Ultrastructural studies of H-1 parvovirus replication. II. Induced changes in the deoxyribonucleoprotein and ribonucleoprotein components of human NB cell nuclei.

Ultrastructural changes in the nuclear DNP and RNP components of human NB cells induced by synchronous infection with H-1 parvovirus were studied using Bernhard's EDTA method of staining. Early events (12 h after infection) occurred in the nucleolus. Chromatin within the nucleolar fibrous centers condensed thereby converting the centers to vacuoles. DNP associated with the granular nucleolonema also contracted markedly, causing a disruption of this skein-like structure; it then migrated peripherally forming a heterochromatic cortex surrounding the granular nucleolar vestige. Subsequently (24–36 h after inoculation), condensation of extranucleolar chromatin took place concurrently with the accumulation of extensive amounts of interchromatin granules in the nucleus and cytoplasm. Conglomerates of perichromatin fibrils and interchromatin granules were frequently juxtapposed to the condensing chromatin. Large clumps of interchromatin granules were also closely associated with fragmenting nucleoli, and the apparent transformation of nucleolar granules into interchromatin granules was observed. Accumulation of H-1 protein on chromatin evidently fostered its condensation resulting in the pathology described.     

Immunoelectron microscopic localization of estrogen receptor on pre-mRNA containing constituents of rat uterine cell nuclei

The localization and quantitative changes of estradiol receptor (ER) were studied by means of immunogold-electron microscope methods using a polyclonal antibody directed against an amino acid sequence representing the DNA binding site of ER, a monoclonal antibody against hnRNP core protein, and anti-DNA antibody. The uteri of normal rats in estrus and those of ovariectomized females were used. Ovariectomized rats were studied 21 days after surgery at different times after the injection of normal saline or estradiol-17 beta. The density of labeling was measured in interchromatin space, compact chromatin, nucleolus, cytoplasm, and background of epithelial cells, muscle cells, and fibroblasts. In the three types of cells ER was found mainly on extranucleolar ribonucleoprotein (RNP) fibrils. In epithelial and muscle cells the nucleolus was labeled but compact chromatin was not labeled. In epithelial cells there was a low but significant labeling of the cytoplasm. Fibroblasts exhibited a low labeling of the compact chromatin. Ovariectomy did not change these distributions. The estradiol injection increased labeling in all compartments of epithelial and muscle cells but decreased the labeling of compact chromatin of fibroblasts. These results show: (a) that ER is mainly nuclear but it is also present in the cytoplasm, (b) that ER binds to the nuclear particles containing newly synthesized RNA, and (c) that the binding to RNPs does not block the DNA binding domain of the ER.     

Intranuclear distribution of SV40 large T-antigen and transformation-related protein p53 in abortively infected cells

The intranuclear localization of SV40 T-antigen (T-Ag) and the cellular protein p53 was studied in SV40 abortively infected baby mouse kidney cells using two complementary methods of ultrastructural immunocytochemistry in combination with preferential staining of nuclear RNP components and electron microscope autoradiography. Both proteins were revealed in association with peri- and interchromatin RNP fibrils containing the newly synthesized hnRNA. In addition, T-Ag and p53 remained bound, at least in part, to the residual internal nuclear matrix following nuclease and salt extractions of infected cells. The localization of T-Ag was different in SV40 lytically infected monkey kidney cells since, in addition to hnRNP fibrils, the viral protein was also associated with cellular chromatin. However, when lytic infection was performed in conditions of blocked viral DNA replication, T-Ag was no longer associated with the cellular chromatin but remained bound to the hnRNP fibrils. We conclude that the transforming and lytic functions of T-Ag can be distinguished by different subnuclear distributions. The significance of the association of T-Ag and p53 with hnRNP fibrils and the internal nuclear matrix is discussed in relation to the role of these structures in the control of cellular mRNA biogenesis.     

Ultrastructure of the DNP fibrils and of the interchromatin granules in isolated nuclei of the rat liver]

The structural organization of DNP fibrils and interchromatin granules of isolated rat hepatocyte nuclei has been studied in various conditions of chromatin solubilization. When observed either in nuclei fixed in situ or in a solution containing 20 mM TEA and 1 mM MgCl2, a DNP fibril consists of globular structures 20--25 nm in diameter. In the nuclei fixed in a magnesium-free solution (20 mM TA), nucleosome structures are revealed in DNP. Condensation of chromatin results from interaction between 20 nm globular fibrils, whereas the complete dispersion of chromatin is a consequence of its conversion into the nucleosomal form. In the conditions of both DNP structuralization and dispersion, the nuclei are revealed to contain zones of interchromatin granules connected by thin fibrils. It is assumed that the different compactness of these granular-fibrillar complexes and of the regions of condensed chromatin may be used for their separation and fractionation.     

Induction of chromatin condensation by nuclear expression of a novel arginine-rich cationic protein genetically engineered from the enhanced green fluorescent protein

In the interphase nuclei of cultured cells, chromatin is compacted and organized in higher-order structures through the condensation and decondensation processes. Chromosomes in the interphase nucleus are known to occupy distinct territories. The chromosome territory-interchromatin compartment model premises that the interchromatin compartment is separated from compact higher-order chromatin domains and expands in between these chromatin-organized territories. Chromatin in cultured cells is compacted under some conditions, such as the stress of heat shock and high osmolarity, and Src-mediated nuclear tyrosine phosphorylation. We report here that a novel arginine-rich cationic protein is generated by frameshift mutation of enhanced green fluorescent protein (EGFP). The arginine-rich cationic protein is highly hydrophilic and contains potential arginine-based nuclear localization signals. Expression of the arginine-rich cationic protein shows its predominant localization to the nucleus and induces striking chromatin condensation in the interphase, which might be involved in interchromatin spacing or euchromatinization. Thus, the arginine-rich cationic protein as a new tool would be useful for dissecting chromatin architecture dynamics.     

Ultrastructural distribution of ribonucleoprotein complexes during mitosis. snRNP antigens are contained in mitotic granule clusters

The great majority of snRNP and hnRNP ribonucleoproteins have been shown to be confined to the nucleus except during periods of cell division. We have now determined the fine structure distribution of polypeptides associated with these RNP complexes during interphase and mitosis in mammalian tissue culture cells using immunoelectron microscopy. Many hnRNP antigens are found at the periphery of heterochromatin masses, known to be the sites of non-rRNP proteins initially surround areas of condensing chromatin and later become generally dispersed throughout the mitotic cell. The Sm protein antigens of snRNP complexes are found diffusely distributed in interphase nuclei as well as concentrated in fields of interchromatin granules (ICG). Proteins of snRNP complexes, unlike those of hnRNP, are associated with discernible cellular structures during mitosis. By prometaphase/metaphase, dense granular clusters are observed to contain a high concentration of snRNPs. These mitotic granule clusters (MGCs) are often in close proximity to chromosomal masses by late anaphase/telophase. The MGC structures are morphologically similar to interchromatin granule fields found in interphase nuclei. Furthermore, like interchromatin granules, they are sites of a high concentration of snRNP antigens and do not contain detectable hnRNP proteins or DNA.     

Assessment of a mechano-regulation theory of skeletal tissue differentiation in an in vivo model of mechanically induced cartilage formation

Mechanical cues are known to regulate tissue differentiation during skeletal healing. Quantitative characterization of this mechano-regulatory effect has great therapeutic potential. This study tested an existing theory that shear strain and interstitial fluid flow govern skeletal tissue differentiation by applying this theory to a scenario in which a bending motion applied to a healing transverse osteotomy results in cartilage, rather than bone, formation. A 3-D finite element mesh was created from micro-computed tomography images of a bending-stimulated callus and was used to estimate the mechanical conditions present in the callus during the mechanical stimulation. Predictions regarding the patterns of tissues—cartilage, fibrous tissue, and bone—that formed were made based on the distributions of fluid velocity and octahedral shear strain. These predictions were compared to histological sections obtained from a previous study. The mechano-regulation theory correctly predicted formation of large volumes of cartilage within the osteotomy gap and many, though not all patterns of tissue formation observed throughout the callus. The results support the concept that interstitial fluid velocity and tissue shear strain are key mec- hanical stimuli for the differentiation of skeletal tissues.     

Ionic milieu and volume adjustments in detergent-extracted thymic nuclei

Detergent-extracted isolated thymic lymphocyte nuclei were incubated in buffers containing 3 mM Ca++ and Mg++ and varying concentrations of Na+ and K+. Nuclei in 15 mM K+, 15 mM Na+ had a smaller size, smaller interchromatin spaces, and less packed chromatin than nuclei in the absence of these ions, but their water content relative to dry mass was not significantly different. NMR relaxation properties of water protons in these different nuclei were different, and nuclei in 15 mM K+, 15 mM Na+ contained twice as much K and Na as in the buffer solution. These findings indicate that the hydration of chromatin bodies and the size of the interchromatin spaces are sensitive to the free monovalent ion concentrations. When isolated nuclei were exposed to solutions containing 150 mM total concentration of K + Na, the nucleoplasm became disrupted and the hydration index was greater. The results are discussed in regard to possible mechanisms of nuclear volume control in cells.     

Identification of apoptotic cell death in distraction osteogenesis

The purpose of this experimental work was to investigate whether apoptosis contributes to tissue remodelling during distraction bone healing. In a rabbit model of mandibular distraction osteogenesis, we quantitatively analysed the extent of apoptotic cell death in relation to differently applied mechanical loadings. Apoptotic cells were identified by means of an in situ detection assay for nuclear DNA fragmentation using a modified TUNEL procedure and by electron microscopical examination for typical morphological features of programmed cell death. TUNEL-positive cells were frequently detected in samples distracted at higher strain magnitudes. Ultrastructurally, these apoptotic cells displayed a condensed chromatin and fragmented nuclei, while the continuity of their plasma membranes remained intact. Our results clearly indicated that the discontinuous traction of osteotomized mandibles induced enhanced apoptosis. In contrast to non-distracted samples and mandibles distracted at low strain magnitudes, in which only minimal evidence of apoptotic cell death was detected, the application of hyperphysiological strain magnitudes resulted in an increased apoptosis rate. Thus, mechanical loading seems to be a triggering factor for apoptotic changes in osteoblastic cells. These findings suggest a pathophysiological role of apoptotic cell death in the control of tissue integrity during distraction osteogenesis.     

Direct noninvasive measurement and numerical modeling of depth-dependent strains in layered agarose constructs

Biomechanical factors play an important role in the growth, regulation, and maintenance of engineered biomaterials and tissues. While physical factors (e.g. applied mechanical strain) can accelerate regeneration, and knowledge of tissue properties often guide the design of custom materials with tailored functionality, the distribution of mechanical quantities (e.g. strain) throughout native and repair tissues is largely unknown. Here, we directly quantify distributions of strain using noninvasive magnetic resonance imaging (MRI) throughout layered agarose constructs, a model system for articular cartilage regeneration. Bulk mechanical testing, giving both instantaneous and equilibrium moduli, was incapable of differentiating between the layered constructs with defined amounts of 2% and 4% agarose. In contrast, MRI revealed complex distributions of strain, with strain transfer to softer (2%) agarose regions, resulting in amplified magnitudes. Comparative studies using finite element simulations and mixture (biphasic) theory confirmed strain distributions in the layered agarose. The results indicate that strain transfer to soft regions is possible in vivo as the biomaterial and tissue changes during regeneration and maturity. It is also possible to modulate locally the strain field that is applied to construct-embedded cells (e.g. chondrocytes) using stratified agarose constructs.     

High-resolution detection of newly synthesized DNA by anti-bromodeoxyuridine antibodies identifies specific chromatin domains

We analyzed the incorporation of bromodeoxyuridine (BrdUrd) into DNA in exponentially growing murine erythroleukemia cells (FLC-745), using fluorescent anti-BrdUrd antibodies with light microscopy and flow cytometry. The fine localization of the DNA replicating sites was investigated at the ultrastructural level by using a second antibody conjugated with colloidal gold. The latter approach, which does not require acidic denaturation of the DNA, enables preservation of good morphology and obtains a better resolution power than that of electron microscopic autoradiography, the percentage of labeled cells obtained with the two techniques being comparable. After short BrdUrd pulses, characteristic distribution of the labeling can be identified in the heterochromatin, in interchromatin domains, or at the boundary between the dispersed and the condensed chromatin. Similar patterns are also observable in the nuclear structures which condense after acid denaturation, suggesting that DNA replication takes place at fixed sites associated with the nuclear matrix.     

A novel mechanical loading model for studying the distributions of strain and mechano-growth factor expression

Mechano-growth factor (MGF), an insulin-like growth factor-I (IGF-I) splice variant, often serves as an important local tissue repair factor in response to the mechanical environment. However, there is no model for exhibiting the MGF expression in a series of strain distribution up to now. In this study, a novel mechanical loading model containing different stresses and strains simultaneously was developed to examine the MGF expression. The strain distributions were predicted by finite element modeling. The MC3T3-E1 cells on a silicone membrane with a central circular hole were exposed to a variable strain environment through stretching. The finite element analysis showed that, when the strain reached the magnitude of 10%, the strain concentration near the circular hole displayed along with the vertical stretch direction, while the minimum strain appeared in the parallel stretch direction. Furthermore, the results showed that MGF expression decreased gradually from high to low strain regions by immunocytochemistry. Meanwhile, the proliferation of osteoblasts increased significantly in the high strain region. In conclusion, this mechanical loading model can present the different distributions of the strain of osteoblasts in vitro. MGF expression and osteoblast proliferation have a high correlation with the levels of strain.