Responses of epithelial and fibroblast-like cells to discontinuous configuration of the culture substrate.

The behaviour of epitheliocytes, their transformed analogues, and fibroblasts was studied on special culture substrates--lattices with large square openings (the area of an opening was 2000 microm2). It was shown that normal epithelocytes and fibroblasts initially attached to and spread on the lattice bars, were soon displaced into the lattice openings and appeared to be "sagged" in the substrate-free spaces. The cells remained attached to the bars only by their edges (epitheliocytes) or lateral processes (fibroblasts), whereas basal surfaces of the cells had no contacts with the substrate. Displacement of the cells from the bars into the lattice openings was observed only if during spreading the cell body was located on two perpendicular bars. In this position the cell body underwent bending which presumably induced stretching of the cell and its displacement into the opening. Unlike epitheliocytes, which gradually "covered" the lattice openings completely, the fibroblasts were retracted and elongated upon their displacement, "crossing" the openings by their bodies and processes. The epitheliocytes transformed by the ras oncogene and displaying a fibroblast-like shape, most often remained on the bars and were not displaced into the lattice openings. Induction of the epithelioid phenotype in fibroblasts by the agents, depolymerizing (colcemid) or disintegrating (taxol) the cytoskeletal system of microtubuli, was accompanied by a change in the behaviour of the cells: the treated fibroblasts, like epitheliocytes, acquired the ability to "cover" the lattice openings. Possible mechanisms of the cell reactions to the substrate having discontinuous configuration are discussed. It is supposed that these distinctions in reactions of epitheliocytes and fibroblast-like cells may result from different bending ability of the cells and/or differences between forces responsible for the cell adhesion to the lattice bars and forces stretching the cells over the lattice openings.     

Effect of colcemid on the spreading of fibroblasts in culture

The effect of colcemid upon the spreading of mouse embryo fibroblast-like cells on substrates was studied with the aid of time-lapse microcinematography and scanning electron microscopy. Two types of substrates were used: flat glass and narrow strips of glass surrounded by non-adhesive lipid film; on the latter, spreading and polarization of cells proceeded simultaneously. On glass, colcemid did not prevent transition of cells into a well-attached state; however, the time required for this transition increased considerably as compared with control cultures. Similar effects were caused by two other drugs inhibiting the formation of microtubules: colchicine and vinblastine. The intermediate stages of spreading on flat glass had several abnormal features in the colcemid-containing medium: (a) the shape of cytoplasmatic outgrowths formed by the cell was altered and their distribution became less regular; (b) partial detachment of the attached parts of the cells was very frequent; (c) the spreading of various parts of the cell was not well correlated: the central part of the cell could remain unspread long after the spreading of the peripheral part. Similar effects of colcemid were observed in experiments with cells spreading on the narrow strips of the glass. In addition, colcemid prevented stabilization of the cell surface, i.e., differentiation of the cellular edge into active and stable parts. About two-thirds of the cells attached to the narrow strips of glass were completely detached from the substrate in the course of spreading in colcemid-containing medium. The possible mechanisms of the action of colcemid on spreading are discussed and it is suggested that intracellular structures sensitive to colcemid are essential for the coordination of the reactions in various parts of the cell in the course of spreading.     

Differences in the character of interaction of normal and transformed human keratinocytes with laminin isoforms

Laminins constitute a family of heterotrimeric glycoproteins of basement membranes. Laminins promote cell adhesion, migration, growth, and differentiation. So far, at least 12 different isoforms of laminin have been known. However, no sufficient knowledge is available on the nature of cell response on different laminins. The study was aimed to compare adhesive properties of two laminin isoforms, laminin-1 and laminin-2/4, with respect to normal (freshly isolated keratinocytes) and transformed (A-431) human skin cells. We have used the following assays: cell adhesion to the substrate covered with laminin isoformes, interaction of latex beads (D = 1 micron) coated with the same proteins with cells in suspension, and a comparative study of the cytoskeleton structure of cells spread on the immobilized laminins. It was demonstrated that laminin-2/4 is a more effective potent promotor of adhesion for both normal keratinocytes and transformed A-431 cells, compared with laminin-1. A comparison of many attached protein-covered beads allowed to estimate a relative quantity of cell surface receptors to laminin isoforms in different cell types. The relative number of receptors to laminin-2/4 on the keratinocyte surface is 7 times higher than that to laminin-1 after a 30 min incubation with cells, and is 6 times higher after 1 hour. As for A-431 cells, their attachment to laminin-2/4 beads is 5 times higher than that to laminin-1-beads after a 1 min incubation, but as early as after 5 min this distinction disappeared, owing to bead internalization. The presence of a specific receptor to laminin-2/4 but not to laminin-1 on the keratinocyte surface has been suggested. Keratin differences in cytoskeleton organization in normal and transformed skin cells spread on the substrates covered with laminin-1 and laminin-2/4 were demonstrated.     

Effect of colcemid on the distribution of pseudopodial activity in fibroblasts. Microtubule-independent stabilization of cell surface

The effect of microtubule-destroying drugs on the pseudopodial activity of cultured fibroblasts was examined. As previously described, colcemid and similar drugs caused almost complete disappearance of inactive zones of the edge of normal mouse fibro-blasts. However, similarly treated, poorly spread, transformed TLSF cells often had inactive zones at the edges; these zones in colcemid-treated cells were shorter than similar zones in control TLSF cells. It is suggested that in addition to previously described microtubule-dependent stabilization of cell surface there exists another, more local and less effective microtubule-independent stabilization process.     

Altered cell spreading in cytochalasin B: a possible role for intermediate filaments.

Trypsinized chicken embryo dermal fibroblasts plated in the presence of cytochalasin B (CB) quickly attached to the substrate and within 24 h obtained an arborized morphology. This morphology is the result of the pushing out of pseudopodial processes along the substrate from the round central cell body. There were no microfilament bundles in the processes of these cells plated in the presence of CB; however, the processes were packed with highly oriented, parallel-aligned intermediate filaments. Only a few scattered microtubules were seen in these processes. These results demonstrated that in CB, cells are capable of a form of movement, i.e., the extension of pseudopodial processes, without the presence of the microfilament structures usually associated with extensions of the cytoplasm and pseudopodial movements. We also found that arborization did not depend on fibronectin since cells plated in CB did not have fibronectin fibers associated with the processes. Chicken fibroblasts transformed with tsLA24A, a Rous sarcoma virus which is temperature sensitive for pp60src, formed arborized cells with properties similar to those of uninfected fibroblasts when plated in the presence of CB at the nonpermissive temperature (41 degrees C). At the permissive temperature for transformation (36 degrees C), the cells attached to the substrate but remained round. These round cells were not only deficient in microfilament bundles but also lacked the highly organized intermediate filaments found in the processes of the arborized cells at 41 degrees C. Although both microfilament bundles and the fibronectin matrix were decreased after transformation with Rous sarcoma virus, neither was involved in the formation of processes in normal cells plated in CB. Therefore, the inability of the transformed cells to form or maintain processes in CB must be the result of another structural alteration in the transformed cells, such as that of the intermediate filaments.     

The characteristics of actin cytoskeleton structure and its rearrangements by extracellular matrix proteins in normal, immortalized and transformed rat fibroblasts

Comparative analysis of actin cytoskeleton structure in rat embryonic fibroblasts, E1A-immortalized and E1A + cHa-ras-transformed cells has been carried out. A decrease in adhesiveness and the rate of changes in actin cytoskeleton structures was shown to correlate with the level of morphological transformation of cells. E1A + cHa-ras-transformants show the lowest adhesiveness and complete disorganization of actin structures. Cultivation on serum-free media promoted disassembling of actin cytoskeleton structures in a small part of normal fibroblast population, only in a few immortalized cells, but exerted no influence on transformed cells. The influence of immobilized extracellular matrix proteins fibronectin, laminin and collagens type I and III on actin cytoskeleton structure in normal, immortalized and transformed fibroblasts was studied. Transformed cells spread on fibronectin completely restored highly organized actin structures, displayed a lot of stress fibers and focal contacts. The use of laminin revealed differences in locomotion between normal and transformed cells. Normal, immortalized and transformed fibroblasts spread on fibronectin and laminin demonstrate some peculiarities in actin cytoskeleton structures as a result of specificity of ligand-receptor interaction. Cells spread on fibronectin have polygonal shapes, many stress fibers and focal contacts, whereas cells spread on laminin are highly polarized and develop broad lamellae filled with actin microfilament meshwork. Collagens type I and III can affect adhesive properties and actin cytoskeleton structure in all cell lines studied only slightly, in comparison with fibronectin and laminin.     

Effect of agents disrupting microtubules on the distribution of receptors on the surface of cultured cells]

Substrate-attached normal mouse fibroblasts, transformed mouse fibroblasts (L-strain) and epithelial cells (MPTR strain) were incubated with two ligands that are cross-linking different group of the surface receptors: concanavalin A and cationic ferritin. Surface-attached ligands were revealed by the indirect immunofluorescent methods. The incubation of control cells with these ligands induced a patching of corresponding surface receptors, and a clearing of these receptors from the surface zones located on the lamellar cytoplasm near the cell edges actively protruding pseudopodia. Effects of three antitubulins (colcemid, colchicine and vinblastin) on the ligand-induced redistribution of receptors were examined and compared with the previously described effects of these drugs on the distribution of active cell edges.     

Studies on cell transformation.

Seven different transformation stigmata of the transformed CHO cell line, including morphological characteristics, growth behavior, cell membrane biochemical properties, and failure of fibronectin deposition, are reversed by addition of cAMP derivatives to the medium. Simultaneously the microtubular pattern changes from a sparse, relatively random set to an orderly arrangement of tubules largely parallel to each other and to the long axis of the resulting fibroblastic cell. Agents like colcemid and cytochalasin B, respectively disorganizing microtubular and particular microfilamentous structures, prevent at least certain aspects of the reverse transformation reaction induced by cAMP in interphase cells. It is proposed that malignant transformation can be effected by damage to the microtubular and microfilamentous structures which changes cell constitution and behavior in two ways: (1) chromosomal instability is introduced which promotes continuous selection for variants better able to resist environmental signals to limit reproduction and (2) a variety of metabolic defects in biochemical processes such as specific membrane functions are introduced which may alter the growth responses of the cell. This picture offers a reasonable explanation for a number of aspects of normal and malignant cell behavior.     

F-actin aggregates in transformed cells contain alpha-actinin and fimbrin but apparently lack tropomyosin

Transformation-specific F-actin structures are examined in tumor cells after in vitro tumor cell growth alone or on an untransformed cell monolayer. In transformed cells F-actin aggregates near the ventral plasma membrane in close substrate adhesion areas contain the cytoskeletal proteins alpha-actinin and fimbrin but, unlike microfilament bundles, are not labeled with antibody against tropomyosin. By electron microscopy the dense ventral aggregates in transformed cells resemble stress fiber termini found at the membrane in normal cells. These transformed-cell cytoskeletal structures are not limited solely to substrate adhesion areas; they are also expressed at cell-cell contacts about 48 h after transformed cells are plated on untransformed cells. These specialized F-actin aggregates appear to be implicated in the processes of penetration of these transformed cells between adjoining untransformed cells in vitro.     

Spreading of normal and transformed fibroblasts in dense cultures

Cell spreading in dense cultures of normal mouse embryo fibroblasts and of the two lines of mouse transformed fibroblasts was examined by electron microscopy. The mean number of cell layers in culture and cell population density per unit area of the substrate were detetmined; the mean area of the cell projection on the substratum was found from these data.Normal fibroblasts formed multilayefed sheet in dense culture. The cells in this sheet were well-spread. These cells formed thin lamellae (lamellar cytoplasm) over the surface of other cells and over the intercellular substance. The mean cell area in dense culture was not smaller than that of the cell spread on the substratum in sparse culture.Dense cultures of two transformed lines (M 22 and L) had differing morphologies: cultures of one line (M 22) were multilayered, those of the other line (L) were monolayered. Decreased spreading and almost complete (M 22) or complete (L) absence of lamellar cytoplasm were characteristic of both transformed lines. The mean area of the cell in dense cultures of both lines was several times smaller than that of their normal progenitors.It is concluded that similar reactions leading to the spreading accompanied by the formation of lamellar cytoplasm can be induced by the contact of fibroblast with various surfaces: that of the substratum in sparse culture, that of other cells and of intercellular structures in dense culture. Deficiency of these reactions characteristic for transformed fibroblasts may be responsible for abnormal morphology of their cultures.     

Phenotypic and karyotypic transitions in the spontaneous transformation of a rat cell line

After 20-50 transfers, a rat myofibroblast line, Hmf-n, 'spontaneously' transforms to an established (immortalized) line of smaller, rapidly cycling fibroblastoid cells (tHmf-f). From these 1 degree transformants, colonies of larger, slower growing anchorage-independent (tHmf-e) cells of epithelioid phenotype emerge. Both transformants grow in low serum and low calcium media, but the tHmf-f cells are highly tumorigenic in nude mice, have diminished substrate adhesivity, and limited anchorage independence, whereas tHmf-e are less tumorigenic, firmly substrate adherent, and markedly anchorage independent. Most tHmf-f are trisomic; most tHmf-e transformants are hypodiploid, a third are tetraploid, and all have chromosomal abnormalities, but no trisomy. Hmf-n cells have polar stress fiber arrays terminating in vinculin adhesion plaques, colinear extracellular fibronectin matrices, and linear non-coincident deposits of fodrin. Microtubules (mt) and vimentin-intermediate filaments (IF) parallel the actin cables. Stress fibers of the tHmf-f are moderately reduced, their vinculin adhesion plaques and fibronectin matrices intact; fodrin is diffuse. Mts and IFs are normal and axial. Most epithelioid tHmf-e have no stress fibers, adhesion plaques, or extracellular fibronectin; instead, dense actin microfilament meshworks are attached to plasma membrane, as is fodrin. Mt and IF are radial. Both transformed phenotypes are stable over greater than 300 continuous passages. The differentiation-inducing agents DMSO, cyclic AMP, 5-azacytidine, and mezerein, were ineffective in normalizing shape or cytoskeleton of transformed Hmf, and butyrate was selectively toxic to 50% of tHmf-e. But hydrocortisone induced striking polarization, and increase in number, and alignment of stress fibers of both tHmf-f and tHmf-e. Growth, anchorage, cytoskeletal arrangements, and tumorigenic potential are not closely correlated in these stable, spontaneously transformed lines of distinct pheno- and karyotype originating from the same normal parental cell, suggesting independent acquisition of properties associated with transformation.     

Method of preparing suspended cells for scanning electron microscopy]

To preserve the lifetime morphology of the surface of suspended cells, these must be fixed in suspensions. The subsequent stages of cell preparation for scanning electron microscopy (dehydratation, critical point drying, coating) are considerably facilitated if fixed cells are preliminary attached to some substrate surface. An effective substrate should provide a firm rather than selective attachment of the overwhelming majority of fixed cells; the substrate should be also available for a wide application. The trial of different types of substrates showed a sufficient effectivity of plates made of commercial aluminium foil. In tests with murine embryonal and transformed fibroblasts as well as with human blood leukocytes, in average 90 per cent of cells fixed with glutaraldehyde in suspensions got attached to foil substrate surfaces; the fixed cells both settled from suspension and attached were seen distributed evenly on the substrate surface. The use of aluminium foil substrates made it possible to study the surface topography of some types of suspended cells.     

Contact-mediated changes in the fluidity of membrane lipids in normal and malignant transformed mammalian fibroblasts

The degree of microviscosity, gh, (fluidity/rigidity behavior) of membrane lipids of normal and transformed mammalian fibroblasts obtained from mice, hamsters and rats was quantitatively monitored by fluorescence polarization, P, analysis of the fluorescent probe 1,6-diphenyl 1,3,5-hexatriene (DPH) when embedded in lipid regions of cellular membranes of intact viable cells. Analysis of membrane microviscosity of six different cell populations and of individual cells in each cell population have indicated that the membrane microviscosity of all cell types, both normal and transformed fibroblasts, changes as a function of the cell density in the growing cultures. The membrane microviscosity was found to be low (high lipid fluidity) in sparse conditions but high (high lipid rigidity) in dense conditions. The induced changes in membrane microviscosity are practically reversible for all cell types and a complete reversion can be obtained within a few hours after changing the cell density conditions from sparse to dense and vice versa.Comparative studies with normal and transformed fibroblasts have shown that transformed fibroblasts have a more rigid lipid layer in their cellular membranes than normal or untransformed fibroblasts. The difference in membrane microviscosity between transformed and normal fibroblasts is higher in confluent conditions as compared with subconfluent cultures. These differences in the degree of fluidity of membrane lipids that are controlled by possible differences in the cellto-cell contact in normal and transformed fibroblasts may play a major role in determining the growth behavior of normal and malignant cells that are growing as a solid tissue and may have a direct effect on the control mechanisms that determine the presence or absence of the “density dependent inhibition” of growth.     

Normal and transformed fibroblast spreading: Role of microfilament polymerization and actin-myosin contractility

The polymerization of microfilaments and their subsequent rearrangements under the control of actin-myosin interactions are two major processes that underlie the morphogenetic reactions of cells. We studied their role in the spreading of normal and transformed REF52tetRas fibroblasts with adjustable ras-oncogene expression. Treatment with inhibitors of cell contractility (Y27632 or blebbistatin) led to the disappearance of actin bundles and focal adhesions; however, pseudopodial activity in both normal and transformed cells remained high. Under these conditions, spreading was more accelerated in normal cells then in ras-transformed cells. In normal cells treated with low concentrations of latrunculin A actin polymerization was suppressed, stress fibers and focal adhesions were preserved, but lamellipodial activity was lost and spreading was dramatically inhibited. In transformed fibroblasts treated with low doses of latrunculin, actin bundles and focal adhesions almost disappeared, but pseudopodial activity was apparent and spreading was less suppressed. Therefore, the most significant process in the regulation of cell spreading and polarization is the microfilament polymerization at the leading edge. ras-Transformed cells are less sensitive to inhibitors that affecting the cytoskeletal structure than nontransformed cells. Possible mechanisms that underlie the difference are discussed.     

Centrioles and microtubules in interphase cells exposed to colcemid. The concentration- and time-dependent effect of the action of the poison

Under the action of colcemid on SPEV cells the network of cytoplasmic microtubules disappears within less than 1 hour; microtubules attached to pericentriolar satellites are retained for 4 hours. The disassembly time of these microtubules does not depend on colcemide concentration. It is therefore assumed that most of the microtubules are not attached to the centrioles, but have two free ends, thus confirming a hypothesis that they are conveyer-assembled. With colcemid concentration equal to 0.5 mcg/ml, the following dynamics of events is observed for the cell centre: after the microtubules attached to the satellites had disappeared, clusters of electron dense material appear around the centrioles (6 hour incubation), then short microtubules occur among clusters (8 hour incubation) to be subsequently retained (up to 40 hour incubation).     

Use of fluorescent dyes as molecular probes for the study of multidrug resistance

Fluorescence microscopy has shown that 18 different fluorescent dyes, staining various intracellular structures in transformed hamster fibroblasts (DM-15), did not stain or stained weakly multidrug-resistant cells selected from DM-15 by colchicine. Reduced staining by fluorescent dyes was characteristic also of five other tested multidrug-resistant cell lines of hamster and mouse origin, selected by actinomycin D, colcemid, rubomycin, and ruboxyl. The intensity of staining of two revertant cell lines was similar to that of parental sensitive cells. All tested inhibitors of multidrug resistance, including weak detergent, metabolic inhibitors, calcium channel blockers, calmodulin inhibitors, and reserpine, restored normal staining of multidrug-resistant cells. The dyes accumulated in resistant cells in presence of these inhibitors left the cells several minutes after the removal of the inhibitor from the incubation medium. Sensitive cells retained the dyes for several hours. The efflux of the dyes from resistant cells is an active process since it occurred even in the presence of the dyes in the incubation medium. The efflux could be blocked by all tested inhibitors of multidrug resistance and it is possibly a basic mechanism of the reduced staining of resistant cells. These data support the idea that multidrug resistance is based on active nonspecific efflux of the drugs and indicate that the simple procedure of cell staining can be used for the detection of resistant cells and further study of the phenomenon of multidrug resistance.     

Effects of novel maleimide derivatives on cell cultures with different properties

The paper is focused on pilot study of effects of novel synthetic protein kinase inhibitors—maleimide derivatives in different concentrations on normal, transformed and multipotent cell lines. Influence on cell proliferation and morphological characteristics has been demonstrated. The chosen agents cause antiproliferative effect on transformed cells and are not cytotoxic to normal cell lines. Moreover, different maleimide derivatives’ effects on multipotent cells in attached and floating states has been shown. Described results can be used for further research of the maleimide derivatives as antitumor agents.     

SUBSTRATE-ATTACHED GLYCOPROTEINS MEDIATING ADHESION OF NORMAL AND VIRUS-TRANSFORMED MOUSE FIBROBLASTS

When BALB/c 3T3, simian virus 40 (SV40)-transformed 3T3 (SVT2), and revertant variants of the transformed cells are removed by EGTA treatment from the substrate on which they were grown, they leave behind a layer of glycoprotein which has been characterized biochemically (Terry, A. H. and L. A. Culp. 1974. Biochemistry. 13:414.)—substrate-attached material (SAM). The influence of SAM from normal and from transformed cells on cellular attachment to the substrate, morphology, movement, and growth has been examined. All three cell types displayed a 30% higher plating efficiency when grown on 3T3 SAM. The morphology of SVT2 colonies and of individual SVT2 cells was dramatically affected by growth on 3T3 SAM—the cells (a) were more highly spread on the substrate, (b) resisted crawling over neighboring cells, and (c) resisted movement away from the edge of colonies; SVT2 SAM was not effective in causing these changes. A cell-to-substrate attachment assay using thymidine-radiolabeled cells and untreated or SAM-coated cover slips was developed. SVT2 cells attached to 3T3 SAM- or SVT2 SAM-coated cover slips with a faster initial rate and to a higher saturation level than to untreated substrate, whereas 3T3 and revertant cells exhibited no preference; there was no species specificity in these cell-substrate attachment phenomena. Trypsin-released cells attached much more slowly than EGTA-released cells. 3T3 SAM, however, was not effective in lowering the saturation density of mass cultures of virus-transformed cells. These experiments suggest that the substrate-attached glycoproteins of normal cells affect the cellular adhesivity, morphology, movement, and perhaps growth patterns of virus-transformed cells—i.e., causing partial reversion of these properties of transformed cells to those found in contact-inhibited fibroblasts. A model for the involvement of substrate-attached glycoproteins in cell-to-substrate adhesion, and possibly cell-to-cell adhesion, has been proposed.     

Immunolocalization of the intermediate filament-associated protein plectin at focal contacts and actin stress fibers.

The distribution of plectin in the cytoplasm of Rat1 and glioma C6 cells was examined using a combination of double and triple immunofluorescence microscopy and interference reflection microscopy. In cells examined shortly after subcultivation (less than 48 h), filamentous networks of plectin structures, resembling and partially colocalizing with vimentin filaments, were observed as reported in previous studies. In cells kept attached to the substrate without growth for periods of 72 h to 8 days (stationary cultures), thick fibrillary plectin structures were observed. These structures were located at the end of actin filament bundles and showed co-distribution with adhesion plaques (focal contacts), vinculin, and vimentin. Only relatively large adhesion plaques (dash-like contacts) were decorated by antibodies to plectin, smaller dot-like contacts at the cell edges remained undecorated. Moreover, in stationary Rat1 cells plectin structures were found to be predominantly colocalized with actin stress fibers. However, after treatment of such cells with colcemid, plectin's distribution changed dramatically. The protein was no longer associated with actin structures, but was distributed diffusely throughout the cytoplasm. After a similar treatment with cytochalasin B, plectin's association with stress fibers again was completely abolished, although stress fibers were still present. The association of plectin with focal contact-associated intermediate filaments was demonstrated also by immunogold electron microscopy of quick-frozen, deep-etched replicas of rat embryo fibroblasts. These data confirm previous reports suggesting a relationship between intermediate filaments on the one hand, and actin stress fibers and their associated plasma membrane junctional complexes, on the other. Furthermore, the data establish plectin as a novel component of focal contact complexes and suggest that plectin plays a role as mediator between intermediate filaments and actin filaments.     

Inhibition of melanosome transformation in embryonic chick pigment retina cultured in vitro.

When the retinal pigment epithelial cells of the chick embryo are transferred to monolayer cultures, they lose their phenotypic trait-- melanin granules-- after a few days. Within the first 24 hours almost all of the melanosomes and premelanosomes are transformed into the degradative structures of the dense bodies or the melanosome complexes. Then, within a few days, these structures disappear completely from the cytoplasm. Actinomycin D, added to the culture medium during the first four hours, almost completely prevents the transformation of melanosomes and premelanosomes. The inhibition of cell proliferation, caused by the addition of colcemid, does not prevent the transformation, though the time of initiation of transformation is delayed considerably. The mechanisms of the transformation of pigment granules are discussed.