Reorganization of microtubule nucleation during muscle differentiation

Skeletal muscle differentiation involves a complete reorganization of the microtubule network. Nearly 20 years ago, Tassin et al. [1985: J Cell Biol 100:35-46] suggested a mechanism for this reorganization by showing a redistribution of the microtubule organizing center from the centrosome to the nuclear membrane. Little progress has been made since. It is still not clear whether centrosomal proteins are redistributed together, whether microtubules are nucleated at the nuclear membrane or transported there post-nucleation, and whether gamma-tubulin (gammatub) remains necessary for nucleation in myotubes. To investigate these questions, we have examined the redistribution of the centrosomal proteins pericentrin (PC), gammatub, and ninein in the C2 muscle cell line. Immunofluorescence of differentiated myotubes shows PC along the nuclear membrane whereas gammatub is only detected there after pre-fixation detergent extraction. After expression of a GFP-tagged gammatub, we observe a weak fluorescence along the nuclear membrane, confirming the presence of gammatub at a low concentration relative to PC. Microinjection of anti-gammatub antibodies into myotubes blocks microtubule growth from both nuclear membranes and centrosomal sites. The centrosomal microtubule-anchoring protein, ninein, is found at the nuclear membrane as well and its distribution appears independent of microtubule integrity. We conclude that centrosomal proteins are redistributed independently during muscle differentiation, to sites that nucleate microtubules both along the nuclear membranes and through the cytoplasm.     

Chromosomal rearrangements during human epidermal keratinocyte differentiation

Undifferentiated human epidermal keratinocytes are self‐renewing stem cells that can be induced to undergo a program of differentiation by varying the calcium chloride concentration in the culture media. We utilize this model of cell differentiation and a 3D chromosome painting technique to document significant changes in the radial arrangement, morphology, and interchromosomal associations between the gene poor chromosome 18 and the gene rich chromosome 19 territories at discrete stages during keratinocyte differentiation. We suggest that changes observed in chromosomal territorial organization provides an architectural basis for genomic function during cell differentiation and provide further support for a chromosome territory code that contributes to gene expression at the global level. J. Cell. Physiol. J. Cell. Physiol. 221: 139–146, 2009. © 2009 Wiley‐Liss, Inc.     

Analysis of global sumoylation changes occurring during keratinocyte differentiation

Sumoylation is a highly dynamic process that plays a role in a multitude of processes ranging from cell cycle progression to mRNA processing and cancer. A previous study from our lab demonstrated that SUMO plays an important role in keratinocyte differentiation. Here we present a new method of tracking the sumoylation state of proteins by creating a stably transfected HaCaT keratinocyte cell line expressing an inducible SNAP-SUMO3 protein. The SNAP-tag allows covalent fluorescent labeling that is denaturation resistant. When combined with two-dimensional gel electrophoresis, the SNAP-tag technology provides direct visualization of sumoylated targets and can be used to follow temporal changes in the global cohort of sumoylated proteins during dynamic processes such as differentiation. HaCaT keratinocyte cells expressing SNAP-SUMO3 displayed normal morphological and biochemical features that are consistent with typical keratinocyte differentiation. SNAP-SUMO3 also localized normally in these cells with a predominantly nuclear signal and some minor cytoplasmic staining, consistent with previous reports for untagged SUMO2/3. During keratinocyte differentiation the total number of proteins modified by SNAP-SUMO3 was highest in basal cells, decreased abruptly after induction of differentiation, and slowly rebounded beginning between 48 and 72 hours as differentiation progressed. However, within this overall trend the pattern of change for individual sumoylated proteins was highly variable with both increases and decreases in amount over time. From these results we conclude that sumoylation of proteins during keratinocyte differentiation is a complex process which likely reflects and contributes to the biochemical changes that drive differentiation.     

Changes in keratin gene expression during terminal differentiation of the keratinocyte

Cells of the inner layers of the epidermis contain small keratins (46-58K), whereas the cells of the outer layers contain large keratins (63-67K) in addition to small ones. The changes in keratin composition that take place within each cell during the course of its terminal differentiation result largely from changes in synthesis. Cultured epidermal cells resemble cells of the inner layers of the epidermis in synthesizing only small keratins. The cultured cells possess translatable mRNA only for small keratins, whereas mRNA extracted from whole epidermis can be translated into both large and small keratins. As no synthesis takes place in the outermost layer of the epidermis (stratum corneum), the keratins of this layer must be synthesized earlier, but in some cases they then become smaller: this presumably occurs by post-translational processing of the molecules during the final stages of differentiation. Stratified squamous epithelia of internal organs do not form a typical stratum corneum and do not make the large keratins characteristic of epidermis. Their keratins are also different from those of cultured keratinocytes, implying that they have embarked on an alternate route of terminal keratin synthesis.     

Reorganization of cortical microtubules during cell differentiation in tobacco explants

Summary Using indirect immunofluorescence on polyethylene glycol embedded material, the organization of cortical microtubules (MTs) has been studied in explants ofNicotiana tabacum. Within 6 hours after explantation the orientation of the cortical MTs shifts from transverse to longitudinal to the long axis of the cell in all cells. This change of direction is followed by further shifts that occur only locally and predict the orientation of future cell divisions. These reorientations are independent of the formation of protrusions and buds that will develop in the explants (after 4–7 days) and they represent a stage of de-differentiation of the explants. After two days of culturing clusters of cells can be recognized, at the proximal side of the explants, with randomly oriented cortical MTs. These regions represent the origin of the protrusions from which floral buds will develop. The formation of these clusters represent the first signs of re-differentiation and formation of new polar axes in the explants. The cells thus show a very early commitment (within 2 days) as to their differentiation.Abbreviations BAP benzyl-amino-purine - DMSO dimethylsulfoxid - EGTA ethylene glycol bis(2-aminoethylether)-N,N,N,N-tetraacetic acid - GA glutaraldehyde - MTs microtubules - MTOCs microtubule organizing centres - NAA -naphthalene acetic acid - PEG polyethylene glycol - PFA paraformaldehyde - PPBs preprophase bands     

Change of intracellular fluidity during keratinocyte differentiation measured by fluorescence polarization

Summary The fluorescence polarization method was applied to measure the intracellular fluidity of fractionated guinea pig keratinocytes. Guinea pig epidermal cell suspension was obtained by treatment with EDTA and trypsin, and was separated into high, intermediate, and low density fractions using Percoll density gradient centrifugation. Morphological observation and cytofluorometric analysis of DNA content in the fractionated epidermal cells showed that the high, intermediate, and low density fractions were basal, spinous, and granular cell-rich fractions, respectively. Intracellular fluorescence polarization of each fraction was determined by a polarization spectrofluorometer (Hitachi MPF-4, prototype) with fluorescein diacetate. The P-values were calculated for high, intermediate, and low density fractions as 0.192 ± 0.021, 0.172 ± 0.019, and 0.147 ± 0.012, respectively. Since low P-values indicate a high degree of fluidity, the results indicate that intracellular fluidity of keratinocytes is lower in basal cells and higher in granular cells. Dye-binding experiments showed that fluorescein-binding proteins were not detected in the soluble fraction of the epidermal cells. The present findings suggest that intracellular fluidity of the guinea pig keratinocyte increases during the process of its differentiation.     

Annexation of the interchromosomal space during viral infection

The nucleus is known to be compartmentalized into units of function, but the processes leading to the spatial organization of chromosomes and nuclear compartments are not yet well defined. Here we report direct quantitative analysis of the global structural perturbations of interphase chromosome and interchromosome domain distribution caused by infection with herpes simplex virus-1 (HSV-1). Our results show that the peripheral displacement of host chromosomes that correlates with expansion of the viral replication compartment (VRC) is coupled to a twofold increase in nuclear volume. Live cell dynamic measurements suggest that viral compartment formation is driven by the functional activity of viral components and underscore the significance of spatial regulation of nuclear activities.     

Multiple pathways are involved in DNA degradation during keratinocyte terminal differentiation

Loss of the nucleus is a critical step in keratinocyte terminal differentiation. To elucidate the mechanisms involved, we focused on two characteristic events: nuclear translocation of N-terminal fragment of profilaggrin and caspase-14-dependent degradation of the inhibitor of caspase-activated DNase (ICAD). First, we demonstrated that epidermal mesotrypsin liberated a 55-kDa N-terminal fragment of profilaggrin (FLG-N) and FLG-N was translocated into the nucleus. Interestingly, these cells became TUNEL positive. Mutation in the mesotrypsin-susceptible Arg-rich region between FLG-N and the first filaggrin domain abolished these changes. Furthermore, caspase-14 caused limited proteolysis of ICAD, followed by accumulation of caspase-activated DNase (CAD) in TUNEL-positive nuclei. Knockdown of both proteases resulted in a significant increase of remnant nuclei in a skin equivalent model. Immunohistochemical study revealed that both caspase-14 and mesotrypsin were markedly downregulated in parakeratotic areas of lesional skin from patients with atopic dermatitis and psoriasis. Collectively, our results indicate that at least two pathways are involved in the DNA degradation process during keratinocyte terminal differentiation.     

Alterations in membrane fluidity during keratinocyte differentiation measured by fluorescence polarization

Summary The epidermis shows a distinctive pattern of differentiation wherein keratinocytes proliferate in the basal cell layer and mature into spinous and granular cells. Using a discontinuous density-gradient centrifugation method, guinea-pig keratinocytes were separated into high (HDF), intermediate (IDF), and low (LDF) density fractions. Morphological and flow cytometrical observations demonstrated that HDF, IDF, and LDF were basal, spinous, and granular cell-rich fractions, respectively. Membrane fluidity of the fractionated keratinocytes was measured by diphenylhexatriene fluorescence polarization. Polarization (p)-value of keratinocytes was negatively correlated with temperature. At each temperature, HDF cells showed a lower p-value than IDF or HDF cells except at 40° C. Since a low p-value indicates a high degree of Brownian motion, membrane fluidity is higher in basal cells and lower in spinous and granular cells. Our results indicate that membrane fluidity of guinea-pig keratinocytes decreases during their maturation.     

Epithelial-specific gene expression during differentiation of stratified primary human keratinocyte cultures.

Cultured epithelial cells are used to generate extensive patches of autologous skin equivalent for patients with burns or wounds and to investigate the growth and differentiation of epithelia in vitro. We have undertaken a comprehensive study of the morphological and molecular events that occur during culturing of human foreskin keratinocytes at the liquid-air interface on a dermal equivalent consisting of a collagen matrix containing fibroblasts. Using radioactively labeled RNA probes for mRNAs and monoclonal antibodies for proteins, we found that the expression of a comprehensive set of differentiation stage-specific genes was affected by the type of fibroblasts included in the matrix as well as by the age of the culture. The expression of these genes was not always coordinated and could not be predicted from the histological appearance of the stratified epithelium. Surprisingly, the mouse fibroblasts promoted epithelial differentiation much more closely resembling foreskin than did the homologous primary foreskin fibroblasts.     

Variable expression of some "housekeeping" genes during human keratinocyte differentiation

We investigated the expression levels of four cellular "housekeeping" genes during epithelial differentiation. Differentiation is a dynamic process and various cellular RNAs have been targeted for use as internal controls during differentiation of human keratinocytes, but the consistent expression of such standards has not been previously validated. We used the organotypic (raft) culture system to grow stratified and differentiated epithelium in vitro. We compared cellular RNAs from epithelial tissues of both normal human keratinocytes and keratinocytes whose differentiation scheme is altered by the replication of human papillomavirus. Using ribonuclease protection assays to quantify RNA expression levels, we found that beta-actin and glyceraldehyde-3-phosphate dehydrogenase levels fluctuated during epithelial differentiation, whereas cyclophilin RNA and 28S-ribosomal RNA were the most consistently expressed during epithelial differentiation. These stably expressed cellular RNAs can be targeted as controls to permit quantitative expression analyses of cellular and pathogen RNAs during epithelial differentiation under various experimental conditions.     

Differential cytoskeletal association of ErbB1 and ErbB2 during keratinocyte differentiation

ErbB1 and ErbB2 display differential subcellular localization in human skin and cultured keratinocytes. To determine whether ErbB1 and ErbB2 also differ in cytoskeletal binding properties, normal human keratinocytes grown under conditions favoring a basal or differentiated phenotype were repeatedly extracted in a non-ionic detergent buffer. In basaloid keratinocytes, cytoskeletal association of ErbB1 and ErbB2 was limited. ErbB1 ( approximately 5%) was tightly associated with the cytoskeleton, compared to <1% of ErbB2 (p=0.004). After EGF stimulation, activated ErbB1 and ERK associated with the cytoskeleton to a greater extent than did total ErbB1 and total ERK. Association of ErbB2 increased markedly in differentiated keratinocytes, whereas association of ErbB1 was similar in basaloid and differentiated cells. Cytoskeletal association of ErbB2 correlated with plasma membrane localization. These results suggest that ErbB1 and ErbB2 employ different mechanisms of plasma membrane targeting during keratinocyte differentiation, and that cytoskeletal association may facilitate the coupling of activated ErbB1 and ERK.     

Vitamin D regulated keratinocyte differentiation

The epidermis is the largest organ in the body. It is comprised primarily of keratinocytes which are arranged in layers that recapitulates their programmed life cycle. Proliferating keratinocytes are on the bottom-the stratum basale. As keratinocytes leave the stratum basale they begin to differentiate, culminating in the enucleated stratum corneum which has the major role of permeability barrier. Calcium and the active metabolite of vitamin D, 1,25(OH)(2)D(3), play important roles in this differentiation process. The epidermis has a gradient of calcium with lowest concentrations in the stratum basale, and highest concentrations in the stratum granulosum where proteins critical for barrier function are produced. Vitamin D is made in different layers of the epidermis, but 1,25(OH)(2)D(3) is made primarily in the stratum basale. Together calcium and 1,25(OH)(2)D(3) regulate the ordered differentiation process by the sequential turning on and off the genes producing the elements required for differentiation as well as activating those enzymes involved in differentiation. Animal models in which the sensing mechanism for calcium, the receptor for 1,25(OH)(2)D(3), or the enzyme producing 1,25(OH)(2)D(3) have been rendered inoperative demonstrate the importance of these mechanisms for the differentiation process, although each animal model has its own phenotype. This review will examine the mechanisms by which calcium and 1,25(OH)(2)D(3) interact to control epidermal differentiation.     

Ceramide-dependent regulation of human epidermal keratinocyte CD1d expression during terminal differentiation

Human keratinocytes (KC), when cultured under conditions to remain undifferentiated or to terminally differentiate, changed their cellular distribution of CD1d. As studied by confocal microscopy, undifferentiated KC had a pool of cytoplasmic CD1d, whereas after terminal differentiation, this molecule localized in the cell membrane, which recapitulates CD1d expression in vivo. A comparison of undifferentiated and differentiated cultured KC did not reveal any differences in the association with beta(2)-microglobulin, invariant chain of class II MHC, or patterns of glycosylation, suggesting that these biochemical properties are not regulating the cellular distribution of CD1d. Time-course studies of CD1d gene expression indicated that KC slowly increased gene expression with CaCl(2)-induced terminal differentiation. Increased CD1d gene expression was dependent on ceramide synthesis, because fumonisin B1, a ceramide synthetase inhibitor, blocked the increase in CD1d gene expression during terminal differentiation. Similarly, exogenous ceramide or the ceramidase inhibitor, B13, induced CD1d gene expression by undifferentiated, but not terminally differentiated, KC. A protein kinase C-zeta (PKC-zeta) inhibitor (a pseudosubstrate oligopeptide), but not a PKC-alphabeta inhibitor, significantly decreased CD1d gene expression by undifferentiated or ceramide-stimulated cultured, undifferentiated KC. As expected, downstream signaling events of PKC-zeta (JNK phosphorylation and NF-kappaBeta accumulation in the nucleus) were also attenuated. The calcineurin phosphatase inhibitor cyclosporine A, which blocks KC terminal differentiation, also blocked CD1d gene expression by cultured KC. In conclusion, this novel function of cellular ceramides extends the importance of this class of biologically active lipids beyond that of terminal differentiation and barrier function in normal human skin.