THE ROLE OF GLUCOCORTICOID HORMONES IN THE CONTROL OF EPIDERMAL MITOSIS

It has previously been established that the epidermal chalone inhibits epidermal mitotic activity more powerfully in the presence of adrenalin, although adrenalin itself is not a mitotic inhibitor. It is now shown that in low concentrations hydrocortisone has little if any antimitotic activity, that when it is present together with chalone and adrenalin it does not markedly increase their antimitotic activity, but that it does act to prolong the mitotic depression which they induce. It is known that, without hydrocortisone, adrenalin rapidly escapes from epidermal cells so that the chalone action is weakened. It appears that the role of hydrocortisone may be to reduce the rate of adrenalin loss and thus to prolong the chalone-adrenalin activity. It is also shown that the rate of loss of adrenalin from epidermal cells is inhibited, though to a much lesser extent, in the presence of excess chalone.     

CONTROL OF GRANULOCYTE PRODUCTION

In normal conditions the granulocytic cell population is prevented from excessive cell proliferation by a humoral mechanism based on a specific feedback inhibitor, granulocytic chalone. In conditions of acute functional demand a tissue-specific stimulator, granulocytic antichalone, replaces chalone in rat serum. Mature granulocytes contain, and presumably produce, the chalone which is also present in fresh normal serum. Thus, the inhibitor is both humoral and present within the same cell system on which it acts: the action of this chalone is target tissue specific as it only inhibits granulocytic precursor cells in normal rat bone marrow in vitro. Granulocytic chalone and antichalone were partly purified by gel filtration on Sephadex; the elution parameters suggested molecular weights of 4000 and 30,000–35,000, respectively. Granulocytic chalone was not separated from the erythrocytic chalone (present in fresh normal serum and in blood erythrocytes) on Sephadex; however, separation at the cellular level was easily achieved.     

ERYTHROCYTIC CHALONE, A TISSUE-SPECIFIC INHIBITOR OF CELL PROLIFERATION IN THE ERYTHRON

Control of the rate of cellular proliferation in the erythron seems to be mediated by a tissue-specific mitotic inhibitor, termed the erythrocytic chalone. the function of this substance seems to be to prevent excessive proliferation of the erythrocyte precursor cells by means of a negative feedback and in terms of peripheral cell numbers.
The erythrocytic chalone is present in mature erythrocytes, from which it can be extracted by incubation in a chemically defined medium. It is also present in fresh normal serum and it is possible that in physiological conditions the factor is continuously liberated from mature erythrocytes into the surrounding plasma.
In the rat, in an artificially induced polycythaemia the concentration of the chalone in the serum is increased and this increment appears to be the sole cause of the enhanced inhibitory action of polycythaemic serum on the proliferation of the bone marrow cells in vitro.
The mode of action of the erythrocytic chalone seems to be to prevent the erythrocyte precursor cells from entering the generative cell cycle; the chalone thus regulates the production of erythrocytes by changing the 'proliferation efficiency' in the erythron.
So far, nothing is known about the chemical nature of the erythrocytic chalone. However, in gel filtration it is eluted in the same zone as the granulocytic chalone, its molecular weight thus being about 2000-4000.     

CONTROL OF GRANULOCYTE PRODUCTION: SEPARATION AND CHEMICAL IDENTIFICATION OF A SPECIFIC INHIBITOR (CHALONE)

Abstract. It has previously been shown by others that blood serum contains inhibitors of blood cell production acting on the proliferation of granulocy tic and erythrocytic precursor cells in the bone marrow. It is now shown that the active extract from calf blood serum can be further subfractionated into six different components, all of them exhibiting inhibitory effects on the proliferation of rat bone marrow cells in vitro. Ascitic fluid from rats treated intraperitoneally with polyvinylpyrrolidone contains inhibitors which apparently are the same as those found in calf serum.
It was further possible to demonstrate that only one of these inhibitors is contained in mature granulocytes where it is actively synthesized from amino acids and subsequently released into the surrounding medium. By chromatography on Sephadex G-25 of this conditioned medium the inhibiting substance could be obtained in relatively pure form being contaminated only by low amounts of two ninyhdrin-positive substances. the experiments allow the granulocytic inhibitor to be identified as a polypeptide with a molecular weight below 5000. the results suggest that this substance is the granulocytic chalone.     

THE CELL SPECIFIC EFFECT OF THE GRANULOCYTE CHALONE DEMONSTRATED WITH THE DIFFUSION CHAMBER TECHNIQUE

The granulocytic chalone is secreted by mature granulocytes and inhibits ³H-thymidine incorporation of proliferating granulocytes in vitro . The effect and the cell line specificity of this chalone was assessed with the in vivo diffusion chamber culture technique. Tests were carried out on cultures from normal mouse bone marrow cells and mouse and rat blood leucocytes. The majority of the DNA synthesizing cells in marrow cultures were proliferating granulocytes. Macrophages and immunoblasts proliferated in rat leucocyte cultures, when the chambers had been carried for 5 days in host mice. Repeated chalone or control injections were given i.p. to the host mice during 6–7 hr prior to ³H-thymidine injection. Isotope uptake of proliferative granulocytes was reduced by the chalone treatment. No such effect was found on the rat immunoblasts and macrophages. The viability of cultured cells was apparently not affected by the chalone treatment.     

CHALONE CONTROL OF MITOTIC ACTIVITY IN SEBACEOUS GLANDS

Extracts of skin with sebaceous glands contain a substance which inhibits mitotic activity in sebaceous glands both in vivo and in vitro. This substance is neither the epidermal chalone nor the melanocyte chalone, both of which are also present in skin extracts. However, it resembles these other chalones in that it is water soluble, is precipitated by ethanol, is activated by the two stress hormones adrenalin and hydrocortisone, and is not species specific. It is present within the sebaceous glands, and it is evidently a sebaceous gland chalone.     

Chalones and the Control of Normal, Regenerative, and Neoplastic Growth of the Skin

SYNOPSIS Chalones,inhibitors of cell dmsion have been isolatedand studied from a number of mammalian tissues, most notably,the epidermis The epidermal rhalone is a glycoprotein It exhibitsconsiderable, but not complete specificity The epidermal chalone decreases mitotic activity by inhibitingcells in the G 2 phase of the cell cycle from entering mitosis,and probably also by inhibiting ceils in the G 1 phase of thecell cycle from entering mitosis To inhibit cells in G 2 fromentering mitosis the chilone requnes adrenalin, and for maximalactivity hydrocortisone It is not known if idrenalin and hydrocortisoneare required for chalone inhibition of cells in G 1 In addition to inhibiting cell division in normal epidermalcells the epidermal chalone can inhibit cell division in regeneratingepidermal cells induced to proliferate by chemical damage Thephase of the cell cycle in which the chalone inhibits legeneratingepidermal cells from entering mitosis is not known Epidermal tumors contain a decreased amount of chalone Mitosisin epidermal tumors is inhibited by treatment with epidermalchalone Tumor cells are inhibitedfrom entering mitosis fromeither the G 1 or G 2 phases of the cell cycle Chalones are said to inhibit mitosis by a negative feedbackmechanism However, experiments which presumably result in adecrease in chalone concentration do not result in an increasein mitotic activity It is suggested that if chalones are physiological controllers of cell division they do not act by a simplenegative feedback mechanism but require the action of a substanceto decrease their concentration     

Interaction of chalones and glucocorticoid hormones in regulation of cell division

The action of hepatic chalone on cell proliferation in inoculated hepatoma 22a of mice was studied in the presence of a changed level of glucocorticoid hormones in experimental animals. Chalone was obtained from the liver of intact rats by ethanol precipitation. The intensity of cell proliferation in hepatoma was evaluated by the colcemide and autoradiography methods. Six hours after chalone injection c-mitosis in the tumor decreased 2.7-fold, and the DNA index 6.8-fold. It may be concluded that the preparation used contains both G1- and G2-chalones. Single or repeated injections of hydrocortisone to mice inhibits cell proliferation to a less degree than administration of chalone alone. Combination of hydrocortisone and chalone produces the same effect as injection of chalone alone. Adrenalectomy diminishes susceptibility of hepatoma cells to exogenous chalone. The degree of tumor proliferative activity in the adrenalectomized animals was half as much after chalone injection, as compared to that in intact animals. Thus, a certain level of glucocorticoid hormones in hepatoma tissue is necessary to reveal the action of chalones.     

Investigation of putative control mechanisms for thyroid growth

We have previously shown that the growth response of the rat thyroid to a sustained elevation of the serum level of TSH, induced by goitrogen administration, is self-limiting. This study investigated the possibility that this limitation of growth is due to the inhibitory action of a chalone secreted by the thyroid follicular cells, the serum concentration of which increases as the gland grows. Twenty-seven adult rats were treated with the goitrogen aminotriazole for 5 months to reach a 'plateau of growth'. One group of 9 rats was then subjected to hemithyroidectomy, another to a sham operation, while a third acted as unoperated controls. Four weeks later there was no significant difference between the groups in thyroid weight, follicular cell number or serum TSH. The absence of regeneration following hemithyroidectomy indicates that a systemically-circulating chalone does not play a role in the regulation of growth in the goitrous thyroid. Other mechanisms including the possible role of a 'local' chalone are briefly discussed.     

Granulocyte chalone: tissue specificity of action in short-term cultures]

Granulocytic chalone containing extracts were obtained by incubating rat bone marrow cells in Hanks salt solution and further purification of the conditioned medium by ultrafiltration and gel chromatography. These extracts cause specific inhibition of 3H-thymidine incorporation in short-term cultures of rat bone marrow and murine myeloic leukemias. Ehrlich ascites tumour, spleen (mouse), lymphatic leukemia L1210 and melanoma AMel 3 (hamster) are not influenced under identical experimental conditions. Comparing the action of cell proliferation inhibitors (chalones) from Ehrlich ascites tumour and spleen lymphocytes it was shown that inhibition of 3H-thymidine incorporation occurs only with those cells corresponding to the origin of the inhibitor. Therefore, the described short-term cultures seem to be suitable for testing the tissue specificity of action, as the main criterion for authenticity of the chalone effect, at least in the case of granulocytic chalone.     

EFFECT OF EHRLICH ASCITES CELL CHALONE ON NASCENT DNA SYNTHESIS IN ISOLATED NUCLEI

Ehrlich Ascites Tumor (EAT) chalone has been shown to inhibit nascent DNA synthesis by inhibiting DNA polymerase α and β (Nakai, 1976), but one of the problems in studying eurkaryotic DNA replication has been the relative impermeability of the cell membrane to precursors and macromolecules; hence, to circumvent this restriction without sacrificing the integrity of the replication process, a broken cell system utilizing nuclei in aqueous media was investigated. Isolated nuclei appear to continue the process of DNA replication that was proceeding in vivo before their isolation and under optimal conditions are able to initiate new synthesis (Fraser & Huberman, 1977). The effects of partially purified EAT chalone on nascent DNA could be studied directly in this nuclear system, which excluded effects of the cell membrane, nucleotide pools and other cytosol elements. A concentration-related inhibition of [³H]thymidine triphosphate ([³H]-dTTP) incorporation was noted over a chalone range of 50–200 μg/ml. It appears that chalone can inhibit DNA polymerase α directly within the nucleus without an intermediate step such as a cell membrane receptor.     

THE EFFECT OF POLYCYTHAEMIC SERUM ON THE PROLIFERATION OF RAT BONE MARROW CELLS IN VITRO

The effect of experimental polycythaemia on the rate of proliferation of erythrocytic precursor cells was investigated by means of an in vitro technique. The serum obtained from polycythaemic rats was found to inhibit significantly ³H-thymidine incorporation in normal rat bone marrow cells in vitro, as compared with normal serum. Autoradiographic analysis revealed that this inhibition resulted from a reduction in the number of labelled bone marrow cells. The inhibition proved to be specific to the erythrocyte precursor cells; the labelling index was reduced in the erythrocytic cell population by 21–50% (P < 0.001) at different incubation times, while the effect on the granulocytic cell population was negligible. It is deduced that an inhibitor substance responsible for the effects observed is present in polycythaemic serum. It is proposed that this factor is the ‘erythrocytic chalone'. The results support the general view that triggering of stem cells is not the only mode of regulation of erythropoiesis, but that the rate of proliferation of the precursor cells in the erythron is also regulated.     

Action of epidermal chalone on the vaginal epithelial cell proliferation in ovariectomized mice stimulated by 17 beta-estradiol

It has been shown that the DNA synthesis inhibitory effect of chalone on the vaginal epithelium of ovariectomized mice administered epidermal chalone three times (8, 4 and 1 h before 17-beta-estradiol injection) is dependent on chalone injection made 1 h before hormone injection. The decrease in the number of DNA synthesizing cells induced by 3-fold injection of chalone during 2 days is linked with the reduction in the level of exogenous estrogen in ovariectomized mice rather than with the duration of epidermal chalone action.     

CELL CYCLE EVENTS IN THE HYDROCORTISONE REGULATION OF ALKALINE PHOSPHATASE IN HELA S3 CELLS

The increase in alkaline phosphatase in asynchronous cultures of HeLa S₃ cells grown in medium supplemented with hydrocortisone is characterized by a lag period of 10–12 hr. Present studies utilizing synchronous cell populations indicate: (a) a minimum of 8–10 hr of incubation with hydrocortisone is necessary for maximum induction of alkaline phosphatase; (b) the increase in enzyme activity produced by hydrocortisone is initiated exclusively in the synthetic phase of the cell cycle; (c) alkaline phosphatase activity does not vary appreciably over a normal control cell cycle. Radioactive hydrocortisone is rapidly distributed into HeLa cells irrespective of their position in the cell cycle, indicating that inductive effects are not governed by selective permeability during the cell cycle. Hydrocortisone-1,2-[³H] diffuses back from the cell into the medium when the cells are incubated in fresh medium containing no hydrocortisone, and the alkaline phosphatase induction, under these conditions, is completely reversible.     

Effect of adrenaline on the mitosis-inhibiting action of a chalone-containing preparation in Ehrlich ascites tumor

The effect of adrenaline and Ehrlich ascite carcinoma (EAC) chalone on cell division was studied. It has been established that EAC chalone inhibited cell proliferation. The action of adrenaline was also accompanied by a decrease in mitotic index, but the inhibitory effect of the hormone was weaker than that of chalone, it occurred later and its duration was less. A combined effect of adrenaline and chalone depended on the time interval between the administration of the substances. It has been found that chalone administration 1 h after adrenaline administration prolonged mitotic inhibitory effect by 4 h and its synchronous action on cell division in EAC was weak during the experiment. Combined effect of adrenaline and chalone did not differ from the effect of chalone alone if chalone was administered 3 h after adrenaline administration.     

EFFECTS OF BLEOMYCIN ON THE EPIDERMAL CONTENT OF GROWTH-REGULATORY SUBSTANCES (CHALONES)

Hairless male mice were given 2 mg Bleomycin i.p. on two successive days. At different time intervals from 1 to 10 days after the last Bleomycin injection, groups of animals were killed and water extracts of homogenized skin were made. These extracts, supposed to contain the epidermal G₁ and G₂ chalones, were injected into female hairless mice, and their growth inhibitory potency determined by two methods. 5 mg of lyophilized crude skin extract were injected i.p. together with Colcemid, and the animals killed 4 hr later. The number of Colcemid-arrested mitoses was determined, and was considered to be a measure of the G₂ inhibitor present in the skin extracts. 10 mg of the same extracts were injected i.p., and these animals also got ³H-TdR i.p. 12 hr later, and were killed after a subsequent 30 min. The epidermal LI was determined, and was considered to be a measure of the epidermal G₁ factor in the skin extracts. The results obtained were compared to the effect of Bleomycin alone and to the effects of skin extracts from non-Bleomycin-treated animals. The results show that Bleomycin provoked slight alterations in the growth-inhibitory potency of the G₁ chalone, whereas significant effects were seen in the G₂ chalone. There was an increased amount of growth-inhibiting factors on days 2 and 3, and on days 8–10. The results are discussed and it is concluded that the most probable hypothesis is that Bleomycin, in addition to its known inhibitory effect on epidermal cell proliferation, exerts growth inhibition by accumulation of cells with high growth inhibitory potency. An initial, additional direct effect of Bleomycin on the chalone system cannot be excluded.     

CELL PROLIFERATION KINETICS OF EPIDERMIS AND SEBACEOUS GLANDS IN RELATION TO CHALONE ACTION

Median S-phase lengths of pinna epidermis and sebaceous glands, and of epithelia from the oesophagus and under surface of the tongue of Albino Swiss S mice were estimated by the percentage labelled mitoses method (PLM). The 18.4 and 18.8 hr for the median length of S-phase for pinna epidermis and sebaceous glands respectively made it possible for these two tissues to be used experimentally for testing tissue specificity in chalone assay experiments. The 10.0 and 11.5 hr for oesophagus and tongue epithelium respectively made experimental design for chalone assay difficult when pinna epidermis was the target tissue. The results of the Labelling Index measured each hour throughout a 24-hr period showed no distinct single peaked diurnal rhythm for pinna epidermis and sebaceous glands. Instead a circadian rhythm with several small peaks occurred which would be expected if an S-phase of approximately 18 hr was imposed on the diurnal rhythm. This indicates that there may be very little change in the rate of DNA synthesis. The results are given for the assay in vivo of purified epidermal G₁ and G₂ chalones, and the 72–81% ethanol precipitate of pig skin from which they could be isolated. These experiments were performed over a time period which took into account the diurnal rhythm of activity of the mice as well as the S-phase lengths. Extrapolating the results with time of action of the chalone shows that the G₁ chalone acts at the point of entry into DNA synthesis and that the S-phase length was approximately 17 hr for both the pinna epidermis and sebaceous glands. This may be a more correct value since the PLM method overestimates the median S-phase length as it is known that in pinna skin the [³H]TdR is available to the tissues for 2 hr and true flash labelling does not take place. The previous reports that epidermal G₁ chalone acts some hours prior to entry into S-phase resulted from experiments on back skin where the S-phase is shorter and there is a pronounceddiurnal rhythm which could mask the chalone effect. The epidermal G, chalone had no effect on DNA synthesis even at different times in the circadian rhythm. Thus the circadian rhythms and S-phase lengths of the test tissues need to be considered when experiments are performed with chalones. Ideally, the target tissues selected for cell line specificity tests should have the same cell kinetics for the easier and more accurate assessment and interpretation of results. When the tissues have markedly different cell kinetics, experimental procedures and results need to be evaluated accordingly. The point of action of G, chalone can only be assessed if the effect is measured over the peak of incorporation of 13H]TdR into DNA. The results of the effects of skin extracts are analysed in relation to changes in the availability of i3H]TdR for the incorporation into DNA and to the possibility of there being two distinct populations of proliferating cells.     

MITOTIC CONTROL IN ADULT MAMMALIAN TISSUES

Mitotic homeostasis: Mitotic control is maintained by the interaction of a tissue-specific mitosis-inhibiting chalone, which permeates the whole tissue, and a non-tissue-specific mitosis-promoting mesenchymal factor, which originates in the connective tissue and acts only on connective-tissue-adjacent cells. In the basal layer of the epidermis the mitotic rate is determined by the relative concentrations of these two substances; in the distal layers the chalone is dominant so that all cells must become post-mitotic, age, and die. Thus the perfect balance between cell gain and cell loss that is maintained equally in hypoplasia, normality, and hyperplasia is ensured by the fact that all cells forced distally by mitotic pressure enter a chalone concentration that is high enough to direct them into post-mitosis and so to their deaths. The mitotic rate of the basal epidermal cells and the ageing rate of the distal cells are both inversely related to the chalone concentration. A change in the mitotic rate is matched by an equal change in the ageing rate so that, within limits, epidermal thickness (or mass) remains constant. Epidermal thickness is determined by the tissue-specific ratio, mitotic rate: ageing rate; it is influenced by the mitotic rate only when this exceeds a certain critical level. Evidently all epithelial tissues, even when these form solid masses (e.g. liver hepato-cytes), have a similar control mechanism, the ‘basal cells’ being those that are connective-tissue-adjacent and the ‘distal cells' those that are not. Tissues that are not connective-tissue-based (e.g. erythrocytes and granulocytes) have specialized mechanisms involving differentiation from relatively undifferentiated stem cell populations, as also do the connective tissues themselves. Local tissue damage leads via local chalone loss to a temporarily and locally increased mitotic rate; chronic damage leads via chronic chalone loss to hyperplasia, the increase in tissue mass being limited by the reduced life-span of the post-mitotic cells. Compensatory hypertrophy When a tissue mass is so large (e.g. the hepatocytes) in relation to the total body mass that the escaping chalone forms a significant systemic concentration, extensive damage leads to compensatory hypertrophy. The reduced tissue mass (e.g. after partial hepatectomy) produces less chalone, leading to a reduced systemic concentration, and therefore a higher chalone loss from the surviving tissue. This results in a general mitotic response in that tissue, as the relative power of the mesenchymal factor increases, and thus to an increase in tissue mass. Growth ceases when the normal tissue mass is attained. When a large tissue suffers chronic damage (e.g. liver cirrhosis) the chronic chalone lack results in hypertrophy, which is limited by the reduced life-span of the post-mitotic cells. Tumour growth Mitotic control is lost when the chalone concentration falls so low that the ‘distal cells’ remain mitotic; cell gain then exceeds cell loss and a tumour appears. Such chalone loss is related to permanent membrane damage, which may be the central event in carcinogenesis. The evidence is that a tumour continues to produce and to respond to the chalone of its tissue of origin. As a tumour grows the systemic concentration of its chalone rises steadily so that there is an increasing mitotic inhibition, first, in the parent tissue, and second, in the tumour itself. Thus tumour growth may be described as an exponential process limited by an exponential retardation. This means that, if the host survives, the tumour growth will cease and the tumour mass will reach a plateau. This is a negative feedback mechanism which differs from compensatory hypertrophy only in that, at the plateau, the mass attained is greater than normal, and also in that, at any time, further cell damage may cause the tumour to ‘progress’. When this happens the new and higher plateau may be unattainable before the host is killed. Tumour growth is normally slower than would be expected if the mitotic advantage were the only factor involved; clearly tumour growth is usually inhibited by factors other than the chalone, in particular perhaps by the immune response to the altered cell membrane. It is an especial pleasure to acknowledge the constant help and encouragement that has been given by Johanna U. R. Deol.     

Superficial origin of erythrocytic chalone in polycythemia in vitro]

It was shown in the culture of rat bone marrow cells in experimental polycythemia that the chalone activity of erythrocytic chalone considerably drops in the presence of phytohemagglutinin (PHA). The chalone inhibits the agglutinating activity of PHA with respect to bone marrow cells. Absorption of the chalone on the immobilized PHA leads to disappearance from it and of PAS-positive bands recorded electrophoretically and to a strong decrease in PAS-negative band intensity. Experiments with preliminary incubation of rat red cells before preparation of the chalone suggest that in the course of its preparation two polypeptides one of which is PAS-positive are released into the medium. It is suggested that the chalone includes superficial membrane proteins of red cells, possibly, in the form of a combination of PAS-positive and PAS-negative bands. Potential mechanisms of chalone release from the surface of cells and features of their action on the cells are discussed.     

THE ROLE OF AUXINS AND CYTOKININS IN THE RELEASE OF BUDS FROM DOMINANCE

The paper deals with the general problem of the physiological basis of branching, and the roles of known and unexplored factors in sensitivity to apical dominance. It is shown that when pea seedling shoots are completely or partially inhibited by other shoots on the same plant auxin can promote their elongation, even though it does not have this effect on inhibited buds. This influence of auxin is only exerted on internodal elongation and not on apical growth. When kinetin in a solution of alcohol and carbowax is applied directly to the lateral buds of pea seedlings, it releases them from inhibition by the growing apex. It is shown that the role of alcohol in this solution is to act as a surfactant, permitting good contact with the buds, while that of carbowax, being hygroscopic, is to maintain a thin film of solution over the buds. Buds thus released from apical dominance by kinetin do not elongate as much as do uninhibited control buds. Such kinetin-treated buds can, however, be made to elongate normally by the application of auxin locally to their apices. It is concluded that growing shoots are relatively insensitive to correlative inhibition because they synthesize two types of growth substances, namely, auxin, which antagonizes the inhibitory effect on internodal elongation, and cytokinins, which permit the apex itself to develop. In the discussion it is brought out that many cases of branching, which appear at first to bear little relation to one another, can be understood on the basis of two principles, namely: (1) Any reduction in the growth rate of a dominant apex reduces its inhibitory effect on other apices, and (2) once an apex starts growing it becomes less sensitive to inhibition by other apices These generalizations and the experimental results are tentatively interpreted in terms of an interaction between the syntheses of auxin and of cytoldnin.