Role of the Elastic Protein Projectin in Stretch Activation and Work Output of Drosophila Flight Muscles

2000 ◽  
pp. 237-250 ◽  
Author(s):  
Jim O. Vigoreaux ◽  
Jeffrey R. Moore ◽  
David W. Maughan
Keyword(s):  
Work Output ◽  
Stretch Activation ◽  
Flight Muscles ◽  
Elastic Protein

scholarly journals Histopathological Features of Symptomatic and Asymptomatic Honeybees Naturally Infected by Deformed Wing Virus

Pathogens ◽  
2021 ◽  
Vol 10 (7) ◽  
pp. 874
Author(s):  
Karen Power ◽  
Manuela Martano ◽  
Gennaro Altamura ◽  
Nadia Piscopo ◽  
Paola Maiolino
Keyword(s):  
Viral Load ◽  
Asymptomatic Group ◽  
Deformed Wing Virus ◽  
Stage Of Development ◽  
Pathogenic Action ◽  
Degenerative Alterations ◽  
Flight Muscles ◽  
Asymptomatic Individuals ◽  
Histopathological Results

Deformed wing virus (DWV) is capable of infecting honeybees at every stage of development causing symptomatic and asymptomatic infections. To date, very little is known about the histopathological lesions caused by the virus. Therefore, 40 honeybee samples were randomly collected from a naturally DWV infected hive and subjected to anatomopathological examination to discriminate between symptomatic (29) and asymptomatic (11) honeybees. Subsequently, 15 honeybee samples were frozen at −80° and analyzed by PCR and RTqPCR to determinate the presence/absence of the virus and the relative viral load, while 25 honeybee samples were analyzed by histopathological techniques. Biomolecular results showed a fragment of the expected size (69bp) of DWV in all samples and the viral load was higher in symptomatic honeybees compared to the asymptomatic group. Histopathological results showed degenerative alterations of the hypopharyngeal glands (19/25) and flight muscles (6/25) in symptomatic samples while 4/25 asymptomatic samples showed an inflammatory response in the midgut and the hemocele. Results suggest a possible pathogenic action of DWV in both symptomatic and asymptomatic honeybees, and a role of the immune response in keeping under control the virus in asymptomatic individuals.

Cytoskeletal proteins of insect muscle: location of zeelins in Lethocerus flight and leg muscle

1994 ◽  
Vol 107 (5) ◽  
pp. 1115-1129 ◽  
Author(s):  
C. Ferguson ◽  
A. Lakey ◽  
A. Hutchings ◽  
G.W. Butcher ◽  
K.R. Leonard ◽  
...  
Keyword(s):  
Insect Flight ◽  
Regular Structure ◽  
Thick Filament ◽  
Cytoskeletal Proteins ◽  
Stretch Activation ◽  
Insect Muscle ◽  
Thick Filaments ◽  
Flight Muscles ◽  
Leg Muscle ◽  
Low Ionic Strength

Asynchronous insect flight muscles produce oscillatory contractions and can contract at high frequency because they are activated by stretch as well as by Ca2+. Stretch activation depends on the high stiffness of the fibres and the regular structure of the filament lattice. Cytoskeletal proteins may be important in stabilising the lattice. Two proteins, zeelin 1 (35 kDa) and zeelin 2 (23 kDa), have been isolated from the cytoskeletal fraction of Lethocerus flight muscle. Both zeelins have multiple isoforms of the same molecular mass and different charge. Zeelin 1 forms micelles and zeelin 2 forms filaments when renatured in low ionic strength solutions. Filaments of zeelin 2 are ribbons 10 nm wide and 3 nm thick. The position of zeelins in fibres from Lethocerus flight and leg muscle was determined by immunofluorescence and immunoelectron microscopy. Zeelin 1 is found in flight and leg fibres and zeelin 2 only in flight fibres. In flight myofibrils, both zeelins are in discrete regions of the A-band in each half sarcomere. Zeelin 1 is across the whole A-band in leg myofibrils. Zeelins are not in the Z-disc, as was thought previously, but migrate to the Z-disc in glycerinated fibres. Zeelins are associated with thick filaments and analysis of oblique sections showed that zeelin 1 is closer to the filament shaft than zeelin 2. The antibody labelling pattern is consistent with zeelin molecules associated with myosin near the end of the rod region. Alternatively, the position of zeelins may be determined by other A-band proteins. There are about 2.0 to 2.5 moles of myosin per mole of each zeelin. The function of these cytoskeletal proteins may be to maintain the ordered structure of the thick filament.

scholarly journals The activities of lipases and carnitine palmitoyl-transferase in muscles from vertebrates and invertebrates

1972 ◽  
Vol 130 (3) ◽  
pp. 697-705 ◽  
Author(s):  
B. Crabtree ◽  
E. A. Newsholme
Keyword(s):  
Insect Flight ◽  
Glycerol Kinase ◽  
O2 Uptake ◽  
Carnitine Palmitoyl Transferase ◽  
Fat Utilization ◽  
Metabolic Role ◽  
Intact Muscle ◽  
Flight Muscles ◽  
Hydrolysis Of

1. The activities of tri-, di- and mono-glyceride lipase and carnitine palmitoyltransferase were measured in homogenates of a variety of muscles. These activities were used to estimate the rate of utilization of glycerides and fatty acids by muscle. In muscles whose estimated rates of fat utilization can be compared with rates calculated for the intact muscle from such information as O2 uptake, there is reasonable agreement between the estimated and calculated rates. 2. In all muscles investigated the maximum rates of hydrolysis of glycerides increase in the order triglyceride, diglyceride, monoglyceride. The activity of diglyceride lipase is highest in the flight muscles of insects such as the locust, waterbug and some moths and is lowest in the flight muscles of flies, bees and the wasp. These results are consistent with the utilization of diglyceride as a fuel for some insect flight muscles. 3. In many muscles from both vertebrates and invertebrates the activity of glycerol kinase is similar to that of lipase. It is concluded that in these muscles the metabolic role of glycerol kinase is the removal of glycerol produced during lipolysis. However, in some insect flight muscles the activity of glycerol kinase is much greater than that of lipase, which suggests a different role for glycerol kinase in these muscles.

The Myosin Filament Superlattice in the Flight Muscles of Flies: A-band Lattice Optimisation for Stretch-activation?

2006 ◽  
Vol 361 (5) ◽  
pp. 823-838 ◽  
Author(s):  
John M. Squire ◽  
Tanya Bekyarova ◽  
Gerrie Farman ◽  
David Gore ◽  
Ganeshalingam Rajkumar ◽  
...  
Keyword(s):  
Myosin Filament ◽  
Stretch Activation ◽  
Flight Muscles

Relation between work output of respiratory muscles and end-tidal CO2 tension

1963 ◽  
Vol 18 (3) ◽  
pp. 497-504 ◽  
Author(s):  
J. Milic-Emili ◽  
J. M. Tyler
Keyword(s):  
Carbon Dioxide ◽  
Pulmonary Ventilation ◽  
Respiratory Muscles ◽  
Normal Subjects ◽  
Work Output ◽  
Inspiratory Muscles ◽  
Expiratory Muscles ◽  
End Tidal ◽  
End Tidal Co2

End-tidal CO2 tension, pulmonary ventilation, and work output of respiratory muscles were determined in six normal subjects breathing various mixtures of carbon dioxide in air, with three graded resistances added to both inspiration and expiration. In two individuals, the resistances were also added separately to inspiration or expiration. A linear relationship was found between work output of inspiratory muscles and end-tidal CO2 tension; this relationship was uninfluenced by added resistance. No consistent relationship was observed between either ventilation or work output of expiratory muscles and end-tidal CO2 tension. These results suggest that carbon dioxide controls directly the activity of inspiratory muscles alone and that the activity of expiratory muscles is only coincidentally involved. The possible role of intrinsic properties of respiratory muscles and of nervous mediation in the control of breathing is discussed. Submitted on October 22, 1962

Neural Control of Fibrillar Muscles in Bees During Shivering and Flight

1991 ◽  
Vol 159 (1) ◽  
pp. 419-431 ◽  
Author(s):  
HARALD ESCH ◽  
FRANZ GOLLER
Keyword(s):  
Muscle Activity ◽  
Neural Control ◽  
Stretch Activation ◽  
Warm Up ◽  
Modes Of Action ◽  
Flight Muscles ◽  
First Time ◽  
Longitudinal Muscles ◽  
Shivering Thermogenesis ◽  
Muscle Potential

The big indirect flight muscles in the thorax of honeybees and bumblebees show two modes of action: they contract with ‘conventional’ twitches in response to slowly repeated muscle potentials and go into tetanus at higher muscle potential frequencies. They can also contract much faster when quickly stretched (stretch activation). We observed contractions of DV (dorsoventral) and DL (dorsal longitudinal) muscles optically with the help of a tiny mirror glued to the scutellum. We noticed that DL muscles contracted much more than DV muscles during pre-flight warmup. During warm-up, muscle potential frequencies in DL muscles were higher than in DV muscles (DL frequency/DV frequency =1.3), whereas during flight the ratio reversed (DL/DV=0.8). The scutal fissure was completely closed during shivering warm-up, apparently because the DL muscles shortened as much as they could. As a consequence, fast antagonistic stretching was not possible. However, the scutal fissure oscillated between wide open and closed during flight, and antagonists could stretch each other quickly. Flight was started by highly synchronized ‘conventional’ contractions of many muscle elements in DV muscles. Antagonistic stretch-activation during flight led to faster shortening than during shivering warm-up and synchronized all activated muscle elements to produce maximal contractions. The indirect flight muscles of bumblebees were in tetanic contractions during shivering warm-up over the whole range of temperatures between 8 and 36°C. These tetanic contractions probably prevented other researchers from observing mechanical muscle activity. Our results, which for the first time allow us to detect tetanic contractions directly, make it very improbable that non-shivering thermogenesis occurs in bumblebees, as has been proposed previously.

Patterning the dorsal longitudinal flight muscles (DLM) of Drosophila: insights from the ablation of larval scaffolds

Development ◽  
1996 ◽  
Vol 122 (12) ◽  
pp. 3755-3763 ◽  
Author(s):  
J.J. Fernandes ◽  
H. Keshishian
Keyword(s):  
Transcription Factor ◽  
De Novo ◽  
Muscle Fibers ◽  
Myoblast Fusion ◽  
The Other ◽  
Correct Number ◽  
Larval Muscle ◽  
Actin Isoform ◽  
Flight Muscles

The six Dorsal Longitudinal flight Muscles (DLMs) of Drosophila develop from three larval muscles that persist into metamorphosis and serve as scaffolds for the formation of the adult fibers. We have examined the effect of muscle scaffold ablation on the development of DLMs during metamorphosis. Using markers that are specific to muscle and myoblasts we show that in response to the ablation, myoblasts which would normally fuse with the larval muscle, fuse with each other instead, to generate the adult fibers in the appropriate regions of the thorax. The development of these de novo DLMs is delayed and is reflected in the delayed expression of erect wing, a transcription factor thought to control differentiation events associated with myoblast fusion. The newly arising muscles express the appropriate adult-specific Actin isoform (88F), indicating that they have the correct muscle identity. However, there are frequent errors in the number of muscle fibers generated. Ablation of the larval scaffolds for the DLMs has revealed an underlying potential of the DLM myoblasts to initiate de novo myogenesis in a manner that resembles the mode of formation of the Dorso-Ventral Muscles, DVMs, which are the other group of indirect flight muscles. Therefore, it appears that the use of larval scaffolds is a superimposition on a commonly used mechanism of myogenesis in Drosophila. Our results show that the role of the persistent larval muscles in muscle patterning involves the partitioning of DLM myoblasts, and in doing so, they regulate formation of the correct number of DLM fibers.

Mechanics and aerodynamics of perching manoeuvres in a large bird of prey

2010 ◽  
Vol 114 (1161) ◽  
pp. 673-680 ◽  
Author(s):  
A. C. Carruthers ◽  
A. L. R. Thomas ◽  
S. M. Walker ◽  
G. K. Taylor
Keyword(s):  
High Speed ◽  
High Lift ◽  
Still Images ◽  
Video Cameras ◽  
Bird Of Prey ◽  
High Speed Video ◽  
Wing Profile ◽  
Large Bird ◽  
Flight Muscles

Abstract This paper reviews recent results on the mechanics and aerodynamics of perching in a large bird of prey, the Steppe Eagle Aquila nipalensis. Data collected using onboard and high-speed video cameras are used to examine gross morphing of the wing planform by the flight muscles, and smaller-scale morphing of the wing profile by aeroelastic deflection of the feathers, Carruthers et al. High-resolution still images are used to reconstruct the shape of the wing using multi-station photogrammetry, and the performance of the measured wing profile is analysed using a panel code, Carruthers et al. In bringing these lines of research together, we examine the role of aeroelastic feather deflection, and show that the key to perching in birds lies not in high-lift aerodynamics, but in the way in which the wings and tail morph to allow the bird to transition quickly from a steady glide into a deep stall.

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