Regrowth kinetics of cells from different regions of multicellular spheroids of four cell lines

A basic understanding of the recruitment of quiescent tumor cells into the cell cycle would be an important contribution to tumor biology and therapy. As a first step in pursuing this goal, we have investigated the regrowth kinetics of cells from different regions in multicellular spheroids of rodent and human origin. Cells were isolated from four different depths within the spheroids using a selective dissociation technique. The outer cells were proliferating and resumed growth after replating with a 0-8-hour lag period, similar to cells from exponentially growing monolayers. With increasing depth of origin, the lag periods prior to regrowth increased to 2-3 times the monolayer doubling time; cells from plateau-phase monolayers showed a lag period of 1-1.5 times the doubling period. After resuming growth, all cells of a given cell line grew with the same doubling time and achieved the same confluency level. The inner spheroid cells and cells from plateau-phase monolayers had reduced clonogenic efficiencies. The inner cells were initially 1.5-3 times smaller than the outer cells, but began to increase in volume within 4 hours of replating. The fractions of S-phase cells were greatly decreased with increasing depth of origin in the spheroids; there were long delays prior to S-phase recovery after plating, to a maximum of 1-1.5 times the normal doubling time. These results suggest that those quiescent cells from spheroids and monolayers which are able to reenter the cell cycle are predominantly in the G1-phase. However, quiescent cells from the innermost spheroid region require approximately twice as long to enter normal cell cycle traverse as cells from plateau-phase monolayers. The selective dissociation method can isolate very pure populations of proliferating and quiescent cells in a rapid and nonperturbing manner; this system will be valuable in further characterizing quiescent cells from spheroids.     

In vitro holding and PLD repair

Summary The Stationary or Plateau-Phase of commonly used rodent cell lines like the V79 are often assumed to be quiescent (non-mitotic). An analysis of cell turnover in V79 plateau-phase cultures through BrUdR-incorporation combined with FUdR-block and light exposure (S-phase cytocide) revealed such cultures to be in a state of kinetic equilibrium. Even when the state of maximal permissible density was acquired, at least 50% of the population of cells were cycling within the time for one population doubling. Attempts at holding the cells from cycling (through nutrient-depletion and serum-privation) were unsuccessful, although the turnover-rate was reduced. Our assays for X-irradiated clonogenic survivors after attempted holding combined with delayed plating (DP) showed differences in the survival curves for exponentially growing and confluent cultures. Elimination of cycling cells by S-phase cytocide removed these differences. Since a significant fraction of plateau-phase cells are not mitotically quiescent (Q), one must eliminate the proliferating (P) fraction if one wishes to examine the PLDR of the Q cells. For V79 cells, removal of the P cells eliminates the higher survival (usually interpreted as Q cell PLDR) of plateau-phase cells.     

Location and phenotype of human adult keratinocyte stem cells of the skin

The location and identity of interfollicular epidermal stem cells of adult human skin remain undefined. Based on our previous work in both adult murine and neonatal human foreskin, we demonstrate that cell surface levels of the alpha6 integrin and the transferrin receptor (CD71) are valid markers for resolving a putative stem cell, transit amplifying and differentiating compartment in adult human skin by flow cytometry. Specifically, epidermal cells expressing high levels of alpha6 integrin and low levels of the transferrin receptor CD71 (phenotype alpha6 (bri)CD71(dim)) exhibit several stem cell characteristics, comprising a minor population (2%-5%) of the K14(bri) fraction, enriched for quiescent and small blast-like cells with high clonogenic capacity, lacking the differentiation marker K10. Conversely, the majority of K14(bri) K10(neg) epidermal cells express high levels of CD71 (phenotype alpha6 (bri)CD71(bri)), and represent the actively cycling fraction of keratinocytes displaying greater cell size due to an increase in cytoplasmic area, consistent with their being transient amplifying cells. The alpha6 (bri)CD71(bri) population exhibited intermediate clonogenic capacity. A third population of K14(dim) but K10 positive epidermal cells could be identified by their low levels of alpha6 integrin expression (i.e. alpha6 (dim) cells), representing the differentiation compartment; predictably, this subpopulation exhibited poor clonogenic efficiency. Flow cytometric analysis for the hair follicle bulge region (stem cell) marker K15 revealed preferential expression of this keratin in alpha6 (bri) cells (i.e., both stem and transient amplifying fractions), but not the alpha6 (dim) population. Given that K15 positive cells could only be detected in the deep rete ridges of adult skin in situ, we conclude that stem and transient amplifying cells reside in this location, while differentiating (K15 negative) cells are found in the shallow rete ridges.     

Influence of the estrous cycle on clock gene expression in reproductive tissues: Effects of fluctuating ovarian steroid hormone levels

Circadian rhythms in physiology and behavior are known to be influenced by the estrous cycle in female rodents. The clock genes responsible for the generation of circadian oscillations are widely expressed both within the central nervous system and peripheral tissues, including those that comprise the reproductive system. To address whether the estrous cycle affects rhythms of clock gene expression in peripheral tissues, we first examined rhythms of clock gene expression (Per1, Per2, Bmal1) in reproductive (uterus, ovary) and non-reproductive (liver) tissues of cycling rats using quantitative real-time PCR (in vivo) and luminescent recording methods to measure circadian rhythms of PER2 expression in tissue explant cultures from cycling PER2::LUCIFERASE (PER2::LUC) knockin mice (ex vivo). We found significant estrous variations of clock gene expression in all three tissues in vivo, and in the uterus ex vivo. We also found that exogenous application of estrogen and progesterone altered rhythms of PER2::LUC expression in the uterus. In addition, we measured the effects of ovarian steroids on clock gene expression in a human breast cancer cell line (MCF-7 cells) as a model for endocrine cells that contain both the steroid hormone receptors and clock genes. We found that progesterone, but not estrogen, acutely up-regulated Per1, Per2, and Bmal1 expression in MCF-7 cells. Together, our findings demonstrate that the timing of the circadian clock in reproductive tissues is influenced by the estrous cycle and suggest that fluctuating steroid hormone levels may be responsible, in part, through direct effects on the timing of clock gene expression.     

Role of brain hormone in oogenesis of the Indian freshwater leech,Poecilobdella viridis (Blanchard) during the annual reproductive cycle

The possible role of a brain hormone in oogenesis of Poecilobdella viridis has been investigated by brain extirpation and brain extract injections during non-reproductive (November to January) and reproductive (March to May) periods. Brain extirpation during the non-reproductive period ceased maturation of the ovary. It is inferred that brain secretion bears possibly a gonadotropic principle which governs and regulates the oogenesis during the annual reproductive cycle.     

Female genitalia,reproductive cycle and sperm storage in Armadillidium vulgare (Crustacea,Isopoda, Oniscidea)

Light and electron microscopic studies that we have published in the past have reported many aspects of the reproductive process in Armadillidium vulgare with particular emphasis on the reconstruction of female genitalia. Together this body of work provides an almost complete, albeit fragmented picture of these processes and include many data on sperm storage and sperm translocation. Females of A. vulgare have a pair of cuticular genitalia in the lumen of the oviduct. For insemination, these genitalia can receive the copulatory organs of males formed by the elongated tips of the first two pleon endopods. During transitions between reproductive (parturial) and non-reproductive (normal, non-parturial) moult cycles the genitalia undergo intriguing structural changes resulting in two types of genitalia. Throughout their reproductive lifetime, either type is reconstructed after each moult depending on the reproductive phase of the female. In this review, we integrate the events that occur during a reproductive cycle with particular emphasis on the genitalia reconstruction and sperm storage, and discuss functional aspects of the genitalia. Thereby, we provide a case model that can be useful for further studies on genitalia diversity and female reproductive strategies in terrestrial isopods.     

Male reproductive cycle in Aspidoscelis costata costata (Squamata: Teiidae) from Tonatico,Estado de México,México

The purpose of this study was to investigate the reproductive cycle of a high‐elevation population of Aspidoscelis costata costata (1500–1600 m) and compare its reproductive cycle with that of other populations, species, and closely related genera. Adult male A. costata costata lizards were collected, and the reproductive tracts were removed and subjected to histological analyses. Testicular activity commences in March with maximum testicular activity and highest sperm abundance (in the epididymides) occurring between May and July. The testis remains at peak activity until September when a late regression/early quiescent phase is observed. Leydig cells follow this same pattern except these hormone‐producing cells remain at maximum secretory level through September. Sperm are present in the epididymides in April–September. This pattern is consistent with the spring recrudescence found in a multitude of male lizard taxa. However, this differs from the continuous cycle observed in some tropical Teiid species and other lizard taxa at high elevation. This study indicates that our knowledge about lizard spermatogenic cycles remains incomplete, and additional studies are required to fully understand the interactions between phenotype, evolution, phylogenetics and environment.     

Tumor-specific cell-cycle decoy by Salmonella typhimurium A1-R combined with tumor-selective cell-cycle trap by methioninase overcome tumor intrinsic chemoresistance as visualized by FUCCI imaging

We previously reported real-time monitoring of cell cycle dynamics of cancer cells throughout a live tumor intravitally using a fluorescence ubiquitination cell cycle indicator (FUCCI). Approximately 90% of cancer cells in the center and 80% of total cells of an established tumor are in G₀/G₁ phase. Longitudinal real-time FUCCI imaging demonstrated that cytotoxic agents killed only proliferating cancer cells at the surface and, in contrast, and had little effect on the quiescent cancer cells. Resistant quiescent cancer cells restarted cycling after the cessation of chemotherapy. Thus cytotoxic chemotherapy which targets cells in S/G₂/M, is mostly ineffective on solid tumors, but causes toxic side effects on tissues with high fractions of cycling cells, such as hair follicles, bone marrow and the intestinal lining. We have termed this phenomenon tumor intrinsic chemoresistance (TIC). We previously demonstrated that tumor-targeting Salmonella typhimurium A1-R (S. typhimurium A1-R) decoyed quiescent cancer cells in tumors to cycle from G₀/G₁ to S/G₂/M demonstrated by FUCCI imaging. We have also previously shown that when cancer cells were treated with recombinant methioninase (rMETase), the cancer cells were selectively trapped in S/G₂, shown by cell sorting as well as by FUCCI. In the present study, we show that sequential treatment of FUCCI-expressing stomach cancer MKN45 in vivo with S. typhimurium A1-R to decoy quiescent cancer cells to cycle, with subsequent rMETase to selectively trap the decoyed cancer cells in S/G₂ phase, followed by cisplatinum (CDDP) or paclitaxel (PTX) chemotherapy to kill the decoyed and trapped cancer cells completely prevented or regressed tumor growth. These results demonstrate the effectiveness of the praradigm of “decoy, trap and shoot” chemotherapy.     

The Proliferative State of Clonogenic Cells In the Lewis Lung Tumour After Treatment With Cytotoxic Agents

The proportion of clonogenic cells from the Lewis lung carcinoma which are in S-phase of the cell cycle has been measured as the fraction killed by a short exposure to hydroxyurea in vitro. Estimates of the proportions of Sphase cells before and 30 min after doses of γ-radiation of 1000–2000 rad suggest no alternation in the cell cycle age distribution due to these doses of radiation. As the survivors of these high doses of radiation are predominantly hypoxic, the results imply that hypoxic cells have the same cell cycle age distribution as oxygenated cells in Lewis lung tumours. After treatment with cyclophosphamide or CCNU, the proportion of S-phase cells among the survivors exceeds the faction of S-phase cells in untreated populations. This increase is consistent with a relative resistance of S-phase cells to alkylating agents and nitrosoureas.     

Considerations in the design of possible cell cycle effective drugs

Antineoplastic agents are known to induce differential cytotoxic and cytostatic effects throughout the cell cycle. Many drugs have greater toxicity for cycling cells and act selectively at one or more phases of the cycle and may cause partial synchrony of surviving cells. However, these observations have been generally carried out on in vitro systems only and present a variety of complexities and pitfalls. Furthermore, human tumours are often characterized by a relatively low fraction of proliferating cells and present a large cellular heterogeneity as far as their cytogenetic, cytokinetic, and clonogenic features and their responses to drugs are concerned. Therefore, resistance to chemotherapy is due to various factors characterizing, in some instances, each individual tumour. In spite of the advent of technological advances such as flow cytometry, it is still difficult to design kinetic-orientated therapies especially for the treatment of solid tumours. Consequently, it is also difficult to design protocols based on cell cycle effective drugs. The possibility remains, at least for the moment, to stratify tumours according to their cellular heterogeneity. Different protocols could then be assigned to classes of tumours. Such an approach could be completed by further advances in the cellular monitoring of individual tumours.     

Immuno-electron microscopic localization of estradiol receptor in cells of male and female reproductive and non-reproductive organs

Summary— The localization of estradiol receptor (ER) in various tissues and their distribution in sub-cellular compartments were studied by means of immunogold-electron microscopic methods using a site-directed polyclonal antibody developed against a peptide from the DNA binding site of ER. This method was used to determine the presence and localization of ER in tissues and cells of male and female reproductive and non-reproductive organs. In the female reproductive tract, endometrial cells and the cells of the corpus luteum were found to contain ER. In non-reproductive organs of both sexes the following cell types showed significant labeling: hepatocytes, epithelial duodenal cells, striated muscle fibers, cells of the proximal convoluted tubules of the kidney, lymphocytes, neurons, and adipose cells. Alveolar epithelial cells were studied only in female specimens and were labeled by the anti-ER. Prostatic and epididymal epithelial cells were found to be labeled in the male reproductive organs. In all these cells a higher density of label was found in the nucleus, especially in the space between the clumps of compact chromatin, as was previously found in epithelial endometrial cells. These results suggest that estradiol exerts its effects through a common nuclear mechanism in cells of male and female reproductive and non-reproductive organs.     

Different sensitivity of chromatin to acid denaturation in quiescent and cycling cells as revealed by flow cytometry.

The properties of DNA in situ as reflected by its staining with acridine orange are different in quiescent nonstimulated lymphocytes as compared with interphase lymphocytes that have entered the cell cycle after stimulation by mitogens. The difference is seen after cell treatment with buffers at pH 1.5 (1.3-1.9 range) followed by staining with acridine orange at pH 2.6 (2.3-2.9). Under these conditions the red metachromatic fluorescence of the acridine orange-DNA complex is higher in quiescent cells than in the cycling lymphocytes while the orthochromatic green fluorescence is higher in the cycling, interphase cells. The results suggest that DNA in condensed chromatin of quiescent lymphocytes (as in metaphase chromosomes) is more sensitive to acid-denaturation than DNA in dispersed chromatin of the cycling interphase cells. The phenomenon is used for flow cytometric differentiation between G0 and G1 cells and between G2 and M cells. In contrast to normal lymphocytes the method applied to neoplastic cells indicates the presence of cell subpopulations with condensed chromatin but with DNA content characteristic not only of G1 but also of S and G2 cells. The possibility that these cells represent quiescent (resting) subpopulations, arrested in G1, S and/or G2, is discussed.     

Female reproductive cycles in two subspecies of the tropical lizard Mabuya striata

Summary Female reproductive cycles were examined in two subspecies of the live-bearing lizard Mabuya striata from Central Africa, an area with distinct rainy and dry seasons. The low altitude M. s. striata was reproductive throughout the year apart from a brief period at the start of the rainy season, and probably produced three clutches a year. Most females of the high altitude M. s. punctatissima were non-reproductive in the rainy season, came into reproductive condition in the early dry season, and gave birth in the late dry season. For some females, there was a second reproductive cycle starting in the late dry season with birth in the rainy season. For the low altitude M. s. striata it appears that availability of moisture may affect reproduction. For the high altitude M. s. punctatissima it appears that the low temperatures and short hours of sunshine of the early dry season constrain reproduction, and that reproductive cycles are timed to avoid birth occurring in the early dry season.     

Prep1 (pKnox1) Regulates Mouse Embryonic HSC Cycling and Self-Renewal Affecting the Stat1-Sca1 IFN-Dependent Pathway

A hypomorphic Prep1 mutation results in embryonic lethality at late gestation with a pleiotropic embryonic phenotype that includes defects in all hematopoietic lineages. Reduced functionality of the hematopoietic stem cells (HSCs) compartment might be responsible for the hematopoietic phenotype observed at mid-gestation. In this paper we demonstrate that Prep1 regulates the number of HSCs in fetal livers (FLs), their clonogenic potential and their ability to de novo generate the hematopoietic system in ablated hosts. Furthermore, we show that Prep1 controls the self-renewal ability of the FL HSC compartment as demonstrated by serial transplantation experiments. The premature exhaustion of Prep1 mutant HSCs correlates with the reduced quiescent stem cell pool thus suggesting that Prep1 regulates the self-renewal ability by controlling the quiescence/proliferation balance. Finally, we show that in FL HSCs Prep1 absence induces the interferon signaling pathway leading to premature cycling and exhaustion of fetal HSCs.     

A Method For Measuring the Generation Time and Length of Dna Synthesizing Phase of Clonogenic Cells In A Heterogenous Population

Information on the cell cycle of progenitor cells in haemopoietic tissue is useful for understanding population control under physiological and abnormal conditions. Unfortunately, methods that have been developed for measuring cell cycle parameters are applicable only to cells of homogenous populations and not to morphologically non-recognizable progenitor cells such as colony forming units (CFU) that are present at low frequency in a heterogenous population. to circumvent this difficulty, a method was developed to measure CFU cell cycle parameters based on specific killing of cells in S phase by [³H]thymidine ([³H]TdR). This was done by estimating the number of CFU killed following exposure of the cell suspension to [³H]TdR for various time periods. Since cycling CFU are continuously entering S phase, a linear curve relating the percentage CFU-kill to the length of exposure of the cells to [³H]TdR in culture can be obtained. the slope of the curve (percentage kill/hr) indicates the rate that CFU enter the S phase and travel through the cell cycle. the inverse of this value will then represent a time period for CFU to move through a complete cell cycle (generation time). the length of S phase can then be obtained by multiplying generation time by the fraction of cells in S phase at time zero. This method has been used to measure generation time and length of S phase of three kinds of haemopoietic progenitor cells: mouse granulocyte-macrophage CFU, human T lymphocyte CFU and CFU from regenerating mouse spleens. This method should be applicable to any normal or neoplastic clonogenic cell populations and the latter could be either of haematological or of solid tumour origin.     

The interstitial cells of the trout testis (Oncorhynchus mykiss): ultrastructural characterization and changes throughout the reproductive cycle

The major non-vascular cell types present in the interstitial compartment in trout testes have been ultrastructurally characterized and cell changes in the course of the two first reproductive cycles have been studied. Three major cell types are always present fibroblasts, myoid cells and Leydig cells. Their structure varies with the maturational stage of the gonad. Fibroblasts are centrally located in the interstitial areas. Numerous typical myoid cells are always present near the basal lamina. However, at the end of a cycle some of them display degenerative changes, then disappear. At the beginning of the next cycle, fibroblasts appear to differentiate to new myoid cells. Leydig cells present before the start of the first spermatogenesis are replaced by new ones which probably also arise from fibroblasts. These cells progressively differentiate during spermatogenesis, so that most of the Leydig cells present during the spermiation phase are fully-differentiated steroidogenic cells. At the end of a cycle, a certain number of the Leydig cells disappear and are replaced at the beginning of the next cycle by new ones most likely derived from fibroblasts. The remaining Leydig cells dedifferentiate to cells which may redifferentiate during gonadal activity. Macrophages are present mostly at the end of a cycle and participate at this time in the removal of dead interstitial cells. In conclusion, at least some fibroblast-like cells are precursor cells, able to replace myoid cells and Leydig cells which disappear between two consecutive reproductive cycles.     

动物生殖抑制研究进展：理论模型、方式和机制

生殖抑制指原本具有生育能力的动物个体因特定外界环境或生理条件而减少或丧失生殖能力的现象,有时是受环境变化的主动调控,更多的是出现在其他个体影响下的被动抑制,极端情况发生在社会性动物的永久性抑制,即永久无法生殖或无法生殖成熟。研究发现非社会性动物也有生殖的推迟及可恢复性的生殖抑制,生殖抑制影响着动物种群数量动态、维持和进化。随着多学科的发展,生殖抑制机理研究取得了诸多进展。从阐述生殖抑制的概念出发,解析生殖抑制的形态、激素和分子生理特征,总结了生殖抑制的原因、作用,终述现有的理论模型以及不同物种方面的最新进展,并就生殖抑制在生物资源管理方面的应用价值进行了展望,旨在丰富生殖抑制的理论,扩展应用实践,为后续的生物资源管理提供理论参考。     

Splenic lymphocytes of adult Xenopus respond differentially to PMA in vitro by either dying or dividing: significance for cancer resistance in this species

Wild-type populations of amphibians, unlike mammalians, appear to be resistant to spontaneous and chemically induced neoplasms. Few true cancers have been reported for non-isogeneic members of Xenopus laevis, despite their widespread use in laboratories around the world. Injection of even the most powerful direct mammalian oncogens e.g. N-methyl N-nitrosourea, that depleted specific populations of T lymphocytes, did not induce cancer. Phorbol diesters, e.g. PMA, are mitogens and apoptogens in both amphibian, and mammalian immunocytes. In mammalian cells, regulation of the cell cycle and of apoptosis are often intimately linked, however, a disjunction in time between early apoptosis and later cell cycling, has been observed with PMA-treated Xenopus splenocytes. Thus, a particular difference between amphibians and mammals may be the requirement to enter the cell cycle before a progression to death by apoptosis. This hypothesis was tested here using dual staining flow cytometry. Xenopus laevis splenocytes were cultured for 8, 24 and 48 hours with phorbol 12-myristate 13-acetate (PMA), previously shown to be mitogenic and apoptotic with mature Xenopus lymphocytes. The cells were stained with FITC-conjugated Annexin V or with FITC-labeled deoxyuridine triphosphates (FITC-dUTP) to assay for the apoptotic markers phosphotidylserine or DNA strand breaks respectively. Phycoerythrin (PE)-conjugated anti-human proliferating cell nuclear antigen (PE-PCNA) was used as a cell cycle marker that is present during the entire cell cycle. Propidium iodide (PI) binds DNA and was used to assay for late stage apoptosis, as well as to assess DNA content.Significantly higher levels of apoptosis develop rapidly in PMA-exposed splenocytes and are maintained at 24 hours, declining by 48 hours. Cells expressing PCNA or incorporating PI in excess of the normal genomic level were found by 48 hours following PMA exposure. The absence of any significant rise in a small (<5%) dual staining cell population indicates that the apoptotic cell population remained distinct from cells already in the cell cycle from the onset of PMA exposure. Thus, Xenopus splenocytes respond differentially to PMA. Those that undergo apoptosis rapidly were quiescent, non-cycling small lymphocytes. Moreover, the cells that eventually begin division, following PMA exposure, were unaffected by the early apoptois and do not themselves die while in the cell cycle. The rapid apoptotic response of X. laevis cells to PMA may confer a natural cancer resistance in this species, as cells that fail to enter the cell cycle after exposure to cancer promoting reagents cannot express genetic destabilization that might have led to transformation.     

Preferential association of irreversibly silenced E2F-target genes with pericentromeric heterochromatin in differentiated muscle cells

The heterochromatin-associated H3K9 tri-methylase Suv39h1 is involved in the permanent silencing of E2F target genes in differentiating but not in quiescent cells. Here, we tested the hypothesis that permanent silencing of E2F target genes is associated with their subnuclear positioning close to the pericentromeric heterochromatin compartment, enriched in Suv39h1. Using fluorescence in situ hybridization, we analyzed the subnuclear localization of three E2F target genes relative to the pericentromeric heterochromatin, in cycling fibroblasts or differentiating myoblasts. We observed that all three E2F-target genes have a tendency to relocate closer to the pericentromeric heterochromatin, only when cells differentiate and undergo an irreversible cell cycle withdrawal. These data suggest that repression of E2F target genes in cycling or in differentiating cells is achieved through distinct mechanisms. In differentiating cells, permanent silencing is driven by a Suv39h1-dependent H3K9 tri-methylation and positioning close to the heterochromatin compartment, whereas repression in cycling cells seems independent from subnuclear positioning and requires distinct H3K9 methylation levels.     

Evidence for differences in the mechanism of cell cycle arrest between senescent and serum-deprived human fibroblasts: Heterokaryon and metabolic inhibitor studies

It has previously been shown that serum-deprived, early passage quiescent human diploid fibroblastlike (HDFL) cells are able to inhibit cycling cells from entry into DNA synthesis upon cell fusion. We have found that the degree of inhibition of DNA synthesis in the heterokaryon correlates with the duration of serum deprivation, which is consistent with the suggestion that serum-deprived cells may enter progressively deeper stages of G₀ as they increase their time in quiescence. In contrast to fusions with senescent cells, in heterokaryons between serum-deprived early passage and cycling young cells transient inhibition of protein synthesis with cycloheximide or inhibition of RNA synthesis with 5–6-dichloro-1-β-D-ribofuranosyl benzimidazole (DRB) did not stimulate nuclear [₃H]-thymidine incorporation. These results suggest that differences may exist in the mechanisms responsible for inhibiting cell cycle progression in senescent vs early passage quiescent HDFL cells.