Heterogeneous bone-marrow stromal progenitors drive myelofibrosis via a druggable alarmin axis

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Actin localization in male germ cell intercellular bridges in the rat and ground squirrel and disruption of bridges by cytochalasin D

Filaments about 6-7 nm in diameter were seen associated with germ cell intercellular bridges in detergent-permeabilized cells treated with tannic acid. Approximately 40-50 filaments were present subjacent to the bridge density. Filaments encircled the bridge channel in a manner similar to contractile ring actin filaments of dividing cells. NBD-phallacidin and myosin S-1 subfragments were employed to demonstrate that the filaments observed at intercellular bridges are actin. Intratesticular injection of a single dose of cytochalasin D, a specific inhibitor of actin filaments, caused certain intercellular bridges of spermatids to open within 3 hr after injection, leading to the production of symplasts. During bridge opening, remnants of bridge densities were gradually incorporated into the lateral aspect of the plasma membrane of the symplast. Thus actin, present in bridge structures, appeared to participate in maintaining certain intercellular bridges. A model of intercellular bridge structure is presented.     

Loud calls of male Nilgiri langurs (Presbytis johnii): Age-, individual-, and population-specific differences

Adult male Nilgiri langurs (Presbytis johnii) utter loud call bouts consisting of one or more phrases. Phrases are made up of several units showing similar or different structural features. The units involved differ with respect to not only their physical structure but also their overall utilization: three vocal patterns are uttered exclusively by mature males living in bisexual groups or all-male bands and, in addition to being part of loud call bouts, are given during encounters with terrestrial predators; two vocal patterns are uttered by males and females, again not just as constituents of loud calls; and one vocal pattern is given exclusively by mature males living in bisexual groups. Within a given bout, phrases differ not only with respect to their composition but also in their temporal organization. In addition to the acoustic components, loud calls are regularly accompanied by stereotyped motoric displays. The motoric and acoustic components of loud call displays appear independently of each other and at different times during ontogeny. The development of the display is characterized by combination of units with different structural features and synchronization of vocal and motoric components. Although more evidence is needed, our observations suggest that the development of loud call displays coincides with the aquisitation of social maturation and competence and requires not only social experience but also a certain amount of motoric training. In spite of the high degree of ritualization, loud call displays are not completely fixed in form, but instead are open to individual- and population-specific variation.     

Histological analysis of the nasal roof cartilage in a neonate sperm whale (Physeter macrocephalus – Mammalia, Odontoceti)

The nasal roof cartilage of a neonate sperm whale (Physeter macrocephalus) was examined by gross dissection and routine histology. This cartilage is part of the embryonic Tectum nasi and is a critical feature in the formation of the massive sperm whale forehead. In neonates as well as in adults, the blade-like nasal roof cartilage extends diagonally through the huge nasal complex from the bony nares to the blowhole on the left side of the rostral apex of the head. It accompanies the left nasal passage along its entire length, which may reach several meters in adult males. The tissue of the nasal roof cartilage in the neonate whale shows an intermediate state of development. For example, in embryos and fetuses, the nasal roof cartilage consists of hyaline cartilage, but in adult sperm whales, it also includes elastic fibers. In our neonate sperm whale, the nasal roof cartilage already consisted of adult-like elastic cartilage. In addition, the active or growing, layer of the perichondrium was relatively thick compared to that of fetuses, and a large number of straight elastic fibers that were arranged perpendicularly to the long axis of the nasal roof cartilage were present. These neonatal features can be interpreted as characteristics of immature and growing cartilaginous tissue. An important function of the nasal roof cartilage may be the stabilization of the left nasal passage, which is embedded within the soft tissue of the nasal complex. The nasal roof cartilage with its elastic fibers may keep the nasal passage open and prevent its collapse from Bernoulli forces during inhalation. Additionally, the intrinsic tension of the massive nasal musculature may be a source of compression on the nasal roof cartilage and could explain its hyaline character in the adult. In our neonate specimen, in contrast, the cartilaginous rostrum (i.e., mesorostral cartilage) consisted of hyaline cartilage with an ample blood supply. The cartilaginous rostrum does not change its histological characteristics during development, but its function in adults is still not understood.     

Developmental quantitative genetic models of evolutionary change

Discussions about evolutionary change in developmental processes or morphological structures are predicated on specific quantitative genetic models whose parameters predict whether evolutionary change can occur, its relative rate and direction, and if correlated change will occur in other related and unrelated structures. The appropriate genetic model should reflect the relevant genetical and developmental biology of the organisms, yet be simple enough in its parameters so that deductions can be made and hypotheses tested. As a consequence, the choice of the most appropriate genetic model for polygenically controlled traits is a complex tissue and the eventual choice of model is often a compromise between completeness of the model and computational expediency. Herein, we discuss several developmental quantitative genetic models for the evolution of development and morphology. The models range from the classical direct effects model to complex epigenetic models. Further, we demonstrate the algebraic equivalency of the Cowley and Atchley epigenetic model and Wagner's developmental mapping model. Finally, we propose a new multivariate model for continuous growth trajectories. The relative efficacy of these various models for understanding evolutionary change in developmental and morphological traits is discussed. © 1994 Wiley-Liss, Inc.     

Microtubule polarity in Sertoli cells: a model for microtubule-based spermatid transport

Bundles of microtubules occur adjacent to ectoplasmic specializations (ESs) that line Sertoli cell crypts and support developing spermatids. These microtubules are oriented parallel to the direction of spermatid movement during spermatogenesis. We propose a model in which ESs function as vehicles, and microtubules as tracks, for microtubule-based transport of spermatids through the seminiferous epithelium. Microtubule polarity provides the basis for the direction of force generation by available mechanoenzymes. As part of a more general study designed to investigate the potential role of microtubule-based transport during spermatogenesis, we have studied the polarity of cytoplasmic microtubules of Sertoli cells. Rat testis blocks were incubated in a lysis/decoration buffer, with and without exogenous purified bovine brain tubulin. This treatment results in the decoration of endogenous microtubules with curved tubulin protofilament sheets (seen as hooks in cross section). The direction of curvature of the hooks indicates microtubule polarity; that is, clockwise hooks are seen when viewing microtubules from the plus to the minus end. We found that, in Sertoli cells, most of the hooks were orientated in the same direction. Significantly, when viewed from the base of the epithelium, hooks pointed in a clockwise direction. The clockwise direction of dynein arms on axonemes of sperm tails, in the same section, provided an internal check of the section orientation. Electron micrographs of fields of seminiferous epithelium were assembled into montages for quantitative analysis of microtubule polarity. Our data indicate that Sertoli cell cytoplasmic microtubules are of uniform polarity and are orientated with their minus ends toward the cell periphery. These observations have significant implications for our proposed model of microtubule-based transport of spermatids through the seminiferous epithelium.