A novel role for the chloride intracellular channel protein Clic5 in ciliary function

Primary cilia and cancer: a tale of many faces

Cilia are microtubule-based sensory organelles which project from the cell surface, enabling detection of mechanical and chemical stimuli from the extracellular environment. It has been shown that cilia are lost in some cancers, while others depend on cilia or ciliary signaling. Several oncogenic molecules, including tyrosine kinases, G-protein coupled receptors, cytosolic kinases, and their downstream effectors localize to cilia. The Hedgehog pathway, one of the most studied ciliary-signaling pathways, is regulated at the cilium via an interplay between Smoothened (an oncogene) and Patched (a tumor suppressor), resulting in the activation of pro-survival programs. Interestingly, cilia loss can result in resistance to Smoothened-targeting drugs and increased cancer cell survival. On the other hand, kinase inhibitor-resistant and chemoresistant cancers have increased cilia and increased Hedgehog pathway activation, and suppressing cilia can overcome this resistance. How cilia regulate cancer is therefore context dependent. Defining the signaling output of cilia-localized oncogenic pathways could identify specific targets for cancer therapy, including the cilium itself. Increasing evidence implicates cilia in supporting several hallmarks of cancer, including migration, invasion, and metabolic rewiring. While cell cycle cues regulate the biogenesis of cilia, the absence of cilia has not been conclusively shown to affect the cell cycle. Thus, a complex interplay between molecular signals, phosphorylation events and spatial regulation renders this fascinating organelle an important new player in cancer through roles that we are only starting to uncover. In this review, we discuss recent advances in our understanding of cilia as signaling platforms in cancer and the influence this plays in tumor development.

The Glutamine Synthetases Are Required for Sensory Hair Cell Formation and Auditory Function in Zebrafish

The development of sensory hair cells (HCs) is closely linked to hearing loss. There are still many unidentified genes that may play a crucial role in HC development and function. Glutamine synthetase, Glul, is expressed in sensory hair cells and auditory organs. However, the role of the Glul gene family in the auditory system remains largely unexplored. This study aims to investigate the function of the Glul gene family in the auditory system. The expression patterns of the glul gene family were examined via in situ hybridization in zebrafish embryos. It was revealed that the expression of glula occurred in the otic vesicle, while glulb was expressed in the neuromast. In contrast, glulc did not exhibit any discernible signal. glula loss of function caused abnormal otolith formation and reduced hair cell number in otic vesicles, while glulb knockdown caused a decrease in HC number in both neuromasts and otic vesicles and impaired auditory function. Furthermore, we found that the knockdown of glulb induces apoptosis of hair cells. Transcriptomic analysis of zebrafish with glula and glulb knockdown revealed significant alterations in the expression of many genes associated with auditory organs. The current study sheds light on the requirement of glula and glulb in zebrafish hair cell formation and auditory function.

Kif21a deficiency leads to impaired glomerular filtration barrier function

The renal glomerulus represents the major filtration body of the vertebrate nephron and is responsible for urine production and a number of other functions such as metabolic waste elimination and the regulation of water, electrolyte and acid-base balance. Podocytes are highly specialized epithelial cells that form a crucial part of the glomerular filtration barrier (GFB) by establishing a slit diaphragm for semipermeable plasma ultrafiltration. Defects of the GFB lead to proteinuria and impaired kidney function often resulting in end-stage renal failure. Although significant knowledge has been acquired in recent years, many aspects in podocyte biology are still incompletely understood. By using zebrafish as a vertebrate in vivo model, we report a novel role of the Kinesin-like motor protein Kif21a in glomerular filtration. Our studies demonstrate specific Kif21a localization to the podocytes. Its deficiency resulted in altered podocyte morphology leading to podocyte foot process effacement and altered slit diaphragm formation. Finally, we proved considerable functional consequences of Kif21a deficiency by demonstrating a leaky GFB resulting in severe proteinuria. Conclusively, our data identified a novel role of Kif21a for proper GFB function and adds another piece to the understanding of podocyte architecture and regulation.