Unique microtubules in luteal cells from superovulated rats

Microdensitometer-computer correlation analysis of two distinct, spatially segregated classes of microtubule bridges in Allogromia pseudopodia

Previous video-light microscopic studies have shown that the microtubule bundles in the pseudopodia of foraminiferan protists display several types of movements in vivo, including active bending, zipping/splaying, and axial translocations. To gain insight into the types and arrangement of microtubule-associated proteins (e.g., mechanoenzymes, crosslinkers) in such a highly dynamic system, we employed microdensitometric-computer correlation methods to analyze, quantitatively, intermicrotubule bridges in thin-section electron micrographs of Allogromia laticollaris and Allogromia sp. (strain NF). Two distinct bridges occupying mutually exclusive zones between adjacent microtubules were identified. Type I bridges displayed a single axial repeat (34 nm for A. laticollaris and 28 nm for Allogromia sp.) and Type II bridges showed a typical 12-dimer helical superlattice pattern. In A. laticollaris, the two types of bridges were morphologically distinct: Type I bridges were aligned perpendicular to the microtubule wall and were 23-nm wide with an electron-lucent core; Type II bridges were irregular filaments projecting from the microtubules at various angles. When compared with the known distribution of microtubule-associated proteins in other systems, our findings indicate that, in vivo, Allogromia pseudopodial microtubules are decorated with MAP2-like bridges interrupted by discrete clusters of a dynein-like component.

Analysis of the spatial organization of microtubule-associated proteins

We have developed microdensitometer-computer correlation techniques to analyze the arrangement of microtubule arms and bridges (i.e., microtubule-associated proteins [MAPs]). A microdensitometer was used to scan immediately adjacent to the wall of longitudinally sectioned microtubules in positive transparency electron micrographs. Signal enhancement procedures were applied to the digitized densitometer output to produce a binary sequence representing the apparent axial spacing of MAP projections. These enhanced records were analyzed in two ways. (a) Autocorrelograms were formed for each record and correlogram peaks from a group of scans were pooled to construct a peak frequency histogram. (b) Cross-correlation was used to optimize the match between each enhanced record and templates predicted by different models of MAP organization. Seven symmetrical superlattices were considered as well as single axial repeats. The analyses were repeated with randomly generated records to establish confidence levels. Using the above methods, we analyzed the intrarow bridges of the Saccinobaculus axostyle and the MAP2 projections associated with brain microtubules synthesized in vitro. We confirmed a strict 16-nm axial repeat for axostyle bridges. For 26 MAP2 records, the only significant match was to a 12-dimer superlattice model (P less than 0.002). However, we also found some axial distances between MAP2 projections which were compatible with the additional spacings predicted by a 6-dimer superlattice. Therefore, we propose that MAP2 projections are arranged in a "saturated 12-dimer, unsaturated 6-dimer" superlattice, which may be characteristic of a wide variety of MAPs.

Three-dimensional network of microtubules in secretory ameloblasts of rat incisors

Secretory ameloblasts appear to contain isolated microtubules and microtubules arranged in bundles associated with filaments or sheets of filaments. The relation between isolated and bundled microtubules in secretory ameloblasts was investigated by serial sections. Some isolated microtubules entered microtubule bundles in adjacent sections. Microtubules which diverged from a bundle sometimes converged into another bundle in other sections. Microtubules were associated with filaments or sheets of filaments for varying distances. It is concluded that isolated microtubules frequently form bundles by joining with other microtubules, and thus, microtubules make a three-dimensional network throughout the whole cytoplasm which is probably concerned with the transport of secretion granules.

The effects of taxol on embryonic chick tectum maintained in culture: an electron microscope study

Tectal explants from chick embryos, established in culture for 2-3 weeks, were exposed to taxol-enriched media for 1-7 days, fixed, and studied by transmission electron microscopy. Taxol treatment resulted in no apparent disruption of the overall integrity of the organization of the explants nor in grossly increased cell death, but caused marked abnormalities of cytoskeletal elements. Intermediate filaments were increased in number in both neuronal and glial cells and very large numbers of microtubules were present, some aligned below the plasma membrane but most as components of large bundles in neuronal cell bodies and processes. Some such microtubules were associated with a network of intermicrotubule substance, consisting of 10-nm filaments running parallel to the microtubules, in hexagonal arrays surrounding individual microtubules, together with a very fine amorphous or filamentous component which was drawn into thread-like structures that linked the larger filaments to one another and formed the sides of the hexagons. Taxol treatment also resulted in the formation of concentric rings of microtubules separated by cylindrical sheets of electron-dense material. These observations extend previous descriptions of the effects of taxol on cytoskeletal elements, add to growing evidence for heterogeneity of microtubules within neurons, and suggest that taxol may be useful in studies of the functions of cytoskeletal elements and of microtubule heterogeneity in neurons.