Cochlear outer hair cell electromotility enhances organ of Corti motion on a cycle-by-cycle basis at high frequencies in vivo.

Mammalian hearing depends on an amplification process involving prestin, a voltage-sensitive motor protein that enables cochlear outer hair cells (OHCs) to change length and generate force. However, it has been questioned whether this prestin-based somatic electromotility can operate fast enough in vivo to amplify cochlear vibrations at the high frequencies that mammals hear. In this study, we measured sound-evoked vibrations from within the living mouse cochlea and found that the top and bottom of the OHCs move in opposite directions at frequencies exceeding 20 kHz, consistent with fast somatic length changes. These motions are physiologically vulnerable, depend on prestin, and dominate the cochlea's vibratory response to high-frequency sound. This dominance was observed despite mechanisms that clearly low-pass filter the in vivo electromotile response. Low-pass filtering therefore does not critically limit the OHC's ability to move the organ of Corti on a cycle-by-cycle basis. Our data argue that electromotility serves as the primary high-frequency amplifying mechanism within the mammalian cochlea.

Susceptibility of outer hair cells to cholesterol chelator 2-hydroxypropyl-ß-cyclodextrine is prestin-dependent.

Niemann-Pick type C1 disease (NPC1) is a fatal genetic disorder caused by impaired intracellular cholesterol trafficking. Recent studies reported ototoxicity of 2-hydroxypropyl- ß-cyclodextrin (HPßCD), a cholesterol chelator and the only promising treatment for NPC1. Because outer hair cells (OHCs) are the only cochlear cells affected by HPßCD, we investigated whether prestin, an OHC-specific motor protein, might be involved. Single, high-dose administration of HPßCD resulted in OHC death in prestin wildtype (WT) mice whereas OHCs were largely spared in prestin knockout (KO) mice in the basal region, implicating prestin's involvement in ototoxicity of HPßCD. We found that prestin can interact with cholesterol in vitro, suggesting that HPßCD-induced ototoxicity may involve disruption of this interaction. Time-lapse analysis revealed that OHCs isolated from WT animals rapidly deteriorated upon HPßCD treatment while those from prestin-KOs tolerated the same regimen. These results suggest that a prestin-dependent mechanism contributes to HPßCD ototoxicity.

[Genetic complexity of ciliopathies and novel genes identification]. / Complexité génétique des ciliopathies et identification de nouveaux gènes.

Ciliopathies are a large group of human disorders caused by dysfunction of primary or motile cilia and unified by their overlapping clinical features (brain malformations, retinal dystrophy, cystic kidney disease, liver fibrosis and skeletal abnormalities). Ciliopathies are mendelian disorders with prominent genetic heterogeneity and marked allelism between different clinical entities, which are in part explained by the recently identified functional modules and multi-protein complexes formed by ciliopathy-associated gene products. The current review provides an updated snapshot of this complex evolving field, highlighting the key phenotypic features and causative genes for commonly-studied ciliopathies and summarizing our emerging understanding of the correlations between the functions of subgroups of genes and clinical sub-types of ciliopathies. Using the example of Joubert syndrome, a ciliopathy characterized by a distinctive hindbrain malformation and caused by mutations in more than 20 different genes, this work also reviews the principal methods used for new gene identification, including candidate gene approaches, homozygosity mapping as well as high throughput next-generation and exome sequencing.

[Non-ciliary functions of cilia proteins]. / De nouvelles fonctions extraciliaires pour les protéines ciliaires - quelles conséquences sur l'apparition de ciliopathies ?

Cilia proteins have long been characterized for their role in cilia formation and function, and their implications in ciliopathies. However, several cellular defects induced by cilia proteins deregulation suggest that they could have non-ciliary roles. Indeed, several non-ciliary functions have been recently characterized for cilia proteins including roles in intra-cellular and in vesicular transport, in spindle orientation or in the maintenance of genomic stability. These observations thus raise the crucial question of the contribution of non-ciliary functions of cilia proteins to the pathological manifestations associated with ciliopathies such as polycystic kidney disease.

Occurrence of thrombosis in congenital thrombocytopenic disorders: a critical annotation of the literature.

Patients with a low platelet count are prone to bleeding. The occurrence of a thrombotic event in congenital thrombocytopenic patients is rare and puzzling. At least nine patients with Glanzmann thrombasthenia have been reported to have had a thrombotic event, eight venous and one arterial (intracardiac, in the left ventricle). On the contrary, three patients with Bernard-Soulier syndrome have been shown to have had arterial thrombosis (myocardial infarction) but no venous thrombosis. Finally, seven patients with the familiar macrothrombocytopenia due to alterations of the MYH9 gene have been reported to have had thrombosis (five myocardial infractions, one ischemic stroke, one deep vein thrombosis and one portal vein thrombosis). The significance of these findings is discussed with particular emphasis on the discrepancy between venous and arterial thrombosis seen in patients with Glanzmann thrombasthenia and Bernard-Soulier syndrome.

Flightin is necessary for length determination, structural integrity, and large bending stiffness of insect flight muscle thick filaments.

Despite the fundamental role of thick filaments in muscle contraction, little is known about the mechanical behavior of these filaments and how myosin-associated proteins dictate differences between muscle types. In this study, we used atomic force microscopy to study the morphological and mechanical properties of fully hydrated native thick filaments isolated from indirect flight muscle (IFM) of normal and mutant Drosophila lacking flightin (fln(0)). IFM thick filaments from newly eclosed (0-1 h old) wild-type flies have a mean length of 3.04+/-0.05 microm. In contrast, IFM thick filaments from newly eclosed fln(0) flies are more variable in length and, on average, are significantly longer (3.90+/-1.33 microm) than wild-type filaments from flies of the same age. In the absence of flightin, thick filaments can attain lengths >300% of wild-type filaments, indicating that flightin is required for setting the proper filament length in vivo. Filaments lacking flightin are structurally compromised, and filament preparations from fully matured 3- to 5-day-old adult fln(0) IFM yielded fragments of variable length much shorter than 3.20+/-0.04 microm, the length obtained from wild-type flies of similar age. The persistence length, an index of bending stiffness, was calculated from measurements of filament end-to-end length and contour length. We show that the presence of flightin increases persistence length by more than 40% and that wild-type filaments increase in stiffness with age. These results indicate that flightin fulfills an essential role in defining the structural and mechanical properties of IFM thick filaments.

Kif5B and Kifc1 interact and are required for motility and fission of early endocytic vesicles in mouse liver.

Early endocytic vesicles loaded with Texas Red asialoorosomucoid were prepared from mouse liver. These vesicles bound to microtubules in vitro, and upon ATP addition, they moved bidirectionally, frequently undergoing fission into two daughter vesicles. There was no effect of vanadate (inhibitor of dynein) on motility, whereas 5'-adenylylimido-diphosphate (kinesin inhibitor) was highly inhibitory. Studies with specific antibodies confirmed that dynein was not associated with these vesicles and that Kif5B and the minus-end kinesin Kifc1 mediated their plus- and minus-end motility, respectively. More than 90% of vesicles associated with Kifc1 also contained Kif5B, and inhibition of Kifc1 with antibody resulted in enhancement of plus-end-directed motility. There was reduced vesicle fission when either Kifc1 or Kif5B activity was inhibited by antibody, indicating that the opposing forces resulting from activity of both motors are required for fission to occur. Immunoprecipitation of native Kif5B by FLAG antibody after expression of FLAG-Kifc1 in 293T cells indicates that these two motors can interact with each other. Whether they interact directly or through a complex of potential regulatory proteins will need to be clarified in future studies. However, the present study shows that coordinated activity of these kinesins is essential for motility and processing of early endocytic vesicles.

Targeted disruption of mouse ortholog of the human MYH9 responsible for macrothrombocytopenia with different organ involvement: hematological, nephrological, and otological studies of heterozygous KO mice.

Among three different isoforms of non-muscle myosin heavy chains (NMMHCs), only NMMHCA is associated with inherited human disease, called MYH9 disorders, characterized by macrothrombocytopenia and characteristic granulocyte inclusions. Here targeted gene disruption was performed to understand fundamental as well as pathological role of the gene for NMMHCA, MYH9. Heterozygous intercrosses yielded no homozygous animals among 552 births, suggesting that MYH9 expression is required for embryonic development. In contrast, MYH9+/- mice were viable and fertile without gross anatomical, hematological, and nephrological abnormalities. Immunofluorescence analysis also showed the normal cytoplasmic distribution of NMMHCA. We further measured the auditory brainstem response and found two of six MYH9+/- mice had hearing losses, whereas the remaining four were comparable to wild-type mice. Such observation may parallel the diverse expression of Alport's manifestations of human individuals with MYH9 disorders and suggest the limited requirement of the gene for maintenance and function of specific organs.

Nonmuscle Myosin motor of smooth muscle.

Nonmuscle myosin can generate force and shortening in smooth muscle, as revealed by studies of the urinary bladder from mice lacking smooth muscle myosin heavy chain (SM-MHC) but expressing the nonmuscle myosin heavy chains A and B (NM-MHC A and B; Morano, I., G.X. Chai, L.G. Baltas, V. Lamounier-Zepter, G. Lutsch, M. Kott, H. Haase, and M. Bader. 2000. Nat. Cell Biol. 2:371-375). Intracellular calcium was measured in urinary bladders from SM-MHC-deficient and SM-MHC-expressing mice in relaxed and contracted states. Similar intracellular [Ca2+] transients were observed in the two types of preparations, although the contraction of SM-MHC-deficient bladders was slow and lacked an initial peak in force. The difference in contraction kinetics thus do not reflect differences in calcium handling. Thick filaments were identified with electron microscopy in smooth muscle cells of SM-MHC-deficient bladders, showing that NM-MHC can form filaments in smooth muscle cells. Maximal shortening velocity of maximally activated, skinned smooth muscle preparations from SM-MHC-deficient mice was significantly lower and more sensitive to increased MgADP compared with velocity of SM-MHC-expressing preparations. Active force was significantly lower and less inhibited by increased inorganic phosphate. In conclusion, large differences in nucleotide and phosphate binding exist between smooth and nonmuscle myosins. High ADP binding and low phosphate dependence of nonmuscle myosin would influence both velocity of actin translocation and force generation to promote slow motility and economical force maintenance of the cell.

Molecular motor KIF1C is not essential for mouse survival and motor-dependent retrograde Golgi apparatus-to-endoplasmic reticulum transport.

KIF1C is a new member of the kinesin superfamily of proteins (KIFs), which act as microtubule-based molecular motors involved in intracellular transport. We cloned full-length mouse kif1C cDNA, which turned out to have a high homology to a mitochondrial motor KIF1Balpha and to be expressed ubiquitously. To investigate the in vivo significance of KIF1C, we generated kif1C(-/-) mice by knocking in the beta-galactosidase gene into the motor domain of kif1C gene. On staining of LacZ, we detected its expression in the heart, liver, hippocampus, and cerebellum. Unexpectedly, kif1C(-/-) mice were viable and showed no obvious abnormalities. Because immunocytochemistry showed partial colocalization of KIF1C with the Golgi marker protein, we compared the organelle distribution in primary lung fibroblasts from kif1C(+/+) and kif1C(-/-) mice. We found that there was no significant difference in the distribution of the Golgi apparatus or in the transport from the Golgi apparatus to the endoplasmic reticulum (ER) facilitated by brefeldin A between the two cells. This retrograde membrane transport was further confirmed to be normal by time-lapse analysis. Consequently, KIF1C is dispensable for the motor-dependent retrograde transport from the Golgi apparatus to the ER.

Molecular motors: from one motor many tails to one motor many tales.

Kinesin and dynein molecular motor proteins generate the movement of a wide variety of materials in cells. Such movements are crucial for many different cellular and developmental functions, including organelle movement, localization of developmental determinants, mitosis, meiosis and possibly long-range signaling in neurons. Kinesins that control the dynamics of microtubules have also been discovered. Recent work has begun to identify processes in which defective molecular motor function can cause human disease.