Sherry N. Hsieh’s research while affiliated with Northwestern University and other places

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Publications (6)


[Supplemental Material Index]
  • Data

May 2008

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4 Reads

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Evangeline V. Amargo

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PKP2 is required for proper assembly of DP into desmosomes. (A and B) Impaired DP border localization in PKP2-deficient cultures. SCC9 cells (A, wide-field microscopy) or A431 cells (B, confocal microscopy) expressing pooled siRNAs against human PKP2 or nontargeting (NT) control, immunostained for endogenous DP and PKP2. Immunoblot analysis of SCC9 (A, right) or A431 (B, right) from NT or PKP2 siRNA-transfected cells to detect total levels of PKP2, PKP1, PKP3, DP, DSC2, DSG2, DSG3, and α-tubulin. PG protein levels were unaffected (not depicted). Arrows indicate the cell–cell border. (C) DP particles colocalize with keratin IF during PKP2 knockdown. Confocal images of SCC9 cells expressing PKP2 or NT siRNA immunostained for DP (green) and keratin (red). Panels b′ and d′ show magnified views of the boxed areas in a′ and c′, respectively. (D) DP assembly is impaired during PKP2 knockdown. Calcium switch of SCC9 cells transfected with siRNA against PKP2 or NT + siGlo, endogenous PKP2, or DP staining. DP border fluorescence intensity was measured, normalized to background, and plotted in D (right). Arrows indicate siGLO particles. Error bars represent SEM. (E) DP accumulates in a filamentous cytoplasmic pattern during PKP2 knockdown. Shown are stills from Videos 1 and 2 depicting PKP2 or NT siRNA-transfected A431 DP-GFP cells. Arrows indicate where new borders are being formed. Red arrowheads show DP accumulation on IF. Time points indicate time lapsed from beginning of video. Bars, 10 μm.
DPser2849 and PKC activity are required for proper DP border localization. (A, left) PKC inhibition impairs DP border localization and induces a filamentous pattern. SCC9 cells treated with 12.5 μM BIM or DMSO for 30 min and immunostained for endogenous DP. (A, right) BIM-treated A431 DP-GFP cells. (B) PKA inhibition does not affect DP border localization. SCC9 cells in low calcium treated with 10 μM H-89 or DMSO and switched to high calcium for 3 h, immunostained for endogenous DP. Quantitative analysis of border fluorescence intensity confirmed that DP localization was comparable in H-89–treated cells. (C) Mutation of Ser2849 results in IF alignment (Godsel et al., 2005). Fixed A431 cells expressing DP-GFP (a′) or DPS2849G-GFP (b′) for comparison with D. (D, a′) Selected stills from Video 4 of A431 DP-GFP cells treated with 12.5 μM BIM. The drug was added at beginning of video and maintained throughout the 90-min time course. (D, b′) Video 5 of untreated A431 DPS2849G-GFP. Arrows indicate areas where new cell–cell contacts occur. Note the variability in the DPS2849G-GFP pattern ranging from particulate to continuous filaments (compare with C). (E) Impaired DP border localization during PKCα knockdown. Calcium switch of SCC9 cells infected with PKCα small hairpin RNA retrovirus or empty virus immunostained for DP. DP border fluorescence was measured, normalized to background, and plotted on the right. Immunoblot analysis of PKC-deficient cells for DP, PKP2, DSG2, PKCα, or GAPDH loading control. Error bars represent SEM. Bars, 10 μm.
PKP2 regulates PKC signaling. (A) Enhanced PKC substrate phosphorylation during PKP2 knockdown. SCC9 cell lysates from nontargeting (NT) or PKP2 siRNA-transfected cells or cells treated with DMSO, 15 nM PMA, or 12.5 μM BIM for 30 min were probed for PKC substrates phospho-MARCKS or -adducin, total MARCKS, adducin, PKP2, or α-tubulin (loading control). Densitometry numbers below the blots represent ratios of phosphoprotein normalized to total protein from treatment samples relative to the NT siRNA sample. (B) PKCα coimmunoprecipitates the PKP2 N-terminal head but not the central armadillo repeat domain. FLAG-tagged PKCα and myc-tagged PKP2-Head or -Arm were cotransfected into HEK293 cells and subjected to anti-FLAG IP. Blots were probed with anti-myc or anti-FLAG antibodies. (bottom) A schematic of PKP2 constructs. 5% input blots represent 5% of triton lysate from which IP was performed, removed before IP for immunoblot analysis. (C) PKCα coimmunoprecipitates endogenous DP in HEK293 cells. FLAG-tagged wild-type PKCα or myristylated (constitutively active) PKCα were transfected into HEK293 cells and subjected to FLAG IP. Precipitates and lysates were probed for endogenous DP or FLAG. Data are representative of three independent experiments. (D) PKP2 is required for PKC–DP interaction. PKCα-FLAG was immunoprecipitated from HEK293 cells transfected with PKP2 or NT siRNA. Endogenous DP, PKP2, and FLAG were probed. Data are representative of three independent experiments. Densitometry (right) reveals 95% reduction in DP coimmunoprecipitated with PKCα.
PKP2, PMA, or PKCα restores DP incorporation into desmosomes. (A) PKP2 reexpression enhances DP border localization during PKP2 knockdown. Silencing-resistant FLAG-tagged PKP2 was coexpressed with PKP2 or nontargeting (NT) siRNA in SCC9 cells. Cells were stained for DP (right), FLAG, and PKP2 (using the same secondary antibody; left). Intensity of DP border fluorescence at borders between pairs of transfected cells or pairs of untransfected cells is shown on the far right. *, P < 0.001. (B) PKC activation rescues DP border localization during PKP2 knockdown. PKP2 siRNA or NT siRNA cells were treated with 15 nM PMA for 30 min and stained for DP. DP border fluorescence quantitation is shown on the bottom. **, P < 0.001. (C) PKC expression rescues DP border localization during PKP2 knockdown. SCC9 cells transfected with PKP2 or NT siRNA were infected with wild-type PKCα or constitutive active PKCα retrovirus and stained for PKP2 and DP. (C, top) Overexpression of PKCα rescues DP border localization. (C, bottom) DP localization at cell–cell borders was assessed for robustness by taking into account the percentage of occupied border, border continuity, and fluorescence intensity. Borders were scored on a graded scale of 1–5 and plotted as percentages of total borders counted. (C, bottom right) Representative borders scored from 1 to 5. 5 represents the most mature border, with most continuous and intense DP fluorescence, and 1 represents the least mature border, with minimal to no DP fluorescence. Graphs represent mean values from three independent experiments. NT and PKP2 siRNA experiments were performed at same time but separated in the graphs for clarity. Error bars represent SEM. Bars, 10 μm.
Model for role of PKP2 in PKC-regulated DP assembly. (A) Wild type. PKP2 recruits PKC to DP cytoplasmic complexes, where phosphorylation of DP at Ser2849 modulates its interaction with IF and allows DP assembly into cell–cell junctions. (B) PKP2 deficiency. PKC is no longer recruited to DP complexes and is free to phosphorylate other substrates, leading to aberrant accumulation of DP along IF and impaired DP assembly.
Plakophilin 2: A critical scaffold for PKCα that regulates intercellular junction assembly
  • Article
  • Full-text available

May 2008

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674 Reads

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142 Citations

Plakophilins (PKPs) are armadillo family members related to the classical cadherin-associated protein p120(ctn). PKPs localize to the cytoplasmic plaque of intercellular junctions and participate in linking the intermediate filament (IF)-binding protein desmoplakin (DP) to desmosomal cadherins. In response to cell-cell contact, PKP2 associates with DP in plaque precursors that form in the cytoplasm and translocate to nascent desmosomes. Here, we provide evidence that PKP2 governs DP assembly dynamics by scaffolding a DP-PKP2-protein kinase C alpha (PKC alpha) complex, which is disrupted by PKP2 knockdown. The behavior of a phosphorylation-deficient DP mutant that associates more tightly with IF is mimicked by PKP2 and PKC alpha knockdown and PKC pharmacological inhibition, all of which impair junction assembly. PKP2 knockdown is accompanied by increased phosphorylation of PKC substrates, raising the possibility that global alterations in PKC signaling may contribute to pathogenesis of congenital defects caused by PKP2 deficiency.

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Figure 4. Ultrastructural analysis: DP-GFP associates with nascent junctions, mature desmosomes, and PKP2-containing particles. Conventionally prepared keratinocytes (A, C, and E) and extracted, immunogold-labeled DP-GFP expressing cells (B, D, F, G, and H) were switched from low to normal calcium to induce early cell contacts. (A and C) Conventional EM of contact sites before the appearance of desmosomes. Electron dense, IF-associated cytoplasmic particles were seen in close proximity to microfilaments (MF) near borders (arrowheads) and microfilament-associated adherens junctions (AJ) at contact sites. (B and D) IF and immunogold-labeled DP-GFP at early cell-cell contact sites; white arrows indicate zone of contact. Cytoplasmic DP-GFP particles of varying size were observed near the zone of contact. (E) Conventional EM of a mature desmosome. (F) A mature desmosome with DP-GFP labeling (18-nm gold) at the plaque and along IF bundles labeled for keratin18 (10-nm gold). (G) DP-GFP (10-nm gold) and PKP2 (18-nm gold) at an early border. DP-GFP was observed in association with single or sparse IF at early contact sites (bottom right). (H) DP-GFP (10 nm) and PKP2 (18 nm) colocalized in cytoplasmic particles along IF. Bar, 1 m. 
Figure 8. DPgly-GFP associates strongly with IF and is insensitive to forskolin-induced junction recruitment. (A) SCC9 cells were transiently transfected with both full-length DP-RFP and DPgly-GFP. Although DP-RFP was largely at cell borders, DPgly-GFP more prominently decorated IF. Bar, 20 m. (B) Cells were fractionated into cytoplasmic (C), Triton X-100 soluble (S), and triton insoluble (I) fractions. DPgly-GFP in the insoluble fraction was 5 greater than DP-GFP. (C) SCC9 cells stably expressing DP-GFP or DPgly-GFP were treated with 100 M forskolin for 16 h. DP-GFP fluorescence increased at cell borders and was more organized with forskolin treatment. No difference in border fluorescence intensity was observed in cells expressing DPgly-GFP. Average fluorescence intensities for a fixed cell population are depicted graphically to the right of representative fluorescence images (*, P 0.00001). Error bars are SEM. Bar, 20 m. 
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Desmoplakin assembly dynamics in four dimensions: multiple phases differentially regulated by intermediate filaments and actin

January 2006

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123 Reads

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138 Citations

The intermediate filament (IF)-binding protein desmoplakin (DP) is essential for desmosome function and tissue integrity, but its role in junction assembly is poorly understood. Using time-lapse imaging, we show that cell-cell contact triggers three temporally overlapping phases of DP-GFP dynamics: (1) the de novo appearance of punctate fluorescence at new contact zones after as little as 3 min; (2) the coalescence of DP and the armadillo protein plakophilin 2 into discrete cytoplasmic particles after as little as 15 min; and (3) the cytochalasin-sensitive translocation of cytoplasmic particles to maturing borders, with kinetics ranging from 0.002 to 0.04 microm/s. DP mutants that abrogate or enhance association with IFs exhibit delayed incorporation into junctions, altering particle trajectory or increasing particle pause times, respectively. Our data are consistent with the idea that DP assembles into nascent junctions from both diffusible and particulate pools in a temporally overlapping series of events triggered by cell-cell contact and regulated by actin and DP-IF interactions.


Vitamin E: Critical Review of Its Current Use in Cosmetic and Clinical Dermatology

August 2005

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2,253 Reads

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158 Citations

Dermatologic Surgery

The lipophilic antioxidant vitamin E has been used for more than 50 years in clinical and experimental dermatology. However, although a large number of case reports were published, there is still a lack of controlled clinical studies providing a rationale for clinical indications and dosage. In contrast, advances in basic research on the physiology, mechanism of action, penetration, bioconversion, and photoprotection of vitamin E in human skin have led to the development of numerous new formulations for use in cosmetics and skin care products. This article reviews the basic mechanisms and possible cosmetical and clinical implications of the recent advances in cutaneous vitamin E research. Experimental evidence suggests that topical and oral vitamin E has anticarcinogenic, photoprotective, and skin barrier-stabilizing properties. Although its current use is largely limited to cosmetics, controlled clinical studies for indications such as atopic dermatitis or prevention of photocarcinogenesis are needed to evaluate the clinical benefit of vitamin E.


The Antioxidant Network of the Stratum corneum

February 2001

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3,432 Reads

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309 Citations

Current Problems in Dermatology

Many studies have demonstrated beneficial health effects of topical antioxidant application; however, the underlying mechanisms are not well understood. To better understand the protective mechanism of oxogenous anti-oxidants, it is important to clarify the physiological distribution, activity and regulation of antioxidants. Also, the generation of ROS by the resident and transient microbial flora and their interaction with cutaneous antioxidants appears to be of relevance for the redox properties of skin. Our studies have demonstrated that alpha-tocopherol is, relative to the respective levels in the epidermis, the major antioxidant in the human SC, that alpha-tocopherol depletion is a very early and sensitive biomarker of environmentally induced oxidation and that a physiological mechanism exists to transport alpha-tocopherol to the skin surface via sebaceous gland secretion. Furthermore, there is conclusive evidence that the introduction of carbonyl groups into human SC keratins is inducible by oxidants and that the levels of protein oxidation increase towards outer SC layers. The demonstration of specific redox gradients within the human SC may contribute to a better understanding of the complex biochemical processes of keratinization and desquamation. Taken together, the presented data suggest that, under conditions of environmentally challenged skin or during prooxidative dermatological treatment, topical and/or systemic application of antioxidants could support physiological mechanisms to maintain or restore a healthy skin barrier. Growing experimental evidence should lead to the development of more powerful pharmaceutical and cosmetic strategies involving antioxidant formulations to prevent UV-induced carcinogenesis and photoaging as well as to modulate desquamatory skin disorders.


Protein Oxidation in Human Stratum Corneum: Susceptibility of Keratins to Oxidation In Vitro and Presence of a Keratin Oxidation Gradient In Vivo

October 1999

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165 Reads

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135 Citations

Journal of Investigative Dermatology

The stratum corneum is located at the interface between body and environment and thus is constantly exposed to a pro-oxidative environment. Previously, we have demonstrated that stratum corneum lipids are targets of oxidative stress induced by ozone and by ultraviolet A and B exposure. Here, we employed an immunoblotting technique to detect protein oxidation in human stratum corneum obtained by tape stripping. After lysis, protein carbonyl groups were measured by derivatization with dinitrophenylhydrazine, separation by sodium dodecylsulfate-polyacrylamide gel electrophoresis, and immunoblotting using antibodies against dinitrophenyl groups. Keratin 10, identified by use of specific antibodies and by microsequencing, was demonstrated in vitro to be oxidizable by ultraviolet A irradiation, hypochlorite, and benzoyl peroxide. In vivo, a keratin 10 oxidation gradient with low levels in the lower stratum corneum layers, and about 3-fold higher contents of carbonyl groups towards the outer layers was demonstrated in forehead stratum corneum of healthy volunteers (n = 6). As protein oxidation can be associated with an increased susceptibility to proteases, this finding may be important for better understanding the process of desquamation.

Citations (5)


... exposed to oxidative stress, resulting in a gradient of keratin oxidation that exhibits notably more carbonyl groups within the SC, compared to deeper layers of the EP. This predisposition encourages keratin crosslinking [38], leading to a decrease in the Raman signal for the older group, as illustrated in Fig. (2. A), (2. ...

Reference:

Noninvasive in vivo application of confocal Raman spectroscopy in identifying age-related biochemical changes in human stratum corneum and epidermis
Protein Oxidation in Human Stratum Corneum: Susceptibility of Keratins to Oxidation In Vitro and Presence of a Keratin Oxidation Gradient In Vivo
  • Citing Article
  • October 1999

Journal of Investigative Dermatology

... Another extremely important marker of ageing (chronologically or/and premature) is the intensity of lipid peroxidation in the skin sebum lipids. Lipid peroxidation is driven by oxygen or/and nitrogen reactive species and is suppressed by endogenous cutaneous antioxidants or antioxidant substances supplemented by facial cosmetics/cosmeceuticals [51][52][53]. It is common knowledge that more mature skin is less protected by natural endogenous antioxidants, which are decaying with age, due to hostile environmental conditions, bad habits, hormonal status, and skin pathologies [51,[54][55][56]. ...

The Antioxidant Network of the Stratum corneum

Current Problems in Dermatology

... Tocopherol, or vitamin E, is a natural lipophilic vitamin found in fruits, vegetables, and seeds, well-known for its strong antioxidant, peroxyl radical scavenging, and cytoprotective properties [30]. It also inhibits the activity of protein kinase C, which is beneficial in various diseases like cancer, diabetes, and cardiovascular diseases, being involved in a variety of signal transduction pathways; however, tocopherol has poor chemical-and photo-stability and it is easily susceptible to oxidation by alkoxyl radicals, which has led to the development of acetylated and glucoside derivatives [28,30,31] ( Fig. 4). ...

Vitamin E: Critical Review of Its Current Use in Cosmetic and Clinical Dermatology
  • Citing Article
  • August 2005

Dermatologic Surgery

... Therefore, this study seems to suggest that the main element in desmoplakin that is promoting the binding to IFs appears to be PRD C. By extrapolation, it thus seems evident that, physiologically, any regulatory process aiming to disassemble DP-IF complexes would have to mainly involve PRD C (and not necessarily PRD A and PRD B) and possibly DP CT tail as well. Indeed, DP CT tail is known to host the key phosphorylation site Ser2849 (also referred to as Sc23 due to its location 23 residues away from the C-terminus 9 ) which, when phosphorylated by kinases such as PKC, PKA or GSK3, has been shown to be sufficient and necessary to promote DP-IF disassembly, while its mutation to glycine reportedly increases IF-DP interactions 2,6,7,[9][10][11][12][13] . However, while these reports highlight the functional importance of the carboxyterminal part of desmoplakin, more studies are needed to better understand its implications in health and disease. ...

Desmoplakin assembly dynamics in four dimensions: multiple phases differentially regulated by intermediate filaments and actin

... Therefore, this study seems to suggest that the main element in desmoplakin that is promoting the binding to IFs appears to be PRD C. By extrapolation, it thus seems evident that, physiologically, any regulatory process aiming to disassemble DP-IF complexes would have to mainly involve PRD C (and not necessarily PRD A and PRD B) and possibly DP CT tail as well. Indeed, DP CT tail is known to host the key phosphorylation site Ser2849 (also referred to as Sc23 due to its location 23 residues away from the C-terminus 9 ) which, when phosphorylated by kinases such as PKC, PKA or GSK3, has been shown to be sufficient and necessary to promote DP-IF disassembly, while its mutation to glycine reportedly increases IF-DP interactions 2,6,7,[9][10][11][12][13] . However, while these reports highlight the functional importance of the carboxyterminal part of desmoplakin, more studies are needed to better understand its implications in health and disease. ...

Plakophilin 2: A critical scaffold for PKCα that regulates intercellular junction assembly