Developmental changes in messenger RNAs and protein synthesis in Dictyostelium discoideum

The pattern of proteins synthesized at different stages of differentiation of the slime mold Dictyostelium discoideum was studied by two-dimensional polyacrylamide gel electrophoresis. Of the approximately 400 proteins detected during growth and/or development, synthesis of most continued throughout differentiation. Approximately 100 proteins show changes in their relative rates of synthesis. During the transition from growth to interphase, the major change observed is reduction in the relative rate of synthesis of about 8 proteins. Few further changes are noticeable until the stage of late cell aggregation, when production of about 40 new proteins begins and synthesis of about 10 is reduced considerably. Thereafter, there are few changes in the pattern of protein synthesis. Major changes in the relative rates of synthesis of a number of proteins are found during culmination, but few culmination-specific proteins are observed. In an attempt to understand the molecular basis for these changes, mRNA was isolated from different stages of differentiation and translated in an improved wheat germ cell-free system; the products were resolved on two-dimensional gels. The ratio of total translatable mRNA to total cellular RNA is constant throughout growth and differentiation. Messenger RNAs for many, but not all, developmentally regulated proteins can be identified by translation in cell-free systems. Actin is the major protein synthesized by vegetative cells and by early differentiating cells. The threefold increase in the relative rate of synthesis of actin during the first 2 hr of differentiation and the decrease which occurs thereafter can be accounted for by parallel changes in the amount of translatable actin mRNA. Most of the changes in the pattern of protein synthesis which occur during the late aggregation and culmination stages can also be accounted for by parallel increases or decreases in the amounts of translatable mRNAs encoding these proteins. It is concluded that mRNAs do not appear in a translatable form before synthesis of the homologous protein begins, and that regulation of protein synthesis during development is primarily at the levels of production or destruction of mRNA.     

Changes in erythroid membrane proteins during erythropoietin-mediated terminal differentiation

Membrane and membrane skeleton proteins were examined in erythroid progenitor cells during terminal differentiation. The employed model system of erythroid differentiation was that in which proerythroblasts from mice infected with the anemia-inducing strain of Friend virus differentiate in vitro in response to erythropoietin (EP). With this system, developmentally homogeneous populations of cells can be examined morphologically and biochemically as they progress from proerythroblasts through enucleated reticulocytes. alpha and beta spectrins, the major proteins of the erythrocyte membrane skeleton, are synthesized in the erythroblasts both before and after EP exposure. At all times large portions of the newly synthesized spectrins exist in and are turned over in the cytoplasm. The remaining newly synthesized spectrin is found in a cellular fraction containing total membranes. Pulse-chase experiments show that little of the cytoplasmic spectrins become membrane associated, but that the proportion of newly synthesized spectrin which is membrane associated increases as maturation proceeds. A membrane fraction enriched in plasma membranes has significant differences in the stoichiometry of spectrin accumulation as compared to total cellular membranes. Synthesis of band 3 protein, the anion transporter, is induced only after EP addition to the erythroblasts. All of the newly synthesized band 3 is membrane associated. A two-dimensional gel survey was conducted of newly synthesized proteins in the plasma membrane enriched fraction of the erythroblasts as differentiation proceeded. A majority of the newly synthesized proteins remain in the same proportion to each other during maturation; however, a few newly synthesized proteins greatly increase following EP induction while others decrease markedly. Of the radiolabeled proteins observed in two dimensional gels, only the spectrins, band 3 and actin become major proteins of the mature erythrocyte membrane. Examination of total proteins of the plasma membrane enriched fractions of EP-treated erythroblasts using silver staining and 32P autoradiography show that many proteins and phosphoproteins are selectively eliminated from this fraction late in the course of differentiation during the reticulocyte stage. The selective removal of many proteins at the reticulocyte stage of development combined with previous selective synthesis and accumulation of some specific proteins such as alpha and beta spectrin and band 3 in the differentiating erythroblasts lead to the final mammalian erythrocyte membrane structure.     

Decreases in the relative concentrations of specific hepatocyte plasma membrane proteins during liver regeneration: down-regulation or dilution?

Antibodies were used to quantify seven domain-specific integral proteins of the rat hepatocyte plasma membrane during rat liver regeneration in response to two-thirds hepatectomy. Quantitative immunoblotting revealed that a subset of the plasma membrane proteins exhibited transient 30-70% decreases in relative concentration during the period of hepatocyte proliferation. The list of affected proteins included at least one representative from each of the plasma membrane domains: the apical protein HA 4, the lateral protein HA 321, and the basolateral receptors for epidermal growth factor and asialoglycoproteins. In contrast, the relative concentrations of three other plasma membrane proteins, the basolateral protein CE 9 and the two apical proteins dipeptidylpeptidase IV and aminopeptidase N, remained unchanged throughout liver regeneration. The decreases in the relative concentrations of the plasma membrane proteins were observed even when the synthesis of hepatocyte DNA was blocked by hydroxyurea, suggesting that the signalling for these two delayed consequences of two-thirds hepatectomy occurred along parallel, dependent pathways. Pulse and pulse-chase metabolic radiolabeling studies revealed that the decreases in the concentrations of the PM proteins were accomplished through protein-selective decreases in the rates of synthesis of the high-mannose precursors of the affected proteins, but not through the accelerated degradation of the mature plasma membrane proteins.     

The role of erythropoietin in the production of principal erythrocyte proteins other than hemoglobin during terminal erythroid differentiation

Erythropoietin (EP) controls the terminal phase of differentiation in which proerythroblasts and their precursors, the colony forming units-erythroid (CFU-e), develop into erythrocytes. Biochemical studies of this hormone-directed terminal differentiation have been hindered by the lack of a homogeneous population of erythroid cells at the developmental stages of CFU-e and proerythroblasts that will synchronously differentiate in response to EP. Such a population of cells can be prepared from the spleens of mice with the acute erythroblastosis resulting from infection with anemia-inducing Friend virus (FVA). Using these FVA-infected erythroid cells, which were induced to differentiate with EP, four proteins other than hemoglobin that have key functions in mature erythrocytes were monitored during the 48-hour period of terminal differentiation. Synthesis of spectrin and membrane band 3 proteins were determined by immunoprecipitation and SDS-polyacrylamide gel electrophoresis; accumulation of the cytoskeletal protein band 4.1 was monitored by immunoblotting; carbonic anhydrase activity was measured electrometrically. Band 3 synthesis and band 4.1 accumulation could be detected only after exposure of the cells to EP. Spectrin synthesis was ongoing prior to culture with EP, but it did increase after exposure to the hormone. Carbonic anhydrase-specific activity changed very little throughout the terminal differentiation process. These results reveal at least three patterns of production of principal erythrocyte proteins during EP-mediated terminal differentiation of FVA-infected erythroid cells. Depending on the specific protein examined, de novo synthesis can be induced by EP, an ongoing production can be enhanced by EP, or the production of a protein can be completed at a developmental stage prior to EP-mediated differentiation in these cells.     

Protein-transients during heterocyst differentiation in Anabaena circularis and Cylindrospermum sp

The programme of protein synthesis accompanying cellular differentiation to the heterocyst following transfer of the blue-green algae Anabaena circularis and Cylindrospermum sp. (CBSC 1755) from ammonia-enriched medium to nitorgen-free medium was determined by polyacrylamide gel electrophoresis of whole proteins during successive intervals of differentiation. Besides this, total proteins and soluble amino acids were determined quantitatively. At least 4 sets of proteins can be distinguished on the basis of the time at which they are synthesized. Besides this, differentiation is distinguishable on the basis of the time at which their synthesis is turned off. The postmaturation stages revealed the synthesis of two sets in A. circularis andone in Cylindrospermum so. (CBSC 1755).     

Rates of degradation of glycoproteins from normal and regenerating rat livers: A study using double isotopes

The average decay rates (half-lives) of mixed glycoproteins were measured using double isotopes of fucose and glucosamine and compared to those of mixed overall proteins measured with leucine and NaH¹⁴CO₃ in whole homogenates and plasma membranes from normal and regenerating rat livers. A large reutilization of leucine was observed under both normal and regenerating conditions. Fucose seems to be recycling most predominantly in regenerating liver, whereas glucosamine was found to be very little if not at all reutilized under both conditions. Comparison of the results obtained with NaH¹⁴CO₃ and glucosamine demonstrated that glycoproteins from normal liver homogenate are degraded at a faster rate than mixed proteins. Contrary to that of mixed proteins, the half-life of glycoproteins remains unchanged during liver regeneration, and the use of glucosamine revealed that the degradation of plasma membrane glycoproteins is identical to that found in whole homogenate under both normal and regenerating conditions. Finally, the relative degradation rates of fractionated plasma membrane proteins and glycoproteins were evaluated under the same conditions. During liver regeneration some readjustments are observed in the relative degradation rates of individual species which suggest that the synthesis and degradation of the various surface membrane glycoproteins proceed at rates that are controlled independently.     

Protein synthesis and differentiation in a clonal line of teratocarcinoma and in preimplantation mouse embryo.

Undifferentiated cells of a clonal line of teratocarcinoma can differentiate in vitro into embryoid bodies with morphological and biochemical features of early mouse embryo. During the first step of differentiation protein synthesis has been analysed by 2 dimensional gel electrophoresis. While new proteins are synthesized, the synthesis of others turned off with the appearance of endodermal cells in embryoid bodies. We have compared protein synthesis during teratocarcinoma differentiation and during early mouse embryogenesis at three stages of mouse preimplantation embryo. The results demonstrate that only the late blastocyst protein synthesis pattern shows most of the polypeptides identified in the differentiated protein synthesis pattern of teratocarcinoma. In contrast, protein synthesis during the early stages of mouse embryonic development is very different from protein synthesis in undifferentiated teratocarcinoma.     

The biosynthesis and turnover of lipid during the differentiation of Dictyostelium discoideum

Despite the fact that there are only relatively slight changes in lipid composition during the differentiation of Dictyostelium discoideum, the rates of lipid synthesis were found to vary considerably. Polar lipid synthesis declined markedly during aggregation and pseudoplasmodium formation and then increased during the terminal stages of differentiation. Several neutral lipid classes (sterol, the diacylglycerols and triacylglycerol) exhibited similar changes in synthetic rates, although the effects were somewhat less pronounced. In contrast, the rates of synthesis of steryl ester and free fatty acid increased slightly throughout the differentiation period, so that, by the end of the later stages of fruiting body culmination, the rates were essentially doubled. Finally, the synthesis of an unknown component increases at least 10-fold during differentiation. Of the newly synthesized lipid, only triacylglycerol and polar lipid exhibited marked turnover. Accumulation of radioactivity in steryl ester and free fatty acid continued after the removal of radioactive acetate, presumably due to the incorporation of fatty acid produced by polar lipid degradation.     

The expression and synthesis of the band 3 protein initiates the formation of a stable membrane skeleton in murine Rauscher-transformed erythroid cells.

While the temporal sequences of the synthesis and assembly of membrane skeletal proteins has been studied during erythroid maturation, relatively little is known about the events which initiate the assembly of membrane skeleton at the early stages of mammalian erythroid commitment. To investigate the early events that initiate the assembly of the membrane skeleton in mammalian erythroid cells, we have studied the synthesis and assembly of membrane skeletal proteins in murine Rauscher erythroleukemia virus-transformed cells. These cells are blocked in differentiation at around the early progenitor (burst forming unit-erythroid, BFUe) cell stage but can be induced to differentiate in vitro. Pulse-labeling studies reveal that Rauscher cells actively synthesize alpha spectrin, beta spectrin, ankyrin and band 4.1 proteins. However, the synthesis of the band 3 protein and its mRNA are barely detectable in these cells. The peripheral membrane skeletal components assemble only transiently in the membrane skeleton and turn over rapidly, resulting in about 20-fold lower steady state levels than are found in mature erythrocytes. Upon induction with erythropoietin and dimethyl sulfoxide, the mRNA level and synthesis of band 3 are increased about 50-fold. In contrast, the synthesis of spectrin, ankyrin and band 4.1 is increased only about 1.5 to 2.0-fold. However, after induction, the fraction of these proteins assembled on the membrane is increased, their half-lives on the membrane are nearly doubled with a concomitant 4 to 5-fold increase in their steady-state levels. These results suggest that the synthesis of peripheral membrane proteins is detected at the earliest stages of erythroid commitment and increases only slightly during further differentiation.(ABSTRACT TRUNCATED AT 250 WORDS)     

Developmental regulation of Dictyostelium discoideum plasma membrane proteins

Developmental changes in the plasma membrane proteins of Dictyostelium discoideum have been studied using metabolic labeling with [35S]methionine and two-dimensional electrophoresis. Pulse labeling for 1 h at the early interphase, late interphase, aggregation, and tip formation stages of development showed that the profile of newly synthesized plasma membrane proteins changed dramatically over this interval. Only 14% of the polypeptide species were synthesized at all four stages at detectable levels; 86% of the species changed over this developmental interval according to the criterion that they were synthesized at some but not all of the four stages tested. Long-term labeling during vegetative growth followed by initiation of development showed that the "steady-state" levels of the plasma membrane proteins changed very little over the same period. The only changes were in minor species (33% overall change). Similar analyses of whole cell proteins showed 27 and 20% change, respectively. Cell surface radioiodination revealed 52 external proteins in the plasma membrane. Comparison with the uniform methionine labeling results showed that these proteins were, with one notable exception, minor membrane components. In these external proteins, also, developmental changes were limited and were observed in the less abundant species. These results demonstrate the existence of two general classes of plasma membrane proteins. The first is a population of high-abundance proteins that are present in vegetative cells and are largely conserved through development. These possibly serve "housekeeping" functions common to all stages. The second class consists of low-abundance species that are expressed in a highly stage-specific manner and which presumably participate in developmentally important functions.     

Coordinate regulation of contractile protein synthesis during myoblast differentiation

The synthesis of contractile proteins has been studied during the differentiation of quail skeletal muscle myoblasts in culture. Myoblast differentiation was synchronized by transferring secondary cultures of rapidly dividing myoblasts into medium lacking cell division-promoting factors. Cultures at various stages of differentiation were then pulse-labeled with 35S-methionine, and cell extracts were resolved by electrophoresis on two-dimensional gels. Incorporation into specific proteins was quantitated by autoradiography and fluorography using a scanning densitometer. Contractile proteins synthesized by muscle cultures were identified by their co-electrophoresis on two-dimensional gels with contracile proteins purified from quail breast muscle. Our results show that the synthesis of myosin heavy chain, two myosin light chains, two subunits of troponin and two subunits of tropomyosin is first detected at the time of myoblast fusion and then rapidly increase at least 500 fold to maximum rates which remain constant in muscle fibers. Both the kinetics of activation and the molar rates of synthesis of these contractile proteins are virtually identical. Muscle-specific actin (alpha) synthesis also increases at the time of myoblast fusion, but this actin (alpha) is synthesized at 3 times the rate of other contractile proteins. The synthesis of 30 other muscle cell proteins was quantitated, and most of these are shown to follow different patterns of regulation. From these results, we conclude that the contractile proteins are regulated coordinately during myoblast differentiation.     

ATPase in mature and differentiating phloem and xylem

A cytochemical study using a lead precipitation technique has been made of the distribution of adenosine triphosphatase (ATPase) in mature and differentiating phloem and xylem cells of Nicotiana tabacum and Pisum sativum. The sites of ATPase localization in tobacco phloem were the plasma membrane, endoplasmic reticulum, mitochondria, dictyosomes, plasmodesmata, and the dispersed P proteins of mature sieve elements. In pea phloem sieve elements ATPase was localized in the endoplasmic reticulum, but was not associated with the P proteins or plasma membranes at any stage of their differentiation. In pea transfer cells ATPase activity was associated with the endoplasmic reticulum at all stages of their differentiation and with the plasma membrane of transfer cells that had formed wall ingrowths. In xylem cells of both tobacco and pea the patterns of ATPase activity was similar. At early stages of differentiation ATPase activity was associated with the plasma membrane and the endoplasmic reticulum. At intermediate stages of differentiation ATPase activity continued to be associated with the endoplasmic reticulum, but was no longer associated with the plasma membrane. At later stages of xylem element differentiation ATPase activity was associated with disintegrating organelles and with the hydrolyzing cell walls.     

Protein Distribution during Human Erythroblast Enucleation In Vitro

Enucleation is the step in erythroid terminal differentiation when the nucleus is expelled from developing erythroblasts creating reticulocytes and free nuclei surrounded by plasma membrane. We have studied protein sorting during human erythroblast enucleation using fluorescence activated cell sorting (FACS) to obtain pure populations of reticulocytes and nuclei produced by in vitro culture. Nano LC mass spectrometry was first used to determine the protein distribution profile obtained from the purified reticulocyte and extruded nuclei populations. In general cytoskeletal proteins and erythroid membrane proteins were preferentially restricted to the reticulocyte alongside key endocytic machinery and cytosolic proteins. The bulk of nuclear and ER proteins were lost with the nucleus. In contrast to the localization reported in mice, several key erythroid membrane proteins were detected in the membrane surrounding extruded nuclei, including band 3 and GPC. This distribution of key erythroid membrane and cytoskeletal proteins was confirmed using western blotting. Protein partitioning during enucleation was investigated by confocal microscopy with partitioning of cytoskeletal and membrane proteins to the reticulocyte observed to occur at a late stage of this process when the nucleus is under greatest constriction and almost completely extruded. Importantly, band 3 and CD44 were shown not to restrict specifically to the reticulocyte plasma membrane. This highlights enucleation as a stage at which excess erythroid membrane proteins are discarded in human erythroblast differentiation. Given the striking restriction of cytoskeleton proteins and the fact that membrane proteins located in macromolecular membrane complexes (e.g. GPA, Rh and RhAG) are segregated to the reticulocyte, we propose that the membrane proteins lost with the nucleus represent an excess mobile population of either individual proteins or protein complexes.     

Early Synthesis of Membrane Protein After Bacteriophage T4 Infection

Proteins that associate with cellular membrane during the first 5 min after infection with bacteriophage T4 were examined. Several procedures, including electrophoretic separations in three sodium dodecyl sulfate polyacrylamide gel systems and inhibition of host protein synthesis by UV irradiation, were employed to distinguish host-specified proteins from those induced by T4. Residual host protein synthesis was found to account for much of the new protein in preparations of the total membrane and for almost all of the newly synthesized protein in the outer membrane. Preliminary evidence indicates that the synthesis of some host membrane proteins is shut off less rapidly than is host synthesis of soluble protein. One host-directed polypeptide of the outer membrane was unique in that its synthesis or incorporation into the membrane was preferentially inhibited by infection. Also, it was found that the detergent Sarkosyl solubilizes all early T4 membrane proteins; this observation provides the basis for a simple procedure for distinguishing phage proteins from host outer membrane proteins.     

Aproliferin: a modulator of proliferative potential

Cellular differentiation proceeds through a series of steps in which cells undergo modifications in cellular phenotype and proliferative potential. Differentiation has been extensively studied in 3T3-T mesenchymal stem cells and growth arrest, non-terminal and terminal differentiation have been identified as three distinct stages in the adipocyte differentiation of these cells. The terminal stage of differentiation is associated with irreversible loss of proliferative potential and commitment to the expression of the adipocyte phenotype. A protein has been partially purified from human plasma that can induce the transition of 3T3-T adipocytes from the non-terminal to the terminal state of differentiation. This protein, designated aproliferin, has a mol. wt of approximately 45,000 and is trypsin, acid and heat labile. Induction of terminal differentiation by aproliferin is associated with changes in the synthesis of a limited number of cellular proteins. The ability of aproliferin to induce terminal differentiation in non-terminally differentiated cells is highly specific as a wide variety of pharmacological and biochemical agents do not mimic the effects of this agent. Apoliferin may be one of an emerging class of molecules which can affect differentiation and induce irreversible changes in cell function.     

Rapid accumulation and disappearance of plasma membrane proteins during development of wild-type and mutant strains of Dictyostelium discoideum

Plasma membranes were purified from the cellular slime mold Dictyostelium discoideum at different developmental stages and the protein compositions compared. The protein components of the plasma membrane of vegetative cells are largely conserved during development. Specific morphogenetic events are accompanied by synthesis and accumulation of several new proteins which are subsequently lost as development progresses. Proteins with apparent molecular weights of 38,000, 36,500 and 10,000 to 12,000 rapidly accumulate during the first six hours of development and then disappear from the plasma membrane after 12 hours. Later in development, several new high molecular weight proteins are synthesized and appear in the membrane. The pattern of accumulation of membrane proteins in wild-type and mutant strains suggests that appearance of membrane proteins is linked to a dependent sequence of events.     

What determines differentiation of urothelial umbrella cells?

Cytokeratins, uroplakins and the asymmetric unit membrane are biochemical and morphological markers of urothelial differentiation. The aim of our study was to follow the synthesis, subcellular distribution and supramolecular organization of differentiation markers, cytokeratins and uroplakins, during differentiation of umbrella cells of mouse bladder urothelium. Regenerating urothelium after destruction with cyclophosphamide was used to simulate de-novo differentiation of cells, which was followed from day 1 to day 14 after cyclophosphamide injection. Cytokeratin 7 and uroplakins co-localized in the subapical cytoplasm of superficial cells from the early stage of differentiation on. At early stages of superficial cell differentiation cytokeratin 7 was filamentary organized, and rare uroplakins were found on the membranes of relatively small cytoplasmic vesicles, which were grouped in clusters under the apical membrane. Later, cytokeratin 7 gradually reorganized into a continuous trajectorial network, and uroplakins became organized into plaques of asymmetric unit membrane, which formed fusiform vesicles. After insertion of fusiform vesicles into the apical plasma membrane, the surface acquired microridged appearance of umbrella cells. Cytokeratin 20 appeared as the last differentiation marker of umbrella cells. Cytokeratin 20 was incorporated into the pre-existing trajectorial cytokeratin network. These results indicate that differentiation of urothelial cells starts with the synthesis of differentiation-related proteins i.e., cytokeratins and uroplakins, and later with their specific organization. We consider that the umbrella cell has reached its final stage of differentiation when uroplakins form plaques of asymmetric unit membrane that are inserted into the apical plasma membrane and when cytokeratin 20 becomes included in a trajectorial cytokeratin network in the subapical area of cytoplasm.     

The dynamic properties of neuronal chromatin are modulated by triiodothyronine

The effect of triiodothyronine (T3) on the rate of synthesis of nuclear proteins was studied during terminal differentiation of rat cortical neurons cultured in a serum-free medium. To this aim total and acid soluble nuclear proteins were analyzed by different electrophoretic techniques. Our results show that: 1) during maturation in vitro, neuronal nuclei undergo a dramatic change in the rate at which different classes of histones and high mobility group (HMG) proteins are synthesized; the synthetic activity, measured as incorporation of radioactive precursors into nuclear proteins, slows indeed down with age: especially evident is the decrease in core histones synthesis; at day 15, on the other hand, HMG 14 and 17 and ubiquitinated H2A (A24) are synthesized at a high rate, especially in T3-treated neurons; 2) neurons treated with T3 show, at any age tested, a higher level of lysine incorporation into nuclear proteins; 3) even if during the first days of culture neurons synthesize core histones more actively in the presence of T3, there is no accumulation of these proteins at later stages, as compared with untreated cells. Possible implications of these data and relationship with the chromatin rearrangement which accompanies neuronal terminal differentiation are discussed.     

Uroplakins and cytokeratins in the regenerating rat urothelium after sodium saccharin treatment

A sodium saccharin (NaSac) diet was used to induce cell damage and regeneration in the urothelium of the male rat urinary bladder. Foci of terminally differentiated superficial cell exfoliation were detected after 5 weeks and their number increased after 10 and 15 weeks of the diet. At the sites of superficial cell loss, regenerative simple hyperplasia developed. Within 5 weeks of NaSac removal, regeneration re-established normal differentiated urothelium. In order to follow urothelial differentiation during regeneration we studied the expression of uroplakins and cytokeratins by means of immunocytochemistry and immunohistochemistry, respectively. Normal urothelium was characterised by terminally differentiated superficial cells which expressed uroplakins in their luminal plasma membrane and cytokeratin 20 (CK20) in the cytoplasm. Basal and intermediate cells were CK20 negative and cytokeratin 17 (CK17) positive. In hyperplastic urothelium all cells synthesised CK17, but not CK20. Differentiation of the superficial layer was reflected in three successive cell types: cells with microvilli, cells with rounded microridges and those with a rigid-looking plasma membrane on the luminal surface. The cells with microvilli did not stain with anti-uroplakin antibody. When the synthesis of uroplakins was detected rounded microridges were formed. With the elevated expression of uroplakins the luminal plasma membrane becomes rigid-looking which is characteristic of asymmetric unit membrane of terminally differentiated cells. During differentiation, syn-thesis of CK17 ceased in superficial cells while the synthesis of CK20 started. These results indicate that during urothelial regeneration after NaSac treatment, specific superficial cell types develop in which the switch to uroplakin synthesis and transition from CK17 to CK20 synthesis are crucial events for terminal differentiation. Accepted: 19 August 1997