The normal fine structure and aging changes of the human zonular fibers

Summary The normal zonular fibrils of the human eye do not differ from the fibrils of the zonula Zinnii of the rat. Furthermore, there is no difference between the single zonular fibrils and the fibrils of the vitreous body in rat and man. The average diameter of the human zonular fibrils is 109 Å. They are transversely striated at intervals with a periodicity of 70–150 Å. Over periods of mostly 400–440 å, but also of 500–640 Å were observed. At a few places over periods similar to those of the long spacing-type packing were found. Like in the rat eye, the zonular fibrils of the human eye must be regarded as a special form of collagen.An indirect proof for the collageneous nature of the zonular fibrils is the occurence in advanced age of degenerative alterations which are exclusively observed in connective tissue (hyalinization, elastoid degeneration).Supported by the Deutsche Forschungsgemeinschaft. Acknowledgement: I wish to thank Dr. H. Faßl, Institut für Medizinische Statistik und Dokumentation der Universität Mainz, for the statistical analysis.     

Ultrastructural features of adult human tendon

Summary A variety of human tendons have been studied at the electron microscope level. The fibers of these tendons are composed of collagen fibrils that average 1,750 Å and 600 Å in diameter. A third population that measures 100 Å in diameter may represent immature collagen or filaments that are incorporated into tendon elastic fibers. The larger collagen fibrils vary in ratio with respect to one another, and are connected by interfibrillar bridges which in some cases appear to extend through the substance of the fibril. The collagen fibrils of the paratenon are less-well organized than those of the tendon proper and average 600 Å in diameter. Tendons that exhibit the property of lateral stretch (plantaris and palmaris) were compared at the ultrastructural level with tendons that do not have this property. No differences between the two tendon types could be determined in normal or spread preparations, indicating that the differences in physical characteristics are a result of fiber rather than fibril organization.Supported by Edward G. Schlieder Foundation GrantThe authors wish to thank Mrs. Janell Buck and Mrs. Eunice Schwartz for their excellent technical and secretarial assistance, and Mr. Garbis Kerimian for his excellent photographic work     

A specific chromosome element,the telomere of Drosophila polytene chromosomes

The submicroscopic organization of terminal chromosome regions of Drosophila hydei polytene chromosomes is described. A compact region composed of tightly packed fibrils of 100 to 125 Å diameter embedded in an amorphous material is located at each of the chromosome ends of the 5 long chromosome arms. From this compact region, sometimes containing cavities, fibrils extend onto the nearest normal band region. The diameter of the extending fibrils is 100–125 Å, 200–250 Å or 400 Å. Pronase digestion of fixed and squashed chromosomes reduced the electron density of the amorphous matrix in the compact regions but failed to affect the diameter of the fibrils. The extending fibrils, however, showed a decrease in diameter after pronase digestion. The most frequently observed diameter values were 100–125 Å. — The volume of the terminal structures, including the compact region as well as the extending fibrils, is characteristically different for the various elements of the karyotype. Chromosome 2 displays the largest terminal structure, whereas chromosome 4 only occasionally shows the presence of compact regions. — End to end association of the long chromosome arms involves the fusion of the compact terminal structures. The non-random distribution of end to end association seems to be correlated with the volume of the terminal structures. Chromosome 2 which contains the largest compact terminal region is more frequently involved in end to end associations than any other chromosome arm. — The terminal regions show replication of DNA. They belong to the group of regions which display a discontinuous labeling pattern along the chromosomes, representing a late phase of the replication cycle. — The unique structural organization of the terminal chromosome regions, which is never observed at any other location of the genome supports the idea that they are morphological manifestations of the postulated telomeres.     

Mechanical response of individual collagen fibrils in loaded tendon as measured by atomic force microscopy

A precise analysis of the mechanical response of collagen fibrils in tendon tissue is critical to understanding the ultrastructural mechanisms that underlie collagen fibril interactions (load transfer), and ultimately tendon structure–function. This study reports a novel experimental approach combining macroscopic mechanical loading of tendon with a morphometric ultrascale assessment of longitudinal and cross-sectional collagen fibril deformations. An atomic force microscope was used to characterize diameters and periodic banding (D-period) of individual type-I collagen fibrils within murine Achilles tendons that were loaded to 0%, 5%, or 10% macroscopic nominal strain, respectively. D-period banding of the collagen fibrils increased with increasing tendon strain (2.1% increase at 10% applied tendon strain, p < 0.05), while fibril diameter decreased (8% reduction, p < 0.05). No statistically significant differences between 0% and 5% applied strain were observed, indicating that the onset of fibril (D-period) straining lagged macroscopically applied tendon strains by at least 5%. This confirms previous reports of delayed onset of collagen fibril stretching and the role of collagen fibril kinematics in supporting physiological tendon loads. Fibril strains within the tissue were relatively tightly distributed in unloaded and highly strained tendons, but were more broadly distributed at 5% applied strain, indicating progressive recruitment of collagen fibrils. Using these techniques we also confirmed that collagen fibrils thin appreciably at higher levels of macroscopic tendon strain. Finally, in contrast to prevalent tendon structure–function concepts data revealed that loading of the collagen network is fairly homogenous, with no apparent predisposition for loading of collagen fibrils according to their diameter.     

Electron microscopy of crystalline micelles in cellulose elementary fibrils of Dictyostelium discoideum

Summary In negatively stained preparations the cellulose of Dictyostelium discoideum appears in the form of 35 Å wide fibrils of undetermined length. Upon mild acid hydrolysis a periodic pattern may be observed along the fibrils, in the form of fine, electron-dense bands across the full diameter of the fibril spaced apart from each other by electron-transparent segments approximately 100 Å long. We propose that the electron-transparent segments represent the crystalline micelles of the elementary cellulose fibril, whereas the electron-opaque bands represent the amorphous regions.Part of a thesis submitted by the senior author in partial fulfillment of the requirements for the Ph.D. degree, University of Hawaii.     

Studies on the fine structure of the dorsal vessel of arthropods

Summary The heart of the lobster (Palinurus vulgaris L.) is a sleeve of muscle fibres, with the characteristics of the slow muscles of Crustacea: thin/thick filament ratio of about 6/1, sarcolemmal invaginations from which radial tubules arise, diads and triads formed by tubules and sarcoplasmic reticulum, large mitochondria, great amounts of glycogen. The muscle elements are not syncytial, but separated from one another by intercalated discs. The inner and outer surfaces of the muscle wall are ensheathed by connective tissue membranes made up of long-period (700 Å with 9 subbands) collagen fibrils, very low polysaccharide content, and no elastin. Amoebocytes are frequently embedded in the collagen sheath.     

Collagen formation — observations on its intracellular packaging and transport

Summary Odontoblasts, osteoblasts and fibroblasts of young rats were examined in the electron microscope after staining thin sections either with lead citrate alone or with uranyl acetate prior to lead citrate.With lead citrate alone, collagen fibrils in the extracellular matrix stand out as lucent structures against a moderately electron dense background. Within the cells, lucency is restricted to certain dilated portions of the Golgi saccules as well as to the secretory granules located nearby and in the secretory pole of the cells. The lucency present in these compartments may be attributed to fibrils that are similar to the lucent collagen fibrils in the extracellular matrix. Other cellular compartments, e.g. the rough ER, do not display lucency.When preparations are stained with uranyl acetate prior to lead citrate, lucency is observed neither in the matrix nor in the cells. In the matrix, collagen fibrils are easily identifiable by their cross banded pattern. In the odontoblasts, dilated portions of Golgi saccules between the outer and inner face contain filaments aligned in parallel that are approximately 3 000 Å in length. In saccules on the inner face filament aggregates are present, some of them exhibiting a cross banding pattern. In secretory granules, however, the contents appear rather homogeneous.It is suggested that filament aggregates of collagen can assemble in the Golgi apparatus from filamentous units. These are transported through the cell by way of secretion granules and are discharged to the extracellular matrix by exocytosis.This investigation was supported by grants of the Medical Research Council of Canada. The author wishes to express appreciation to Dr. C. P. Leblond for his guidance in the course of this work.     

Structural aspects of amitosis: a light and electron microscope study of the isolated macronuclei of Paramecium aurelia and Tetrahymena pyriformis

Thin sections show the macronuclei of Paramecium aurelia and Tetrahymena pyriformis to contain two types of bodies. The smaller, measuring 0.1–0.2 in diameter, have been resolved in the light microscope by first removing the macronuclei from the cells in the presence of Mg⁺⁺, then chelating that divalent cation with EDTA, resulting in expansion of the nuclear material. By staining with methyl green, Azure B, and the Feulgen procedure, the small bodies were shown to contain DNA. In whole mounts these small bodies appear to be joined to one another producing a complex network suspended in which are the larger bodies, or nucleoli. — Macronuclei from both ciliates were isolated in large quantities and purified for spreading on an air-water interface. When the nuclei burst from surface tension forces and are examined with the electron microscope, the DNA containing bodies remain attached to one another by means of 100 Å fibrils. The pattern of attachment is non-linear. Occasionally individual DNA-containing bodies loosen revealing a coil resembling both in shape and dimensions the 250 Å coil characteristic of eucaryotic chromatin. The substructure of the 250 Å coil has not been directly observed. However, the frequent association of pairs of 100 Å fibrils makes it likely that two such fibrils are tightly complexed in the 250 Å coil. The 100 Å fibril, in turn, contains two 20 Å strands, each presumably a DNA double helix. — In Paramecium each small body of the macronucleus contains approximately one chromosome-equivalent of DNA. The fact that these small bodies are joined to form large structured masses of chromatin within the macronucleus indicates that the distribution of genetic material is not random. It is possible that, similar to bacteria, entire genomes segregate as units, thus accounting for successful amitotic division.This work was supported by a Predoctoral Fellowship to the author from the National Institutes of Health, U.S. Public Health Service, and by grant GM-13882 (NIH-USPHS) to Dr. Daniel Mazia.     

Electron microscopic observations on interband fibrils in Drosophila salivary chromosomes

Acetic alcohol squash, preparations of salivary chromosomes of Drosophila melanogaster stained with uranylacetate during fixation and dehydration were sectioned and examined with the electron microscope. At high magnification the interband regions are seen to be composed of coiled fibrils in the range of 50 Å which often seem to be arranged in pairs. Submicroscopic bodies found along the interband fibrils seem to delimit successive subunits. It is suggested that transverse coiling of the fibrils within the boundaries of each subunit leads to the formation of chromomeres.     

An investigation of ageing in human costal cartilage

Summary Changes in human costal cartilage with increasing age (2–81 years) have been studied in the optical and electron microscope using routine and histochemical techniques.Concurrent with increasing age, chondrocytes undergo degeneration which is characterized initially by the accumulation of lipidic material within cells and, subsequently, by the formation of a halo around degenerating chondrocytes. The halo material is composed of electron dense bodies, amorphous material, and collagen fibrils. Both electron dense bodies and the amorphous material are of cellular origin and they have similar histochemical responses.Using histochemical techniques in the optical and in the electron microscope, it has been shown that chondroitin sulfate decreases with increasing age, while a hyaluronidase resistant material (presumably keratan sulfate) increases, initially in the central zone, and subsequently in the peripheral zones. Hyaluronidase resistant material is minute or absent in the central zone of aged cartilage.The genesis of collagen fibrils progresses from thin unbanded collagen-like fibrils in the pericellular lacunae of chondrocytes in young specimens to thick fibrils (sometimes in excess of 0.5 ) with a period of 640 Å in ageing cartilage. Aggregation of collagen fibrils seems to be related at least initially to the preponderance of matrix granules and beaded filaments which have been shown to originate intracellularly in vacuoles formed in degenerating mitochondria. Both of these structures contain glycosaminoglycans and, with increasing age, glycosaminoglycans decrease while collagen fibrils aggregate. In old age, the amorphous material, and possibly the content of disrupting electron dense bodies, seem to give origin to some collagen fibrils. This and other mechanisms of formation of collagen fibrils have been observed and they are discussed.Calcification of the matrix increases with increasing age and this agrees with previous findings.Supported by grants from the Italian National Research Council. — The authors are indebted to Miss Giuliana Silvestrini and to Mr. Lucio Virgilii for their expert and extensive technical assistance. — To Dr. A. Ascenzi, Director 1° Istituto di Anatomia e Istologia Patologica, and to Dr. C. Cavallero, Director, 2° Istituto di Anatomia e Istologia Patologica, Università di Roma, the senior author would like to express his appreciation for the use of equipment and facilities pursuant to this investigation, while on sabbatical leave from the University of California, Irvine, College of Medicine. — We wish to extend our thanks to the Italian National Research Council for supporting this study.On sabbatical leave from the University of California, Irvine, College of Medicine.     

Quantification of collagen organization in the peripheral human cornea at micron-scale resolution

The collagen microstructure of the peripheral cornea is important in stabilizing corneal curvature and refractive status. However, the manner in which the predominantly orthogonal collagen fibrils of the central cornea integrate with the circumferential limbal collagen is unknown. We used microfocus wide-angle x-ray scattering to quantify the relative proportion and orientation of collagen fibrils over the human corneolimbal interface at intervals of 50 μm. Orthogonal fibrils changed direction 1–1.5 mm before the limbus to integrate with the circumferential limbal fibrils. Outside the central 6 mm, additional preferentially aligned collagen was found to reinforce the cornea and limbus. The manner of integration and degree of reinforcement varied significantly depending on the direction along which the limbus was approached. We also employed small-angle x-ray scattering to measure the average collagen fibril diameter from central cornea to limbus at 0.5 mm intervals. Fibril diameter was constant across the central 6 mm. More peripherally, fibril diameter increased, indicative of a merging of corneal and scleral collagen. The point of increase varied with direction, consistent with a scheme in which the oblique corneal periphery is reinforced by chords of scleral collagen. The results have implications for the cornea's biomechanical response to ocular surgeries involving peripheral incision.     

Surface-sensitive Raman spectroscopy of collagen I fibrils

Collagen fibrils are the main constituent of the extracellular matrix surrounding eukaryotic cells. Although the assembly and structure of collagen fibrils is well characterized, very little appears to be known about one of the key determinants of their biological function—namely, the physico-chemical properties of their surface. One way to obtain surface-sensitive structural and chemical data is to take advantage of the near-field nature of surface- and tip-enhanced Raman spectroscopy. Using Ag and Au nanoparticles bound to Collagen type-I fibrils, as well as tips coated with a thin layer of Ag, we obtained Raman spectra characteristic to the first layer of collagen molecules at the surface of the fibrils. The most frequent Raman peaks were attributed to aromatic residues such as phenylalanine and tyrosine. In several instances, we also observed Amide I bands with a full width at half-maximum of 10–30 cm⁻¹. The assignment of these Amide I band positions suggests the presence of 3₁₀-helices as well as α- and β-sheets at the fibril's surface.     

The structure of calcified tendon

Summary The small angle X-ray scattering from unheated and heated calcified chicken tendon has been accurately measured using an automatically recording Kratky camera. A two-dimensional optical diffraction pattern of electron micrographs has been recorded and is in excellent agreement with the small angle X-ray diffraction pattern.The wide and small angle X-ray diffraction pattern, the Fraunhofer diffraction pattern, electron microscopic appearance, and a Fourier synthesis are mutually consistent, and indicate that the crystalline fraction of apatite in normal calcified tendon exists in the form of well oriented crystallites of about 330 Å in length and 50–60 Å in width with the long axis being parallel to the local fibre axis. The separate crystallites are largely located in parallel rows which repeat every 660 Å in the longitudinal direction of the tendon.Analysis of the small angle equatorial scattering shows the crystallites to be clustered together into three well-defined groups with diameters of about 60 Å, 190 Å, and 400 Å. It is suggested that the largest clusters are located in between the collagen fibrils and correspond to the primary calcification.This work was carried out under the supervision of Professor Arne Engström (Head of the Department of Medical Physics, Karolinska Institutet, Stockholm) while the author held a Longterm Fellowship from the European Molecular Biology Organization.     

Fine structure of interphase nuclei

The initiation and replication sites of DNA synthesis in the plasmodial nuclei of Physarum polycephalum were studied with electron microscopic autoradiography. By using both thin sectioning and whole mount techniques, it was shown that the dense chromatin masses in the nucleus consisted of predominantly elementary chromatin-like fibrils, approximately 300 Å in diameter while the electron transparent region in the nucleus consisted of predominantly finer fibrils, less than 100 Å in diameter. With electron microscopic autoradiography it was found that (1) the initiation sites of DNA synthesis were definitely in the boundary regions between the dense chromatin masses and the electron transparent region, (2) the initiation and replication sites of DNA synthesis were definitely not on the nuclear membrane, (3) within a few minutes, replication sites migrated from the initiation sites to the electron transparent region and (4) in this electron transparent region, almost all of the nuclear DNA was synthesized.     

An electrostatic model for collagen fibrils. The interaction of reconstituted collagen with Ca++, Na+, and Cl−

A model for the electrostatic properties of hydrated collagen fibrils, based on the concept of a “penetrable” protein, has been evaluated through studies of collagen fibrils that had been chemically modified to change their electrostatic properties,. A value of 0.28 ± 0.07 ml/g was found for the intrafibrillar space sterically inaccessible to a molecule that had an equivalent spherical radius of 4.5 Å. The net intrinsic charge on reconstituted collagen is +14 mol/mol under physiological conditions, but decreases, at constant pH, with ionic strength. A value of 7.1 for the pK of the histidine and α-amino groups in reconstituted collagen was obtained through the application of the electrostatic model to this effect. The values obtained for calcium binding parameters for collagen fibrils, under solution conditions in which the nonspecific electrostatic properties of collagen fibrils were eliminated (3–5 M tetramethyl ammonium chloride), were in agreement with values obtained in 0.16 M NaCl solutions calculated through the use of the electrostatic theory. These are 0.73 ± 0.23 and 56.2 ± 12.3 sites per molecule with intrinsic association constants of 1101 ± 386 and 21.4 ± 5.2 M^?1, respectively. The model also predicts that an average 4-mV potential difference exists between the reconstituted collagen fibrils and physiological solutions, and that collagen fibrils under such conditions have piezoelectriclike properties. The pattern of interaction of ions with collagen fibrils is such that an allosteric mechanism for the catalytic step in the mineralization of collagen is a possibility.     

Elektronenmikroskopische Untersuchungen menschlicher Metaphasen-Chromosomen

Zusammenfassung Chromosomen von Mitosen im Metaphasestadium nach Colchicinbehandlung normaler menschlicher Fibroblastenkulturen wurden mit dem Elektronenmikroskop untersucht.Nach Fixierung in Glutaraldehyd und Einbettung in Epon zeigen Schnittpräparate nach Kontrastierung mit Uranylacetat als feinste erkennbare Elemente etwa 30 Å dicke, schraubig gewundene Fibrillen, die dickere, vielfach und unregelmäßig gefaltete Fibrillen von 100–150 Å Durchmesser aufbauen.Isolierte ganze Chromosomen, die zur Präparation mit hypotoner Salzlösung vorbehandelt, in Alkohol-Essigsäure fixiert und luftgetrocknet wurden, lassen stark gewundene dicke Fibrillen von 200–300 Å durchmesser erkennen, die aus schraubig gewundenen 30 Å dicken Fibrillen bestehen. In Schnittpräparaten von ähnlich vorbehandelten Chromosomen finden sich ebenfalls 200–300 Å dicke Fibrillen, die aus 30 Å dicken feineren Fibrillen in lockerer Anordnung aufgebaut sind. Der größere Durchmesser der dicken Fibrillen in hypoton vorbehandelten Präparaten könnte durch Auflockerung der feinen Fibrillen hervorgerufen sein.In allen Präparaten sind die auch lichtmikroskopisch sichtbaren primären Windungen der Chromatiden angedeutet. Die dickeren Fibrillen lassen sonst keine regelmäßige Anordnung erkennen. Längsunterteilungen im Sinne von Halb- oder Viertelchromatiden sind nicht zu sehen. In Totalpräparaten erscheint die Region des Zentromers weniger dicht, und Kinetochoren sind nicht erkennbar.Es wird die Frage diskutiert, ob nur eine kontinuierliche und vielfach gewundene Fibrille oder mehrere miteinander verflochtene Fibrillen und Stränge ein Chromatid aufbauen.

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Metaphase chromosomes of colchizinized normal human fibroblast cultures were investigated with the electron microscope.Sections of glutaradehyde fixed and epon embedded chromosomes show 30 Å thick coiled fibrils building up folded thicker fibrils of 100–150 Å diameter.Isolated total chromosomes pretreated in hypotonic salt solution, fixed in alcohol-acidic acid and air dried, show also 30 Å thick fibrils coiled into thicker fibrils of 200–300 Å diameter. Sections of similarly treated and epon embedded chromosomes show fibrils of similar dimensions but more loosely coiled than in glutaraldehyde fixed sections.Major coils also seen by light microscopy are noticeable in all preparations. No signs of longitudinal subdivisions of the chromatids are detectable. In whole mount preparations the centromere region appears as less dense and kinetochores cannot be seen.The question is discussed whether one single continuous fibril coiled to a thicker fibril which in turn is irregular folded to a strand laid into the major coils builds up a chromatid, or if many thin fibrils join together to thicker fibrils which again form thicker strands which are finally twisted together to a chromatid.

     

Comparative study on the thermostability of collagen I of skin and bone: Influence of posttranslational hydroxylation of prolyl and lysyl residues

Pepsin-solubilized collagen I from skin and bone was analyzed with regard to its thermal stability as a triple helical molecule in solution and afterin vitro fibril formation. Collagen I from human control bone was compared with samples showing deficiencies or surplus in the degree of hydroxylation of lysine. The helix to coil transitions were studied by circulardichroism measurements and limited trypsin digestion. Melting of fibrils from standardizedin vitro self-assembly was investigated turbidimetrically. Human control bone collagen I has a maximum transition rate (T _m ) at 43.3°C in 0.05% acetic acid. This is 1.9°C above control skin (T _m =41.4°C), most likely, due to a higher degree of prolyl hydroxylation—0.48 in bone vs. 0.41 in skin collagen I. Lysyl overhydroxylation of human and mouse bone collagen I appears to reduce theT _m slightly (1°C). Underhydroxylated bone collagen has aT _m which is 2°C below control. Melting temperatures ofin vitro formed fibrils are an indication for higher thermostability in parallel with an increase of lysyl hydroxylation. Accordingly, the melting temperature of such fibrils from human control skin, 49.3°C, exceeds control bone by 1.4°C. The degree of lysyl hydroxylation in these samples is 0.14 and 0.10, respectively. Further underhydroxylation (0.06) reduced it down to 45.4°C, while extensive overhydroxylation did not continue to increase the thermal stability of fibrils.     

Cartilage induction in vitro : Ultrastructural studies

When 19-day fetal rat triceps muscle was cultured for 7 to 14 days upon decalcified, sequentially extracted adult rat bone, cartilage formed within clefts and vascular spaces of the decalcified bone. The bone substrata were prepared by extracting tibias and femurs of Sprague-Dawley rats with 1:1 chloroform:methanol, 0.6 N HCl, 2 M CaCl₂, 0.6 M EDTA, 8 M LiCl, and H₂O at 56°C. The culture medium used was CMRL 1066 with 15% newborn calf serum. During cultivation, fibroblastic mesenchymal cells migrated out of muscle and into bone crevices where they secreted a cartilaginous matrix composed of thin, randomly dispersed collagen fibrils and proteoglycan granules. The latter are characteristic for cartilage matrix. Extracted bone matrix contained mature collagen fibrils, some of which retained their typical 640-Å banding. Other collagen fibrils were partially disaggregated and expanded to reveal component 50-Å-thick, beaded micro fibrils. Such an expansion of collagen fibrils is known to result from exposure to proteoglycan solvents such as 2 M CaCl₂. The decalcified bone matrix contained many residual devitalized cells and cell fragments which often were seen in close proximity to chondrifying mesenchymal cells. This finding indicates the possibility that residual cellular material could play a role in stimulating cartilage development.     

Wall fibrils ingerminating sporangiospores of Gilbertella persicaria (Mucorales)

Summary In germinated sporangiospores of Gilbertella persicaria, negatively contrasted fibrils, 20–70 Å diam, are seen in thin sections of the inner vegetative wall that is continuous with the germ tube wall. The fibrils are randomly oriented in a loose network in this wall and in the germ tube wall. Germ tubes have an additional surface layer of fine, positively contrasted fibrils which appear as a nap-like coating on the hyphae. Patterns of wall fibril orientation are not revealed by transverse sections of spore and germ tube walls, whereas oblique and tangential sections are favorable for examining cell wall architecture in situ. Staining patterns show textural and compositional differences among various wall layers.     

Microfibrils: a constitutive component of reticular fibers in the mouse lymph node

Summary Fibrous components other than collagen fibrils in the reticular fiber of mouse lymph node were studied by electron microscopy. Bundles of microfibrils not associated by elastin and single microfibrils dispersed among collagen fibrils were present. The diameter of the microfibrils was 13.29±2.43 nm (n=100). Elastin-associated microfibrils occurred at the periphery of the reticular fiber. Elastin was enclosed by microfibrils, thus forming the elastic fiber, which was clearly demonstrated by tannic acid-uranyl acetate staining. In the reticular fiber of lymph nodes, the elastic fiber consisted of many more microfibrils and a small amount of elastin. These microfibrils, together with the collagen fibrils, may contribut to the various functions of the reticular fibers.