Periodontal ligament on pulp-free root slices – an in vitro model for early tooth (re)integration. An exploratory study

Reintegration of freshly extracted healthy teeth is very successful, most likely due to the regenerative capacity of their roots’ residual periodontal ligament (PDL). We hypothesised that in vitro cultures of the consecutive slices of a sectioned root will represent the entity of PDL cell types engaged in tooth-sided reintegration. For confirmation, apex and pulp from human premolars were removed and roots cut into 6 to 9 about 1 mm thick slices. These were immobilised to separate wells and cultured for 20 days, under daily inspection for the initiation of cell outgrowth (ICO). ICO and the distribution of vital slices along, the cell growth around as well as the expansion of outgrown cells off the root axes after 20 days were displayed for each tooth as 3D-like profiles. Of the 81 slices from 11 teeth, 55 showed ICO; 64% within one week and 96% within two weeks. Such dynamics compare to the early (day 2–5) and the intermediate (day 9–14) integration phase reported for PDL cells in vivo. Experimental phase contrast images of a single slice showed at ICO few fibroblast- and stem/progenitor- like cells. Four and five days later at the same site cells had grown in number and changed in shape and space over time. This exploratory study indicates that in root slice cultures PDL cells behave similarly to those during reintegration in vivo. It favours our hypothesis, which is now to be adequately verified. Eventually, the model may facilitate the identification of outgrowing cells and cellular changes over time, as triggered by tissue rupture. It may further allow for emulating cellular interactions between the root surface and alveolar bone or engineered constructs, natural or engineered scaffolds, or other tissue, in an in vivo-like situation.

Hes1, a new target for interleukin 1beta in chondrocytes

OBJECTIVES

To investigate the effects of interleukin 1beta (IL1beta) treatment on the Notch1/Hes1 pathway in chondrocytes in vitro.

METHODS

Mouse articular chondrocytes in primary culture were challenged with IL1beta, alone or combined with Notch1 and IL1beta pathway inhibitors. Notch1 and Hes1 expressions were investigated by immunocytochemistry, western blot and real-time quantitative (q)PCR. IL1beta-responsive genes were assessed by real-time qPCR and a specific siRNA against Hes1 was used to identify Hes1 target genes.

RESULTS

Notch1 labelling remained nuclear and stable in intensity irrespective of treatment, suggesting a steady state activation of this pathway in our model. IL1beta transiently increased Hes1 mRNA (2.5-fold) and protein expression in treated versus naive chondrocytes. Hes1 mRNA level then decreased below control and its cyclic pattern of expression was lost. This was associated with nuclear translocation of the cytoplasmic Hes1 protein. IL1beta induced increase in Hes1 mRNA was transcriptional, occurred through nuclear factor (NF)kappaB activation and appeared to be associated with downregulation by its own protein. Hes1 induction was insensitive to the gamma-secretase inhibitor N-(N-(3,5-difluorophenacetyl)-l-alanyl)-S-phenylglycine t-butyl ester (DAPT), which suggested its independence from novel Notch1 activation. Hes1 expression was efficiently silenced by a specific siRNA. This experiment revealed that Hes1 did not mediate IL1beta-induced downregulation of Sox9, type II collagen and aggrecan transcription but mediated IL1beta induction of matrix metalloproteinase (MMP)13 and ADAM metallopeptidase with thrombospondin type 1 motif, 5 (ADAMTS5). The Hes1-related repressor Hey1 was expressed at a very low level and was not inducible by IL1beta.

CONCLUSION

Hes1 is a novel IL1beta target gene in chondrocytes which influences a discrete subset of genes linked to cartilage matrix remodelling and/or degradation.

Early detection of aging cartilage and osteoarthritis in mice and patient samples using atomic force microscopy

The pathological changes in osteoarthritis--a degenerative joint disease prevalent among older people--start at the molecular scale and spread to the higher levels of the architecture of articular cartilage to cause progressive and irreversible structural and functional damage. At present, there are no treatments to cure or attenuate the degradation of cartilage. Early detection and the ability to monitor the progression of osteoarthritis are therefore important for developing effective therapies. Here, we show that indentation-type atomic force microscopy can monitor age-related morphological and biomechanical changes in the hips of normal and osteoarthritic mice. Early damage in the cartilage of osteoarthritic patients undergoing hip or knee replacements could similarly be detected using this method. Changes due to aging and osteoarthritis are clearly depicted at the nanometre scale well before morphological changes can be observed using current diagnostic methods. Indentation-type atomic force microscopy may potentially be developed into a minimally invasive arthroscopic tool to diagnose the early onset of osteoarthritis in situ.

Surface-induced modulation of human mesenchymal progenitor cells. An in vitro model for early implant integration

Clinical experience indicates that the surface architecture of dental implants has an important impact on their integration. This has been related to the finding that differentially treated substrates can modulate the expression of osteogenic markers in various bone-related cell lines and primary cells. Here, we investigated the influence of surface architecture on the differentiation of human mesenchymal progenitor cells (HMPC) from adult bone marrow, i. e. the cells likely involved in initial bone synthesis at the bone-implant interface. Cells were seeded on machine surfaced (MS) or sandblasted/acid etched (SE) titanium discs in agarose-coated dishes, and on polystyrene (PS) controls. On all substrates cell densities did not change between days 7 and 14. Cell numbers were higher on SE, likely due to increased attachment to the rougher material. Alkaline phosphatase activity (ALP) was similar on all substrates, whereas mRNA expression of bone sialoprotein (BSP) at day 14 was about tenfold higher on SE (p < 0.05%). The SE-related increase of BSP in progenitor cells indicates an earlier differentiation of immigrated cells and could thus explain earlier implant integration and shorter time to functional loading observed in the clinic. The in vitro model and BSP quantification could be used to screen for changes in osteogenic cell differentiation induced by specific implant surfaces, with potential relevance on the prediction of bone-implant integration.

Dynamic elastic modulus of porcine articular cartilage determined at two different levels of tissue organization by indentation-type atomic force microscopy

Cartilage stiffness was measured ex vivo at the micrometer and nanometer scales to explore structure-mechanical property relationships at smaller scales than has been done previously. A method was developed to measure the dynamic elastic modulus, |E(*)|, in compression by indentation-type atomic force microscopy (IT AFM). Spherical indenter tips (radius = approximately 2.5 microm) and sharp pyramidal tips (radius = approximately 20 nm) were employed to probe micrometer-scale and nanometer-scale response, respectively. |E(*)| values were obtained at 3 Hz from 1024 unloading response curves recorded at a given location on subsurface cartilage from porcine femoral condyles. With the microsphere tips, the average modulus was approximately 2.6 MPa, in agreement with available millimeter-scale data, whereas with the sharp pyramidal tips, it was typically 100-fold lower. In contrast to cartilage, measurements made on agarose gels, a much more molecularly amorphous biomaterial, resulted in the same average modulus for both indentation tips. From results of AFM imaging of cartilage, the micrometer-scale spherical tips resolved no fine structure except some chondrocytes, whereas the nanometer-scale pyramidal tips resolved individual collagen fibers and their 67-nm axial repeat distance. These results suggest that the spherical AFM tip is large enough to measure the aggregate dynamic elastic modulus of cartilage, whereas the sharp AFM tip depicts the elastic properties of its fine structure. Additional measurements of cartilage stiffness following enzyme action revealed that elastase digestion of the collagen moiety lowered the modulus at the micrometer scale. In contrast, digestion of the proteoglycans moiety by cathepsin D had little effect on |E(*)| at the micrometer scale, but yielded a clear stiffening at the nanometer scale. Thus, cartilage compressive stiffness is different at the nanometer scale compared to the overall structural stiffness measured at the micrometer and larger scales because of the fine nanometer-scale structure, and enzyme-induced structural changes can affect this scale-dependent stiffness differently.

Repetitive versus monomeric antigen presentation: direct visualization of antibody affinity and specificity

The concept of presenting antigens in a repetitive array to obtain high titers of specific antibodies is increasingly applied by using surface-engineered viruses or bacterial envelopes as novel vaccines. A case for this concept was made 25 years ago, when producing high-titer antisera against ordered arrays of gp23, the major capsid protein of bacteriophage T4 (Aebi et al., Proc. Natl. Acad. Sci. USA, 74 (1977) 5514-5518). In view of the current interest in this concept we thought it useful to employ this system to directly visualize the dependence of antibody affinity and specificity on antigen presentation. We compared antibodies raised against T4 polyheads, a tubular variant of the bacteriophage T4 capsid, which have gp23 hexamers arranged in a crystalline lattice (gp23(repetitive)), with those raised against the hexameric gp23 subunits (gp23(monomeric)). The labeling patterns of Fab-fragments prepared from these antibodies when bound to polyheads were determined by electron microscopy and image enhancement. Anti-gp23(repetitive) bound in a monospecific, stoichiometric fashion to the gp23 units constituting the polyhead surface. In contrast, anti-gp23(monomeric) decorated the polyhead surface randomly and with a 40-fold lower occupancy. These results concur with the difference in titers established by ELISA for the antisera against the repetitively displayed form of antigen (anti-gp23(repetitive)) and the randomly presented antigen (gp23(monomeric)), and they constitute a compelling visual documentation of the concept of repetitive antigen presentation to elicite a serotype-like immune response.

Immunofluorescence and confocal laser scanning microscopy of chronic myeloproliferative disorders on archival formaldehyde-fixed bone marrow

Spatial analysis of the histoarchitecture and photographic documentation at high resolution are the principal advantages of confocal laser scanning microscopy (CLSM) over conventional fluorescence microscopy (CFM) if combined with appropriate software. Restrictions for the use of CFM and CLSM, on the other hand, include nonspecific background fluorescence, fading of photolabile fluorochromes, and both tissue-specific and fixation-induced autofluorescence. Most of those shortcomings can now be avoided. Autofluorescence, the most limiting factor of high-resolution CLSM, was recently controlled also for paraffin sections of archival formaldehyde-fixed tissues. This allowed the present study on cytoskeletal fibers and extracellular matrix proteins in both neoplastic cells of myeloproliferative disorders and in medullary stromal cells using CLSM under proper autofluorescence control. By multiple fluorescence labeling, we found that the intracellular smooth muscle alpha-actin (SMA) fibers and the two extracellular adhesive matrix proteins tenascin and fibronectin vary in their presence in stromal and/or myeloid cells according to the degree of bone marrow fibrosis in chronic myeloproliferative disorders (CMPDs). CLSM offers further insight in our attempts to understand a complex interplay between the two cellular compartments.

[Influence of the implant surface on the early phase of osteogenesis in vitro]

The specific structure of a dental implant's surface is often used as an argument for a better overall performance and durability. Nonetheless, it is not yet fully clear to what extent an implant's material or surface structure improves its performance. For a better understanding of the early integration-related processes, growth and initiation of mineralization of human MG-63 osteoblasts grown on glass slides or on polished (MS: machine-surfaced) or structured (SB: deep-structured) titanium surfaces were monitored. Cells were cultured under non-confluent conditions in absence and presence of osteogenic medium (OS). The 3D-architecture of growing cells was documented by confocal laser scanning microscopy (CLSM) upon fluorescently labeling for collagen I. Collagen I distribution was found comparable under all conditions. In control cultures on glass, MS and SB, cells had grown as multilayered but not yet confluent networks, which additionally comprised dome-like structures on the two Ti-surfaces. While on glass and SB cells essentially maintained this architecture also in presence of OS, three-dimensional structures on MS were--if at all--only barely visible. This was reflected also in the protein content of the cultures that was significantly lower under OS in the case of MS only. The activity of the early mineralization marker alkaline phosphatase (ALP) was higher in the controls on glass than on MS or SB. In presence of OS it was significantly higher on MS and SB than in the controls, yet not on glass. Obviously both, the surface material and the surface structure contribute--possibly synergistically--to early processes of implant integration, such as matrix formation and mineralization. The impact of such effects is discussed, in relation to implant loading and implant durability.

Contraction-mediated pinocytosis of RGD-peptide by dermal fibroblasts: inhibition of matrix attachment blocks contraction and disrupts microfilament organisation

Force generation in collagen and matrix contraction are basic functions of fibroblasts and important elements of tissue repair. Cell-matrix attachment is critical to this contraction, involving RGD-binding integrins. We have investigated how this process operates, in terms of force generation (in the Culture Force Monitor) and cytoskeletal structure, using a synthetic RGD-decapeptide. The RGD-peptide blocked force generation over the first 6 h, followed by near complete recovery by 20 h. However, dose response was complex indicating multiple processes were operating. Analysis of cytoskeletal structure after treatment with RGD-peptide indicated major disruption with condensed aggregates of actin and microtubular fragmentation. Fluorescent labeling and tracking of the RGD-peptide demonstrated intracellular uptake into discrete cytoplasmic aggregates. Critically, these RGD-peptide pools co-localised with the condensed actin microfilament aggregates. It is concluded that RGD-peptide uptake was by a form of contraction-mediated pinocytosis, resulting from mechanical tension applied to the untethered RGD-peptide-integrin, as contractile microfilament were assembled. These findings emphasize the importance of sound mechanical attachment of ligand-occupied integrins (e.g., to extracellular matrix) for normal cytoskeletal function. Conversely, this aspect of unrestrained cytoskeletal contraction may have important pathogenic and therapeutic applications.

Control of autofluorescence of archival formaldehyde-fixed, paraffin-embedded tissue in confocal laser scanning microscopy (CLSM)

Confocal laser scanning microscopy (CLSM) offers the advantage of quasi-theoretical resolution due to absence of interference with out-of-focus light. Prerequisites include minimal tissue autofluorescence, either intrinsic or induced by fixation and tissue processing, and minimal background fluorescence due to nonspecific binding of the fluorescent label. To eliminate or reduce autofluorescence, three different reagents, ammonia-ethanol, sodium borohydride, and Sudan Black B were tested on paraffin sections of archival formaldehyde-fixed tissue. Paraffin sections of biopsy specimens of human bone marrow, myocardium, and of bovine cartilage were compared by CLSM at 488-nm, 568-nm and 647-nm wavelengths with bone marrow frozen sections fixed either with formaldehyde or with glutaraldehyde. Autofluorescence of untreated sections related to both the specific type of tissue and to the tissue processing technique, including fixation. The reagents' effects also depended on the type of tissue and technique of tissue processing, including fixation, and so did the efficiency of the reagents tested. Therefore, no general recipe for the control of autofluorescence could be delineated. Ammonia-ethanol proved most efficient in archival bone marrow sections. Sudan Black B performed best on myocardium, and the combination of all three reagents proved most efficient on paraffin sections of cartilage and on frozen sections fixed in formaldehyde or glutaraldehyde. Sodium borohydride was required for the reduction of unwanted fluorescence in glutaraldehyde-fixed tissue. In formaldehyde-fixed tissue, however, sodium borohydride induced brilliant autofluorescence in erythrocytes that otherwise remained inconspicuous. Ammonia-ethanol is believed to reduce autofluorescence by improving the extraction of fluorescent molecules and by inactivating pH-sensitive fluorochromes. The efficiency of borohydride is related to its capacity of reducing aldehyde and keto-groups, thus changing the fluorescence of tissue constituents and especially of glutaraldehyde-derived condensates. Sudan Black B is suggested to mask fluorescent tissue components.

Enhanced cartilage tissue engineering by sequential exposure of chondrocytes to FGF-2 during 2D expansion and BMP-2 during 3D cultivation

Bovine calf articular chondrocytes, either primary or expanded in monolayers (2D) with or without 5 ng/ml fibroblast growth factor-2 (FGF-2), were cultured on three-dimensional (3D) biodegradable polyglycolic acid (PGA) scaffolds with or without 10 ng/ml bone morphogenetic protein-2 (BMP-2). Chondrocytes expanded without FGF-2 exhibited high intensity immunostaining for smooth muscle alpha-actin (SMA) and collagen type I and induced shrinkage of the PGA scaffold, thus resembling contractile fibroblasts. Chondrocytes expanded in the presence of FGF-2 and cultured 6 weeks on PGA scaffolds yielded engineered cartilage with 3.7-fold higher cell number, 4.2-fold higher wet weight, and 2.8-fold higher wet weight glycosaminoglycan (GAG) fraction than chondrocytes expanded without FGF-2. Chondrocytes expanded with FGF-2 and cultured on PGA scaffolds in the presence of BMP-2 for 6 weeks yielded engineered cartilage with similar cellularity and size, 1.5-fold higher wet weight GAG fraction, and more homogenous GAG distribution than the corresponding engineered cartilage cultured without BMP-2. The presence of BMP-2 during 3D culture had no apparent effect on primary chondrocytes or those expanded without FGF-2. In summary, the presence of FGF-2 during 2D expansion reduced chondrocyte expression of fibroblastic molecules and induced responsiveness to BMP-2 during 3D cultivation on PGA scaffolds.

Direct evidence for bioconversion of vitamin E acetate into vitamin E: an ex vivo study in viable human skin

For better stability, vitamin E is commonly used as the non-active esterified pro-drug. Such esters are postulated to be hydrolyzed to the free active form by skin-related esterases. So far, successful conversion of esterified vitamin E to free vitamin E (tocopherol) has been mainly delineated from observed biological effects. Quantitative evidence in human skin is poor. In vitro and in vivo studies on human and animal skin have proved ambiguous. Formulation-based effects may have added to this controversy. In the present study, comparable amounts of vitamin E acetate (i) in oil (Mygliol-812N), (ii) surfactant-solubilized in water, (iii) encapsulated in liposomes, or (iv) encapsulated in Nanotopes were applied to human skin mounted in modified Franz-perfusion chambers that permit emulation of both open or occlusive conditions. The distribution of vitamin E(total) (vitamin E acetate + vitamin E) was assessed on the skin surface, in the horny layers, and in the underlying skin by high-pressure liquid chromatography (HPLC), with a recovery higher than 90%. Vitamin E acetate in Mygliol deposited exclusively on the surface and in the stratum corneum. In contrast, solubilized or encapsulated vitamin E acetate deposited also in the underlying skin. Nanotopes performed best, followed by liposomes and solubilized vitamin E acetate. Non-occlusive application favored deposition in the skin relative to occlusive application. Conversion of vitamin E acetate to vitamin E was not observed on the skin surface or in the horny layers, while in the underlying skin up to 50% of the vitamin E(total) was deacetylated.

Confocal laser scanning microscopy and scanning electron microscopy of tissue Ti-implant interfaces

Microscopic inspection of heterogenous three-dimensional (3D) objects such as oral implants, or implants in general, is conventionally performed either on ground sections of methyl-metacrylate-embedded material, at the cellular level by histologic analysis of the peri-implant tissue by light microscopy (LM), or at the supramolecular level by transmission electron microscopy (TEM). Alternatively, the architecture of the tissue/implant interface is visualized by scanning electron microscopy (SEM). The two approaches exclude each other because of the sample preparation.We elaborate conditions for the non-invasive analysis of tissue/implant interfaces by confocal laser scanning microscopy (CLSM) in buffer, hoping to obtain a 3D view of fluorescently labeled tissue constituents at the tissue implant interface and, through subsequent SEM, of the metal surface. The use of water-immersion objectives, originally developed for high LM under physiological conditions is essential. In an exploratory approach, the tissue/Ti-interfaces of two retrieved dental implants were analyzed. One was a step-cylinder used for orthodontic anchoring and the other was an endosseous step-screw implant retrieved after infection-related loosening prior to load. The adhering tissue fragments were fluorescently triple-labeled for actin, fibronectin, and sm-alpha-actin. Optical sections for fluorescent images and for the laser reflection map were registered concomitantly. This approach allowed the labeled structures to be located on the metal surface. Subsequently, the same implants were prepared for SEM of the tissue/implant interface, and upon removal of the adhering structures, of the underlying metal surface. Thus, specific proteins can be identified and their spatial architecture as well as that of the underlying metal surface can be visualized for one and the same implant. The immediate visualization after fluorescence labeling in buffer by means of water immersion objective lenses proved most critical.

Molecular weight determination of membrane proteins by sedimentation equilibrium at the sucrose or nycodenz-adjusted density of the hydrated detergent micelle

The determination of the molecular weight of a membrane protein by sedimentation equilibrium is complicated by the fact that these proteins interact with detergents and form complexes of unknown density. These effects become marginal when running sedimentation equilibrium at gravitational transparency, i.e., at the density corresponding to that of the hydrated detergent micelles. Dodecyl-maltoside and octyl-glucoside are commonly used for dissolving membrane proteins. The density of micelles thereof was measured in sucrose or Nycodenz. Both proved to be about 50% lower than those of the corresponding non-hydrated micelles. Several membrane proteins were centrifuged at sedimentation equilibrium in sucrose- and in Nycodenz-enriched solutions of various densities. Their molecular weights were then calculated by using the resulting slope value at the density of the hydrated detergent micelles, i.e. at gravitational transparency, and the partial specific volume corrected for a 50% hydration of the membrane protein. The molecular weights of all measured membrane proteins, i.e. of photosystem II complex, reaction center of Rhodobacter sphaeroides R26, spinach photosystem II reaction center (core complex), bacteriorhodopsin, OmpF-porin and rhodopsin from Bovine retina corresponded within +/-15% to those reported previously, indicating a general applicability of this approach.

Preparation, use, and enlargement of ultrasmall gold particles in immunoelectron microscopy

The introduction of ultrasmall (approximately 1-3 nm) colloidal gold markers in immunoelectron microscopy (IEM) in 1989 has considerably improved the sensitivity of this marker system. Ultrasmall gold markers have opened the field of pre-embedding labeling studies to gold markers without the need of harsh permeabilizing steps. They are recommended for the detection of scarce antigens in ultrathin cryosections which may otherwise escape immunodetection. However, reports concerning the preparation of ultrasmall gold colloids, their conjugation to proteins, and their use in high-resolution studies (without an additional enlargement step) are very limited. Also, the available enlargement techniques necessary for the use of this marker in conventional electron microscopy require detailed discussion to clarify the large number of contradictory observations. The present review summarizes and discusses the findings accumulated within the last 10 years on the application of ultrasmall gold markers in IEM with regard to their merits, limitations, detection sensitivity, and suitability for different labeling techniques. It should provide practical hints for the use of ultrasmall gold colloids and discusses problems arising with enlargement techniques such as silver enhancement and gold toning procedures.

Visualizing nuclear export of different classes of RNA by electron microscopy

Export of RNA from the cell nucleus to the cytoplasm occurs through nuclear pore complexes (NPCs). To examine nuclear export of RNA, we have gold-labeled different types of RNA (i.e., mRNA, tRNA, U snRNAs), and followed their export by electron microscopy (EM) after their microinjection into Xenopus oocyte nuclei. By changing the polarity of the negatively charged colloidal gold, complexes with mRNA, tRNA, and U1 snRNA can be formed efficiently, and gold-tagged RNAs are exported to the cytoplasm with kinetics and specific saturation behavior similar to that of unlabeled RNAs. U6 snRNA conjugates, in contrast, remain in the nucleus, as does naked U6 snRNA. During export, RNA-gold was found distributed along the central axis of the NPC, within the nuclear basket, or accumulated at the nuclear and cytoplasmic periphery of the central gated channel, but not associated with the cytoplasmic fibrils. In an attempt to identify the initial NPC docking site(s) for RNA, we have explored various conditions that either yield docking of import ligands to the NPC or inhibit the export of nuclear RNAs. Surprisingly, we failed to observe docking of RNA destined for export at the nuclear periphery of the NPC under any of these conditions. Instead, each condition in which export of any of the RNA-gold conjugates was inhibited caused accumulation of gold particles scattered uniformly throughout the nucleoplasm. These results point to the existence of steps in export involving mobilization of the export substrate from the nucleoplasm to the NPC.

Punch-wounded, fibroblast populated collagen matrices: a novel approach for studying cytoskeletal changes in three dimensions by confocal laser scanning microscopy

Depending on growth conditions and cell type, collagen matrices populated with viable cells, i.e. commonly with fibroblasts, contract in a manner resembling wound contraction in vivo. If matrix cultures can be grown to provide the environment of contracting wounds in vitro, other conditions may be established under which fibroblasts grow reminiscent of those in normal dermis. Wounding such dermal equivalents may then initiate cells to change their phenotype in space and time in an in vivo-like environment. In turn, such a system should allow to study the underlying cytoskeletal changes at the onset of tissue repair and beyond. To test this hypothesis, we established the conditions for human skin-derived fibroblasts (KD cells) to grow within collagen matrices without contraction. We then excised from the center of such "attached, low-contracting dermal equivalents" (ALDE) "punch biopsies" with a diameter of 1 mm, and monitored the cell's shape and their microtubular networks and F-actin-containing structures over time by i) conventional fluorescence microscopy and ii) by confocal laser scanning microscopy in combination with optical sectioning and volume rendering software. Prior to wounding and in non-wounded controls up to 8 days post seeding (ps), cells predominantly exhibited an elongated, spindle-shaped morphology with distinct microtubular networks and F-actin-containing structures. Wounding induced most of the fibroblasts lining the wound edge to immediately round up. The round cells still revealed a microtubular network but only diffuse labeling for F-actin. One day post wounding (pw), these fibroblasts had resumed their spindle-shaped structure. They displayed the microtubular network and again thin F-actin-containing structures. From 2 days pw on and up to 6 days pw, the number of fibroblasts in the wound zone had increased, forming dense, multilayered patches oriented parallel to the wound surface, and the cells lining the wound margin showed the most extensive and massive F-actin-containing stress fiber-like structures. Quantification of the cell densities at the wound margin and in adjacent zones corroborated this increase, which is reminiscent of the fibroblasts migrating to the wound edge in the early phase of connective tissue repair.

Cooperative effects in vitro on fibroblast and keratinocyte functions related to wound healing by transforming growth factor-beta and a low molecular weight fraction from hemolyzed blood

Blood or its constituents, respectively, contain a.o. substances such as TGF-beta (transforming growth factor-beta), PDGF (platelet-derived growth factor) and other factors, which beneficially influence wound healing. Patients with perivascular disturbances and consequently with inadequate supply of the affected tissue cells often suffer from poor healing of dermal wounds. Here, various cellular functions in situations of poor supply and related to wound healing, such as proliferation, colony formation, and migration of fibroblasts, and of monolayer formation by keratinocytes were emulated in vitro by supplementing cultures with reduced amounts of serum. Computer-aided image analysis allowed to quantify the cellular reactions under normal and serum-deprived medium conditions and under the influence of a low molecular weight fraction manufactured by dialysis of hemolyzed calf blood (HD, Solcoseryl) and of TGF-beta. Both preparations are in use for the treatment of poorly healing wounds. While HD preferentially normalized the reduced viability of fibroblasts, the keratinocyte activity was enhanced by TGF-beta. Restoration of fibroblast and keratinocyte functions proved most effective when combining HD with TGF-beta.

Fibroblast migration and proliferation during in vitro wound healing. A quantitative comparison between various growth factors and a low molecular weight blood dialysate used in the clinic to normalize impaired wound healing

During the formation of granulation tissue in a dermal wound, platelets, monocytes and other cellular blood constituents release various peptide growth factors to stimulate fibroblasts to migrate into the wound site and proliferate, in order to reconstitute the various connective tissue components. The effect on fibroblast migration and proliferation of these growth factors, and of Solcoseryl (HD), a deproteinized fraction of calf blood used to normalize wound granulation and scar tissue formation, was quantified in vitro. The presence of basic fibroblast growth factor (bFGF), platelet-derived growth factor (PDGF), transforming growth factor-beta (TGF-beta) and hemodialysate (HD) increased the number of cells in the denuded area, i.e., in the "wound space" of an artificially ruptured monolayer of LM-fibroblasts (mouse lung fibroblasts). When cell proliferation was blocked with Mitomycin C, in the first 24 h all factors, i.e., bFGF, PDGF, TGF-beta and HD, promoted cell migration, whereas after 48 h it became obvious that each factor stimulated both migration and proliferation, each in a characteristic way. The effects were significant and more distinct after 48 h, following the order: PDGF (46%) approximately bFGF (87%) > HD (45%) approximately TGF-beta (40%) > control (62%). The relative contributions of migration after inhibiting proliferation are given in brackets. The modulatory activity of HD was localized in its hydrophilic fraction. It was destroyed by acid hydrolysis. Furthermore, this activity could be blocked by protamine sulfate, an inhibitor blocking peptide growth factor receptor binding.

Effect of a protein-free dialysate from calf blood on human monocyte differentiation in vitro

Solcoseryl is a protein-free, standardized dialysate/ultrafiltrate derived from calf blood, which has been shown to improve situations of impaired healing in both experimental animals and man. Its activity seems to be multifactorial although the precise cellular and molecular mechanisms contributing to its effect have not been fully elucidated. Since monocyte-derived macrophages play a central role in inflammation and particularly in wound healing and tissue remodelling, the effect of the dialysate on human monocytes cultured in vitro for 10 days in the presence of human serum was studied. The results show that the drug, at concentrations ranging from 0.2 to 2%, increases the cell density of the cultures and the cell protein content, and favours the differentiation of monocytes into macrophages when 1% serum concentration is used in the culture medium. These effects are no more apparent when the serum concentration was raised to 10%. These data suggest that the drug may substitute, at least in part, for serum in monocyte-macrophage cultures. The observed effects give a sound basis for at least a partial explanation of the therapeutic effects of the drug, particularly at sites where the supply of serum-derived factors is limited.

Growth-promoting effect of a protein-free hemodialysate used in situations of hypoxia and for tissue repair as measured via stimulation of S6-kinase

Solcoseryl is the low-molecular weight fraction of calf blood as manufactured by counterflow dialysis. This hemodialysate (HD) is in clinical use in situations involving hypoxia and for the normalization of tissue repair. The influence of the HD on ZR-75 cells was tested. These cells preferably express receptors for Epidermal Growth Factor (EGF)/Transforming Growth Factor alpha (TGF-alpha) or Somatomedin C (SMC = insulin like growth factor I resp. ILA-I) and react upon stimulation by enhancement of their S6-kinase activity, the latter being a prerequisite for growth. The functional presence of one or several of these peptide growth factors should therefore reflect in a stimulation of S6-kinase activity.

Topical treatment of standardized burns with a protein-free haemodialysate

The utility of the protein-free haemodialysate Solcoseryl (HD) in the treatment of chronic skin ulcers and minor burns is well documented (Haigis et al., 1985). In this study the effects of HD ointment and HD gel on the healing of standardized deep partial thickness burns were investigated in rats. Treatment with HD-containing topical agents significantly reduced healing time (P less than or equal to 0.01) in comparison with non-treated controls; HD ointment and HD gel reduced relative healing rates by 20 per cent and 15 per cent respectively. Macroscopic and histological findings indicate that the effects of HD start in the early phase of the healing process (inflammatory/exudative), and that the entire healing process is improved.

Mass analysis of bacteriophage T4 proheads and mature heads by scanning transmission electron microscopy and hydrodynamic measurements

Quantitative mass analysis of bacteriophage T4 proheads by scanning transmission electron microscopy (STEM) revealed a mass of 79.5 +/- 0.6 MDa, while hydrodynamic measurements yielded a prohead mass of about 80 MDa. This is 25% less than the prohead mass deduced from its polypeptide composition, and this finding implies that the bacteriophage T4 prohead is built of fewer polypeptide copies than previously reported. In contrast, the mass of mature heads measured by STEM, 194 +/- 2 MDa, is in agreement with previous mass measurements of DNA and protein content, and it is consistent with the previously determined stoichiometry. This good agreement of average STEM values for proheads and mature heads with corresponding hydrodynamic measurements suggests that STEM allows faithful evaluation of the masses of large supramolecular assemblies (i.e., greater than or equal to 200 MDa) such as whole viruses or cellular organelles.

Small colloidal gold conjugated to Fab fragments or to immunoglobulin G as high-resolution labels for electron microscopy: a technical overview

Fab-colloidal gold labelling in conjunction with negative staining and high-resolution electron microscopy was used for targeting single protein units in regular arrays. These were bacteriophage T4 polyheads with Fab-Au2.5, and a specific antibody binding site on the haemagglutinin polypeptide of influenza virus with Fab-Au3, Fab-Au2.5, and Fab-Au1-2. For the latter, IgG-Au3 was also used. Experimental details are summarized to provide generally applicable methods for the preparation of small gold colloids Fab-Au and of labelling. The putative mechanism of protein-gold complex formation and adsorption to preferred sites on Fab and IgG, most probably to sulphur-rich regions, is discussed. The influence of pH during complex formation was found to be of minor importance in the samples investigated. Reported experimental details and our own experiences suggest that the importance of a protein's pI relative to its optimum gold complexing pH critically depends on the nature of the protein in question rather than being of general importance for protein-gold complex stability.

Head structure of bacteriophages T2 and T4

The length-to-width ratios of bacteriophage T2 and T4 heads and stereometric angles specifying the prolate icosahedral T2 capsid were evaluated on electron micrographs recorded from samples prepared by a variety of methods. The copy numbers of the major capsid protein, gp23*, of T2 and T4 phages were compared by quantitative gel electrophoresis. Taken together, the resulting values are most compatible with triangulation numbers T = 13 and Q = 21 for both T2 and T4, thus confirming the previously proposed capsid architecture of T4 revealed by indirect measurements and thereby eliminating the repeatedly reported discrepancy between T2 and T4 in favor of a common Q number of 21 corresponding to 960 copies of gp23*.

Organization of double-stranded DNA in bacteriophages: a study by cryo-electron microscopy of vitrified samples

In this paper it is shown that conformation and packing of double-stranded DNA within the head of bacteriophages lambda and T4 can be assessed by cryo-electron microscopy of vitrified specimens. Electron diffraction patterns show that DNA within vitrified bacteriophages has a B conformation. Electron micrographs of vitrified bacteriophages show domains within the head formed by a approximately 2.5-nm striation and arising from the DNA packing. The number of differently oriented domains seen within a vitrified bacteriophage depends upon the geometry of the DNA container: the bacteriophage capsid. The packing of DNA within bacteriophages seems then to be governed by at least two phenomena. The first is the tendency of DNA to form local alignments (nematic liquid crystals). The second is the orientation of these liquid crystals by the bacteriophage capsid. From these observations we propose a possible packaging mechanism: constrained nematic crystallization.

Preparation of protein colloidal gold complexes in the presence of commonly used buffers

In the presence of various commonly used buffers, phosphate-buffered saline (PBS), tris-buffered saline (TBS), Na-cacodylate, bovine serum albumin and a wide range of cytochemically active proteins (monoclonal and polyclonal IgG, concanavalin A, Ricinus communis lectin I, Helix pomatia lectin, protein A) were complexed to colloidal gold of different particle sizes (6 nm, 9 nm, 22 nm). The resulting complexes were active in cytochemical labelling. Complex-formation in the presence of electrolyte opens the possibilities of: maintenance of ionic environment during complexing of proteins sensitive to low ionic strength, pH control by addition of buffers to the protein solution or to the gold sol, direct coupling of protein supplied in PBS or saline avoiding dialysis against low ionic strength buffers. Using the electron microscope to estimate the protein amounts needed for stabilization provided a sensitive and economical method to obtain aggregate-free protein-gold complexes.

Lyophilization of protein-gold complexes

Conditions for dialysis, freezing and lyophilization of protein-gold complexes were established. Lyophilized complexes formed by colloidal gold with staphylococcal protein A, with Helix pomatia lectin and with horseradish peroxidase retained their original staining properties when reconstituted after several months of storage.

"Thiocyanate gold": small (2-3 nm) colloidal gold for affinity cytochemical labeling in electron microscopy

Reduction of HAuCl4 by NaSCN or KSCN produces colloidal gold particles of 2.6 nm in diameter and homogeneous in size (coefficient of variation approximately 15%). The AuSCN sol forms protein-gold complexes. The amount of protein required to form an AuSCN-protein complex is best determined in the electron microscope, where serial dilutions of protein with gold sol are inspected for the presence of aggregates. By immuno-electron microscopy SCN-gold complexed to protein A is active and visible as is shown by revealing alpha-amylase in rat pancreatic acinar cells.

Reversible fixation for the study of morphology and macromolecular composition of fragile biological structures

Many subcellular structures are assemblies of subunits, which are in dynamic equilibrium with free subunits in solution. Their dissociation upon dilution, resulting from cell lysis, can be prevented by adequate fixation. If the latter is reversible, the constituting proteins of such subcellular structures can be analysed electrophoretically. Polyheads of bacteriophage T4 are in dynamic equilibrium with their subunits. They fit very well as a probe to measure the efficiency of crosslinking by the arrest of dissociation upon dilution and upon treatment with hot SDS. Formaldehyde (5%, 20 min, 20 degrees C) leads to a stabilisation comparable to fixation with glutaraldehyde (1%, 30 min). The fixation is shown to be reversible up to 86% by acid and borohydride treatment, but is stable towards heat and SDS-mercaptoethanol. Bands of the reversed proteins are neat and not found in detectably different positions in comparison to controls, when checked by SDS gel electrophoresis.

Comparison of surface iodination methods by electron microscopic autoradiography applied in vitro to different life-stages of Dipetalonema viteae (Filarioidea)

Different states of Dipetalonema viteae (males, females, microfilariae, and 3rd-stage larvae) have been iodinated in vitro under physiological conditions by chloroglycoluril, lactoperoxidase or chloramine T. The concentrations of the catalysts were correlated with the viability of the worms. Localization of the label with the different iodination methods had been visualized by electro microscopical autoradiography. Chloroglycoluril-mediated iodination is predominantly localized on the filarial cuticle. Lactoperoxidase-catalysed iodination is less specific and chloramine T catalyses iodination in a gradient decreasing from the cuticle to inner structures. It is necessary to visualize the labelling by electron microscopical autoradiography prior to biochemical and immunological experiments to avoid the extraction of structures iodinated by leakage of the catalyst into sub-cuticular regions.