Changes In Retraction Research Articles

Galvanin is an electric-field sensor for directed cell migration.

Directed cell migration is critical for the rapid response of immune cells, such as neutrophils, following tissue injury or infection. Endogenous electric fields, generated by the disruption of the transepithelial potential across the skin, help to guide the movement of immune and skin cells toward the wound site. However, the mechanisms by which cells sense these physical cues remain largely unknown. Through a CRISPR-based screen, we identified Galvanin, a previously uncharacterized single-pass transmembrane protein that is required for human neutrophils to change their direction of migration in response to an applied electric field. Our results indicate that Galvanin rapidly relocalizes to the anodal side of a cell on exposure to an electric field, and that the net charge on its extracellular domain is necessary and sufficient to drive this relocalization. The spatial pattern of neutrophil protrusion and retraction changes immediately upon Galvanin relocalization, suggesting that it acts as a direct sensor of the electric field that then transduces spatial information about a cell's electrical environment to the migratory apparatus. The apparent mechanism of cell steering by sensor relocalization represents a new paradigm for directed cell migration.

A narrative review of the management of pars flaccida tympanic membrane retractions without cholesteatoma.

Review the effectiveness of surgical and non-surgical management strategies for isolated pars flaccida and combined pars tensa and flaccida tympanic membrane retractions in preventing progression or recurrence, improving hearing and preventing development of cholesteatoma. Narrative review. ENT and otology services worldwide. Patients with non-cholesteatoma tympanic membrane retractions. Changes in retraction (progression or resolution, or development of a known sequela such as perforation). Eight full text papers are included: three randomised controlled trials and five case series or cohort studies of more than five patients (a total of 238 ears). Data exists for the use of conservative management, ventilation tubes, laser tympanoplasty, cartilage and fascia tympanoplasty, lateral attic reconstruction as well as mastoid procedures. Few high-quality studies on the management of isolated and combined pars flaccida retractions exist. For isolated pars flaccida retractions deemed to require surgical intervention, this review suggests that lateral attic reconstruction and cartilage tympanoplasty carries least risk of recurrence.

Efficient Front-Rear Coupling in Neutrophil Chemotaxis by Dynamic Myosin II Localization

Efficient chemotaxis requires rapid coordination between different parts of the cell in response to changing directional cues. Here, we investigate the mechanism of front-rear coordination in chemotactic neutrophils. We find that changes in the protrusion rate at the cell front are instantaneously coupled to changes in retraction at the cell rear, while myosin II accumulation at the rear exhibits a reproducible 9-15-s lag. In turning cells, myosin II exhibits dynamic side-to-side relocalization at the cell rear in response to turning of the leading edge and facilitates efficient turning by rapidly re-orienting the rear. These manifestations of front-rear coupling can be explained by a simple quantitative model incorporating reversible actin-myosin interactions with a rearward-flowing actin network. Finally, the system can be tuned by the degree of myosin regulatory light chain (MRLC) phosphorylation, which appears to be set in an optimal range to balance persistence of movement and turning ability.

Changes in the neuromuscular synapse induced by an antibody against gangliosides

In this study, we used a monoclonal IgM antibody from a patient with a pure motor chronic demyelinating polyneuropathy, which binds specifically to the complex gangliosides GM(2), GalNAc-GD(1a), and GalNAc-GM(1b), which appear to have a common epitope of -[GalNAcbeta1-4Gal(3-2alphaNeuAc)beta1]. This was done for the following reasons: (1) to localize these gangliosides in specific cellular components of the neuromuscular junction (NMJ), and (2) to describe the anti-ganglioside antibody-induced structural and functional changes in the NMJs to gain insight into the role of gangliosides in the synaptic function. Using immunofluorescence techniques, we found that these gangliosides are located only in the presynaptic component of the motor end-plates, both in nerve terminals and in Schwann cells. After 2 weeks of continued passive transfer of the IgM monoclonal antibody over the mouse levator auris longus muscle, electromyography showed an axonal or NMJ disorder. Morphology showed important nerve terminal growth and retraction changes. Using intracellular recording electrophysiology, we found neurotransmitter release alterations, including quantal content reduction and an immature expression of voltage-dependent calcium channels similar to what occurred during NMJ development and regeneration. These changes were complement independent. The results showed that these gangliosides were involved in the reciprocal Schwann cell-nerve terminal interactions, including structural stability and neurotransmission.

Sprawling locomotion in the lizard Sceloporus clarkii: the effects of speed on gait, hindlimb kinematics, and axial bending during walking

Although the hindlimb is widely considered to provide the propulsive force in lizard locomotion, no study to date has analysed kinematic patterns of hindlimb movements for more than one stride for a single individual and no study has considered limb and axial kinematics together. In this study, kinematic data from several individuals of the Sceloporus clarkii are used to describe the movement patterns of the axial skeleton and hindlimb at different speeds, to analyse how kinematics change with speed, and to compare and contrast these findings with the inferred effects of speed cited in the literature. Angular limb movements and axial bending patterns (standing wave with nodes on the girdles) did not change with speed. Only the relative speed of retracting the femur and flexing the knee during limb retraction changes with speed. Based on these data and similar results from a recent study of salamanders, it appears that, over a range of speeds involving a walking trot, sprawling vertebrates increase speed by simply retracting the femur relatively faster, thus this simple functional adjustment may be a general mechanism to increase speed in tetrapods. The demonstration that femoral retraction alone is the major speed effector in Sceloporus clarkii lends strong functional support to ecomorphological implications of limb length (and especially femur length and caudifemoralis size) in locomotory ecology and performance in phrynosomatid lizards. It also lends support to inferences about the caudifemoralis muscle as a preadaptation to terrestrial locomotion and as a key innovation in the evolution of bipedalism.

Retraction of injection-molded polypropylene

The retraction of injection-molded polypropylene at temperatures close to its melting point has been studied. At a given temperature above 150°C., retraction reaches a limit within a few minutes. Upon increasing the temperature, this equilibrium retraction changes to a higher characteristic value. The previous heating history strongly affects the equilibrium retraction. In fact, specimens can be prepared which exhibit negligible retraction up to the melting point where complete shrinkage occurs. Equilibrium retraction at a given temperature is ascribed to a melting of crystallites smaller than the specific size associated with that temperature. The remaining larger crystallites prevent further shrinkage.