Augmin-dependent microtubule nucleation at microtubule walls in the spindle

© The Author(s), 2013. This article is distributed under the terms of the Creative Commons Attribution License. The definitive version was published in Journal of Cell Biology 202 (2013): 25-33, doi:10.1083/jcb.201304031.The formation of a functional spindle requires microtubule (MT) nucleation from within the spindle, which depends on augmin. How augmin contributes to MT formation and organization is not known because augmin-dependent MTs have never been specifically visualized. In this paper, we identify augmin-dependent MTs and their connections to other MTs by electron tomography and 3D modeling. In metaphase spindles of human cells, the minus ends of MTs were located both around the centriole and in the body of the spindle. When augmin was knocked down, the latter population of MTs was significantly reduced. In control cells, we identified connections between the wall of one MT and the minus end of a neighboring MT. Interestingly, the connected MTs were nearly parallel, unlike other examples of end–wall connections between cytoskeletal polymers. Our observations support the concept of augmin-dependent MT nucleation at the walls of existing spindle MTs. Furthermore, they suggest a mechanism for maintaining polarized MT organization, even when noncentrosomal MT initiation is widespread.This work was supported by the Next Generation grant (Japan Society for the Promotion of Science), Human Frontier Science Program, James A. and Faith Miller Memorial Fund (to G. Goshima), the Hori Sciences and Arts Foundation, the Sasakawa Scientific Research Grant, the Kazato Research foundation (to T. Kamasaki), and the National Institutes of Health (8P41GM103431-42 to A. Hoenger). T. Kamasaki was a recipient of the Japan Society for the Promotion of Science postdoctoral fellowship.2014-01-0

Three-dimensional reconstruction of the membrane skeleton at the plasma membrane interface by electron tomography

Three-dimensional images of the undercoat structure on the cytoplasmic surface of the upper cell membrane of normal rat kidney fibroblast (NRK) cells and fetal rat skin keratinocytes were reconstructed by electron tomography, with 0.85-nm–thick consecutive sections made ∼100 nm from the cytoplasmic surface using rapidly frozen, deeply etched, platinum-replicated plasma membranes. The membrane skeleton (MSK) primarily consists of actin filaments and associated proteins. The MSK covers the entire cytoplasmic surface and is closely linked to clathrin-coated pits and caveolae. The actin filaments that are closely apposed to the cytoplasmic surface of the plasma membrane (within 10.2 nm) are likely to form the boundaries of the membrane compartments responsible for the temporary confinement of membrane molecules, thus partitioning the plasma membrane with regard to their lateral diffusion. The distribution of the MSK mesh size as determined by electron tomography and that of the compartment size as determined from high speed single-particle tracking of phospholipid diffusion agree well in both cell types, supporting the MSK fence and MSK-anchored protein picket models

Physiological Properties of Rod Photoreceptor Cells in Green-sensitive Cone Pigment Knock-in Mice

Rod and cone photoreceptor cells that are responsible for scotopic and photopic vision, respectively, exhibit photoresponses different from each other and contain similar phototransduction proteins with distinctive molecular properties. To investigate the contribution of the different molecular properties of visual pigments to the responses of the photoreceptor cells, we have generated knock-in mice in which rod visual pigment (rhodopsin) was replaced with mouse green-sensitive cone visual pigment (mouse green). The mouse green was successfully transported to the rod outer segments, though the expression of mouse green in homozygous retina was ∼11% of rhodopsin in wild-type retina. Single-cell recordings of wild-type and homozygous rods suggested that the flash sensitivity and the single-photon responses from mouse green were three to fourfold lower than those from rhodopsin after correction for the differences in cell volume and levels of several signal transduction proteins. Subsequent measurements using heterozygous rods expressing both mouse green and rhodopsin E122Q mutant, where these pigments in the same rod cells can be selectively irradiated due to their distinctive absorption maxima, clearly showed that the photoresponse of mouse green was threefold lower than that of rhodopsin. Noise analysis indicated that the rate of thermal activations of mouse green was 1.7 × 10−7 s−1, about 860-fold higher than that of rhodopsin. The increase in thermal activation of mouse green relative to that of rhodopsin results in only 4% reduction of rod photosensitivity for bright lights, but would instead be expected to severely affect the visual threshold under dim-light conditions. Therefore, the abilities of rhodopsin to generate a large single photon response and to retain high thermal stability in darkness are factors that have been necessary for the evolution of scotopic vision

Cooperative binding of the outer arm-docking complex underlies the regular arrangement of outer arm dynein in the axoneme

Outer arm dynein (OAD) in cilia and flagella is bound to the outer doublet microtubules every 24 nm. Periodic binding of OADs at specific sites is important for efficient cilia/flagella beating; however, the molecular mechanism that specifies OAD arrangement remains elusive. Studies using the green alga Chlamydomonas reinhardtii have shown that the OAD-docking complex (ODA-DC), a heterotrimeric complex present at the OAD base, functions as the OAD docking site on the doublet. We find that the ODA-DC has an ellipsoidal shape approximately 24 nm in length. In mutant axonemes that lack OAD but retain the ODA-DC, ODA-DC molecules are aligned in an end-to-end manner along the outer doublets. When flagella of a mutant lacking ODA-DCs are supplied with ODA-DCs upon gamete fusion, ODA-DC molecules first bind to the mutant axonemes in the proximal region, and the occupied region gradually extends toward the tip, followed by binding of OADs. This and other results indicate that a cooperative association of the ODA-DC underlies its function as the OAD-docking site and is the determinant of the 24-nm periodicity

Spindle microtubules generate tension-dependent changes in the distribution of inner kinetochore proteins

The N and C termini of CENP-T undergo tension-dependent separation, suggesting that CENP-T elongation is responsible for changes in the shape of the inner kinetochore

Application of electron microscopic tomography to the biological materials

生物分野 にか ぎらず物質の立体構造を知ることはその物 質の性質や機能の類推にとって必須である.と りわけ生物で は蛋 白質が様 々な複合体 を形成 し,い ろいろな機 能を生み 出 すので,蛋 白質複合体やそれらと細胞内小器官の複合体の立 体構造の解明は重要である.特 に細胞内における標的蛋白質 の位置を測定す るにはその周辺 の立体構造解 明は不可欠 であ る.電 子顕微鏡 トモグラフィーも形態観察から構造測定への 過程 での必要手段 として開発されてい る.我 々は凍結 エ ッチ ン グ レプ リカ法(freeze deep etching replica)と そ の変 法 を 主な手段として数年ほど前から膜の裏打ち骨格構造を解析し ている.膜 骨格と膜蛋白の相互関係を調べるときは膜表面か ら骨格線維 までの距離 の測 定は極めて重 要であ るとともに, 膜蛋 白複合体 を横 か ら観察す ることは機能を類推 するために も重要である.そ のためトモグラフィーを導入し,計 測して いる.こ こでは膜構造のトモグラフィーを中心に述べるが, 最初に立体再構築 とトモグラフィーが対象となる試料の大 き さに よりどの よ うな意味合いにな るかを述べる