluorescent single chain antibody (SCA) that can be fused to a protein of interest and fluorogens, which in our case are derivatives of malachite green that are non‐fluorescent when free in solution. When the SCA and fluorogen bind, there is a 20,000‐fold fluorescent increase relative to unbound dye. The FAP‐technology has two major advantages to standard fluorescent probes: i) the fluorogen exists as either a membrane‐permeant or impermeant form and this allows for selective labeling of cell surface proteins and (2) since SCA does not fluoresce when it is not bound by dye and so there is no background fluorescence during the imaging of other markers until after the fluorogen is added. Although developed in yeast, this technology surprisingly has not been applied in this model system until our recent studies. In order to make this technology more available to the yeast community, we have optimized the SCA sequence for yeast expression, created a series for FAP‐tagged plasmid constructs, and generated a suite of intracellular localization markers to aid in cell biology studies in yeast. We further employ the FAP technology to study the trafficking of the G‐protein coupled receptor Ste3 and its regulation by the alpha‐arrestins, an important class of trafficking adaptor.

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Natalie Hager

Select α-arrestins control cell-surface abundance of the mammalian Kir2.1 potassium channel in a yeast model

A metabolic puzzle: Consumption of C1 compounds and thiosulfate in Hyphomicrobium denitrificans XT

Inwardly Rectifying Potassium Channel Kir2.1 and its “Kir-ious” Regulation by Protein Trafficking and Roles in Development and Disease

Fluorogen‐Activating Proteins as a powerful new imaging tool for quantitative protein trafficking studies in yeast

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