Ca2+-dependent regulations and signaling in skeletal muscle: from electro-mechanical coupling to adaptation
about
Diaphragm Muscle Adaptation to Sustained Hypoxia: Lessons from Animal Models with Relevance to High Altitude and Chronic Respiratory DiseasesCalcium Dyshomeostasis in Tubular Aggregate MyopathyReview of RyR1 pathway and associated pathomechanismsRyanodine receptor fragmentation and sarcoplasmic reticulum Ca2+ leak after one session of high-intensity interval exercise.Gene profiling of embryonic skeletal muscle lacking type I ryanodine receptor Ca(2+) release channel.Greater Strength Gains after Training with Accentuated Eccentric than Traditional Isoinertial Loads in Already Strength-Trained Men.Failure to up-regulate transcription of genes necessary for muscle adaptation underlies limb girdle muscular dystrophy 2A (calpainopathy).Calcium homeostasis alterations in a mouse model of the Dynamin 2-related centronuclear myopathy.Calcium Homeostasis and Muscle Energy Metabolism Are Modified in HspB1-Null Mice.Comparative Skeletal Muscle Proteomics Using Two-Dimensional Gel Electrophoresis.Transcription Factor EB Controls Metabolic Flexibility during Exercise.Reduced firing rates of high threshold motor units in response to eccentric overload.Evaluation of dynamic changes in interstitial fluid proteome following microdialysis probe insertion trauma in trapezius muscle of healthy women.Increased Reliance on Muscle-based Thermogenesis upon Acute Minimization of Brown Adipose Tissue Function.NO-sGC Pathway Modulates Ca2+ Release and Muscle Contraction in Zebrafish Skeletal Muscle.In vivo Ca2+ dynamics induced by Ca2+ injection in individual rat skeletal muscle fibers.CD38 enhances the proliferation and inhibits the apoptosis of cervical cancer cells by affecting the mitochondria functions.Skeletal muscle cell contraction reduces a novel myokine, chemokine (C-X-C motif) ligand 10 (CXCL10): potential roles in exercise-regulated angiogenesis.Cerebrovascular function and mitochondrial bioenergetics after ischemia-reperfusion in male rats.Development of the excitation-contraction coupling machinery and its relation to myofibrillogenesis in human iPSC-derived skeletal myocytes.Are mechanically sensitive regulators involved in the function and (patho)physiology of cerebral palsy-related contractures?Proteomic profiling of muscle fibre type shifting in neuromuscular diseases.Distinct transcriptomic changes in E14.5 mouse skeletal muscle lacking RYR1 or Cav1.1 converge at E18.5.Calpain 3 and CaMKIIβ signaling are required to induce HSP70 necessary for adaptive muscle growth after atrophy.Calcium electroporation for treatment of sarcoma in preclinical studies.Muscle Stem Cell and Physical Activity: What Point is the Debate at?Bone Remodeling and the Role of TRAF3 in Osteoclastic Bone ResorptionDietary Nitrate Enhances the Contractile Properties of Human Skeletal Muscle
P2860
Q28066535-6D13C9DF-066D-425F-B7C4-A1445669E747Q28078298-9C7168BD-D6D7-452B-9CEC-C36B57EAD9EEQ28078420-DC8F057C-D177-42FD-9C64-D6320131854EQ36394470-EA8C96A8-1DDE-4EFA-8724-6EBF7FEE48ECQ36527573-9737CB85-F27B-4C9B-B71B-53882EB8E358Q36842188-CC51A970-530A-48E8-92E9-050ACEF52EAEQ37367980-8226700F-0963-4E99-AB04-8B43A8D3A28BQ37502210-3ACDE605-E48F-4801-B308-3E4CB7AE6EFBQ37566382-019C5CD6-8417-4041-8DC6-03F3828EFA93Q37566405-893F3233-8887-4F86-8FB1-467E29806B29Q37590472-ABD73BE8-E92B-4661-BDBD-27918B58D51DQ37609059-5CDD336D-15D8-4C3E-A7D2-044B541F9851Q37684075-127DA410-E3C7-4C3B-8D72-B1EA392A65DFQ41045820-1C404057-4B5A-4723-8A52-C4F5386A1166Q41525971-F21F16EF-167D-4B7C-87C4-423D3953E296Q42316489-8A60F74B-AE67-4399-8EEC-25C004F7DB6AQ46360856-A6E8FA3D-3256-41C7-8528-63E9634DC141Q47299087-09D941F0-753A-40E5-A8F2-CF35FC41DC78Q47320290-EFC2A81B-9AFC-4CC9-AC1D-8D9636741A0AQ48508890-CD33F791-5A39-496E-8AD5-5F479A0AFF65Q49490232-B79EE447-E026-442D-9A81-6F28259144ACQ51664676-EE9F07DA-4658-489F-9B9E-6EB5C8049B6CQ52726366-2582D936-16C2-4ED9-9458-1DE51D5458D1Q54121876-87E7C241-4191-4CF1-88DD-C62CADDF0614Q54961514-F5E2B9E3-C669-4B7B-BFC6-ED3705DB7095Q55048133-E03DEE6B-F172-4817-A355-0080A0D42343Q57490079-829C0631-5EE4-40A7-85F1-61AB1DF0A9DCQ58741032-B3F09793-64E2-42D4-B896-2644FAB2581F
P2860
Ca2+-dependent regulations and signaling in skeletal muscle: from electro-mechanical coupling to adaptation
description
2015 nî lūn-bûn
@nan
2015 թուականի Յունուարին հրատարակուած գիտական յօդուած
@hyw
2015 թվականի հունվարին հրատարակված գիտական հոդված
@hy
2015年の論文
@ja
2015年論文
@yue
2015年論文
@zh-hant
2015年論文
@zh-hk
2015年論文
@zh-mo
2015年論文
@zh-tw
2015年论文
@wuu
name
Ca2+-dependent regulations and ...... hanical coupling to adaptation
@ast
Ca2+-dependent regulations and ...... hanical coupling to adaptation
@en
Ca2+-dependent regulations and ...... hanical coupling to adaptation
@nl
type
label
Ca2+-dependent regulations and ...... hanical coupling to adaptation
@ast
Ca2+-dependent regulations and ...... hanical coupling to adaptation
@en
Ca2+-dependent regulations and ...... hanical coupling to adaptation
@nl
prefLabel
Ca2+-dependent regulations and ...... hanical coupling to adaptation
@ast
Ca2+-dependent regulations and ...... hanical coupling to adaptation
@en
Ca2+-dependent regulations and ...... hanical coupling to adaptation
@nl
P2860
P921
P3181
P356
P1476
Ca2+-dependent regulations and ...... hanical coupling to adaptation
@en
P2093
Frank Suhr
Wilhelm Bloch
P2860
P304
P3181
P356
10.3390/IJMS16011066
P407
P577
2015-01-05T00:00:00Z