An SLC12A9-dependent ion transport mechanism maintains lysosomal osmolarity

The spectrum of lysosomal stress and damage responses: from mechanosensing to inflammation

Cells and tissues turn over their aged and damaged components in order to adapt to a changing environment and maintain homeostasis. These functions rely on lysosomes, dynamic and heterogeneous organelles that play essential roles in nutrient redistribution, metabolism, signaling, gene regulation, plasma membrane repair, and immunity. Because of metabolic fluctuations and pathogenic threats, lysosomes must adapt in the short and long term to maintain functionality. In response to such challenges, lysosomes deploy a variety of mechanisms that prevent the breaching of their membrane and escape of their contents, including pathogen-associated molecules and hydrolases. While transient permeabilization of the lysosomal membrane can have acute beneficial effects, supporting inflammation and antigen cross-presentation, sustained or repeated lysosomal perforations have adverse metabolic and transcriptional consequences and can lead to cell death. This review outlines factors contributing to lysosomal stress and damage perception, as well as remedial processes aimed at addressing lysosomal disruptions. We conclude that lysosomal stress plays widespread roles in human physiology and pathology, the understanding and manipulation of which can open the door to novel therapeutic strategies.

Lysosomal Ion Channels and Transporters: Recent Findings, Therapeutic Potential, and Technical Approaches

In recent years, there has been a growing interest in lysosomal ion channels and transporters due to their critical role in maintaining lysosomal function and their involvement in a variety of diseases, particularly lysosomal storage diseases, cancer, and neurodegenerative disorders. Recent advancements in research techniques, including manual and automated patch clamp (APC) electrophysiology, solid-supported membrane-based electrophysiology (SSME), and fluorescence-based ion imaging, have further enhanced our ability to investigate lysosomal ion channels and transporters in both physiological and pathological conditions, spurring drug discovery efforts. Several pharmaceutical companies are now developing therapies aimed at modulating these channels and transporters to improve lysosomal function in disease. Small molecules targeting channels like transient receptor potential mucolipin (TRPML) 1 and TMEM175, as well as drugs modulating lysosomal pH, are currently in preclinical and clinical development. This review provides an overview of the role of lysosomal ion channels and transporters in health and disease, highlights the cutting-edge techniques used to study them, and discusses the therapeutic potential of targeting these channels and transporters in the treatment of various diseases. Furthermore, in addition to summarizing recent discoveries, we contribute novel functional data on cystinosin, TRPML1, and two-pore channel 2 (TPC2), utilizing both SSME and APC approaches.

Don't Be Surprised When These Surprise You: Some Infrequently Studied Sphingoid Bases, Metabolites, and Factors That Should Be Kept in Mind During Sphingolipidomic Studies

Sphingolipidomic mass spectrometry has provided valuable information-and surprises-about sphingolipid structures, metabolism, and functions in normal biological processes and disease. Nonetheless, many noteworthy compounds are not routinely determined, such as the following: most of the sphingoid bases that mammals biosynthesize de novo other than sphingosine (and sometimes sphinganine) or acquire from exogenous sources; infrequently considered metabolites of sphingoid bases, such as N-(methyl)n-derivatives; "ceramides" other than the most common N-acylsphingosines; and complex sphingolipids other than sphingomyelins and simple glycosphingolipids, including glucosyl- and galactosylceramides, which are usually reported as "monohexosylceramides". These and other subspecies are discussed, as well as some of the circumstances when they are likely to be seen (or present and missed) due to experimental conditions that can influence sphingolipid metabolism, uptake from the diet or from the microbiome, or as artifacts produced during extraction and analysis. If these compounds and factors are kept in mind during the design and interpretation of lipidomic studies, investigators are likely to be surprised by how often they appear and thereby advance knowledge about them.

PIKFYVE inhibition induces endosome- and lysosome-derived vacuole enlargement via ammonium accumulation

FYVE-type zinc finger-containing phosphoinositide kinase (PIKFYVE), which is essential for phosphatidylinositol 3,5-bisphosphate [PtdIns(3,5)P2] production, is an important regulator of lysosomal homeostasis. PIKFYVE dysfunction leads to cytoplasmic vacuolization; however, the underlying mechanism remains unknown. In this study, we explored the cause of vacuole enlargement upon PIKFYVE inhibition in DU145 prostate cancer cells. Enlargement of vacuoles upon PIKFYVE inhibition required glutamine and its metabolism by glutaminases. Addition of ammonia, a metabolite of glutamine, was sufficient to enlarge vacuoles via PIKFYVE inhibition. Moreover, PIKFYVE inhibition led to intracellular ammonium accumulation. Endosome-lysosome permeabilization resulted in ammonium leakage from the cells, indicating ammonium accumulation in the endosomes and lysosomes. Ammonium accumulation and vacuole expansion were suppressed by the lysosomal lumen neutralization. It is therefore assumed that PIKFYVE inhibition interferes with the efflux of NH4+, which formed through protonation of NH3 in the lysosomal lumen, leading to osmotic swelling of vacuoles. Notably, glutamine or ammonium is required for PIKFYVE inhibition-induced suppression of lysosomal function and autophagic flux. In conclusion, this study shows that PIKFYVE inhibition disrupts lysosomal homeostasis via ammonium accumulation.