EB1 is required for primary cilia assembly in fibroblasts

EB1 is a small microtubule (MT)-binding protein that associates preferentially with MT plus ends and plays a role in regulating MT dynamics. EB1 also targets other MT-associated proteins to the plus end and thereby regulates interactions of MTs with the cell cortex, mitotic kinetochores, and different cellular organelles [1, 2]. EB1 also localizes to centrosomes and is required for centrosomal MT anchoring and organization of the MT network [3, 4]. We previously showed that EB1 localizes to the flagellar tip and proximal region of the basal body in Chlamydomonas[5], but the function of EB1 in the cilium/flagellum is unknown. We depleted EB1 from NIH3T3 fibroblasts by using siRNA and found that EB1 depletion causes a approximately 50% reduction in the efficiency of primary cilia assembly in serum-starved cells. Expression of dominant-negative EB1 also inhibited cilia formation, and expression of mutant dominant-negative EB1 constructs suggested that binding of EB1 to p150(Glued) is important for cilia assembly. Finally, expression of a C-terminal fragment of the centrosomal protein CAP350, which removes EB1 from the centrosome but not MT plus ends [6], also inhibited ciliogenesis. We conclude that localization of EB1 at the centriole/basal body is required for primary cilia assembly in fibroblasts.     

Phospholipase C in human endometrial fibroblasts and its regulation by estrogens

1. Stimulated inositolphospholipid turnover has been proposed as a signal-transducing mechanism in many cell types. It appears to be initiated by stimulation of hydrolysis of inositolphospholipid by a phospholipase C. 2. In human endometrial fibroblasts, estradiol was observed to cause sequential enhancement of [32P]phosphate incorporation into phosphatidic acid (PA) and phosphatidylinositol (PI), indicating an accelerating effect of estradiol on inositolphospholipid turnover. Specific 32P-radioactivity in the gamma-phosphate of ATP was increased in response to estradiol. Estrone or estriol were without any effects. 3. To investigate possible mechanisms by which estradiol activates a phospholipase C enzyme in the fibroblasts, the plasma membrane fraction isolated from the fibroblasts was exposed to estradiol in the presence of guanosine triphosphate (GTP) to detect inositol trisphosphate (IP3) production. The IP3 production was Ca2+ dependent, a dependency not affected by estradiol. 4. However, ATP decreased the Ca2+ concentration required for IP3 production in a dose-dependent manner; adenosine diphosphate (ADP), cytidine triphosphate (CTP) showed no effects. 5. These findings from cell and cell-free systems might suggest that estradiol stimulates a phospholipase C, as a result of enhancement of intracellular ATP synthesis, but not as a result of a direct effect on the enzyme molecule or direct activation of receptor-phospholipase C unit. 6. This may give us new insight into estrogen-stimulated cellular phenomenon through some mechanisms other than that classically associated with the action of estrogen.     

High expression of the taurine transporter TauT in primary cilia of NIH3T3 fibroblasts

Taurine, present in high concentrations in various mammalian cells, is essential for regulation of cell volume, cellular oxidative status as well as the cellular Ca2+ homeostasis. Cellular taurine content is a balance between active uptake through the saturable, Na(+)-dependent taurine transporter TauT, and passive release via a volume-sensitive leak pathway. Here we demonstrate that: (i) TauT localizes to the primary cilium of growth-arrested NIH3T3 fibroblasts, (ii) long-term exposure to TNF(alpha) or hypertonic sucrose medium, i.e., growth medium supplemented with 100 mM sucrose, increases ciliary TauT expression and (iii) long-term exposure to hypertonic taurine medium, i.e., growth medium supplemented with 100 mM taurine, reduces ciliary TauT expression. These results point to an important role of taurine in the regulation of physiological processes located to the primary cilium.     

Frequency of occurrence and position of cilia in fibroblasts of the periodontal ligament of the mouse incisor

Solitary cilia occur in motile as well as in non-motile fibroblasts of the peridontal ligament. The cells which moved with the erupting incisor are bipolar and oriented with their long axes parallel to the tooth surface. In cross section these cells have a flattened appearance. Cilia are localized in close vicinity to the nuclear area and show a definite orientation with respect to the transverse cell axis. The frequency of occurrence of this organelle was estimated from the percentage of diplosomes containing a basal body. Analysis of the composition of the paired structures indicated that at least 70 per cent of the fibroblasts are ciliated. The frequency of cilia in motile fibroblasts does not differ from that in non-motile cells suggesting that the presence of this organelle is not directly associated with cell locomotion.     

Oxidative stress response of human fibroblasts and endometrial mesenchymal stem cells

Human mesenchymal stem cells are a promising cell source for tissue engineering. During transplantation, they may be subjected to oxidative stress due to unfavorable cellular microenvironment characterized by an increased level of reactive oxygen species. Recently, we have demonstrated that oxidative stress response of human mesenchymal stem cells derived from endometrium (hMESCs) depends on the oxidizer concentration. The duration of cell treatment with an oxidizer also may play an important role. In this study, we investigated the dependence of the cell response on H₂O₂ treatment duration. The effects of high H₂O₂ doses on hMESCs and human lung embryonic fibroblasts were compared. In both cell types, H₂O₂ treatment for 60 min caused multiphase cell cycle arrest, with dose-dependent cell death occurring equally in all phases of the cell cycle. However, the cell death dynamics in hMESCs and fibroblasts were different. Interestingly, in both cell types, shortening of H₂O₂ treatment from 60 to 10 min induced growth retardation, G1-phase cell accumulation, and cell size increase. Collectively, these findings suggest that there is induction of premature senescence. Thus, shortening of oxidative stress induced in human endometrial stem cells and embryonic fibroblasts by high H₂O₂ doses enables one to modulate cellular response as both cell death and premature senescence.     

When cilia go bad: cilia defects and ciliopathies

Defects in the function of cellular organelles such as peroxisomes, lysosomes and mitochondria are well-known causes of human diseases. Recently, another organelle has also been added to this list. Cilia--tiny hair-like organelles attached to the cell surface--are located on almost all polarized cell types of the human body and have been adapted as versatile tools for various cellular functions, explaining why cilia-related disorders can affect many organ systems. Several molecular mechanisms involved in cilia-related disorders have been identified that affect the structure and function of distinct cilia types.     

Transmembrane currents in frog olfactory cilia

Summary We have measured transmembrane currents in intact single cilia from frog olfactory receptor neurons. A single cilium on a neuron was sucked into a patch pipette, and a high-resistance seal was formed near the base of the cilium. Action potentials could be induced by applying suction or a voltage ramp to the ciliary membrane. A transient current was seen in some cells on stimulation with odorants. After excision from the cell, most of the cilia showed increased conductance in a bath containing cAMP, indicating that the cytoplasmic face of the ciliary membrane was accessible to the bath. The estimated resistance of a single cilium was surprisingly low.     

Alignment of cilia in immotile-cilia syndrome

Alignment of cilia in nasal epithelial cells from eight human subjects suffering from immotile-cilia syndrome was compared with that of cells from five control subjects. Individual cilia were assessed according to the orientation of their basal feet. The range of orientation of basal feet on a single cell varied from 26 degrees to 261 degrees and 54 degrees to 275 degrees in controls and patients respectively. Less than 10% of the cells from each group supported cilia that were aligned randomly. Alignment was worse in subjects with immotile-cilia syndrome but this could well have been due to secondary characteristics of the disease, such as common viral infection. Very accurate alignment of mucus-propelling cilia may be unnecessary. Measurements from control subjects and some invertebrates suggest that ranges of 140 degrees are common and do not seriously impair mucus propulsion.