OXYGEN TENSION AND THE RATES OF MITOSIS AND INTERPHASE IN ROOTS

The object of this work was to determine the influence of a wide range of oxygen tensions upon the relative rates of respiration, mitosis, and interphase in pea root tips, compared with the normal rates of these processes in air. From the rates of disappearance of mitotic figures in excised tips kept in various oxygen tensions, the relative rates of mitosis were found to decrease gradually from 122 per cent in 100 per cent oxygen to 24 per cent in 0.0007 per cent oxygen. From the mitotic indices of intact seedlings, the relative rates of interphase were found to decrease sharply from 82 per cent in 10 per cent oxygen to 6 per cent in 5 per cent oxygen. The data on relative rates of respiration, mitosis, and interphase in root tips were compared, and it was shown that the three processes are perfectly distinct in their quantitative relationships to low oxygen tensions.     

DNA SYNTHESIS AND MITOSIS IN ERYTHROPOIETIC CELLS

Studies of newt (Triturus or Diemictylus viridescens) erythropoietic cells showed that DNA synthesis and mitosis normally occur throughout most of the developmental process. Mitotic divisions were found in all immature precursor stages from the proerythroblast to the highly hemoglobinized reticulocyte. Mitoses were absent in mature erythrocytes. Radioautographic examination of thymidine-³H incorporation into DNA revealed that all erythroid cells except the mature erythrocyte were labeled. Microphotometric measurements of Feulgen-stained smears showed that all immature stages were undergoing DNA synthesis whereas the mature erythrocyte was inactive. The results obtained from three independent methods clearly demonstrate that (a) no loss of DNA or of chromosomes occurs during erythrocytic development and (b) highly hemoglobinized and, therefore, well-differentiated cells normally do undergo DNA synthesis and mitosis.     

DNA SYNTHESIS AND MITOSIS IN MERISTEMS: REQUIREMENTS FOR RNA AND PROTEIN SYNTHESIS

Following provision of sucrose to starved, stationary phase pea root meristems, G₁ and G₂ cells enter DNA synthesis and mitosis, respectively. Puromycin (450 μg/ml) and cycloheximide (5 μg/ml) completely prevent this initiation of progression through the cell cycle. Actinomycin D (10 μg/ml) has no effect on the initial entry of G₁ and G₂ cells into S and mitosis, although later entry is prevented. The resistance of the cells to actinomycin D is lost slowly with time in medium without sucrose, suggesting that an RNA required for the resumption of proliferative activity is being gradually lost. The effects of the inhibitors on transitional and proliferative phase meristem cells indicate that such dividing cells do indeed have sufficient of the requisite RNA for 8-12 hr progression through the cycle, but that protein synthesis is required continuously. It is suggested that this RNA is the one lost slowly during starvation, allowing starved cells to reinitiate progression through the cycle in the presence of actinomycin D.     

SYNTHESIS OF RNA IN MAMMALIAN CELLS DURING MITOSIS AND INTERPHASE

Chinese hamster cells in the mitotic and G₁ phases of the growth cycle were incubated for 30 or 60 min in suspension tissue culture and pulse-labeled with tritiated uridine. After appropriate chases, washes, and extractions, it was found that all incorporation into the nucleic acid may be accounted for by those cells in interphase. An average of 410 counts was found for incorporation into the cell population (approximately 2.0 x 10⁵ cells) of which over 80% of the cells was initially in mitosis. The increasing number of cells leaving mitosis and entering interphase during the 30 min incubation was theoretically able to account for 470 counts. In addition, short-pulse labeling experiments have shown a consistent linear relationship between the percentage of cells in division and the incorporation of the isotope, which strongly suggests that, if 100% of the cells were in mitosis, the counts would be essentially zero. Thus, the entire label may be attributed to those cells in interphase where portions of the chromosomal material are known to be already extended.     

DNA SYNTHESIS, MITOSIS, AND DIFFERENTIATION IN PANCREATIC ACINAR CELLS IN VITRO

Pieces of mouse embryonic pancreatic epithelium cultured in an inductive situation in vitro, or when examined at critical times in vivo, show a gradient of zymogen granule accumulation. Cells located internally in explants, or in central acini in vivo, show this overt differentiation first. As the epithelia age, the more peripheral cell population proceeds in a similar differentiation. Observations of autoradiograms of H³-thymidine-labeled tissues indicate that the first cells which cease incorporating the DNA-precursor are in the central regions that differentiate first. In older explants, thymidine incorporation is largely restricted to the periphery of the tissue as zymogen appears in the internal cells. Evidence suggests that cells or nuclei which have replicated DNA move inward before dividing. Some daughter cells apparently return peripherad to divide again, whereas others remain centrally where they undergo differentiation. During at least the first 24 hours of these maturational changes, mesenchyme has a stimulatory effect upon epithelial thymidine-incorporation frequencies. The presence of a post-DNA-synthetic population is seen in the form of a group of nonlabeling central cells that remains intact in the midst of a labeled epithelium for as long as 48 hours in vitro (from 72 to 120 hours). If explants are treated with 5-bromodeoxyuridine for any 24-hour segment of the 0 to 72-hour period, before the non-incorporating population arises, no subsequent overt zymogen formation occurs. If explants are treated continuously from 72 to 120 hours, on the other hand, zymogen still forms in some internal cells. Presumably, this differentiation is limited to the postmitotic population as revealed in the thymidine autoradiograms.     

RIBONUCLEIC ACID SYNTHESIS DURING MITOSIS AND MEIOSIS IN THE MOUSE TESTIS

The pattern of ribonucleic acid synthesis during germ cell development, from the stem cell to the mature spermatid, was studied in the mouse testis, by using uridine-H³ or cytidine-H³ labeling and autoradiography. Incorporation of tritiated precursors into the RNA occurs in spermatogonia, resting primary spermatocytes (RPS), throughout the second half of pachytene stage up to early diplotene, and in the Sertoli cells. Cells in leptotene, zygotene, and in the first half of pachytene stage do not synthesize RNA. No RNA synthesis was detected in meiotic stages later than diplotene, with the exception of a very low rate of incorporation in a fraction of secondary spermatocytes and very early spermatids. At long intervals after administration of the tracer, as labeled cells develop to more mature stages, late stages of spermatogenesis also become labeled. The last structures to become labeled are the residual bodies of Regaud. Thus, the RNA synthesized during the active meiotic stages is partially retained within the cell during further development. The rate of RNA synthesis declines gradually with the maturation from type A to intermediate to type B spermatogonia and to resting primary spermatocytes. "Dormant" type A spermatogonia synthesize little or no RNA. The incorporation of RNA precursors occurs exclusively within the nucleus: at later postinjection intervals the cytoplasm also becomes labeled. In spermatogonia all mitotic stages, except metaphase and anaphase, were shown to incorporate uridine-H³. RNA synthesis is then a continuous process throughout the cell division cycle in spermatogonia (generation time about 30 hours), and stops only for a very short interval (1 hour) during metaphase and anaphase.     

PROTEIN SYNTHESIS AND RNA SYNTHESIS DURING MITOSIS IN ANIMAL CELLS

Protein synthesis and RNA synthesis during mitosis were studied by autoradiography on mammalian tissue culture cells. Protein synthesis was followed by incubating hamster epithelial and human amnion cells for 10 or 15 minutes with phenylalanine-C¹⁴. To study RNA synthesis the hamster cells were incubated for 10 minutes with uridine-C¹⁴. Comparisons of the synthetic capacity of the interphase and mitotic cells were then made using whole cell grain counts. The rate of RNA synthesis decreased during prophase and reached a low of 13 to 16 per cent of the average interphase rate during metaphase-anaphase. Protein synthesis in the hamster cells showed a 42 per cent increase during prophase with a subsequent return to the average interphase value during metaphase-anaphase. The human amnion cells showed no significant change at prophase but there was a 52 to 56 per cent drop in phenylalanine incorporation at metaphase-anaphase as compared to the average interphase rate. Colcemide was used on the hamster cells to study the effect of a prolonged mitotic condition on protein and RNA synthesis. Under this condition, uridine incorporation was extremely low whereas phenylalanine incorporation was still relatively high. The drastic reduction of RNA synthesis observed under mitotic conditions is believed to be due to the coiled condition of the chromosomes. The lack of a comparable reduction in protein synthesis during mitosis is interpreted as evidence for the presence in these cells of a relatively stable messenger RNA.     

PARTICIPATION OF A NON-RESPIRATORY FERROUS COMPLEX DURING MITOSIS IN ROOTS

A systematic survey was undertaken, of the effects of carbon monoxide and hydrogen cyanide (in the presence of 20 per cent oxygen), in darkness and light, on the relative rates of respiration, mitosis, and interphase in pea root tips. The inhibition of respiration by carbon monoxide was light-sensitive, but the inhibition by hydrogen cyanide was light-stable. The inhibitions were presumably due to combination of the inhibitor with the iron of cytochrome oxidase, in its divalent and trivalent forms respectively. In contrast, the inhibitions of mitosis by both poisons proved to be light-sensitive. The light-sensitive inhibition of mitosis by carbon monoxide shows that an iron complex is responsible for the process. That the inhibition of mitosis by hydrogen cyanide is also light-reversible shows that, in contrast with cytochrome oxidase, the mitotic iron complex remains always in the divalent state. The relative affinities of the mitotic ferrous complex, in molar units, were 0.68 for CO/O₂, and 0.37 for HCN/O₂. The properties of the complex are analogous to, yet distinct from, Gastrophilus haemoglobin and reduced cytochrome oxidase. It is considered that the arrest of mitosis by oxygen lack, carbon monoxide, and hydrogen cyanide is definitely due to interference with this unidentified, non-respiratory ferrous complex.     

增殖的淋巴细胞中DNA合成和DNA含量的分析

体外培养受PHA刺激的人淋巴细胞经~3H-TdR参入0、0.5、2、4、7和17小时后,放射自显术表明标记指数为0%、1.90%、9.15%、13.14%、15.01%和30.13%。未标记细胞的福尔根光密度为15.42、15.45、14.88、13.77、13.20和12.94。DNA分布直方图显示部分未标记细胞介于2C—4C,表明S期细胞的DNA合成可能是不连续的。对同位素参入17小时的标记细胞连续进行两项测量表明,这些细胞的银粒光密度相差悬殊,但其DNA含量均为2C—4C。细胞的DNA合成率随其DNA含量而增高。     

MITOSIS, CELL WALL AND FLAGELLA SYNTHESIS IN SYNCHRONIZED CULTURES OF THE PRASINOPHYTE, SCHERFFELIA DUBIA

Cell division occurs within the parental cell wall, yielding two progeny cells. Since Scherffelia dubia sheds all four flagella prior to cell division, the maturing progeny cells must regenerate new cell walls and flagella during and/or after cytokinesis. To better understand these processes, we have synchronized cell division in cultures of S. dubia and observed all stages of mitosis, cytokinesis, and progeny cell maturation, including flagella and cell wall formation, via DAPI staining of fixed cells, DIC microscopy of live cells embedded in agarose and standard TEM. Microscopical observations revealed the following sequence of events: 1) Golgi stacks divide during late interphase and immediately begin producing theca scales; 2) deflagellation and release of the parental cell wall from the plasma membrane occurs during early prophase; 3) synthesis of theca and flagella scales within the Golgi and/or scale reticulum continues throughout mitosis; 4) during cytokinesis, a coalescence of vesicles containing theca scales at the posterior end of the cell results in a cleavage furrow slightly diagonal to the cells' longitudinal axis (40 min); 5) post-mitotic nascent basal body formation and flagella elongation at the inherited basal bodies (and later at the mature nascent basal bodies) occurs concurrently with continued cell wall synthesis; 6) the cleavage furrow rotates into a transverse position (35 min); 7) reorientation of the nuclei results in a "head to tail" orientation of the maturing progeny cells; and 8) matured progeny cells emerge from the posterior end of the parental theca not before 8 hrs after the onset of mitosis.     

似金隐藻有丝分裂及胞质分裂的观察

似金隐藻(Cryptomonas chrysoidea)是从青岛附近渤海湾海水中分离得到的一种单细胞藻类。对它的胞质分裂和有丝分裂进行的观察表明,它的胞质分裂在有丝分裂的中期开始,细胞前端沟口处先开始分裂,继而沿纵轴纵沟处形成一收缩沟完成的。似金隐藻的有丝分裂过程中没有染色体和着丝点形成;核膜进入中期时完全消失,纺锤体呈桶状,微管通过染色质团中的通道或直接与染色质团块相联;在后期和末期,两块分开的染色质团十分靠近相应的色素体内质网膜。本文对其分裂过程进行了讨论。     

MITOSIS AND THE PROCESSES OF DIFFERENTIATION OF MYOGENIC CELLS IN VITRO

The relation between the mitotic cycle and myoblast fusion has been studied in chick skeletal muscle in vitro. The duration of the cell cycle phases was the same in both early and late cultures. By tracing a cohort of pulse-labeled cells, it was found that myoblast fusion does not occur in S, G₂, or M. Cell surface alterations required for fusion are dependent upon the position of the cell in the division cycle. In early cultures, fusion takes place only after a minimum delay of 5 hr from the time the cell has entered G₁. The mitosis preceding fusion may condition the cell for the abrupt shift in synthetic activity that occurs in the subsequent G₁. In older cultures fusion of labeled cells is diminished. Two factors account for the cessation of fusion in older cultures. First, the number of myogenic stem cells declines, but these cells do not disappear as the cultures mature. Their persistence was demonstrated by labeling dividing mononucleated cells in older cultures and challenging them with nascent myotubes. Some of these labeled cells were incorporated into the forming myotubes. Second, a block to fusion develops during myotube maturation. Well developed myotubes challenged with labeled competent myogenic cells failed to incorporate the labeled nuclei.