FRAP Analysis Reveals Stabilization of Adhesion Structures in the Epidermis Compared to Cultured Keratinocytes

Proper development and tissue maintenance requires cell-cell adhesion structures, which serve diverse and crucial roles in tissue morphogenesis. Epithelial tissues have three main types of cell-cell junctions: tight junctions, which play a major role in barrier formation, and adherens junctions and desmosomes, which provide mechanical stability and organize the underlying cytoskeleton. Our current understanding of adhesion function is hindered by a lack of tools and methods to image junctions in mammals. To better understand the dynamics of adhesion in tissues we have created a knock-in ZO-1-GFP mouse and a BAC-transgenic mouse expressing desmoplakin I-GFP. We performed fluorescence recovery after photobleaching (FRAP) experiments to quantify the turnover rates of the tight junction protein ZO-1, the adherens junction protein E-cadherin, and the desmosomal protein desmoplakin in the epidermis. Proteins at each type of junction are remarkably stable in the epidermis, in contrast to the high observed mobility of E-cadherin and ZO-1 at adherens junctions and tight junctions, respectively, in cultured cells. Our data demonstrate that there are additional mechanisms for stabilizing junctions in tissues that are not modeled by cell culture

Rap1 and Canoe/afadin are essential for establishment of apical-basal polarity in the Drosophila embryo

The small GTPase Rap1 and the actin-junctional linker protein Canoe/afadin are essential for the initial establishment of polarity in Drosophila, acting upstream of Bazooka/Par3 and the adherens junctions. However, feedback and cross-regulation occur, so polarity establishment is regulated by a network of proteins rather than a linear pathway.The establishment and maintenance of apical–basal cell polarity is critical for assembling epithelia and maintaining organ architecture. Drosophila embryos provide a superb model. In the current view, apically positioned Bazooka/Par3 is the initial polarity cue as cells form during cellularization. Bazooka then helps to position both adherens junctions and atypical protein kinase C (aPKC). Although a polarized cytoskeleton is critical for Bazooka positioning, proteins mediating this remained unknown. We found that the small GTPase Rap1 and the actin-junctional linker Canoe/afadin are essential for polarity establishment, as both adherens junctions and Bazooka are mispositioned in their absence. Rap1 and Canoe do not simply organize the cytoskeleton, as actin and microtubules become properly polarized in their absence. Canoe can recruit Bazooka when ectopically expressed, but they do not obligatorily colocalize. Rap1 and Canoe play continuing roles in Bazooka localization during gastrulation, but other polarity cues partially restore apical Bazooka in the absence of Rap1 or Canoe. We next tested the current linear model for polarity establishment. Both Bazooka and aPKC regulate Canoe localization despite being “downstream” of Canoe. Further, Rap1, Bazooka, and aPKC, but not Canoe, regulate columnar cell shape. These data reshape our view, suggesting that polarity establishment is regulated by a protein network rather than a linear pathway

Abelson kinase acts as a robust, multifunctional scaffold in regulating embryonic morphogenesis

Abelson family kinases (Abl) are key regulators of cell behavior and the cytoskeleton during development and in leukemia. Abl's SH3, SH2, and tyrosine kinase domains are joined via a linker to an F-actin-binding domain (FABD). Research on Abl's roles in cell culture led to several hypotheses for its mechanism of action: 1) Abl phosphorylates other proteins, modulating their activity. 2) Abl directly regulates the cytoskeleton via its cytoskeletal interaction domains, and/or 3) Abl is a scaffold for a signaling complex. The importance of these roles during normal development remains untested. We tested these mechanistic hypotheses during Drosophila morphogenesis using a series of mutants to examine Abl's many cell biological roles. Strikingly, Abl lacking the FABD fully rescued morphogenesis, cell shape change, actin regulation, and viability, while kinase dead Abl, though reduced in function, retained substantial rescuing ability in some but not all Abl functions. We also tested the function of four conserved motifs in the linker region, revealing a key role for a conserved PXXP motif known to bind Crk and Abi. We propose Abl acts as a robust multi-domain scaffold with different protein motifs and activities contributing differentially to diverse cellular behaviors

Lis1 is essential for cortical microtubule organization and desmosome stability in the epidermis

Desmoplakin recruits the centrosomal protein Lis1 to the epidermal cell cortex, where it regulates cortical microtubule organization and desmosome stability

Novel Roles for Desmosomes in Cytoskeletal Organization

<p>Microtubules often adopt non-centrosomal arrays in differentiated tissues, where they are important for providing structure to the cell and maintaining polarity. Although the formation and organization of centrosomal arrays has been well-characterized, little is known about how microtubules form non-centrosomal arrays.</p><p>In the mouse epidermis, centrosomes in differentiated cells lose their microtubule-anchoring ability through the loss of proteins from the centrosome. Instead, microtubules are organized around the cell cortex. The cell-cell adhesion protein desmoplakin is required for this organization. Our model is that desmoplakin recruits microtubule-anchoring proteins like ninein to the desmosome, where they subsequently recruit and organize microtubules.</p><p>To test this model, we confirmed that the microtubule-binding proteins Lis1, Ndel1, and CLIP170 are recruited by desmoplakin to the cell cortex. Furthermore, by creating an epidermis-specific conditional Lis1 knockout mouse, I found that Lis1 is required for cortical microtubule organization. Surprisingly, however, Lis1 is also required for desmosome stability. This work reveals essential desmosome-associated components that control cortical microtubule organization and unexpected roles for centrosomal proteins in epidermal function.</p><p>Although Lis1 is required for microtubule organization, it is not sufficient. I created a culture-based system to determine what other factors may be required for cortical organization for microtubules. My work reveals that stabilization of the microtubules is sufficient to induce their cortical organization. Functionally, cortical microtubules are important for increasing the mechanical integrity of cell sheets by engaging adherens junctions. In turn, tight junction activity is increased. Therefore, I propose that cortical microtubules in the epidermis are important in forming a robust barrier by cooperatively strengthening each cell-cell junction.</p><p>To determine whether desmosomes play similar roles in simple epithelia as stratified epithelia, I examined intestinal epithelial-specific conditional desmoplakin conditional knockout mice. Unexpectedly, I found that desmoplakin is not required for cell-cell adhesion and tissue integrity in the small intestine. Furthermore, it does not organize intermediate filaments. Desmoplakin is required, however, for proper microvillus architecture. </p><p>Overall, my studies highlight novel tissue-specific roles for desmosomes, in particular desmoplakin, in organizing and integrating different cytoskeletal networks. How desmoplakin's function is regulated in each tissue will be a new interesting area of research.</p>Dissertatio

FRAP analysis reveals stabilization of adhesion structures in the epidermis compared to cultured keratinocytes.

Proper development and tissue maintenance requires cell-cell adhesion structures, which serve diverse and crucial roles in tissue morphogenesis. Epithelial tissues have three main types of cell-cell junctions: tight junctions, which play a major role in barrier formation, and adherens junctions and desmosomes, which provide mechanical stability and organize the underlying cytoskeleton. Our current understanding of adhesion function is hindered by a lack of tools and methods to image junctions in mammals. To better understand the dynamics of adhesion in tissues we have created a knock-in ZO-1-GFP mouse and a BAC-transgenic mouse expressing desmoplakin I-GFP. We performed fluorescence recovery after photobleaching (FRAP) experiments to quantify the turnover rates of the tight junction protein ZO-1, the adherens junction protein E-cadherin, and the desmosomal protein desmoplakin in the epidermis. Proteins at each type of junction are remarkably stable in the epidermis, in contrast to the high observed mobility of E-cadherin and ZO-1 at adherens junctions and tight junctions, respectively, in cultured cells. Our data demonstrate that there are additional mechanisms for stabilizing junctions in tissues that are not modeled by cell culture

ZO-1 GFP exhibits low mobility in epidermis.

<p>A–D) Localization of ZO-1-GFP in skin sections taken from a ZO-1-GFP knock-in mouse. Scale bar 10 µm. A) ZO-1-GFP co-localizes with the tight junction protein occludin in kidney tissue sections of adult mouse. DNA is stained blue. B) Tissue section of lung taken from adult mouse. C) Whole mount epidermis of embryonic day 17.5 mouse. Note the ZO-1 signal in distinctive cobblestone pattern at cell-cell junctions in the granular layer. D) Whole mount small intestine taken from adult mouse. E) Mobile fractions from FRAP experiments are plotted. The box represents the 25^th to 75^th percentile and the whiskers represent the 10^th and 90^th percentiles. ** p<.005. *** p<.0001. F) Representative kymographs are shown of individual FRAP experiments. The bleach point is indicated by the red triangle. Scale bar 1 µm.</p

DPI-GFP is stable at desmosomes in both epidermis and in cultured keratinocytes.

<p>A–C) Tissue sections from the adult BAC transgenic DPI-GFP mouse. DNA is stained in blue. Scale bar 10 µm. A) DPI-GFP localization in heart tissue section. Note the strong bands of signal at intercalated discs (arrow). There is strong autofluorescence from thick actin bundles in cardiac muscle fibers (arrow head). B) DPI-GFP localization in lung tissue section. C) DPI-GFP localization in epidermal tissue section. Asterisk labels autofluorescence of cornified layer. D) Mobile fractions from FRAP experiments are plotted. The box represents the 25^th to 75^th percentile and the whiskers represent the 10^th and 90^th percentiles.</p

Spine Patterning Is Guided by Segmentation of the Notochord Sheath

The spine is a segmented axial structure made of alternating vertebral bodies (centra) and intervertebral discs (IVDs) assembled around the notochord. Here, we show that, prior to centra formation, the outer epithelial cell layer of the zebrafish notochord, the sheath, segments into alternating domains corresponding to the prospective centra and IVD areas. This process occurs sequentially in an anteroposterior direction via the activation of Notch signaling in alternating segments of the sheath, which transition from cartilaginous to mineralizing domains. Subsequently, osteoblasts are recruited to the mineralized domains of the notochord sheath to form mature centra. Tissue-specific manipulation of Notch signaling in sheath cells produces notochord segmentation defects that are mirrored in the spine. Together, our findings demonstrate that notochord sheath segmentation provides a template for vertebral patterning in the zebrafish spine. Wopat et al. show that the outer layer of the zebrafish notochord, the sheath, segments into alternating mineralizing and cartilage-like domains prior to vertebral body formation. Mineralized sheath domains, patterned by the segmented activation of Notch, then recruit osteoblasts to form vertebral bodies. Thus, the notochord instructs spine patterning

Loss of Serum Glucocorticoid-Inducible Kinase 1 SGK1 Worsens Malabsorption and Diarrhea in Microvillus Inclusion Disease (MVID)

Microvillus inclusion disease (MVID), a lethal congenital diarrheal disease, results from loss of function mutations in the apical actin motor myosin VB (MYO5B). How loss of MYO5B leads to both malabsorption and fluid secretion is not well understood. Serum glucocorticoid-inducible kinase 1 (SGK1) regulates intestinal carbohydrate and ion transporters including cystic fibrosis transmembrane conductance regulator (CFTR). We hypothesized that loss of SGK1 could reduce CFTR fluid secretion and MVID diarrhea. Using CRISPR-Cas9 approaches, we generated R26(Cre)ER;MYO5B(f/f) conditional single knockout (cMYO5BKO) and R26(Cre)ER;MYO5B(f/f);SGK1(f/f) double knockout (cSGK1/MYO5B-DKO) mice. Tamoxifen-treated cMYO5BKO mice resulted in characteristic features of human MVID including severe diarrhea, microvillus inclusions (MIs) in enterocytes, defective apical traffic, and depolarization of transporters. However, apical CFTR distribution was preserved in crypts and depolarized in villus enterocytes, and CFTR high expresser (CHE) cells were observed. cMYO5BKO mice displayed increased phosphorylation of SGK1, PDK1, and the PDK1 target PKC iota in the intestine. Surprisingly, tamoxifen-treated cSGK1/MYO5B-DKO mice displayed more severe diarrhea than cMYO5BKO, with preservation of apical CFTR and CHE cells, greater fecal glucose and reduced SGLT1 and GLUT2 in the intestine. We conclude that loss of SGK1 worsens carbohydrate malabsorption and diarrhea in MVID