Sanne Remmelzwaal scite author profile

The microtubule cytoskeleton regulates cell polarity by spatially organizing membrane trafficking and signaling processes. In epithelial cells, microtubules form parallel arrays aligned along the apico-basal axis, and recent work has demonstrated that the members of CAMSAP/Patronin family control apical tethering of microtubule minus ends. Here, we show that in mammalian intestinal epithelial cells, the spectraplakin ACF7 (also known as MACF1) specifically binds to CAMSAP3 and is required for the apical localization of CAMSAP3-decorated microtubule minus ends. Loss of ACF7 but not of CAMSAP3 or its homolog CAMSAP2 affected the formation of polarized epithelial cysts in three-dimensional cultures. In short-term epithelial polarization assays, knockout of CAMSAP3, but not of CAMSAP2, caused microtubule re-organization into a more radial centrosomal array, redistribution of Rab11-positive (also known as Rab11A) endosomes from the apical cell surface to the pericentrosomal region and inhibition of actin brush border formation at the apical side of the cell. We conclude that ACF7 is an important regulator of apico-basal polarity in mammalian intestinal cells and that a radial centrosome-centered microtubule organization can act as an inhibitor of epithelial polarity.

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Targeted Analysis of Lysosomal Directed Proteins and Their Sites of Mannose-6-phosphate Modification

Čaval

Zhu

Tian

et al. 2019

Molecular & Cellular Proteomics

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Correspondence a.j.r.heck@uu.nl In BriefHere a Fe 3ϩ -IMAC-based enrichment method is presented targeting mannose-6-phosphate (M6P) modified glycopeptides enabling the detailed profiling of these in both HeLa and CHO cells. A gene engineering strategy was used to remove the Acp2/5 phosphatases, which increased the abundance and coverage of the M6P-modified glycoproteome. We demonstrate that such a gene engineering strategy can be beneficial for the expression of alpha-galactoside and other enzymes used in the treatment of lysosomal storage diseases. Graphical AbstractP P P P P P P P P Fe 3+ -IMAC P P P P P P P P P P P P P P P P P P Peptide mixture HCD P P P P P P P P P P EThcD P P P P P P P P P P LVQAEYWHDPIKEDVYRNHSIFLADINQER P P Highlights• Fe 3ϩ -IMAC enables co-enrichment of mannose-6-phosphate (M6P) modified glycopeptides.• Detailed characterization of intact M6P modified glycopeptides from HeLa and CHO cell lines.• EThcD results in a cleavage between 2 core GlcNAc residues enabling unambiguous glycoform identification.• Double knock out of the phosphatases Acp2/5 results in a 20-fold increase in abundance of M6P modified glycopeptides.• Recombinant expression of alpha-galactoside in an Acp2/5 KO CHO cell drastically increases its M6P content.

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MICAL3 Flavoprotein Monooxygenase Forms a Complex with Centralspindlin and Regulates Cytokinesis

Liu

et al. 2016

Journal of Biological Chemistry

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During cytokinesis, the antiparallel array of microtubules forming the central spindle organizes the midbody, a structure that anchors the ingressed cleavage furrow and guides the assembly of abscission machinery. Here, we identified a role for the flavoprotein monooxygenase MICAL3, an actin disassembly factor, in organizing midbody-associated protein complexes. By combining cell biological assays with cross-linking mass spectrometry, we show that MICAL3 is recruited to the central spindle and the midbody through a direct interaction with the centralspindlin component MKLP1. Knock-out of MICAL3 leads to an increased frequency of cytokinetic failure and a delayed abscission. In a mechanism independent of its enzymatic activity, MICAL3 targets the adaptor protein ELKS and Rab8A-positive vesicles to the midbody, and the depletion of ELKS and Rab8A also leads to cytokinesis defects. We propose that MICAL3 acts as a midbody-associated scaffold for vesicle targeting, which promotes maturation of the intercellular bridge and abscission.

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BBLN-1 is essential for intermediate filament organization and apical membrane morphology

et al. 2021

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Epithelial tubes are essential components of metazoan organ systems that control the flow of fluids and the exchange of materials between body compartments and the outside environment. The size and shape of the central lumen confer important characteristics to tubular organs and need to be carefully controlled. Here, we identify the small coiled-coil protein BBLN-1 as a regulator of lumen morphology in the C. elegans intestine. Loss of BBLN-1 causes the formation of bubble-shaped invaginations of the apical membrane into the cytoplasm of intestinal cells and abnormal aggregation of the subapical intermediate filament (IF) network. BBLN-1 interacts with IF proteins and localizes to the IF network in an IF-dependent manner. The appearance of invaginations is a result of the abnormal IF aggregation, indicating a direct role for the IF network in maintaining lumen homeostasis. Finally, we identify bublin (BBLN) as the mammalian ortholog of BBLN-1. When expressed in the C. elegans intestine, BBLN recapitulates the localization pattern of BBLN-1 and can compensate for the loss of BBLN-1 in early larvae. In mouse intestinal organoids, BBLN localizes subapically, together with the IF protein keratin 8. Our results therefore may have implications for understanding the role of IFs in regulating epithelial tube morphology in mammals.

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Facilitating identification of minimal protein binding domains by cross-linking mass spectrometry

Liu

Remmelzwaal

Heck

et al. 2017

Sci Rep

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Characterization of protein interaction domains is crucial for understanding protein functions. Here we combine cross-linking mass spectrometry (XL-MS) with deletion analysis to accurately locate minimal protein interaction domains. As a proof of concept, we investigated in detail the binding interfaces of two protein assemblies: the complex formed by MICAL3, ELKS and Rab8A, which is involved in exocytosis, and the complex of SLAIN2, CLASP2 and ch-TOG, which controls microtubule dynamics. We found that XL-MS provides valuable information to efficiently guide the design of protein fragments that are essential for protein interaction. However, we also observed a number of cross-links between polypeptide regions that were dispensable for complex formation, especially among intrinsically disordered sequences. Collectively, our results indicate that XL-MS, which renders distance restrains of linked residue pairs, accelerates the characterization of protein binding regions in combination with other biochemical approaches.

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