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Query: UMLS:C0032290 (
aspiration pneumonia
)
2,291
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
According to current models of muscle contraction (Huxley, H. E., Science 164: 1356-1366 [1969]), motion of flexible
myosin
crossbridges is essential to the contractile cycle. Using a spin-label analog of iodoacetamide bound to the subfragment No. 1 (S1) region of
myosin
, we have obtained rotational correlation times (tau 2) for this region of the molecule with the ultimate goal of making quantitative measurements of the motion of the crossbridges under conditions comparable to those in living, contracting muscle. We used the newly developed technique of saturation transfer electron paramagnetic resonance spectroscopy (Hyde, J.S., and Thomas, D.D., Ann. N.Y. Acad Sci. 22:680-692 [1973]), which is uniquely sensitive to rotational motion in the range of 10(-7)-10(-3) sec. Our results indicate that the spin label is rigidly bound to S1 (tau 2 for isolated S1 is 2 X 10(-7) sec) and that the motion of the label reflects the motion of the S1 region of
myosin
. the value of tau 2 for the S1 segment of
myosin
is less than twice that for isolated S1, while the molecular weights differ by a factor of 4, indicating flexibility of
myosin
in agreement with the conclusions of
Mendelson
et al. (Biochemistry 12:2250-2255 [1973]). Adding F-actin increses tau 2 in either
myosin
or isolated S1 by a factor of mearly 103, indicating rigid immobilization of S1 by actin. Formation of
myosin
filaments (at an ionic strength of 0.15 or less) increses tau 2 by a factor of 10-30, depending on the ionic strength, indicating a decrease of the rotational mobility of S1 in these agregates. The remaining motion is at least a factor of 10 faster than would be expected for the filament itself, suggesting motion of the S1 region independent of the filament backbone but slower than in a single molecule. F-actin has a strong immobilizing effect on labeled S1 in
myosin
filaments (in 0.137 M KC1), but the immobilization is less complete than that observed when F-actin is added to labeled
myosin
monomers (in 0.5 M KC1). A spin-label analog of maleimide, attached to the SH-2 thiol groups of S1, is immobilized to a much lesser extent by F-actin than is the label on SH-1 groups. The maleimide label also was attached directly to F-actin and was sufficiently immobilized to suggest rigid binding to actin.
...
PMID:The quantitative measurement of rotational motion of the subfragment-1 region of myosin by saturation transfer epr spectroscopy. 17 39
X-ray results are presented concerning the structural state of
myosin
heads of synthetic filaments in threads. These were made from purified rabbit skeletal muscle
myosin
and studied by x-ray diffraction and electron microscopy by Cooke et al. (Cooke, P. H., E. M. Bartels, G. F. Elliott, and R. A. Hughes, 1987, Biophys. J., 51:947-957). X-ray patterns show a meridional peak at a spacing of 14.4 nm. We concentrate here on the only other feature of the axial pattern: this is a central region of diffuse scatter, which we find to be similar to that obtained from
myosin
heads in solution (
Mendelson
, R. A., K. M. Kretzschmar, 1980, Biochemistry, 19:4103-4108). This means that the
myosin
heads have very large random displacements in all directions from their average positions, and that they are practically randomly oriented. The
myosin
heads do not contribute to the 14.4-nm peak, which must come entirely from the backbone. Comparison with x-ray data from the unstriated Taenia coli muscle of the guinea pig indicates that in this muscle at least 75% of the diffuse scatter comes from disordered
myosin
heads. The results confirm that the diffuse scatter in x-ray patterns from specimens that contain
myosin
filaments can yield information about the structural behavior of the
myosin
heads.
...
PMID:Diffuse X-ray scatter from myosin heads in oriented synthetic filaments. 360 14
Hydrodynamic calculations lead to the conclusion that chymotryptic (or ethylenediaminetetraacetic acid)
myosin
S1 in solution (hydrated), at 1-5 degrees C, can be modeled as a prolate ellipsoid, with an axial ratio lying between p = 1.0 and 2.5 (major axis between 100.5 A, for p = 1.0, and 162.5 A, for p = 2.5). The degree of hydration is considerable (1.24 g/g for p = 2.5 and 2.02 g/g for p = 1.0). The dehydrated
myosin
head is pear-shaped under the electron microscope, and its narrowest part is located near the junction with the tail [Elliott, A., & Offer, G. (1978) J. Mol. Biol. 123, 505-519].
Mendelson
& Kretzschmar [
Mendelson
, R. A., & Kretzschmar, K.M. (1980) Biochemistry 19, 4103-4108] have shown that the pear-shaped molecule does not predict the experimental X-ray scattering curve. Nor is this model able to predict the hydrodynamic values. The three-dimensional model for S1 used by
Mendelson
and Kretzschmar gives a rather good fit to the experimental X-ray scattering curve, but it does not predict the hydrodynamic values. In order to try to reconcile the three models and to fit the X-ray scattering curve and the hydrodynamic data, we suggest that, in solution, the S1 monomer has the shape of a prolate ellipsoid and that an inclusion of bound water exists at one extremity of the protein. The rest of bound water surrounds the protein. As first approximation, the dry protein and the hole are assumed to have the same shape as the hydrated molecule (prolate ellipsoid; p).(ABSTRACT TRUNCATED AT 250 WORDS)
...
PMID:Reinvestigation of the shape and state of hydration of the skeletal myosin subfragment 1 monomer in solution. 663 38
The diaphragm of neonatal horses is significantly different from the diaphragm of adult horses in terms of histochemical fiber type composition, myosin heavy chain isoform, and native
myosin
isoform composition. There is a significant increase in the percentage of type I fibers present in the diaphragm with increasing age from birth through about seven months postnatal age. A possible lack of postural tone in the hiatal region of the neonatal diaphragm is suggested to account for increased incidence of vomiting or
aspiration pneumonia
in younger horses. The isoform data lead to rejection of the hypothesis that the diaphragm of the horse should, as an ungulate, be relatively precocial in its rate of maturation relative to other non-ungulate mammals that have been studied.
...
PMID:Neonatal development of the diaphragm of the horse, Equus caballus. 817 12
