Differentiation of Vascular Tissue and Quiescent Centre in the Root Apex of Glycine max (L.) Merr

The differentiation of primary vascular tissue and the development of quiescent centre in the primary root apex of Glycine max (L.) Merr. were observed. The quiescent centre in soybean primary root originated 24 hours after germination, in size to a maximum, and studied by means of [3H]thymidine autoradiography. The height of quiescent centre gradually decreased with an increase of days and was cor- related with the diameter of the root (r=0.94 p=0.01). By the mierodensitometer, most of the cells of quiescent centre are at the 2c level of DNA content and that are in G1. We find that no possible direct relationship between the quiescent centre and the differentiation of vascular tissue of soybean primary root was revealed. The former may not regulate the latter.     

The Proportion of Cells that Divide in Root Meristems of Zea mays L.

The proportion of cells that divide in four regions of the rootmeristem of Zea mays has been determined by an analysis of itscells pulse-labelled with tritiated thymidine. In the quiescent centre less than half of the cells divide andthe fastest of these (less than half of them) have a mitoticcycle duration of about 40 h at 23 °C compared with a cell-doublingtime of 230 h for the region. In the cap initials 80–90per cent of the cells divide and about 80 per cent of thesedivide once in 10 h. In the stele about 80 per cent of cellsdivide near the quiescent centre and all divide at 200 µmfrom the quesecent centre. The fast cells divide every 14 hin both regions, but the cell-doubling time increases from 18to 25 h near the quiescent centre. The root cap is completely replaced by its initials every dayand 10 000 cells are sloughed off. The rest of the meristemadds about 170 000 cells to the root every day. These figures are discussed in relation to the role of the quiescentcentre and the control of cell division.     

An excision and squash technique for analysis of the cell cycle in the root quiescent centre of maize

The quiescent centre of primary roots of Zea mays L. (cvs LG 11 and Golden Bantam) consists of a population of slowly cycling diploid cells. These metabolically inactive cells may be triggered to synthesise DNA under specific conditions and constitute a good model for studying the regulation of the cell cycle. An excision and squash technique is described for the quiescent centre which, when coupled with Feulgen and fluorochrome staining, allows nuclear DNA contents to be determined by microdensitometry in less than a day. This technique was coupled with experiments in which excised quiescent centres were placed on solid culture medium into which hormones and radioactive DNA precursors were incorporated. In complementary and control experiments [methyl-³H]thymidine was supplied to intact roots (with or without root caps) by means of fibre-glass cubes as donors.
Progression of the cell cycle was followed by microdensitometry and autoradiography. Distribution of DNA content was similar in excised and squashed quiescent centres and in histological sections. Labelling experiments showed that the quiescent centre is made up of cells that differ in their cycle time. While some labelled cells had reached mitosis after 8 h, others were still in G₂ after 16 h of continuous labelling. Excision and culture of the quiescent centre resulted in a dramatic activation of the cell cycle as shown by the labelling index that increased from 15% in intact roots fed during 16 h with [methyl-³H]thymidine to 31% in excised quiescent centres to which radioactive precursor was supplied during the same time. Supplying hormones (50 μ M abscisic acid [ABA], 0. 1 μ M zeatin, 1 μ M zeatin riboside) to quiescent centres via the culture medium restored their inactivity (labelling indices dropped to 1% after ABA. and to 11% after zeatin and zeatin riboside treatments. respectively).     

Organelle DNA Synthesis in the Quiescent centre of Arabidopsis thaliana (Col.)

The behaviour of cell nuclei and organelle nucleoids (organellenuclei) was studied in the root apical meristem of 3-d-old seedlingsof Arabidopsis thaliana (Col.). Samples were embedded in Technovit7100 resin, cut into thin sections and stained with 4'-6-diamidino-2-phenylindole(DAPI) for observation of DNA. DNA synthesis in cell nucleiand organelle nucleoids was investigated using the incorporationof [³H] thymidine or 5-bromo-2'-deoxyuridine (BrdU). Incorporated[³H] thymidine and BrdU were detected by microautoradiographyor immunofiuorescence microscopy, respectively. Central cellsand cells just above the central cells of the quiescent centre(QC) showed an extremely low activity of DNA synthesis. However,DNA synthesis occurred in at least one organelle nucleoid ofall cells in the QC within 24 h. This suggests the cells inthe QC are quiescent with regard to nuclear DNA synthesis, butnot with regard to the organelle nucleoids. Key words: Arabidopsis thaliana, quiescent centre, root apical meristem, mitochondrial nucleoid (nuclei), plastid nucleoid (nuclei)     

Mitochondrial deoxynucleotide pools in quiescent fibroblasts: a possible model for mitochondrial neurogastrointestinal encephalomyopathy (MNGIE)

Mitochondrial (mt) DNA depletion syndromes can arise from genetic deficiencies for enzymes of dNTP metabolism, operating either inside or outside mitochondria. MNGIE is caused by the deficiency of cytosolic thymidine phosphorylase that degrades thymidine and deoxyuridine. The extracellular fluid of the patients contains 10-20 microM deoxynucleosides leading to changes in dTTP that may disturb mtDNA replication. In earlier work, we suggested that mt dTTP originates from two distinct pathways: (i) the reduction of ribonucleotides in the cytosol (in cycling cells) and (ii) intra-mt salvage of thymidine (in quiescent cells). In MNGIE and most other mtDNA depletion syndromes, quiescent cells are affected. Here, we demonstrate in quiescent fibroblasts (i) the existence of small mt dNTP pools, each usually 3-4% of the corresponding cytosolic pool; (ii) the rapid metabolic equilibrium between mt and cytosolic pools; and (iii) the intra-mt synthesis and rapid turnover of dTTP in the absence of DNA replication. Between 0.1 and 10 microM extracellular thymidine, intracellular thymidine rapidly approaches the extracellular concentration. We mimic the conditions of MNGIE by maintaining quiescent fibroblasts in 10-40 microM thymidine and/or deoxyuridine. Despite a large increase in intracellular thymidine concentration, cytosolic and mt dTTP increase at most 4-fold, maintaining their concentration for 41 days. Other dNTPs are marginally affected. Deoxyuridine does not increase the normal dNTP pools but gives rise to a small dUTP and a large dUMP pool, both turning over rapidly. We discuss these results in relation to MNGIE.     

The Response of the Primary Root Meristem of Zea mays L. to Various Periods of Cold

Primary roots of maize (Zea mays L.) grown in nutrient solutionat 5?C elongate at about 1% of the rate found at 20?C. The apicalmeristem becomes shorter and shows little proliferative activityat 5?C, but following transfer to 20?C mitoses increase in frequencyand the meristem regrows to its original length. Both the amountby which the meristem shortens and the time for its completeregrowth are related to the period spent at 5?C. The shorteningof the meristem suggests that at the lower temperature the balancewhich normally exists between cell production and differentiationis altered, the latter continuing at a relatively faster ratethan the former. A new, steady-state balance between the twoprocesses is re-established during the recovery period. Themeristem recovers as a result not only of its own mitotic activitybut also through stimulation of cell division in the quiescentcentre. The degree to which the quiescent centre is activated,as judged by its mitotic index and the number of nuclei labelledby feeding with tritiated thymidine, increases as the durationof the preceding cold treatment increases. The close relationshipbetween proliferative activity in the quiescent centre and theminimum length of the meristem following the cold treatmentsuggests that there is communication between these two zoneswhich co-ordinates their respective rates of cell productionand helps to maintain a normal meristem structure. The resultsemphasize the importance of the quiescent centre as a reservoirof cells that can re-establish a meristem rendered non-functionalthrough the impact of unfavourable environmental conditions. Key words: Meristem, quiescent centre, root, temperature, Zea mays     

The Quiescent Centre and Rates of Mitosis in the Root Meristem of Allium sativum

The root apices of Allium sativum have been examined by continuous-and pulse-labelling with tritiated thymidine and by colchicinetreatment to measure the time parameters of the mitotic cyclein various parts of the meristem. There is a quiescent centre of 30–50 cells whose averagerate of mitosis is low because the G₁ period is extended toabout 140 h compared with about 4 h in the othe regions of themeristem. The stele just above the quiescent centre and at 200microns above it and the cap initials just below the quiescentcentre are very similar in their mitotic cycles, the total lengthsof which are about 30 h of which nearly half is taken up byDNA synthesis. Allium thus differs from Zea in having root capinitials whose mitotic cycle is not telescoped by the eliminationof the G₁ phase. These facts are discussed in relation to theradiosensitivity of the meristem.     

A negative image of the quiescent centre in regenerating root apices of Zea mays

Usually the presence of the quiescent centre in roots is demonstrated by the absence of labelled nuclei following treatment of the root with appropriate radioactive markers. By modification of the pulselabelling technique, a negative image of the quiescent center, showing more intense labelling from [³H]thymidine than the surrounding area, was obtained in regenerating root apices of Zea mays L.     

Duration of the Mitotic Cycle in a Meristem

The length of the mitotic cycle and the time spent in mitosisare calculated for six regions of the apical meristem of rootsof Zea. The two methods used are the measurement of the ratesof labelling nuclei with radioactive thymidine and the ratesof accumulation of metaphases in roots grown in colchicine.The mitotic cycle lasts from 12 hours in the cap initials toabout 200 hours in the quiescent centre of the same roots. Somepoints about the organization of apices are discussed in thelight of these estimates.     

Exogenous thymidine is preferentially incorporated into human cytomegalovirus DNA in infected human fibroblasts.

The effect of human cytomegalovirus infection on cellular DNA synthesis in human fibroblasts was measured by fluorometry and by incorporation of radiolabeled thymidine. The results show that although HCMV infection stimulates cellular DNA synthesis in both quiescent and serum-stimulated cells, radiolabeled thymidine is almost exclusively incorporated into viral DNA.     

Double-stranded RNA regulation of DNA synthesis in fibroblasts.

The double-stranded RNA molecule polyinosinic-polycytidylic acid (poly IC) has been found in some studies to have a mitogenic effect on fibroblast proliferation while other studies found poly IC to have an inhibitory effect on proliferation. In this study, we investigated whether a stabilized form of poly IC complexed with poly-L-lysine and carboxymethylcellulose (poly ICLC) had a bidirectional effect on DNA synthesis in fibroblasts from four different cell lines and determined factors that potentially influence this bidirectional effect. In medium containing fetal bovine serum, poly ICLC slightly increased the levels of [3H]thymidine incorporation in growing fibroblasts in three of the four fibroblast cell lines tested, while poly ICLC increased [3H]thymidine incorporation in confluent, quiescent fibroblasts in two of four cell lines. Poly ICLC did not induce DNA synthesis in subconfluent, quiescent or in confluent, quiescent fibroblasts under serum-free conditions. Poly ICLC significantly suppressed serum-induced [3H]thymidine incorporation by quiescent fibroblasts in all cell lines. We conclude that the stimulatory and inhibitory effects of poly ICLC on DNA synthesis are influenced by both the cell line and the presence of serum components in the culture medium but not by population density.     

Mitochondrial DNA depletion and thymidine phosphate pool dynamics in a cellular model of mitochondrial neurogastrointestinal encephalomyopathy

Mitochondrial (mt) neurogastrointestinal encephalomyopathy (MNGIE) is an autosomal recessive disease associated with depletion, deletions, and point mutations of mtDNA. Patients lack a functional thymidine phosphorylase and their plasma contains high concentrations of thymidine and deoxyuridine; elevation of the corresponding triphosphates probably impairs normal mtDNA replication and repair. To study metabolic events leading to MNGIE we used as model systems skin and lung fibroblasts cultured in the presence of thymidine and/or deoxyuridine at concentrations close to those in the plasma of the patients, a more than 100-fold excess relative to controls. The two deoxynucleosides increased the mt and cytosolic dTTP pools of skin fibroblasts almost 2-fold in cycling cells and 8-fold in quiescent cells. During up to a two-month incubation of quiescent fibroblasts with thymidine (but not with deoxyuridine), mtDNA decreased to approximately 50% without showing deletions or point mutations. When we removed thymidine, but maintained the quiescent state, mtDNA recovered rapidly. With thymidine in the medium, the dTTP pool of quiescent cells turned over rapidly at a rate depending on the concentration of thymidine, due to increased degradation and resynthesis of dTMP in a substrate (=futile) cycle between thymidine kinase and 5'-deoxyribonucleotidase. The cycle limited the expansion of the dTTP pool at the expense of ATP hydrolysis. We propose that the substrate cycle represents a regulatory mechanism to protect cells from harmful increases of dTTP. Thus MNGIE patients may increase their consumption of ATP to counteract an unlimited expansion of the dTTP pool caused by circulating thymidine.     

Adenovirus type 5 induces progression of quiescent rat cells into S phase without polyamine accumulation.

Adenovirus type 5 induces cellular DNA synthesis and thymidine kinase in quiescent rat cells but does not induce ornithine decarboxylase. We now show that unlike serum, adenovirus type 5 fails to induce S-adenosylmethionine decarboxylase or polyamine accumulation. The inhibition by methylglyoxal bis(guanylhydrazone) of the induction of thymidine kinase by adenovirus type 5 is probably unrelated to its effects on polyamine biosynthesis. Thus, induction of cellular thymidine kinase and DNA replication by adenovirus type 5 is uncoupled from polyamine accumulation.     

X-Irradiation of Root Meristems

When roots of Zea mays are given heavy doses of X-rays the averagerate of mitosis at first falls in the normally meristematiccells and increases in the quiescent centre. Proliferation inthe quiescent centre gives rise to a new meristem which continuesthe growth of the root and which acquires a quiescent centreof its own. Observations on the micronuclei produced after irradiationsuggest that the quiescent centre is less sensitive to X-raysthan the rest of the meristem. It is probably this lower sensitivitycombined with the initial difference in time at which the radiationdamage to cell viability occurs that gives the quiescent centreits role in the recovery of the meristem.     

Fluridone affects quiescent centre division in the Arabidopsis thaliana root stem cell niche

Plants undergo cell division throughout their life in order to maintain their growth. It is well known that root and shoot tip of plants possess meristems, which contain quiescent cells. Fluridone (1-methyl-3-phenyl-5-(3-trifluoromethyl (phenyl))-4-(1H)-pyridinone) is an established inhibitor of both ABA and carotenoid biosynthesis. However, the other functions of fluridone remain undiscovered. In this report, we provide experimental evidence that fluridone plays a role in the division of the quiescent centre of the Arabidopsis root meristem. This study examined the effects of exogenous fluridone and ABA on the development of the stem cell niche in Arabidopsis root. We show that fluridone promoted the division of stem cells in the quiescent centre, whereas exogenous ABA suppressed quiescent centre division. Furthermore, we established a novel regulatory function for fluridone by demonstrating that it plays an important role in postembryonic development.     

大豆根尖维管组织分化和静止中心

用~3H-胸腺嘧啶核苷标记的自显影方法测定了大豆根尖的静止中心。结果表明在萌发后24小时产生,其高度为最大值,随着天数增加静止中心的高度逐渐减小。静止中心的高度与根的直径显著相关(r=0.94,p=0.01)。用显微光度计测定了静止中心细胞核的DNA 含量,大部分细胞在2c 水平,处在 G_1期。大豆根尖的静止中心与维管组织分化水平不相关,静止中心不直接控制维管组织的分化。     

The Quiescent Centre and Cell Determination in Roots of Pisum sativum

A combined autoradiographic and enzyme cytochemical study ofroot apices from Pisum sativum has permitted the demonstrationof a high naphthol AS-D esterase activity in the central groupof meristematic cells immediately outside the quiescent centre.This high naphthol AS-D esterase activity indicates an expressionof the programming of these cells to form elements of the stele.A consideration is given to the need for a quantal mitosis andof its possible occurrence in the quiescent centre. It is concludedthat the programming and mitotic activity may be two physiologicalevents which whilst occurring in the same cell, are not necessarilylinked events. Pisum sativum, roots, determination, quiescent centre, autoradiography, carboxylesterases     

A method to determine the displacement velocity field in the apical region of the Arabidopsis root

In angiosperms, growth of the root apex is determined by the quiescent centre. All tissues of the root proper and the root cap are derived from initial cells that surround this zone. The diversity of cell lineages originated from these initials suggests an interesting variation of the displacement velocity within the root apex. However, little is known about this variation, especially in the most apical region including the root cap. This paper shows a method of determination of velocity field for this region taking the Arabidopsis root apex as example. Assuming the symplastic growth without a rotation around the root axis, the method combines mathematical modelling and two types of empirical data: the published velocity profile along the root axis above the quiescent centre, and dimensions of cell packet originated from the initials of epidermis and lateral root cap. The velocities, calculated for points of the axial section, vary in length and direction. Their length increases with distance from the quiescent centre, in the root cap at least twice slower than in the root proper, if points at similar distance from the quiescent centre are compared. The vector orientation depends on the position of a calculation point, the widest range of angular changes, reaching almost 90°, in the lateral root cap. It is demonstrated how the velocity field is related to both distribution of growth rates and growth-resulted deformation of the cell wall system. Also changes in the field due to cell pattern asymmetry and differences in slope of the velocity profile are modelled.     

Experimental control of the activity of the quiescent centre in excised root tips of Zea mays

Summary Quiescent centres have been demonstrated in cultured excised root tips of both Pisum sativum and Zea mays. Upon addition of sucrose to Zea roots which have been deprived of carbohydrate, the cells of the quiescent zone as well as those of the rest of the meristem undergo DNA synthesis. Following the onset of proliferative activity in the meristem, DNA synthesis in the quiescent-centre cells is again arrested. It is suggested that the dividing cells of the meristem are responsible for the maintenance of the quiescent centre. It has also been shown that DNA-synthesising cells do occur within the quiescent centre and that they appear to be localised in specific regions.     

Quiescent mammary epithelial cells have reduced connexin43 but maintain a high level of gap junction intercellular communication

Gap junctions have been implicated in growth control, but it remains unclear whether cells that enter a quiescent state continue to express connexins and maintain a high level of gap junction intercellular communication (GJIC). To this end, MAC-T cells, a bovine mammary epithelial cell line, were serum starved for 48 h to induce a quiescent (G0) state. In quiescent cells, [3H]thymidine incorporation was reduced by 97.3% from serum-fed controls. Western blotting in conjunction with Phosphorlmager analysis revealed up to a 20-fold decrease in the expression of the gap junction protein connexin43 (Cx43 or alpha 1) and a shift toward the unphosphorylated form in quiescent cells. However, cell-to-cell transfer of the gap junction-permeable fluorescent tracer, Lucifer yellow, was only moderately reduced in quiescent cells. In control cells, Cx43 was predominantly perinuclear, although it was also present at sites of cell-cell apposition. In quiescent cells, intracellular labeling for Cx43 decreased without a corresponding reduction at areas of cell-cell contact. Recovery from serum deprivation resulted in increased thymidine incorporation that corresponded with an elevation in Cx43 protein expression and phosphorylation. In parallel studies, MAC-T cells were also induced to enter a quiescent state through contact inhibition. Despite a 20-fold reduction in 5-bromo-2'-deoxyuridine and a substantial reduction in intracellular Cx43, contact inhibited MAC-T cells also maintained gap junctions and GJIC. These experiments demonstrate that the maintenance of dye coupling in quiescent mammary cells is correlated with a redistribution of intracellular stores of Cx43.