<scp>MALDI‐MS</scp> profiling of serum <i>O</i>‐glycosylation and <i>N</i>‐glycosylation in <scp>COG5‐CDG</scp>

Palmigiano, Angelo; Bua, Rosaria Ornella; Barone, Rita; Rymen, Daisy; Régal, Luc; Deconinck, Nicolas; Dionisi‐Vici, Carlo; Fung, Cheuk‐Wing; Garozzo, Domenico; Jaeken, Jaak; Sturiale, Luisa

doi:10.1002/jms.3936

Cited by 23 publications

(24 citation statements)

References 26 publications

(58 reference statements)

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“…N-glycan mass spectrometry (MS) analysis confirmed hyposialylation of N-glycans, similar to CHO-COG mutants and COG-CDG patients (discussed in the next section). Fly COG mutants also displayed increased high-mannose, paucimannose, and Humans, COG4-CDG COG4 (R729W), COG4 (G516R) Cells: reduction in COG3 (50%), COG2 (40%), COG1 (25%), and COG5 (40%) protein levels, COG complex formation seemed to be unaffected, mild Golgi dysfunction (compared to COG7 or COG8-CDG), Golgi dilatation and fragmentationPatients: Saul-Wilson syndrome, a rare form of primordial dwarfism with characteristic facial and radiographic features [102,115] Humans, COG5-CDG COG5 (homozygous intronic substitution (c.1669-15T>C) leading to exon skipping) Cells: undersialylation of N-and O-glycansPatients: moderate psychomotor retardation with language delay, truncal ataxia and slight hypotonia [110,166,174,175] Humans, COG6-CDG COG6 (G549V) Cells: reduction in STX6 levels, glycosylation defects including reduced sialyation of O-glycans; decreased activity of B4GALT1 but normal import of UDP-galactose into the Golgi, reduced protein levels of COG5 (55%), COG6 (21%), and COG7 (62%), degradation of mRNA encoding COG6, formation of the COG complex affectedPatients: microcephaly, chronic inflammatory bowel disease, micronodular liver cirrhosis, severe neurologic disease characterized by vitamin K deficiency, vomiting, intractable focal seizures, intracranial bleedings and fatal outcome in early infancy [176][177][178][179] Humans, COG7-CDG COG7 (intronic splice site mutation (c.169+4A>C)) Cells: disruption of multiple N-and O-glycosylation pathways, completely destabilized COG complexPatients: growth retardation, microcephaly, hypotonia, adducted thumbs, feeding problems, failure to thrive, cardiac anomalies, wrinkled skin and episodes of extreme hyperthermia, skeletal anomalies and a mild liver involvement [96,101,173,180] Humans, COG8-CDG COG8 Cells: deficient in sialylation of both N-and O-glycans, slower brefeldin A induced disruption of the Golgi matrix, reduction in COG1, COG5, COG6, and COG7 protein levels but not COG2, COG3 and COG4, COG5, COG6, and COG7 were also mislocalizedPatients: cerebellar atrophy, Elevated blood creatine phosphokinase, Alternating esotropia, psychomotor retardation, failure to thrive, intolerance to wheat and dairy products, lack of bowel or bladder control, dry skin with keratosis pilaris, mild contractures of the lower extremities [99,100,103,107,108] Humans, TMED6-COG8 translocation…”

Section: Misglycosylationmentioning

confidence: 99%

Maintaining order: COG complex controls Golgi trafficking, processing, and sorting

2019

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The conserved oligomeric Golgi (COG) complex, a multisubunit tethering complex of the CATCHR (complexes associated with tethering containing helical rods) family, controls membrane trafficking and ensures Golgi homeostasis by orchestrating retrograde vesicle targeting within the Golgi. In humans, COG defects lead to severe multisystemic diseases known as COG‐congenital disorders of glycosylation (COG‐CDG). The COG complex both physically and functionally interacts with all classes of molecules maintaining intra‐Golgi trafficking, namely SNAREs, SNARE‐interacting proteins, Rabs, coiled‐coil tethers, and vesicular coats. Here, we review our current knowledge of COG‐related trafficking and glycosylation defects in humans and model organisms, and analyze possible scenarios for the molecular mechanism of the COG orchestrated vesicle targeting.

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Section: Misglycosylationmentioning

confidence: 99%

Maintaining order: COG complex controls Golgi trafficking, processing, and sorting

2019

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“…Clinically, patients of COG-CDGs present with prominent incomplete galactosylation and sialylation [149,153], and this is true for variants in both lobe A and B subunits. While the variants mostly consist of missense mutations or truncations for lobe A subunits and full loss-of-function mutations in lobe B subunits, glycan profiles of patients show the same hypogalactosylation and hyposialylation for both types of mutations [154,155]. This raises the question of whether mutations in one COG subunit affect the entire COG complex.…”

Section: Conserved Oligomeric Golgi Tethering Complexmentioning

confidence: 99%

Sugary Logistics Gone Wrong: Membrane Trafficking and Congenital Disorders of Glycosylation

Linders

Peters

Beest

et al. 2020

IJMS

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Glycosylation is an important post-translational modification for both intracellular and secreted proteins. For glycosylation to occur, cargo must be transported after synthesis through the different compartments of the Golgi apparatus where distinct monosaccharides are sequentially bound and trimmed, resulting in increasingly complex branched glycan structures. Of utmost importance for this process is the intraorganellar environment of the Golgi. Each Golgi compartment has a distinct pH, which is maintained by the vacuolar H+-ATPase (V-ATPase). Moreover, tethering factors such as Golgins and the conserved oligomeric Golgi (COG) complex, in concert with coatomer (COPI) and soluble N-ethylmaleimide-sensitive factor attachment protein receptor (SNARE)-mediated membrane fusion, efficiently deliver glycosylation enzymes to the right Golgi compartment. Together, these factors maintain intra-Golgi trafficking of proteins involved in glycosylation and thereby enable proper glycosylation. However, pathogenic mutations in these factors can cause defective glycosylation and lead to diseases with a wide variety of symptoms such as liver dysfunction and skin and bone disorders. Collectively, this group of disorders is known as congenital disorders of glycosylation (CDG). Recent technological advances have enabled the robust identification of novel CDGs related to membrane trafficking components. In this review, we highlight differences and similarities between membrane trafficking-related CDGs.

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“…Apo C-III has only a single O-glycan on Thr-74 which is terminally modified by up to two sialic acids to generate three main IEF isoforms: Apo C-III 0 (no sialic acid), Apo C-III 1 (one sialic acid), and Apo C-III 2 (two sialic acids). Decreased sialylation on Apo C-III profiles has been reported in conserved oligomeric Golgi (COG) defects (Spaapen et al 2005 ; Foulquier et al 2006 ; Foulquier et al 2007 ; Kranz et al 2007 ; Morava et al 2007 ; Wopereis et al 2007 ; Zeevaert et al 2008 ; Ng et al 2011 ; Palmigiano et al 2017 ) and autosomal recessive cutis laxa type-2 (ARCL2) due to ATP6V0A2 dysfunctions (Morava et al 2005 ; Kornak et al 2008 ). The limitation of Apo C-III IEF is that it is not able to differentiate between the three possible Apo C-III 0 isoforms; the “real unglycosylated Apo C-III” and Apo C-III with two non-sialylated monosaccharides namely Gal and GalNAc.…”

Section: Overview Of the Current Cdg Diagnostic Workflowmentioning

confidence: 98%

Clinical glycomics for the diagnosis of congenital disorders of glycosylation

Bakar

Lefeber

Scherpenzeel

2018

J of Inher Metab Disea

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Clinical glycomics comprises a spectrum of different analytical methodologies to analyze glycan structures, which provides insights into the mechanisms of glycosylation. Within clinical diagnostics, glycomics serves as a functional readout of genetic variants, and can form a basis for therapy development, as was described for PGM1-CDG. Integration of glycomics with genomics has resulted in the elucidation of previously unknown disorders of glycosylation, namely CCDC115-CDG, TMEM199-CDG, ATP6AP1-CDG, MAN1B1-CDG, and PGM1-CDG. This review provides an introduction into protein glycosylation and presents the different glycomics methodologies ranging from gel electrophoresis to mass spectrometry (MS) and from free glycans to intact glycoproteins. The role of glycomics in the diagnosis of congenital disorders of glycosylation (CDG) is presented, including a diagnostic flow chart and an overview of glycomics data of known CDG subtypes. The review ends with some future perspectives, showing upcoming technologies as system wide mapping of the N- and O-glycoproteome, intact glycoprotein profiling and analysis of sugar metabolism. These new advances will provide additional insights and opportunities to develop personalized therapy. This is especially true for inborn errors of metabolism, which are amenable to causal therapy, because interventions through supplementation therapy can directly target the pathogenesis at the molecular level.

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MALDI‐MS profiling of serum O‐glycosylation and N‐glycosylation in COG5‐CDG

Cited by 23 publications

References 26 publications

Maintaining order: COG complex controls Golgi trafficking, processing, and sorting

Maintaining order: COG complex controls Golgi trafficking, processing, and sorting

Sugary Logistics Gone Wrong: Membrane Trafficking and Congenital Disorders of Glycosylation

Clinical glycomics for the diagnosis of congenital disorders of glycosylation

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