Abstract
The Golgi apparatus plays a central role in processing and sorting proteins and lipids in eukaryotic cells. Golgi compartments constantly exchange material with each other and with other cellular components, allowing them to maintain and reform distinct identities despite dramatic changes in structure and size during cell division, development, and osmotic stress. We have developed three minimal models of membrane and protein exchange in the Golgi-a discrete, stochastic model, a continuous ordinary differential equation model, and a continuous stochastic differential equation model-each based on two fundamental mechanisms: vesicle-coat-mediated selective concentration of cargoes and soluble N-ethylmaleimide-sensitive factor attachment protein receptor (SNARE) proteins during vesicle formation and SNARE-mediated selective fusion of vesicles. By exploring where the models differ, we hope to discover whether the discrete, stochastic nature of vesicle-mediated transport is likely to have appreciable functional consequences for the Golgi. All three models show similar ability to restore and maintain distinct identities over broad parameter ranges. They diverge, however, in conditions corresponding to collapse and reassembly of the Golgi. The results suggest that a continuum model provides a good description of Golgi maintenance but that considering the discrete nature of vesicle-based traffic is important to understanding assembly and disassembly of the Golgi. Experimental analysis validates a prediction of the models that altering guanine nucleotide exchange factor expression levels will modulate Golgi size.
Highlights
Membrane trafficking is critical to cellular physiology and pathophysiology
The Golgi apparatus plays a central role in processing and sorting proteins and lipids in eukaryotic cells
We have developed three minimal models of membrane and protein exchange in the Golgi—a discrete, stochastic model, a continuous ordinary differential equation model, and a continuous stochastic differential equation model—each based on two fundamental mechanisms: vesicle-coatmediated selective concentration of cargoes and soluble N-ethylmaleimide-sensitive factor attachment protein receptorSNAREproteins during vesicle formation and SNARE-mediated selective fusion of vesicles
Summary
Membrane trafficking is critical to cellular physiology and pathophysiology. Over one quarter of all proteins in eukaryotic cells interact with compartments in the early secretory pathway that mediate protein folding, quality control, glycosylation, proteolytic activation, and localization1–4͔. Golgi compartments engage in a constant flux of material between each other, the endoplasmic reticulumER, and other cellular components through exchange of small trafficking vesicles. This exchange of material allows Golgi compartments to establish, maintain, and reform distinct identities characterized by the presence of distinctive sets of protein markers despite dramatic changes in structure and size during cell division, development, and osmotic stress6–9͔. The Golgi is capable of self-assembling de novo from the ER10͔ It is, not well understood precisely how the Golgi performs these activities or which components of the Golgi are minimally necessary to allow for compartment assembly and maintenance
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