Prismatic cristae and paracrystalline inclusions in mitochondria of myocardial cells of the oyster Crassostrea virginica Gmelin

Summary Several types of unusual mitochondrial configurations were found in myocardial cells of the oyster Crassostrea virginica Gmelin. These mitochondria include, in order of frequency, prismatic cristae, filamentous paracrystals in honeycomb and herringbone configurations, and paracrystals composed of rows of electron dense particles. The long, parallel, evenly spaced prismatic cristae are square or rhomboidal in cross section. In the space between the prismatic cristae are rodlike structures (4–6 nm in diameter) that are regularly spaced about 12nm apart and appear to pass between adjacent cristae. Filamentous paracrystals are observed in slender, elongated mitochondria. The filament spacing and form of these paracrystals suggest that they are composed of the intercristal rods. Alternatively, filamentous paracrystals might be tangential sections of prismatic cristae and intercristal rods. Particulate paracrystals which consist of dense lines or rows of particles are the least frequent type of unusual configuration. The particles are triangular, possibly pyramidal, in shape; their bases are 10–12 nm thick and repeat in rows every 17–18 nm. There is a close association between particulate paracrystals and prismatic cristae plus intercristal rods. Although similar mitochondrial configurations have been associated with disease or altered metabolism in a number of species, we have found no such association in the oyster as yet.Supported in part by the Mississippi-Alabama Sea Grant Consortium, through NOAA, Dept. of Commerce under grant no. NA 79AA-D-0049We wish to thank Ms. Barbara M. Hyde, Ms. Patricia A. Vermiere and Mr. Robert Allen for their technical assistance     

The paracrystalline structure of an insect rhabdomere (Calliphora erythrocephala)

Summary By use of a modified fixation technique, the receptor cells of the compound eye of the blowfly Calliphora erythrocephala were found to contain a regular, paracrystalline array of alternating rows of hexagonally shaped microvilli. The receptor cells R1 to R6 have a cell-specific number of microvilli per row in a cross section. Every microvillus has a filament cluster connecting the axial skeleton with the microvillar membrane. This cluster is preferentially right-left oriented relative to the longitudinal axis of the microvillar array. Three adjacent microvilli are interconnected by an electron-dense substance. A mirroring technique indicated that this intermicrovillar structure consists of three subunits, although these subunits could not be conclusively demonstrated by classical densitometry or image subtraction techniques. The electron-dense substance can be seen in all cross sections of the proximal and distal parts of the microvilli. They are cylindrical structures separating the microvilli along their entire length. It is suggested that these cylindrical aggregates contain an enzymatic complex separating the rhodopsin-containing microvillar membrane into six compartments.     

MORPHOLOGICAL VARIABILITY OF MITOCHONDRIAL FINE STRUCTURE IN CULTURED GONYAULAX POLYEDRA (PYRRHOPHYTA)1

Mitochondria in Gonyaulax polyedra Stein have a highly variable morphology which depends on their location within the cell. The morphology ranges from mitochondria, 1 μm in cross section, with highly dense cristae which are located within the central sphere of golgi bodies to giant pleomorphic mitochondria, 5–8 μm in cross section containing condensed “chromosome” structures and located in the more peripheral regions of the cell. Elongated mitochondria containing microtubule-like elements ware also observed.     

Effects of ethidium bromide, tetramethylethidium bromide and betaine B on the ultrastructure of HeLa cell mitochondria in situ. A comparative binding study

Several investigators have described the ultrastructural changes that occur in the mitochondria of cells in tissue cultures after treatment with the drug ethidium bromide (E). The mitochondria swell and the cristae become greatly altered and finally disappear; in the cristae-free region of the matrix electron-dense granules can be observed. It has been assumed that intercalation of E between the base pairs of the mitochondrial DNA induces the formation of the granular inclusions. To investigate whether intercalation is really the initial step in the generation of dense granules inside the matrix, we performed a comparative incubation study of HeLa-cell mitochondria in situ using three closely related dyes (D), i.e., E, tetramethylethidium bromide (TME) and betaine B (B). They strongly differ with regard to their affinity for DNA and their ability to cross membranes. E was used as a reference dye. TME does not intercalate, but is externally bound to DNA only weakly. The neutral B is not bound at all, but can cross membranes more easily than the cation E. Moreover, in aqueous solutions at pH approximately equal to 7.0, B is in equilibrium with its protonated cation BH. BH and E have almost equal affinities for DNA. Therefore B may quickly pass the inner mitochondrial membranes and the cristae, and should then be bound inside the matrix, thus forming a BH-DNA complex. On the assumption that intercalation is necessary for the generation of intramitochondrial electron-dense bodies, we predicted that BH/B should be more efficient than E, while TME should be relatively ineffective.(ABSTRACT TRUNCATED AT 250 WORDS)     

Further Observations on the Fine Structure of Acanthamoeba palestinensis (Reich, 1933). The Golgi Complex,Microbodies, and Mitochondria1

The fine structure of the trophozoite of Acanthamoeba palestinensis with a special emphasis on the Golgi complex, microbodies, and mitochondria has been examined. Golgi complexes are distributed throughout the cytoplasm but are most abundant in the perinuclear region. Usually two Goigi complexes are found in the same plane on opposite sides of the nucleus. One of them appears to be in an intimate association with the nuclear membrane. The region of contact contains compact cisternae, vesicles of various sizes, as well as granular and amorphous electron-dense material. Structural changes in the nuclear envelope are also observed in this area. A structure consisting of a Golgi complex and electron-dense microtubule organizing center, comparable to the centrosphere of other Acanthamoeba species, has been observed. Microbodies, surrounded by a single unit membrane and containing a granular matrix and tubular inclusions, are scattered throughout the cytoplasm. These organelles, circular (～1 μm in diameter) or ovoidal (～1 μm in length and ～0.5 μm in width) in section, have often an irregular outline. These microbodies are probably the morphological equivalent of peroxisomes and glyoxysomes. Most mitochondria show a typical structure including tubular cristae and intracristal inclusions. Occasionally mitochondria with two apposed double membranes running through the midline are found. Such atypical cristae have never been reported in small amoebae before.     

Ultrastructural Changes during Swelling and Contraction of Mitochondria from Cold-hardened and Non-hardened Winter Wheat

Mitochondria isolated from both 2 and 24 C grown winter wheat (Triticum aestivum L.) undergo spontaneous swelling in isomolar KCI solutions, but only 24 C mitochondria exhibit a substrate-induced contraction response. Electron microscopic examination revealed that 24 C mitochondria have more clearly defined cristae, less matrix material, and are generally more electron-dense than 2 C mitochondria. During swelling, the matrix material of both 2 and 24 C mitochondria expands and the mitochondria become less electron-dense. After partial swelling, 24 C mitochondria contract upon addition of succinate, and regain structural characteristics similar to those of untreated mitochondria. In contrast, mitochondria from 2 C seedlings continue to swell after addition of substrate, and many of the mitochondria become irregular in shape and lose much of their matrix material. A comparison of results obtained from absorbancy measurements, electron microscopy, and a Coulter Counter indicate that swelling and contraction involve changes both in over-all volume, and internal structural characteristics of mitochondria from 2 and 24 C grown seedlings. Electron microscopic examination of shoot cells showed that mitochondria in 24 C grown seedlings possessed more recognizable cristae and greater internal organization than mitochondria in 2 C seedlings.     

Histochemical, ultrastructural and X-ray microprobe analytical studies of localization of calcium in the mucous lining of the rat duodenum

Localization of calcium in a rapid frozen and freeze substituted duodenum of normal, starved or calcium-repleted rat was examined using either of the glyoxal bis(2-hydroxyanil) (GBHA) staining method, a sensitive histochemical calcium stain or electron microscopy. In normally-fed rats, a majority of absorptive cells of the duodenum showed numerous discrete red granular GBHA reactions, approximately 1 micron or less in diameter, located primarily along their lateral plasma membranes and within intercellular spaces. Electron microscopy also revealed electron-dense granules, 30-100 nm in diameter, showing a similar distribution as the GBHA granules in the respective absorptive cells, and confirmed their absence in mitochondria and other intracellular compartments. Some of the absorptive cells located exclusively at the tip of each villus contained highly GBHA-reactive tubulo-vesicular structures extending throughout the cytoplasm. However, they displayed virtually no granular GBHA reaction. In these cells, electron microscopy revealed numerous electron-dense granules in the nucleus, mitochondria and in other unidentified organelles. X-ray microprobe analyses of ultrathin sections confirmed the presence of calcium within electron-dense granules associated with both types of absorptive cells. The number and intensity of all GBHA reactions fluctuated according to luminal calcium concentration. In calcium-repleted rats, strong GBHA reactions appeared in a narrow zone of lamina propria at the tip of the villus, overlaid, predominantly, with absorptive cells showing tubulo-vesicular GBHA reactions. These results suggest the existence of distinct types of absorptive epithelial cells in the rat duodenum, with respect to patterns of calcium localization which they display.     

Effects of ethidium bromide,tetramethylethidium bromide and betaine B on the ultrastructure of HeLa cell mitochondria in situ

Summary Several investigators have described the ultrastructural changes that occur in the mitochondria of cells in tissue cultures after treatment with the drug ethidium bromide (E). The mitochondria swell and the cristae become greatly altered and finally disappear; in the cristae-free region of the matrix electron-dense granules can be observed. It has been assumed that intercalation of E between the base pairs of the mitochondrial DNA induces the formation of the granular inclusions. To investigate whether intercalation is really the initial step in the generation of dense granules inside the matrix, we performed a comparative incubation study of HeLa-cell mitochondria in situ using three closely related dyes (D), i.e. E, tetramethylethidium bromide (TME) and betaine B (B). They strongly differ with regard to their affinity for DNA and their ability to cross membranes. E was used as a reference dye. TME does not intercalate, but is externally bound to DNA only weakly. The neutral B is not bound at all, but can cross membranes more easily than the cation E. Moreover, in aqueous solutions at pH7.0, B is in equilibrium with its protonated cation BH. BH and E have almost equal affinities for DNA. Therefore B may quickly pass the inner mitochondrial membranes and the cristae, and should then be bound inside the matrix, thus forming a BH-DNA complex. On the assumption that intercalation is necessary for the generation of intramitochondrial electron-dense bodies, we predicted that BH/B should be more efficient than E, while TME should be relatively ineffective. In experiments using HeLa cells, these predictions were found to be inaccurate. E, TME and BH/B produced almost the same mitochondrial alterations, but at different concentrations and after different incubation periods. In contrast to our expectations TME was much more effective than E and BH/B, with the last two behaving rather similarly.Therefore, it seems unlikely that the drugs penetrate the inner mitochondrial membrane system by simple physical diffusion or that intercalation is the preliminary step for the generation of dense granules inside the matrix. Instead, we assume that hydrophobic interaction between the dye cations E, BH and TME and the cristae is the main cause of the mitochondrial changes. The favoured binding partner of the dye cations may be the divalent anion, cardiolipin: this phospholipid is an essential part of the inner membrane system but is absent in other membranes of cells. By distributing the dyes between a lipophilic phase and water, it was shown that TME is more lipophilic than E and BH; this may explain the greater effectiveness of TME. The bound dye cations disturb the organization of the cristae, which become altered and finally disappear. We assume that the electron-dense granules in the matrix are mainly composed of the dyes and former membrane materials such as phospholipids and proteins, as well as perhaps some other hydrophobic matrix materials. This would also explain why it was impossible to digest the dense granules by DNase treatment. The drugs enter the mitochondrial matrix by disordering and finally destroying the cristae.     

Ultrastructure of the liver cells in Salamandra salamandra (L.) in the end of Winter

Following hibernation, most salamander liver cells undergo alterations. The liver cells containing the structure of their active period present a normal nucleus, glycogen granules disseminated throughout the entire cytoplasm and granular mitochondria with several peripheral cristae. Most cells, however, possess altered mitochondria, transformed into electron-dense masses, or clear vesicles with the possibility of digesting the ambient organelles. Other cells have clear vacuoles with similar digestive possibilities. The endoplasmic reticulum is poorly represented in the liver cells that have suffered advanced alteration. The nucleus of these cells is homogeneously granular. The sytoplasm is populated by electron-dense bodies and lipid vacuoles. The nucleolemma and plasmalemma are thickened. The pigmented cells, altered concomitantly with the liver cells, contain granular aggregates. Some of the pigmented cells exhibit electron-clear formations similar to the reflecting platelets of the iridocytes of the integument of lower vertebrates.     

Electron-dense endoplasmic reticulum-like profiles closely associated with mitochondria in glomus cells of the carotid body after fixation with oxalate

Fixation in the presence of oxalate was used to demonstrate the electron-dense Ca2+ precipitates in the endoplasmic reticulum in glomus cells of the carotid body. Glomus cells in intact carotid bodies or cells dissociated from the organ by treatment with collagenase were studied electron microscopically. In the intact organ as well as in dissociated glomus cells, electron-dense endoplasmic reticulum-like profiles were seen closely associated with mitochondria, while these lacked reaction product. The interspace between mitochondria was occupied by electron-dense, slightly distended ER, which appeared to contact the outer membrane of the mitochondria. Occasionally, a mitochondrion was in contact with several ER profiles or the ER formed an electron-dense 'cap' on the mitochondrion. The electron-dense precipitates could be removed from ultrathin sections with the calcium chelator ethyleneglycol-2(2-aminoethyl tetra-acetic acid) (EGTA). It is tentatively suggested that the endoplasmic reticulum could be involved in intracellular buffering of Ca2+ in the glomus cell, as has been previously suggested for neurons.     

Epidermal ultrastructure and implications for sulfide tolerance in six species of deep-sea polychaetes

Abstract. Ultrastructural characteristics of the epidermis of 5 deep-sea vestimentiferan tube worms and an orbiniid worm were similar to those described from other organisms inhabiting sulfidic environments. The integument was composed of a simple or pseudostratified layer of columnar or cuboidal cells, covered by a cuticle of varying thickness, and rested on an extracellular matrix. Unusual mitochondrial morphology was observed in the peripheral region of the epidermis, characterized by an electron-dense matrix and granules. The abnormal size, shape, and reduced array of cristae in these mitochondria may have resulted from environmental stress. Mitochondria in the inner epidermal layers, where they are more protected from sulfide exposure, displayed normal morphology. The seep vestimentiferans ( Seepiophila jonesi and Lamellibrachia cf. luymesi ) exhibited numerous electron-dense organelles, similar in morphology to cytolysosomes and previously described as sulfide oxidizing bodies, while in the 3 vent vestimentiferans ( Riftia pachyptila, Tevnia jerichonana , and Oasisia alvinae ) and the seep orbiniid Methanoaricia dendrobranchiata , fewer of these organelles were observed. Energy dispersive x-ray microanalysis of these electron-dense organelles indicated the presence of sulfur, iron, zinc, and copper, as well as lesser amounts of other elements. We propose that these epidermal cytolysosomes are morphologically similar to previously described sulfide oxidizing bodies that have been hypothesized to play a role in maintaining aerobically poised animal metabolism in sulfide-enriched habitats.     

Water movement from intracristal spaces in isolated liver mitochondria

When analyzing mitochondria isolated in a sucrose medium that had been embedded for thin sectioning according to one low denaturation embedding technique, large intracristal spaces were present in close to 90% of the mitochondria. The two crista membranes were closely apposed in only 40% of all cristae. When the mitochondria were transferred to an incubation medium, the percentage of mitochondria with intracristal spaces was reduced to 40%. About 90% of all cristae were lacking any space separating the two crista membranes. The presence of inorganic phosphate in the medium was required for the closing of the intracristal spaces. The percentage of cristae lacking an intracristal space remained the same after addition of substrate for respiration (state 4) and of ADP (state 3). Inhibition or uncoupling of respiration led to an increase in the percentage of intracristal spaces, showing that oxidative phosphorylation is required to maintain the crista membranes closely apposed. The appearance and disappearance of the intracristal spaces was an indication of water movements across the crista membranes. The mean volume of the mitochondria increased 33% when they were transferred from the sucrose medium to the incubation medium, showing that the removal of water from the cristae was not caused by a passive osmotic effect. Addition of substrate made the volume decrease by 28%. After further addition of ADP, the volume decreased another 23%. No change in volume was associated with inhibition or uncoupling of respiration. The observations revealed that water can move into or out of the cristae independently of water movement out from the entire mitochondrion. Therefore, the water moving out from or into the cristae is translocated across the cristae membrane. The observations are interpreted to reveal the presence of a mechanism that actively prevents water from accumulating in the crista membrane. This mechanism allows for a low water activity to be maintained within the membrane. The variations in the frequency of intracristal spaces occurred without any simultaneous changes in the width of the space appearing between the two surface membranes after isolation of the mitochondria. The observations, therefore, do not agree with the concept that there is an outer compartment that communicates freely with intracristal spaces.     

Cytochemical study of catalase activity in Candida boidinii during incubation on methanol

Catalase activity of the methanol-assimilating yeast Candida boidinii M-363 was determined cytochemically and biochemically. Electron microscopic investigations on ultrathin sections were made on cells from 16, 24, and 48h batch cultures in nutrient medium with methanol (or glucose as a control) as the sole source of carbon and energy. The electron-dense oxidation product of 3,3′-diaminobenzidine was found predominantly in the mitochondrial cristae and membranes. The mitochondria were increased in number, enlarged, sometimes aggregated, with variable form and size and they characteristically developed when the strain was grown on methanol. The significant development of these organelles and their intensive DAB staining correlated with the considerable increase in catalase activity. Biochemically, catalase in the cell-free extract was determined to be maximal along the exponential growth phase of the strain during its incubation on methanol. Enzyme analysis of the heavy mitochondrial fraction showed that it possessed catalase activity but not peroxidase activity. The results showed that not only peroxisomes but also mitochondria may be structurally and functionally responsible for the high catalase activity of some methanol-assimilating yeasts. What is more, the contribution of the mitochondria to the utilization of methanol may be significant.     

Freeze-fracture analysis of isolated liver mitochondria in different metabolic states

Isolated liver mitochondria were crosslinked with glutaraldehyde during different respiratory states and then analyzed either by freeze-fracturing, or in thin sections prepared according to a low denaturation embedding technique. In freeze-fractured material, large intracristal spaces were found in 86% of the mitochondria freshly isolated in a sucrose medium. These results were in good agreement with mitochondria analyzed in thin sections, in which case 88% of the mitochondria contained intracristal spaces. In freeze-fractured mitochondria, only 24% of the mitochondria crosslinked after 3 min in respiratory state 4 contained intracristal spaces, while 36% of the mitochondria contained intracristal spaces during state 3. These values compared favorably with those obtained in embedded material in which case 21 and 41% of the mitochondria contained intracristal spaces during states 3 and 4, respectively. The agreement between the observations made with the two methods demonstrated that the disappearance of intracristal spaces is independent of the embedding technique, and is not a special effect caused by dehydration in ethylene glycol.     

MEMBRANE JUNCTIONS IN THE INTERMEMBRANE SPACE OF MITOCHONDRIA FROM MAMMALIAN TISSUES

There have been several reports describing paracrystalline arrays in the intermembrane space of mitochondria. On closer inspection these structures appear to be junctions of two adjoining membranes. There are two types. They can be formed between the outer and inner mitochondrial membranes (designated outer-inner membrane junctions) or between two cristal membranes (intercristal membrane junctions). In rat heart, adjoining membranes appeared associated via a central dense midline approximately 30 Å wide. In rat kidney, the junction had a ladder-like appearance with electron-dense "bridges" approximately 80 Å wide, spaced 130 Å apart, connecting the adjoining membranes. We have investigated the conditions which favor the visualization of such structures in mitochondria. Heart mitochondria isolated rapidly from fresh tissue (within 30 min of death) contain membrane junctions in approximately 10–15% of the cross sections. This would indicate that the percentage of membrane junctions in the entire mitochondrion is far greater. Mitochondria isolated from heart tissue which was stored for 1 h at 0°–4°C showed an increased number of membrane junctions, so that 80% of the mitochondrial cross sections show membrane junctions. No membrane junctions are observed in mitochondria in rapidly fixed fresh tissue or in mitochondria isolated from tissue disrupted in fixative. Thus, the visualization of junctions in the intermembrane space of mitochondria appears to be dependent upon the storage of tissue after death. Membrane junctions can also be observed in mitochondria from other stored tissues such as skeletal muscle, kidney, and interstitial cells from large and small intestine. In each case, no such junctions are observed in these tissues when they are fixed immediately after removal from the animal. It would appear that most studies in the literature in which isolated mitochondria from tissues such as heart or kidney were used were carried out on mitochondria which contained membrane junctions. The presence of such structures does not significantly affect normal mitochondrial function in terms of respiratory control and oxidative phosphorylation.     

Differentiation and distribution of annulate lamellae in growing oocytes in the newt, Cynops pyrrhogaster

Stages of oocyte development in Cynops pyrrogaster are defined, and changes of annulate lamellae in their fine structure, number, sizes and locations during oogenesis are described. The results show that two different types of annulate lamellae occur during oogenesis. One type differentiates in or at the periphery of vesicle-rich cytoplasm at the early stages of vitellogenesis and increases in number and size. The maximum number of about 40 stacks per median section of oocyte is reached at the stage of complete differentiation of the animal and the vegetal hemispheres. In these growing oocytes, all the stacks show elongate appearances and tetragonal arrangements of annuli as common characteristics. A second type of stacks of annulate lamellae is added anew in full-grown oocytes, increasing the number of stacks per median section of the oocyte to about 90. The new stacks occur in close contact with electron-dense bodies in the cytoplasm and have a massive appearance and hexagonal array of annuli. It is suggested that they appear coincidentally with the onset of oocyte maturation. The possible significance of the observed results is discussed.     

OBSERVATIONS ON PRISMATIC-TYPE MITOCHONDRIA WITHIN ASTROCYTES OF THE SYRIAN HAMSTER BRAIN

This paper describes a special form of mitochondria which has been observed using the electron microscope in certain astrocytes of the Syrian hamster brain. The interior structural pattern of these mitochondria is characterized by the presence of numerous equilateral prismatic tubules in a highly regular hexagonal arrangement, instead of the customary foliate cristae. Such mitochondria have been designated as "prismatic type," in contradistinction to the more usually encountered crista and tubular types. The findings are compared with the occasional similar findings reported in the literature, and their possible functional meaning is briefly discussed.     

The ultrastructural organization of femoral muscles in Musca domestica (Diptera)

The femoral muscles of Musca domestica are organized as typical synchronous muscles. The nuclei occupy the central region of the fibres. The myofibrils have a lamellar shape with the major diameter oriented radially with respect to the nuclei; they have an extremely regular organization. In cross section each thick filament is surrounded by 10-12 thin filaments. The mitochondria are relatively abundant and are organized in three concentric layers: perinuclear, intermyofibrillar and subsarcolemmal. They have an elongated shape and possess numerous cristae, which are oriented trasversally with respect to the long axis of mitochondria. The S.R. is organized as a complex system of tubules which completely surround the contractile material. The T-system has a characteristic shape, and takes contact with the sarcoplasmic reticulum forming peculiar triadic structures.     

Histochemical,ultrastructural and X-ray microprobe analytical studies of localization of calcium in the mucous lining of the rat duodenum

Summary Localization of calcium in a rapid frozen and freeze substituted duodenum of normal, starved or calciumrepleted rat was examined using either of the glyoxal bis(2-hydroxyanil) (GBHA) staining method, a sensitive histochemical calcium stain or electron microscopy. In normallyfed rats, a majority of absorptive cells of the duodenum showed numerous discrete red granular GBHA reactions, approximately 1 m or less in diameter, located primarily along their lateral plasma membranes and within intercellular spaces. Electron microscopy also revealed electron-dense granules, 30–100 nm in diameter, showing a similar distribution as the GBHA granules in the respective absorptive cells, and confirmed their absence in mitochondria and other intracellular compartments. Some of the absorptive cells located exclusively at the tip of each villus contained highly GBHA-reactive tubulo-vesicular structures extending throughout the cytoplasm. However, they displayed virtually no granular GBHA reaction. In these cells, electron microscopy revealed numerous electron-dense granules in the nucleus, mitochondria and in other unidentified organelles. X-ray microprobe analyses of ultrathin sections confirmed the presence of calcium within electron-dense granules associated with both types of absorptive cells. The number and intensity of all GBHA reactions fluctuated according to luminal calcium concentration. In calcium-repleted rats, strong GBHA reactions appeared in a narrow zone of lamina propria at the tip of the villus, overlaid, predominantly, with absorptive cells showing tubulo-vesicular GBHA reactions. these results suggest the existence of distinct types of absorptive epithelial cells in the rat duodenum, with respect to patterns of calcium localization which they display.     

Fine structure of the tapetum cellulosum of the grey seal (Halichoerus grypus)

The morphology of the tapetum lucidum of the grey seal (Halichoerus grypus) has been studied by light and electron microscopy. The reflective layer in this species is a tapetum cellulosum situated in the choroid and covering the entire effective fundus. Posteriorly the tapetum is composed of 30-35 layers of flattened polygonal cells. This number gradually declines to 15-20 layers in the extreme periphery. Near the retinal epithelial layer the tapetal cells are larger and more regular (brick-like) in arrangement whereas further from the retina the tapetal cells become more irregular in outline and more widely separated by collagen fibrils and connective tissue cells. In this outer region the tapetal cells are gradually replaced by melanocytes of the choroid. Within the tapetal cells a few mitochondria and profiles of smooth endoplasmic reticulum are scattered peripherally while the majority of the cell organelles are clustered near the centrally located vesicular nucleus. The dominant feature of the tapetal cells is, however, an accumulation of numerous electron-dense rodlets of presumed zinc cysteine. These rodlets are the reflective material of the tapetum and are arranged with their long axes perpendicular to the incoming light. The orientation of these rodlets is usually uniform within each tapetal cell but varies between adjacent cells. The diameter (0.10 micron) and spacing (0.15 micron) of these rodlets is consistent with the principles of constructive interference. Blood vessels penetrate the tapetum at right angles to supply the choriocapillaris which is indented into the amelanotic retinal epithelium to give a flat reflective surface to the tapetum.