Annulate lamellae in human tumor cells

Annulate lamellae in human tumor cells

TISSUE &CELL 1979 II (I) P~hli.shrcl br Longntm 139-146 Group Ltd. Printd in Grcwt Britcrin C. N. SUN and H. J. WHITE ANNULATE CELLS LAMELLAE...

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TISSUE

&CELL

1979 II (I)

P~hli.shrcl br Longntm

139-146

Group Ltd. Printd

in Grcwt Britcrin

C. N. SUN and H. J. WHITE

ANNULATE CELLS

LAMELLAE

IN HUMAN

TUMOR

ABSTRACT. Annulate lamellae have been found in a primitive neuroectodermal tumor, a metastatic cerebellar tumor, a testicular seminoma, a retinoblastoma and three melanomas. These annulate lamellae are arranged in stacked parallel arrays in the cytoplasm of tumor cells. The number of annulate lamellae observed to comprise a single stack varies from 2-4 in the seminoma tumor to 5-18 in the cerebellar tumor. Although the functional significance of annulate lamellae is still unknown, in many instances they have been found to be continuous with rough-surfaced cisternae of the endoplasmic reticulum and ribosomes have been demonstrated on the surface of annulate lamellae. This may suggest that annulate lamellae participate in protein synthesis.

Introduction first electron microscopic observation on annulate lamellae (AL) were made by McCulloch ( 1952) and Lansing et al. (I 952) in oocytes of marine animals. Palade (1955) described this organelle as fenestrated cisternae in the rat spermatocyte. The term ‘annulate lamellae’ was first used by Swift (I 956) to describe this organelle in the pancreatic acinar cells of the larval salamander, oocytes of snail and clam, and rat spermatids. The occurrence of the organelle has been documented in the oocytes of several different species of animals (McCulloch, 1952; Afzelius, 1955; Palade, 1955; Swift, 1956, 1968; Rebhun, 1956; Pasteels etal., 1958; Merriam, 1959; Gross et al., 1960; Kane, 1960; Hsu, 1963; Kessel, 1963, 1964, 1965, 1966), in spermatids and Sertoli cells (Ruthmann, 1958; Kaye et a/., 1961; Barer et al., 1960; Swift, 1956; Bawa, 1963; Nagano, 1966; Smith and Berlin, 1977; Sun et ul., 1977), and in cells of a variety of malignant tumors (Wessel and Bernhard, 1957; Epstein, 1957, 1963 ; I 959 ; Hoshino, I961 ; Binggeli, Chambers and Weiser, 1964 ; Svo boda, 1964;

THE

Veterans Administration of Arkansas for Medical Arkansas 72206. Received 31 March 1978. Revised 30 August 1978.

Hospital and University Sciences, Little Rock,

Ma and Webber, 1966; Locker cl Al., 1969: Ghadially and Parry, 1974). Annulate lamellae seem to have a widespread occurrence in animal tumors; however, their presence in human neoplastic material has been reported in only a few cases (Epstein, 1957; Kumegawa et al., 1961; Leak and Bensch, 1971: et al., 1967; Kadin Kovacs ef al., 1975, 1977). Recently, we found thes: structures in szvzral tumors. The increasing number of reports in neoplastic cells of annulate lamellae may suggest that the annulate lamellae have an unknown role in some neoplastic cells. Materials and Methods Biopsy specimens from a primitive neuroectodermal tumor, a metastatic cerebellar tumor, a testicular seminoma, a retinoblastoma and three melanomas were cut into small pieces about I mm3 and immediately fixed in 4% glutaraldehyde in phosphate buffer fat 2 hr, then post-fixed in 1 ‘A buffered osmium tetroxide for 1 hr. After dehydration, tissues were embedded in Epon 812. Thin sections were stained with uranyl acetate and lead citrate (Reynolds, 1963). Observations The 139

ultrastructural

features

of

annulate

140

SUN

lamellae from the above materials constitute the subject of the present study; other findings will not be presented here. Annulate lamellae are smooth-walled, paired membranes arranged in parallel stacks. The number of annulate lamellae observed to comprise a single stack varies with tissue examined (Figs. l-3 and Table 1). The membranes show regularly spaced discontinuities. By appropriate section, ‘pores’ on the membranes are seen which have an outside diameter of approximately 1000-1600 A. The center of the pores may appear empty, but sometimes a small central granule may be shown in tangential section (Fig. 3a). Granular and fibrillar material is present within the ‘pores’, especially in the vicinity of the periphery (Figs. 1, 3). We found in one case (p.e. tumor) that the annulate lamellae are in contact with the nuclear envelope (Fig. 4). More commonly, the annulate lamellae are in contact with the rough endoplasmic reticulum (Figs. 2, 3). In one of the melanomas, a peculiar membranous body was found in the cytoplasm of the tumor cell. In some profiles, this structure consists of stacks of braided canaliculate elements or channels which pursue a tortuous course and cross one

Fig.

1. Annulate

Table

AND

WHITE

I. Tissue examined No. of AL in

Tumor

a stack

Melanoma Seminoma Retinoblastoma Cerebellar tumor Primative neuroectodermal

tumor

8-10 2-4 t-8 5-18 4-7

another (Fig. 5). In many of the sections, profiles showed many ‘pores’ with central granules (Fig. 6). Here, too, channels are connected to the rough endoplasmic reticulum (Figs. 5, 6). A portion of the profile shows a similarity to the annulate lamellae (Fig. 6) of the myocardial cell in the chick embryo (Merkow and Leighton, 1966) and annulate lamellae of Sertoli cells in azoospermic human testis (Livni et al., 1977). These membranous structures may possibly represent modified annulate lamellae. Tn the cytoplasm of the primitive neuroectodermal tumor, there are many instances of membranous structures which may be precursors of the annulate lamellae (Fig. 7). These membranous structures are quite similar to the Golgi apparatus and sometimes

lamellae (AL) in retinoblastoma.

P, pore; N, nucleus.

x 50,000.

Fig. 2. Annulate lamellae (AL) in a nuclear pocket in melanoma. reticulum; G, Golgi apparatus; N, nucleus. x 16,000.

ER, endoplasmic

Fig. 3. Annulate lamellae reticulum. x 30,000.

ER, endoplasmic

(AL) in testicular

seminoma.

P, pore;

Fig. 3a. Tangential section of annuli: a small dense granule is sometimes in the center of the annulus ( +). ER, endoplasmic reticulum. x 30,000.

observed

Fig. 4. A stack of annulate lamellae is in contact with the nuclear envelope of a primitive neuroectodermal tumor (+). lntranuclear lamellae are also present (IAL). N, nucleus. x 43,000. Fig. 5. Peculiar configuration of agranular reticulum of braided channels in a melanoma tumor cell (+). ER, endoplasmic reticulum; G, Golgi apparatus. x 40,000. Fig. 6. Many of the profiles of the peculiar configuration show pores with central granules (+). ER, endoplasmic reticulum; G, Golgi apparatus. x 40,000. Fig. 7. Membranous structure may be a precursor annulate lamellae; G, Golgi apparatus. x 44,000.

of the annulate

lamellae (+).

AL,

SUN

144

AND

WHITE

Table 2. Some previous observations of annulate lamellae in human tumor cells No. of AL in a stack

Tumor

HeLa cells KB cells Pheochromocytoma Melanoma Apocrine hidrocytoma Warthin’s tumor Fibromyxosarcoma Adenomatous pituitary glands

4-8 4 5 4 3 6 2-l

are closely associated with the Golgi apparatus. Discussion Annulate lamellae occur frequently in rapidly growing and differentiating cell systems under normal and abnormal conditions (Porter, 1961). They are also occasionally associated with cell degeneration. An increase in the number of annulate lamellae has been noted in virus-infected animal (Koestner et al., 1966), and plant cells (Steinkamp and Hoefert, 1977), as well as in cells treated with a variety of chemicals (Hruban et al., 1965b, c). Since annulate lamellae are a constituent of many different types of cells, we may infer that the organelles have multiple functions that may differ depending upon the cell type. Among their suggested functions are protein synthesis (Merkow and Leighton, 1966; Wischnizer, 1970), nucleocytoplasmic exchanges (Kessel, 1968), nucleation sites for tubulin synthesis (De Brabander and Rogers, 1975), storage sites (Fanke, 1974), or as a disposal mechanism (Kessel, 1973). As for their origin, Afzelius (1955) first thought that this lameller system represented fragments of the nuclear membrane remaining in the cytoplasm after mitosis. Rebhum (1956) and Swift (1956) have suggested that annulate lamellae appeared to be synthesized as sheets on the surface of the nuclear envelope. In several cell systems, such as sea urchin and dragonfly oocytes, there is evidence that basophilic masses derived from the nucleus become associated with annulate lamellae (Kessel, 1968; Kessel and Beams, 1969). After the stacks of annulate lamellae have completely formed, rough endoplasmic reticulum extends from each of the annulate lamellae in a stack (Sun et al., 1977). Although many authors believe that annulate lamellae take their origin from the

Authors In In In In In

vitro vitro vitro vitro vivo In vivo In duo In vivo

Epstein (1961) Kumegawa et al. (1967)

Kadin and Bensch (1971) Maul (1970) Gross (1965) Tandler (1966) Leak et al. (1967) Kovacs (1975)

nuclear envelope, the precise origin of the annulate lamellae has not been firmly established. As early as 1955, Palade considered them to be a local differentiation of endoplasmic reticulum. Other authors (Kovacs et al., 1975) also believe they originate from endoplasmic reticulum. Hruban et al. (1965a) suggested that annulate lamellae may represent an intermediate stage in the formation of more typical endoplasmic reticulum, possibly containing only the messenger RNA before addition of free ribosome, or ribosomal RNA before the addition of protein. In the human tumor cells, there are very few instances of annulate lamellae and nuclear envelope association. Our study suggests that in tumors, annulate lamellae may possibly be formed from transformed cisternae of endoplasmic reticulum or the Golgi apparatus. Supporting this contention are reports by Maul (1970) and Scheer and Franke (1969). Hruban et al. (1965a), in a study of transplantable hepatomas of rats, reported their frequent occurrence particularly in rapidly growing tumors probably related to intense protein synthesis. Porter also noted their frequent occurrence in actively proliferating, embryonic, undifferentiated cells (Porter, 1961). By contract, in human tumors, AL are reported infrequently and paradoxically. Sometimes they even occur in slowly growing benign neoplasms (Tandler, 1966) (Table 2). More research is needed to answer the question of how the annulate lamellae relate to growth or protein metabolism. Acknowledgements This work was supported by Veterans Administration Research Funds. The technical assistance of Joe Meador and Bettye Stallings and the secretarial assistance of Diane Butler are greatly appreciated.

ANNULATE

LAMELLAE

IN TUMOR

CELLS

14.5

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in adenomas

infected with porcine of human

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