Golga5 is dispensable for mouse embryonic development and postnatal survival

McGee, Lynessa J.; Jiang, Alex; Lan, Yu

doi:10.1002/dvg.23039

Cited by 14 publications

(16 citation statements)

References 27 publications

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“…There are orthologs of golgin-84 in D. melanogaster and C. elegans , although they have yet to be analyzed at the functional level. Mice lacking golgin-84, also known as GOLGA5, are viable, and there is no overt phenotype in these mice, which develop and grow normally (McGee et al, 2017). There is also no male infertility, indicating that golgin-84 is dispensable for acrosome biogenesis.…”

Section: Animal Models For Golgin Functionmentioning

confidence: 99%

“…Loss of mammalian giantin, also called GOLGB1, in mouse knockout models, has revealed craniofacial defects, including a cleft palate (Lan et al, 2016; McGee et al, 2017). There is reduced accumulation of the matrix glycosaminoglycan (GAG) hyaluronan and reduced protein glycosylation, consistent with giantin functioning to maintain cargo protein glycosylation and GAG synthesis at the Golgi, which in turn is important for proper matrix assembly and formation of the palate (Lan et al, 2016).…”

Section: Animal Models For Golgin Functionmentioning

confidence: 99%

“…Thus, although giantin is widely expressed throughout the body, the knockout phenotype is restricted to certain tissues. The combined knockout of giantin and golgin-84 gives the same phenotype as loss of giantin alone, arguing against the possibility that these golgins function in a redundant manner in vivo (McGee et al, 2017). In contrast to knockout mouse models, rats lacking giantin display a much more severe phenotype, manifesting as an embryonic lethal osteochondrodysplasia, with systemic oedema and shortening of the long bones in addition to craniofacial defects and a cleft palate (Katayama et al, 2011).…”

Section: Animal Models For Golgin Functionmentioning

confidence: 99%

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The Physiological Functions of the Golgin Vesicle Tethering Proteins

Lowe

2019

Front. Cell Dev. Biol.

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The golgins comprise a family of vesicle tethering proteins that act in a selective manner to tether transport vesicles at the Golgi apparatus. Tethering is followed by membrane fusion to complete the delivery of vesicle-bound cargo to the Golgi. Different golgins are localized to different regions of the Golgi, and their ability to selectively tether transport vesicles is important for the specificity of vesicle traffic in the secretory pathway. In recent years, our mechanistic understanding of golgin-mediated tethering has greatly improved. We are also beginning to appreciate how the loss of golgin function can impact upon physiological processes through the use of animal models and the study of human disease. These approaches have revealed that loss of a golgin causes tissue-restricted phenotypes, which can vary in severity and the cell types affected. In many cases, it is possible to attribute these phenotypes to a defect in vesicular traffic, although why certain tissues are sensitive to loss of a particular golgin is still, in most cases, unclear. Here, I will summarize recent progress in our understanding of golgins, focusing on the physiological roles of these proteins, as determined from animal models and the study of disease in humans. I will describe what these in vivo analyses have taught us, as well as highlight less understood aspects, and areas for future investigations.

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Section: Animal Models For Golgin Functionmentioning

confidence: 99%

Section: Animal Models For Golgin Functionmentioning

confidence: 99%

Section: Animal Models For Golgin Functionmentioning

confidence: 99%

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The Physiological Functions of the Golgin Vesicle Tethering Proteins

Lowe

2019

Front. Cell Dev. Biol.

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“…Interestingly, chondrocytes from homozygous animals have expanded ER and Golgi membranes whilst cartilage growth plates contain less extracellular matrix (ECM), indicative of secretory pathway defects ( Katayama et al, 2011 ). Mouse giantin-KO models have less-complex developmental disorders, with the predominant phenotype being cleft palate ( Lan et al, 2016 ) and short stature ( McGee et al, 2017 ). These animals also have ECM abnormalities associated with glycosylation defects, but Golgi structure is normal ( Lan et al, 2016 ).…”

Section: Introductionmentioning

confidence: 99%

Giantin-knockout models reveal a feedback loop between Golgi function and glycosyltransferase expression

Stevenson

Bergen

Skinner

et al. 2017

Journal of Cell Science

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The Golgi is the cellular hub for complex glycosylation, controlling accurate processing of complex proteoglycans, receptors, ligands and glycolipids. Its structure and organisation are dependent on golgins, which tether cisternal membranes and incoming transport vesicles. Here, we show that knockout of the largest golgin, giantin, leads to substantial changes in gene expression but only limited effects on Golgi structure. Notably, 22 Golgi-resident glycosyltransferases, but not glycan-processing enzymes or the ER glycosylation machinery, are differentially expressed following giantin ablation. This includes near-complete loss of function of GALNT3 in both mammalian cell and zebrafish models. Giantin-knockout zebrafish exhibit hyperostosis and ectopic calcium deposits, recapitulating phenotypes of hyperphosphatemic familial tumoral calcinosis, a disease caused by mutations in GALNT3. These data reveal a new feature of Golgi homeostasis: the ability to regulate glycosyltransferase expression to generate a functional proteoglycome.

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“…Animal knockout (KO) models for Golgins such as Giantin or GMAP 210 have shown them to be essential for healthy development, as these animals exhibit defects in craniofacial and skeletal development (Smits et al, 2010; Stevenson et al, 2017). On the other hand, KO of Golgin-84, a protein closely related to Giantin, does not show any significant developmental abnormalities, and compound mutants for both of these Golgins do not show any additional defects (McGee et al, 2017). While these models highlight the importance of Golgins in embryonic development, some Golgins might be dispensable; indeed, several Golgins are associated with human diseases (Toh and Gleeson, 2016), but only a few have been linked to obvious neurological defects.…”

Section: Structural Proteins Of the Gc And Their Role In Neurodevelopmentioning

confidence: 99%

Golgi Complex Dynamics and Its Implication in Prevalent Neurological Disorders

Caracci

Fuentealba

Marzolo

2019

Front. Cell Dev. Biol.

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Coupling of protein synthesis with protein delivery to distinct subcellular domains is essential for maintaining cellular homeostasis, and defects thereof have consistently been shown to be associated with several diseases. This function is particularly challenging for neurons given their polarized nature and differential protein requirements in synaptic boutons, dendrites, axons, and soma. Long-range trafficking is greatly enhanced in neurons by discrete mini-organelles resembling the Golgi complex (GC) referred to as Golgi outposts (GOPs) which play an essential role in the development of dendritic arborization. In this context, the morphology of the GC is highly plastic, and the polarized distribution of this organelle is necessary for neuronal migration and polarized growth. Furthermore, synaptic components are readily trafficked and modified at GOP suggesting a function for this organelle in synaptic plasticity. However, little is known about GOPs properties and biogenesis and the role of GOP dysregulation in pathology. In this review, we discuss current literature supporting a role for GC dynamics in prevalent neurological disorders such as Alzheimer’s disease, Parkinson’s disease, Huntington’s disease, and epilepsy, and examine the association of these disorders with the wide-ranging effects of GC function on common cellular pathways regulating neuronal excitability, polarity, migration, and organellar stress. First, we discuss the role of Golgins and Golgi-associated proteins in the regulation of GC morphology and dynamics. Then, we consider abnormal GC arrangements observed in neurological disorders and associations with common neuronal defects therein. Finally, we consider the cell signaling pathways involved in the modulation of GC dynamics and argue for a master regulatory role for Reelin signaling, a well-known regulator of neuronal polarity and migration. Determining the cellular pathways involved in shaping the Golgi network will have a direct and profound impact on our current understanding of neurodevelopment and neuropathology and aid the development of novel therapeutic strategies for improved patient care and prognosis.

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Golga5 is dispensable for mouse embryonic development and postnatal survival

Cited by 14 publications

References 27 publications

The Physiological Functions of the Golgin Vesicle Tethering Proteins

The Physiological Functions of the Golgin Vesicle Tethering Proteins

Giantin-knockout models reveal a feedback loop between Golgi function and glycosyltransferase expression

Golgi Complex Dynamics and Its Implication in Prevalent Neurological Disorders

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