Abstract
Lipid droplets (LD) are affected in multiple human disorders. These highly dynamic organelles are involved in many cellular roles. While their intracellular dispersion is crucial to ensure their function and other organelles-contact, underlying mechanisms are still unclear. Here we show that Spastin, one of the major proteins involved in Hereditary Spastic Paraplegia (HSP), controls LD dispersion. Spastin depletion in zebrafish affects metabolic properties and organelle dynamics. These functions are ensured by a conserved complex set of splice variants. M1 isoforms determine LD dispersion in the cell by orchestrating endoplasmic reticulum (ER) shape along microtubules (MTs). To further impact LD fate, Spastin modulates transcripts levels and subcellular location of other HSP key players, notably Seipin and REEP1. In pathological conditions, mutations in human Spastin M1 disrupt this mechanism and impacts LD network. Spastin depletion influences not only other key proteins but also modulates specific neutral lipids and phospholipids, revealing an impact on membrane and organelle components. Altogether our results show that Spastin and its partners converge in a common machinery that coordinates LD dispersion and ER shape along MTs. Any alteration of this system results in HSP clinical features and impacts lipids profile, thus opening new avenues for novel biomarkers of HSP.
Highlights
Lipid droplets (LDs) have long been considered as inert organelles, limited to fat storage
Our results provide evidence that Spastin and other Hereditary Spastic Paraplegia (HSP)-related proteins synchronize the shaping of endoplasmic reticulum (ER) and MTs stability to determine the dispersion of LDs in the cell, converging in comparable clinical features in case of alteration
The conservation of the two initiator sites of the gene has been confirmed in fish [48], suggesting that the different transcripts of Spastin play a key role through evolution
Summary
Lipid droplets (LDs) have long been considered as inert organelles, limited to fat storage. A wide range of evidence recently highlighted the multiple functions of LDs in energy supply, embryogenesis, reactive oxygen species management or pathogen invasion [1,2,3,4,5,6]. Yeast, plants and animals, LDs are not limited to adipose tissue in mammals. To face cell-specific needs, LDs adapt in size and number through complex machineries [8], comparable to mitochondrial dynamics. The proteins and mechanisms underlying these pathways are partially elucidated [9]. LDs can adapt their caliber through fusion and fission [15], notably via the role of cell death-inducing DFF45-like effector family proteins [16].
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