Abstract
MCRS1 is involved in multiple cellular activities, including mitotic spindle assembly, mTOR signaling and tumorigenesis. Although MCRS1 has been reported to bind to the dynein regulator NDE1, a functional interaction between MCRS1 and cytoplasmic dynein remains unaddressed. Here, we demonstrate that MCRS1 is required for dynein-dependent cargo transport to the centrosome and also plays a role in primary cilium formation. MCRS1 localized to centriolar satellites. Knockdown of MCRS1 resulted in a dispersion of centriolar satellites whose establishment depends on cytoplasmic dynein. By contrast, NDE1 was not necessary for the proper distribution of centriolar satellites, indicating a functional distinction between MCRS1 and NDE1. Unlike NDE1, MCRS1 played a positive role for the initiation of ciliogenesis, possibly through its interaction with TTBK2. Zebrafish with homozygous mcrs1 mutants exhibited a reduction in the size of the brain and the eye due to excessive apoptosis. In addition, mcrs1 mutants failed to develop distinct layers in the retina, and showed a defect in melatonin-induced aggregation of melanosomes in melanophores. These phenotypes are reminiscent of zebrafish dynein mutants. Reduced ciliogenesis was also apparent in the olfactory placode of mcrs1 mutants. Collectively, our findings identify MCRS1 as a dynein-interacting protein critical for centriolar satellite formation and ciliogenesis.
Highlights
Cytoplasmic dynein is a minus-end-directed microtubule motor which performs critical functions in a wide range of cellular activities including organelle positioning, mitosis and cell migration[13,14,15]
We examined the subcellular localization of Microspherule protein 1 (MCRS1) in telomerase-immortalized human retinal pigmented epithelial (RPE1) cells
We observed that anti-MCRS1 antibody stains scattered particles around the centrosome which colocalized with the centriolar satellite marker Pericentriolar material 1 (PCM1)
Summary
Cytoplasmic dynein is a minus-end-directed microtubule motor which performs critical functions in a wide range of cellular activities including organelle positioning, mitosis and cell migration[13,14,15]. There is accumulating evidence that centriolar satellites play roles in the recruitment and assembly of centrosomal proteins. Dynamic yet consistent distribution patterns of centriolar satellites during the progression of cell cycle suggest that the interaction between centriolar satellites and motor proteins are tightly controlled. It is largely unclear how specific dynein pools are assigned for centriolar satellites and how their activities are regulated in accordance with the assembly of centrosomal or ciliopathy protein complexes. We demonstrate that MCRS1 interacts with the dynein intermediate chain DYNC1I1, and plays an essential role in both the establishment of centriolar satellites and the initiation of primary cilium assembly
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