about
Testosterone plus low-intensity physical training in late life improves functional performance, skeletal muscle mitochondrial biogenesis, and mitochondrial quality control in male miceInsulin signaling regulates mitochondrial function in pancreatic beta-cellsA novel miniature cell retainer for correlative high-content analysis of individual untethered non-adherent cells.Mitochondrial uncoupling protein 2 inhibits mast cell activation and reduces histamine contentReactive oxygen species stimulate insulin secretion in rat pancreatic islets: studies using mono-oleoyl-glycerolRole of mitofusin 2 in the renal stress responseA novel high-throughput assay for islet respiration reveals uncoupling of rodent and human islets.The Lkb1 metabolic sensor maintains haematopoietic stem cell survival.Mitochondria distinguish granule-stored from de novo synthesized tumor necrosis factor secretion in human mast cells.Optimal dynamics for quality control in spatially distributed mitochondrial networks.Altered mitochondrial dynamics contributes to endothelial dysfunction in diabetes mellitus.Beta-cell uncoupling protein 2 regulates reactive oxygen species production, which influences both insulin and glucagon secretionMitochondrial transporter ATP binding cassette mitochondrial erythroid is a novel gene required for cardiac recovery after ischemia/reperfusion.Mitochondrial morphology transitions and functions: implications for retrograde signaling?Association of genetic variation in the mitochondrial genome with blood pressure and metabolic traits.Mitochondrial fusion, fission and autophagy as a quality control axis: the bioenergetic view.Frequency and selectivity of mitochondrial fusion are key to its quality maintenance functionThe interplay between mitochondrial dynamics and mitophagyMitochondrial dynamics in the regulation of nutrient utilization and energy expenditure.Monitoring mitochondrial dynamics with photoactivatable [corrected] green fluorescent protein.Antitelomerase therapy provokes ALT and mitochondrial adaptive mechanisms in cancerDegradable Nanoparticles Restore Lysosomal pH and Autophagic Flux in Lipotoxic Pancreatic Beta Cells
P50
Q27332135-C14413F1-A2E1-4E30-A0A6-B4543FC2EC1EQ30945275-D9DB800C-C6CA-48A8-A913-F1963EDE8F7CQ33252103-72A6762A-513C-44D0-9973-7D339336DBC0Q34077923-6489B113-04EF-4E59-AB64-9767CB8C3D04Q34137563-8FA2EF48-899E-42C0-828E-61AED41E6B15Q34146617-3DA35221-37B0-4D18-87AA-14045DD9FF71Q34273442-BA6FC02C-0A79-435E-8F00-144E8AC30BACQ34568200-9D66D00B-74F1-4C12-B7D3-2DDD7032D539Q34782374-00DD360B-088A-4B36-9D8B-4F931709552DQ34844944-A52E0B69-0163-4714-820F-E49327CF9E01Q35144163-56EB90EE-DEE6-4B0F-8052-B72B6C813F91Q35405168-E0ACC518-7EF5-4F48-A50D-818C519DAE9CQ35819387-F4D64EE2-0E58-4A53-B648-3B9FD7AB0F6CQ36700290-55728701-2C23-44CD-9BE2-899A28337D26Q37120483-A71E8F73-3FAE-463A-AF2E-9E6D46344298Q37179623-C7014AAF-15AD-4672-B335-3C8CB356FBF0Q37263507-D136F1A7-0479-4A64-A610-671D601D9526Q37815475-040DA2C1-BA2D-43AE-9327-FA7CC0D4A95DQ38096612-C9711CDC-DFCE-4556-B5E2-ADE34B7FCB1AQ39854690-16A29E03-2BA8-42CB-84E7-2AD11F20AFFDQ41513960-9EDA465E-9674-424C-A1C4-0252DCE90F7BQ91278038-90E805CF-D42C-4073-ADB8-A20C3E57373A
P50
description
onderzoeker
@nl
researcher
@en
հետազոտող
@hy
name
Orian S Shirihai
@ast
Orian S Shirihai
@en
Orian S Shirihai
@es
Orian S Shirihai
@nl
Orian S Shirihai
@sl
type
label
Orian S Shirihai
@ast
Orian S Shirihai
@en
Orian S Shirihai
@es
Orian S Shirihai
@nl
Orian S Shirihai
@sl
prefLabel
Orian S Shirihai
@ast
Orian S Shirihai
@en
Orian S Shirihai
@es
Orian S Shirihai
@nl
Orian S Shirihai
@sl
P106
P31
P496
0000-0002-9502-2661