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Guidelines for the use and interpretation of assays for monitoring autophagyGuidelines for the use and interpretation of assays for monitoring autophagy (3rd edition)SUMF1 enhances sulfatase activities in vivo in five sulfatase deficienciesSulfatase modifying factor 1 trafficking through the cells: from endoplasmic reticulum to the endoplasmic reticulumA block of autophagy in lysosomal storage disordersBoning up on autophagy: the role of autophagy in skeletal biologyA lysosome-to-nucleus signalling mechanism senses and regulates the lysosome via mTOR and TFEBLysosomal adaptation: how the lysosome responds to external cuesInduction of lysosomal biogenesis in atherosclerotic macrophages can rescue lipid-induced lysosomal dysfunction and downstream sequelaeMolecular and functional analysis of SUMF1 mutations in multiple sulfatase deficiency.Signals from the lysosome: a control centre for cellular clearance and energy metabolism.Insulin granules. Insulin secretory granules control autophagy in pancreatic β cells.Lysosome: regulator of lipid degradation pathways.Direct conversion of fibroblasts into functional astrocytes by defined transcription factorsSystemic inflammation and neurodegeneration in a mouse model of multiple sulfatase deficiencyT-cell protein tyrosine phosphatase regulates bone resorption and whole-body insulin sensitivity through its expression in osteoblastsSulfatases are determinants of alveolar formation.Astrocyte dysfunction triggers neurodegeneration in a lysosomal storage disorder.Lysosomal calcium signalling regulates autophagy through calcineurin and TFEB.A RANKL-PKCβ-TFEB signaling cascade is necessary for lysosomal biogenesis in osteoclasts.Proteoglycan desulfation determines the efficiency of chondrocyte autophagy and the extent of FGF signaling during endochondral ossification.TFEB controls cellular lipid metabolism through a starvation-induced autoregulatory loop.Genetic control of bone formation.New targets for old diseases: lessons from mucolipidosis type II.Defective CFTR induces aggresome formation and lung inflammation in cystic fibrosis through ROS-mediated autophagy inhibition.FGF signalling regulates bone growth through autophagy.Wilson disease protein ATP7B utilizes lysosomal exocytosis to maintain copper homeostasis.Self-eating in skeletal development: implications for lysosomal storage disorders.Autophagy in astrocytes: a novel culprit in lysosomal storage disorders.Autophagy gets to the bone.TFEB and the CLEAR networkCell metabolism: Autophagy transcribedErratum: TFEB controls cellular lipid metabolism through a starvation-induced autoregulatory loopCystic fibrosis: A disorder with defective autophagyTFEB regulates autophagy: An integrated coordination of cellular degradation and recycling processesA selective ER-phagy exerts procollagen quality control via a Calnexin-FAM134B complexTFEB controls vascular development by regulating the proliferation of endothelial cellsGuidelines for the use and interpretation of assays for monitoring autophagy (3rd edition)Beating the ER: novel insights into FAM134B function and regulation
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Q21996341-4C696739-38F9-4B13-A376-4255B02BD684Q22676705-B34E4ED5-4E72-40BD-9931-FFFD1833A648Q24683062-0C7B8C61-9857-4B7F-9865-187546EAFBF8Q24684473-68152635-B0D9-4F97-9369-EA4CD8463C14Q28252016-641E7D57-8D22-4D64-A55C-5BAD4D89EFB9Q28659840-04229B99-09A9-47EA-A9EE-4B45DCE52B0DQ30508509-E5690882-48FB-415D-9080-015ABD196A4AQ33653699-DBCD67E0-EE10-4330-A4E1-4076EB79BD89Q34076245-89C509C6-ECC3-4E90-A48C-929A7EBE3091Q34321165-EBF0E004-72D0-4A1B-928A-93D4E72B0003Q34340780-BDCAF22C-5E68-4CDA-A5AF-BA3CFCAB01DCQ34463845-277006D4-0E36-4C7B-B630-44BB4053021FQ34585737-25CED050-65C0-45F1-B0F6-5532330F4219Q34980759-8AC197F8-A83E-4423-9749-66F4EAC5EB2EQ35663888-1A8B4367-4710-4370-83EA-D89BA4BBD584Q35806647-8A3DAA1F-DF07-46A5-B79A-5D93C97809CAQ35923293-773B1AA9-86D3-4523-BAAD-28809BBCB104Q36212862-80F03377-E96A-4FB5-9165-505E75310645Q36709792-2871EC53-4D1C-4C2E-B145-D0D9C7BC9F6EQ36832193-2416F562-F860-47E1-A657-8865FF266FB1Q36919927-07078E99-0247-44DC-B3C0-09CFFA4D0392Q36977543-ECC9DB08-D5A7-40B6-9039-8C03913E0B77Q37540138-024AFCB4-C959-44AC-A274-E8447472C5F7Q37557178-62941EC1-9BD7-4638-884E-04E98F82448BQ39667316-6C7A43DE-1C90-48C6-A684-E5ECE13D1004Q40288311-69700C3E-5173-4AC6-BEEB-5BE4A6390F71Q41156563-211A632F-2B59-4D76-BADE-28955B96F21EQ42075965-C6E91727-BE56-46EB-89C9-DF848C7000CEQ42614327-BC461238-4EB4-4655-A6A7-25581EBBF0BEQ42746355-5385D4A6-DB48-4B00-89A0-F17D61D16A8BQ57663463-04B202F5-109F-4CAC-8084-83B8077AF8DCQ57663466-A3EB758B-C467-4496-A180-12EB1D68ACDBQ57663479-7035575F-636F-4CBC-8FF2-195558D6BCE7Q57663495-E088138D-F46F-4157-A4AA-034797DA828FQ57663500-358AD163-CFF6-4715-8E95-5E3FB61CCA56Q60950843-D6018F90-8CE0-42F9-9E18-28F5AD934758Q61812478-A2AB1798-ACC0-447A-9384-3D0B2E17E615Q87139132-684E2FAA-704F-48DF-9AC2-2AB4EFBEC3C8Q89774448-FC8AB31C-2699-4A64-B776-03AF14A1C144
P50
description
onderzoeker
@nl
researcher
@en
հետազոտող
@hy
name
Carmine Settembre
@ast
Carmine Settembre
@en
Carmine Settembre
@es
Carmine Settembre
@nl
type
label
Carmine Settembre
@ast
Carmine Settembre
@en
Carmine Settembre
@es
Carmine Settembre
@nl
prefLabel
Carmine Settembre
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Carmine Settembre
@en
Carmine Settembre
@es
Carmine Settembre
@nl
P106
P1153
6504691421
P21
P31
P496
0000-0002-5829-8589