The recycling endosome is required for transport of retrograde toxins

McKenzie, Jenna Elyse

01 December 2009

Shiga toxin and cholera toxin are members of the AB5 family of protein exotoxins. The A subunit is the enzymatic subunit, whereas the pentameric B subunit binds cell surface receptors and carries the A subunit to the endoplasmic reticulum (ER) where it can be released into the cytosol. The B-subunits (STxB or CTxB) mediate toxin traffic along the retrograde pathway from the plasma membrane to the ER via early/recycling endosomes and the Golgi apparatus. It is unknown if STxB requires transport through the Golgi, or if it is just kinetically favorable. It is also unknown if the recycling endosome (RE) plays a role in the retrograde transport of STxB and CTxB. The first goal of this dissertation research was to demonstrate that transport through the Golgi is required for STxB to reach the ER. Using aluminum fluoride treatment, a simple temperature block, and cytoplast studies, I show that Golgi transport is necessary for STxB to reach the ER. The second goal of this dissertation research was to tease apart how STxB and CTxB move through early and recycling endosomes as well as elucidate a mechanism of how STxB exits endosomes en route to the Golgi. The role of the RE in STxB and CTxB transport is unclear. I used transferrin colocalization and temperature block studies to show that STxB and CTxB traffic through the RE. I then used HRP ablation of the RE to show that STxB requires the RE to reach the Golgi. I also examined the role of an RE-specific protein, EHD1, in exit of STxB from the RE. EHD1 has been previously shown to regulate recycling Tfn exit from the RE but its role in STxB transport is unknown. Expression of a dominant negative form of EHD1 arrested STxB at the RE and prevented it from reaching the Golgi. Together, these results suggest that STxB and CTxB transit the RE, STxB requires a functional RE for normal retrograde trafficking, and that STxB exit from the RE is regulated by EHD1.

cholera toxin

EHD1

endosomes

membrane transport

recycling endosome

Shiga toxin

Pharmacology

pH changes localized to the surface of membrane transport proteins

Johnson, Danielle Elaine

06 1900

Intracellular pH was monitored at the cytosolic surface of plasma membrane solute transporters (Na+/H+/nucleoside co-transporters, or Cl-/HCO3- exchangers), using pH-sensitive fluorescent proteins (FPs), dual emission green FP (deGFP4) and a monomeric red FP Nectarine (mNect), whose development and characterization are also reported here. Human concentrative nucleoside transporter, hCNT3, mediates Na+/H+/nucleoside co-transport. We describe a new approach to monitor H+/uridine co-transport in HEK293 cells. pH changes at the intracellular surface of hCNT3 were monitored by fusing mNect to the cytoplasmic N-terminus of hCNT3 (mNect.hCNT3) or an inactive hCNT3 mutant (mNect.hCNT3-F563C). Cells were incubated at the permissive pH for H+-coupled nucleoside transport, pH 5.5, under both Na+-free and Na+-containing conditions. In mNect.hCNT3-expressing cells (but not under negative control conditions) the rate of acidification increased in media containing 0.5 mM uridine, providing the first direct evidence for H+-coupled uridine transport. At pH 5.5, there was no significant difference in uridine transport rates (coupled H+ flux) in the presence or absence of Na+. This suggests that in acidic Na+-containing conditions, 1 Na+ and 1 H+ are transported/uridine molecule, while in acidic Na+-free conditions, 1 H+ alone is transported/uridine. In acid environments, including renal proximal tubule and intestine, H+/nucleoside co-transport may drive nucleoside accumulation by hCNT3. Microdomains, discrete regions of altered cytosolic solute concentration, are enhanced by rapid solute transport and slow diffusion rates. pH-regulatory membrane transporters, like the Cl-/HCO3- exchanger AE1, could nucleate H+ microdomains, since AE1 has a rapid transport rate and cytosolic H+ diffusion is slow. As AE1 drives Cl-/HCO3- exchange, differences in pH, near and remote from AE1, were monitored simultaneously by deGFP4 fused to AE1 (deGFP4.AE1) and mNect.hCNT3-F563C. deGFP4.AE1-mNect.hCNT3-F563C distance was varied by co-expression of different amounts of the two proteins in HEK293 cells. As the deGFP4.AE1-mNect.hCNT3-F563C distance increased, mNect.hCNT3-F563C detected the cytosolic pH change with a time delay and reduced rate of pH change, compared to deGFP4.AE1. Carbonic anhydrase activity was essential for H+ microdomain formation. H+ diffusion along the plasma membrane was 60-fold slower than to the cytosolic ER-surface. During physiological HCO3- transport, a H+ microdomain 0.3 µm in diameter develops around AE1, which will affect nearby pH-sensitive processes.

pH regulation

membrane transport

anion exchange

carbonic anhydrase

bicarbonate transport metabolon

nucleoside transport

fluorescent proteins

A Study of Electrogenic Transient and Steady-state Cotransporter Kinetics: Investigations with the Na+/Glucose Transporter SGLT1

Krofchick, Daniel

31 August 2012

Significant advancements in the field of membrane protein crystallography have provided in recent years invaluable images of transporter structures. These structures, however, are static and require complementary kinetic insight to understand how their mechanisms work. Electrophysiological studies of transporters permit the high quality kinetic measurements desired, but there are significant difficulties involved in analyzing and interpreting the data. Current methods allow a variety of kinetic parameters to be measured but there is a disconnect between these parameters and a fundamental understanding of the carrier. The intent of this research was to contribute new tools for studying the electrogenic kinetics of membrane transport proteins, to understand the link between these kinetics and the carrier, and to ultimately understand the mechanisms involved in transport. In this vein, two projects are explored covering two important kinetic time domains, transient and steady-state. The transient project studies the conformational changes of the unloaded carrier of SGLT1 through a multi-exponential analysis of the transient currents. Crystal structures have potentially identified a gated rocker-switch mechanism and the transient kinetics are used to support and study this kinetically. A protocol taking advantage of multiple holding potentials is used to measure the decay time constants and charge movements for voltage jumps from both hyperpolarizing and depolarizing directions. These directional measurements provide insight into the arrangement of the observed transitions through directional inequalities in charge movement, by considering the potential for a slow transition to hide a faster one. Ultimately, four carrier decays are observed that align with the gated rocker-switch mechanism and can be associated one-to-one with the movement of a gate and pore on each side of the membrane. The steady-state project considers a general theoretical model of transporter cycling. Recursive patterns are identified in the steady-state velocity equation that lead to a broad understanding of its geometric properties as a function of voltage and substrate concentration. This results in a simple phenomenological method for characterizing the I–V curves and for measuring the kinetics of rate limiting patterns in the loop, which we find are the basic structures revealed by the steady-state velocity.

membrane transport

electrophysiology

enzyme kinetics

two-electrode voltage-clamp

SGLT1

0786

0487

A Study of Electrogenic Transient and Steady-state Cotransporter Kinetics: Investigations with the Na+/Glucose Transporter SGLT1

Krofchick, Daniel

31 August 2012

Significant advancements in the field of membrane protein crystallography have provided in recent years invaluable images of transporter structures. These structures, however, are static and require complementary kinetic insight to understand how their mechanisms work. Electrophysiological studies of transporters permit the high quality kinetic measurements desired, but there are significant difficulties involved in analyzing and interpreting the data. Current methods allow a variety of kinetic parameters to be measured but there is a disconnect between these parameters and a fundamental understanding of the carrier. The intent of this research was to contribute new tools for studying the electrogenic kinetics of membrane transport proteins, to understand the link between these kinetics and the carrier, and to ultimately understand the mechanisms involved in transport. In this vein, two projects are explored covering two important kinetic time domains, transient and steady-state. The transient project studies the conformational changes of the unloaded carrier of SGLT1 through a multi-exponential analysis of the transient currents. Crystal structures have potentially identified a gated rocker-switch mechanism and the transient kinetics are used to support and study this kinetically. A protocol taking advantage of multiple holding potentials is used to measure the decay time constants and charge movements for voltage jumps from both hyperpolarizing and depolarizing directions. These directional measurements provide insight into the arrangement of the observed transitions through directional inequalities in charge movement, by considering the potential for a slow transition to hide a faster one. Ultimately, four carrier decays are observed that align with the gated rocker-switch mechanism and can be associated one-to-one with the movement of a gate and pore on each side of the membrane. The steady-state project considers a general theoretical model of transporter cycling. Recursive patterns are identified in the steady-state velocity equation that lead to a broad understanding of its geometric properties as a function of voltage and substrate concentration. This results in a simple phenomenological method for characterizing the I–V curves and for measuring the kinetics of rate limiting patterns in the loop, which we find are the basic structures revealed by the steady-state velocity.

membrane transport

electrophysiology

enzyme kinetics

two-electrode voltage-clamp

SGLT1

0786

0487

Phospholipidmembranen auf mikroporösen Substraten: in situ Bildung elektrochemischer Gradienten / Phospholipid membranes on microporous substrates: in situ generation of electrochemical gradients

Frese, Daniel

25 June 2013

No description available.

540

Pore-spanning membranes

Electrochemical gradients

Membrane transport

Nigericin

Bacteriorhodopsin

Porous silicon substrates

Chemie  (PPN62138352X)

pH changes localized to the surface of membrane transport proteins

Johnson, Danielle Elaine

Unknown Date

No description available.

pH regulation

membrane transport

anion exchange

carbonic anhydrase

bicarbonate transport metabolon

nucleoside transport

fluorescent proteins

Systematic characterization of Rab GTPase cell type expression and subcellular localization in Drosophila melanogaster

Dunst, Sebastian

08 June 2015

The Rab family of small GTPases orchestrates intracellular endomembrane transport through the recruitment of diverse effector proteins. Since its first discovery in 1987, almost 70 Rab proteins have been identified in humans to date and their perturbed function is implicated in several hereditary and acquired diseases. In this Ph.D. thesis, I systematically characterize cell type expression and subcellular localization of all Rab proteins present in Drosophila melanogaster utilizing a genetic resource that represents a major advance for studying membrane trafficking in vivo: the ’Drosophila YRab library’. This collection comprises 27 different D. melanogaster knock-in lines that harbor YFPMyc fusions to each Rab protein, referred to as YRab. For each YRab, I present a comprehensive data set of quantitative and qualitative expression profiles across six larval and adult tissues that include 23 annotated cell types. The whole image data set, along with its annotations, is publicly accessible through the FLYtRAB database that links to CATMAID for online browsing of tissues. I exploit this data set to address basic cell biological questions. i) How do differentiating cells reorganize their transport machinery to perform cell type-specific functions? My data indicates that qualitative and quantitative changes in YRab protein expression facilitate the functional specialization of differentiated cells. I show that about half of the YRab complement is ubiquitously expressed across D. melanogaster tissues, while others are missing from some cell types or reflect strongly restricted cell type expression, e.g. in the nervous system. I also depict that relative YRab expression levels change as cells differentiate. ii) Are specific Rab proteins dedicated to apical or basolateral protein transport in all epithelia? My data suggests that the endomembrane architecture reflects specific tasks performed by particular epithelial tissues, rather than a generalized apicobasal organization. I demonstrate that there is no single YRab that is similarly polarized in all epithelia. Rather, different epithelial tissues dynamically polarize the subcellular localization of many YRab compartments, producing membrane trafficking architectures that are tissue- and stage-specific. I further discuss YRab cell type expression and subcellular localization in the context of Rab family evolution. I report that the conservation of YRab protein expression across D. melanogaster cell types reflects their evolutionary conservation in eukaryotes. In addition, my data supports the assumption that the flexible deployment of an expanded Rab family triggered cell differentiation in metazoans. The FLYtRAB database and the ’Drosophila Rab Library’ are complementary resources that facilitate functional predictions based on YRab cell type expression and subcellular localization, and to subsequently test them by genetic loss-of-function experiments. I demonstrate the power of this approach by revealing new and redundant functions for Rab23 and Rab35 in wing vein patterning. My data collectively highlight that in vivo studies of endomembrane transport pathways in different D. melanogaster cell types is a valuable approach to elucidate functions of Rab family proteins and their potential implications for human disease.

Membran Transport

Rab GTPase

Drosophila melanogaster

Membrane transport

Rab GTPase

Drosophila melanogaster

ddc:570

rvk:WE 5000

PET studies of the dopamine system in relation to cognitive functions /

Erixon-Lindroth, Nina,

January 2007

Diss. (sammanfattning) Stockholm : Karolinska institutet, 2007. / Härtill 4 uppsatser.

Distribution of serotonin receptors and transporters in the human brain: implications for psychosis /

Varnäs, Katarina,

January 2005

Diss. (sammanfattning) Stockholm : Karolinska institutet, 2005. / Härtill 6 uppsatser.

Pet imaging of two monoaminergic neurotransmitter systems in brain : studies of the norepinephrine transporter and dopamine D₂ receptor /

Seneca, Nicholas,

January 2006

Diss. (sammanfattning) Stockholm : Karolinska institutet, 2006. / Härtill 5 uppsatser.