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MAB1628 Anti-Myosin Antibody, slow muscle, clone NOQ7.5.4D

MAB1628
100 µg  
Purchase on Sigma-Aldrich

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Replacement Information

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Kulcsspecifikációk táblázata

Species ReactivityKey ApplicationsHostFormatAntibody Type
H, R, FeRIA, WB, IHCMPurifiedMonoclonal Antibody
Description
Catalogue NumberMAB1628
Brand Family Chemicon®
Trade Name
  • Chemicon
DescriptionAnti-Myosin Antibody, slow muscle, clone NOQ7.5.4D
References
Product Information
FormatPurified
PresentationLiquid.
Quality LevelMQ100
Applications
ApplicationAnti-Myosin Antibody, slow muscle, clone NOQ7.5.4D is an antibody against Myosin for use in RIA, WB, IH.
Key Applications
  • Radioimmunoassay
  • Western Blotting
  • Immunohistochemistry
Application NotesImmunohistochemistry: frozen and formalin fixed sections.

Immunoblotting

RIA

Optimal working dilutions must be determined by end user.
Biological Information
ImmunogenMyosin purified from myofibrils isolated from histochemically mixed human skeletal muscle.
Epitopeslow muscle
CloneNOQ7.5.4D
ConcentrationPlease refer to the Certificate of Analysis for the lot-specific concentration.
HostMouse
SpecificitySlow myosin heavy chain. Clearly identifies Type 1 fibers. Within skeletal muscle MAB1628 is specific for slow myosin heavy chain in a wide variety of species. It reacts strongly with rat and feline slow myosin heavy chain. MAB1628 also identifies beta (slow) myosin heavy chain in heart ventricles.
IsotypeIgG
Species Reactivity
  • Human
  • Rat
  • Feline
Antibody TypeMonoclonal Antibody
Entrez Gene Number
Entrez Gene SummaryMYH7 encodes the cardiac muscle beta (or slow) isoform of myosin. Changes in the relative abundance of MYH7 and MYH6 (the alpha, or fast, isoform of cardiac myosin heavy chain) correlate with the contractile velocity of cardiac muscle. Mutations in MYH7 are associated with familial hypertrophic cardiomyopathy.
Gene Symbol
  • MYH7
  • Myosin-7
  • MYHCB
  • MyHC-beta
  • CMD1S
  • MGC138378
  • MPD1
  • DKFZp451F047
  • MGC138376
  • CMH1
UniProt Number
UniProt SummaryFUNCTION: SwissProt: P12883 # Muscle contraction.
SIZE: 1935 amino acids; 223097 Da
SUBUNIT: Muscle myosin is a hexameric protein that consists of 2 heavy chain subunits (MHC), 2 alkali light chain subunits (MLC) and 2 regulatory light chain subunits (MLC-2).
SUBCELLULAR LOCATION: Cytoplasm, myofibril. Note=Thick filaments of the myofibrils.
DOMAIN: SwissProt: P12883 The rodlike tail sequence is highly repetitive, showing cycles of a 28-residue repeat pattern composed of 4 heptapeptides, characteristic for alpha-helical coiled coils.
DISEASE: SwissProt: P12883 # Defects in MYH7 are the cause of familial hypertrophic cardiomyopathy type 1 (CMH1) [MIM:192600]; also designated FHC or HCM. Hypertrophic cardiomyopathy is a heart disorder characterized by ventricular hypertrophy, which is usually asymmetric and often involves the interventricular septum. The prevalence of the disease in the general population is 0.2%. FHC is clinically heterogeneous, with inter- and intrafamilial variations ranging from benign to malignant forms with high risk of cardiac failure and sudden cardiac death. & Defects in MYH7 are the cause of myosin storage myopathy [MIM:608358]. In this disorder, muscle biopsy shows type 1 fiber predominance and increased interstitial fat and connective tissue. Inclusion bodies consisting of the beta cardiac myosin heavy chain are present in the majority of type 1 fibers, but not in type 2 fibers. & Defects in MYH7 are a cause of dilated cardiomyopathy (CMD) [MIM:115200]. CMD is a disorder characterized by cardiac dilation and reduced systolic function. & Defects in MYH7 are the cause of Laing early-onset distal myopathy (MPD1) [MIM:160500]. MPD1 is an autosomal dominant disorder which differs from other distal myopathies in that onset is as early as 4 years of age. Selective weakness of the anterior tibial muscles is followed by weakness of the finger extensors and selected proximal muscle groups such as the hip abductors and rotators, the shoulder abductors and the sternocleidomastoids.
SIMILARITY: Contains 1 IQ domain. & Contains 1 myosin head-like domain.
MISCELLANEOUS: Each myosin heavy chain can be split into 1 light meromyosin (LMM) and 1 heavy meromyosin (HMM). It can later be split further into 2 globular subfragments (S1) and 1 rod-shaped subfragment (S2). & The cardiac alpha isoform is a 'fast' ATPase myosin, while the beta isoform is a 'slow' ATPase.
Physicochemical Information
Dimensions
Materials Information
Toxicological Information
Safety Information according to GHS
Safety Information
Product Usage Statements
Usage Statement
  • Unless otherwise stated in our catalog or other company documentation accompanying the product(s), our products are intended for research use only and are not to be used for any other purpose, which includes but is not limited to, unauthorized commercial uses, in vitro diagnostic uses, ex vivo or in vivo therapeutic uses or any type of consumption or application to humans or animals.
Storage and Shipping Information
Storage ConditionsMaintain at 2-8°C.
Packaging Information
Material Size100 µg
Transport Information
Supplemental Information
Specifications
Global Trade Item Number
Katalógusszám GTIN
MAB1628 04053252463778

Documentation

Anti-Myosin Antibody, slow muscle, clone NOQ7.5.4D MSDS

Title

Safety Data Sheet (SDS) 

Anti-Myosin Antibody, slow muscle, clone NOQ7.5.4D Certificates of Analysis

TitleLot Number
MOUSE ANTI-SLOW MUSCLE MYOSIN MONOCLONAL ANTIBODY - 2123146 2123146
MOUSE ANTI-SLOW MUSCLE MYOSIN MONOCLONAL ANTIBODY - 2025980 2025980
MOUSE ANTI-SLOW MUSCLE MYOSIN - 3065026 3065026
MOUSE ANTI-SLOW MUSCLE MYOSIN - 3230536 3230536
MOUSE ANTI-SLOW MUSCLE MYOSIN - 3389037 3389037
MOUSE ANTI-SLOW MUSCLE MYOSIN - 3443797 3443797
MOUSE ANTI-SLOW MUSCLE MYOSIN - 3704253 3704253
MOUSE ANTI-SLOW MUSCLE MYOSIN - 3857731 3857731
MOUSE ANTI-SLOW MUSCLE MYOSIN - 3994653 3994653
MOUSE ANTI-SLOW MUSCLE MYOSIN - 4057510 4057510

References

Reference overviewApplicationPub Med ID
Myotubes from severely obese type 2 diabetic subjects accumulate less lipids and show higher lipolytic rate than myotubes from severely obese non-diabetic subjects.
Bakke, SS; Feng, YZ; Nikolić, N; Kase, ET; Moro, C; Stensrud, C; Damlien, L; Ludahl, MO; Sandbu, R; Solheim, BM; Rustan, AC; Hjelmesæth, J; Thoresen, GH; Aas, V
PloS one  10  e0119556  2015

Kivonat megmutatása
25790476 25790476
Skeletal muscle perilipin 3 and coatomer proteins are increased following exercise and are associated with fat oxidation.
Covington, JD; Galgani, JE; Moro, C; LaGrange, JM; Zhang, Z; Rustan, AC; Ravussin, E; Bajpeyi, S
PloS one  9  e91675  2014

Kivonat megmutatása
Immunohistochemistry24632837 24632837
Leiomodin-3 dysfunction results in thin filament disorganization and nemaline myopathy.
Yuen, M; Sandaradura, SA; Dowling, JJ; Kostyukova, AS; Moroz, N; Quinlan, KG; Lehtokari, VL; Ravenscroft, G; Todd, EJ; Ceyhan-Birsoy, O; Gokhin, DS; Maluenda, J; Lek, M; Nolent, F; Pappas, CT; Novak, SM; D'Amico, A; Malfatti, E; Thomas, BP; Gabriel, SB; Gupta, N; Daly, MJ; Ilkovski, B; Houweling, PJ; Davidson, AE; Swanson, LC; Brownstein, CA; Gupta, VA; Medne, L; Shannon, P; Martin, N; Bick, DP; Flisberg, A; Holmberg, E; Van den Bergh, P; Lapunzina, P; Waddell, LB; Sloboda, DD; Bertini, E; Chitayat, D; Telfer, WR; Laquerrière, A; Gregorio, CC; Ottenheijm, CA; Bönnemann, CG; Pelin, K; Beggs, AH; Hayashi, YK; Romero, NB; Laing, NG; Nishino, I; Wallgren-Pettersson, C; Melki, J; Fowler, VM; MacArthur, DG; North, KN; Clarke, NF
The Journal of clinical investigation  124  4693-708  2014

Kivonat megmutatása
25250574 25250574
CaMKII content affects contractile, but not mitochondrial, characteristics in regenerating skeletal muscle.
Eilers, W; Jaspers, RT; de Haan, A; Ferrié, C; Valdivieso, P; Flück, M
BMC physiology  14  7  2014

Kivonat megmutatása
25515219 25515219
Lipid in skeletal muscle myotubes is associated to the donors' insulin sensitivity and physical activity phenotypes.
Bajpeyi, S; Myrland, CK; Covington, JD; Obanda, D; Cefalu, WT; Smith, SR; Rustan, AC; Ravussin, E
Obesity (Silver Spring, Md.)  22  426-34  2014

Kivonat megmutatása
Immunohistochemistry23818429 23818429
The CHC22 clathrin-GLUT4 transport pathway contributes to skeletal muscle regeneration.
Hoshino, S; Sakamoto, K; Vassilopoulos, S; Camus, SM; Griffin, CA; Esk, C; Torres, JA; Ohkoshi, N; Ishii, A; Tamaoka, A; Funke, BH; Kucherlapati, R; Margeta, M; Rando, TA; Brodsky, FM
PloS one  8  e77787  2013

Kivonat megmutatása
24204966 24204966
ACTN3 genotype influences muscle performance through the regulation of calcineurin signaling.
Seto, JT; Quinlan, KG; Lek, M; Zheng, XF; Garton, F; MacArthur, DG; Hogarth, MW; Houweling, PJ; Gregorevic, P; Turner, N; Cooney, GJ; Yang, N; North, KN
The Journal of clinical investigation  123  4255-63  2013

Kivonat megmutatása
24091322 24091322
Remodeling of oxidative energy metabolism by galactose improves glucose handling and metabolic switching in human skeletal muscle cells.
Kase, ET; Nikolić, N; Bakke, SS; Bogen, KK; Aas, V; Thoresen, GH; Rustan, AC
PloS one  8  e59972  2013

Kivonat megmutatása
23560061 23560061
Variable myopathic presentation in a single family with novel skeletal RYR1 mutation.
Attali, R; Aharoni, S; Treves, S; Rokach, O; Becker Cohen, M; Fellig, Y; Straussberg, R; Dor, T; Daana, M; Mitrani-Rosenbaum, S; Nevo, Y
PloS one  8  e69296  2013

Kivonat megmutatása
23894444 23894444
Electrical pulse stimulation of cultured human skeletal muscle cells as an in vitro model of exercise.
Nikolić, N; Bakke, SS; Kase, ET; Rudberg, I; Flo Halle, I; Rustan, AC; Thoresen, GH; Aas, V
PloS one  7  e33203  2011

Kivonat megmutatása
22457744 22457744