Promotive and inhibitory effects of diverse arabinogalactan proteins on Daucus carota L. somatic embryogenesis

In the 3-d-old 2-mm root tip of Pisum sativum L. cv. Lincoln the percentage of actively proliferating cells is estimated to be 70%. The remaining cells are non-cycling and arrested with 2C and 4C DNA content in G₀ and in G₂Q, respectively. In this work we studied the kinetic significance of these quiescent cells, using the sorting capabilities of flow cytometry and immunofluorescence techniques to detect the proliferation marker PCNA (proliferating cell nuclear antigen) inside cells within the different cell-cycle compartments. While in animal cells, PCNA is present at a high level only in actively proliferating cells, in 3-d-old pea root tips 95% of the cells are PCNA-positive. After flow cytometry and sorting of pea non-cycling nuclear populations, all G₂Q nuclei appeared strongly PCNA-positive, indicating that these cells had recently left the cell cycle. By contrast, most G₀ nuclei showed a low level of PCNA immunofluorescence intensity, as measured by image analysis, with about 25% of the nuclei being PCNA-negative. This small percentage was found to correspond to root cap cells, as could be observed in the root tip section. These are the only cells in the root apical region which are fully differentiated and which, therefore, lack the competence to enter the cell cycle. In contrast, the more or less PCNA-positive G₀ nuclei could represent a kinetically heterogeneous population of cells competent to proliferate, but which have either recently left the cell cycle or are progressing to the G₀-G₁ transition. Received: 6 November 1996 / Accepted: 14 January 1997     

Change of chromatin morphology during the cell cycle detected by means of automated image analysis

Mouse embryo fibroblasts growing asynchronously in vitro stained with Feulgen method and their nuclear chromatin was analysed by means of the image analysing computer Quantimet 720D. Cells with 2C, 3C and 4C content of DNA were considered as being in G₁, middle S and G₂ phase of cell cycle, respectively. It was found that the projected area of nuclei increases during the cell cycle and that the mean optical density of chromatin increases from G₁ through S to G₂ phase. The curves showing the areas of chromatin at different optical density thresholds are different for cells in G₁, S and G₂ phase. The results demonstrate cyclic changes in chromatin morphology in the interphase nuclei during the cell cycle.     

Nuclear replication activities during imbibition of abscisic acid- and gibberellin-deficient tomato (Lycopersicon esculentum Mill.) seeds

The role of cis-abscisic acid (ABA) and gibberellins (GAs) in the induction of cell-cycle activities has been studied during imbibition and subsequent germination of tomato seeds. Using flow cytometry, nuclear replication activity was investigated in embryo root tips isolated from seeds of the ABA-deficient mutant sit ^w , the GA-deficient mutant gib-1, and the wild-type (MM) tomato (Lycopersicon esculentum Mill. cv. Moneymaker) upon imbibition in water, 10 μM GA₄₊₇, 5 μM ABA or 5 μM ABA+10 μM GA₄₊₇. The nuclei of fully matured dry MM, sit ^w and gib-1 seeds predominantly showed 2C DNA signals, indicating that the cell-cycle activity of most root-tip cells had been arrested at the G₁ phase of nuclear division. However, ABA-deficient sit ^w seeds contained a significantly higher amount of G₂ cells (4C DNA) compared with the other genotypes, suggesting that, during maturation, cell-cycle activity in sit ^w seeds is less efficiently arrested in G₁. Upon imbibition in water, an induction of the 4C signal, indicating nuclear replication, was observed in the root tip cells of both MM and sit ^w embroys. The augmentation in the 4C signal occurred before visible germination. Gib-1 seeds did not show cell-cycle activity and did not germinate in water. Upon imbibition in GA₄₊₇, both cell-cycle activity and subsequent germination were enhanced in MM and sit ^w seeds, and were induced in gib-1. In ABA, the germination of MM and sit ^w seeds was inhibited while nuclear replication of these seeds was not affected. It is concluded that GA influences germination by acting upon processes that precede cell-cycle activation, while ABA affects growth by acting upon processes that follow cell-cycle activation.     

Cell cycle regulation during growth-dormancy cycles in pea axillary buds

Accumulation patterns of mRNAs corresponding to histones H2A and H4, ribosomal protein genes rpL27 and rpL34, MAP kinase, cdc2 kinase and cyclin B were analyzed during growth-dormancy cycles in pea (Pisum sativum cv. Alaska) axillary buds. The level of each of these mRNAs was low in dormant buds on intact plants, increased when buds were stimulated to grow by decapitating the terminal bud, decreased when buds ceased growing and became dormant, and then increased when buds began to grow again. Flow cytometry was used to determine nuclear DNA content during these developmental transitions. Dormant buds contain G₁ and G₂ nuclei (about 3:1 ratio), but only low levels of S phase nuclei. It is hypothesized that cells in dormant buds are arrested at three points in the cell cycle, in mid-G₁, at the G₁/S boundary and near the S/G₂ boundary. Based on the accumulation of histone H2A and H4 mRNAs, which are markers for S phase, cells arrested at the G₁/S boundary enter S within one hour of decaptitation. The presence of a cell population arrested in mid-G₁ is indicated by a second peak of histone mRNA accumulation 6 h after the first peak. Based on the accumulation of cyclin B mRNA, a marker for late G₂ and mitosis, cells arrested at G₁/S begin to divide between 12 and 18 h after decapitation. A small increase in the level of cyclin B mRNA at 6 h after decapitation may represent mitosis of the cells that had been arrested near the S/G₂ boundary. Accumulation of MAP kinase, cdc2 kinase, rpL27 and rpL34 mRNAs are correlated with cell proliferation but not with a particular phase of the cell cycle.     

Proliferative capacity and DNA content of aging human diploid cells in culture: A cytophotometric and autoradiographic analysis

Using a combination of DNA-cytophotometry and tritiated thymidine-autoradiography, we have shown that the majority of nondividing cells in serially propagated human diploid cell populations have the 2C DNA content consistent with their being arrested in the G₁ phase of the diploid cell cycle. Unlabeled 4C cells appear increasingly with time in culture. These may be arrested G₂ diploids or they may be G₁ tetraploids, since there is an associated increase in polyploidy in older cultures as evidenced by the appearance of labeled 8C cells.     

Cell Cycle Activity and β-Tubulin Accumulation During Dormancy Breaking of Acer platanoides L. seeds

Cell cycle events in embryo axes of Norway maple (Acer platanoides L.) seeds were studied during dormancy breaking by flow cytometric analyses of the nuclear DNA content and by immunodetection of β-tubulin. Most embryonic nuclei of dry, fully matured seeds were arrested in the G₂ phase of the cell cycle. In addition, the lowest content of β-tubulin was detected in dry, mature seeds. Imbibition in water and cold stratification resulted in a decrease in the number of nuclei in G₂, and a simultaneous increase in β-tubulin content. In germinated seeds the content of β-tubulin was the highest and the number of cells in G₂ was the lowest. Both cell cycle events preceded cell expansion and division and subsequent growth of the radicle through the seed coat. The anatomical investigation has proved that the main reason for decrease in the number of nuclei in G₂ is mitosis, started with seeds germination (radicle protrusion). The activation of the cell cycle and the β-tubulin accumulation were associated with embryo dormancy breaking. This revised version was published online in July 2006 with corrections to the Cover Date.     

ON THE EXISTENCE OF 'ARRESTED G2 CELLS' IN MOUSE EPIDERMIS

It has been postulated that mouse epidermis contains two populations of resting cells, one of which is blocked at the G₁-S boundary and the other between G₂ and mitosis. the ‘arrested G₂ cells’ were estimated, by the labelled mitosis method, to comprise 510% of the epidermal population and presumed to function as a ‘reserve pool’ which could be activated by wounding. A comprehensive search has now been carried out for arrested G₂ cells in mouse epidermis using the direct methods of single cell and flow through cytophotometry. No evidence was obtained which supports the existence of such a cell compartment. Suitable control experiments were carried out to ensure that G₂ cells were not lost during the isolation of epidermal nuclei.     

Extra DNA synthesis in the dedifferentiating cells ofVicia faba roots

Summary Cell dedifferentiation was induced inVicia faba root tissues by removing the whole root meristem (decapitation) and the behaviour of the nuclear DNA in the dedifferentiating cells was studied by means of cytophotometric and autoradiographic analyses. Cytophotometric determination after Feulgen-staining showed that: 1. the vast majority of nuclei in differentiated cells were in the DNA postsynthetic phase, but their Feulgen absorption was lower than that of DNA postsynthetic nuclei (G₂, 4 C) in the meristem; 2. such a Feulgen absorption was detected in certain nuclei after root decapitation; 3. all the mitoses in the dedifferentiating tissues were diploid, fully matching the Feulgen absorption of mitoses in the meristem.After³H-thymidine (³H-T) feeding of the decapitated roots and autoradiography, the following results were obtained: 1. two populations of labeled nuclei, characterized by two different levels of scattered labeling occurred in dedifferentiating tissues, slightly labeled nuclei being much more numerous than heavily labeled nuclei; 2. the percentage of labeled nuclei was much greater than that of DNA presynthetic nuclei in the root tissues; 3. almost all the mitoses were labeled after a 16-hour³H-T feeding; 4. the percentage of slightly labeled nuclei paralleled that of dedifferentiating cells; 5. the duration of the DNA synthesis phase and that of the gap between completion of DNA synthesis and mitosis differed in heavily and slightly labeled nuclei; 6. all nuclei which entered DNA synthesis also entered mitosis.These results are interpreted to mean that: 1. after decapitation, two different DNA syntheses occur in the dedifferentiating root tissues ofV. faba: DNA reduplication in cells which dedifferentiate starting from a DNA presynthetic nuclear condition (heavily labeled nuclei) and extra DNA synthesis in cells which dedifferentiate starting from a DNA postsynthetic nuclear condition (slightly labeled nuclei); 2. extra DNA synthesis is required in these dedifferentiating cells for entry into mitosis.     

Cell cycle synchronization of leukemia inhibitory factor (LIF)-dependent porcine-induced pluripotent stem cells and the generation of cloned embryos

Nuclear transfer (NT) from porcine iPSC to create cloned piglets is unusually inefficient. Here we examined whether such failure might be related to the cell cycle stage of donor nuclei. Porcine iPSC, derived here from the inner cell mass of blastocysts, have a prolonged S phase and are highly sensitive to drugs normally used for synchronization. However, a double-blocking procedure with 0.3 μM aphidicolin for 10 h followed by 20 ng/ml nocodazole for 4 h arrested 94.3% of the cells at G₂/M and, after release from the block, provided 70.1% cells in the subsequent G₁ phase without causing any significant loss of cell viability or pluripotent phenotype. Nuclei from different cell cycle stages were used as donors for NT to in vitro-matured metaphase II oocytes. G₂/M nuclei were more efficient than either G₁ and S stage nuclei in undergoing first cleavage and in producing blastocysts, but all groups had a high incidence of chromosomal/nuclear abnormalities at 2 h and 6 h compared with non-synchronized NT controls from fetal fibroblasts. Many G₂ embryos extruded a pseudo-second polar body soon after NT and, at blastocyst, tended to be either polyploid or diploid. By contrast, the few G₁ blastocysts that developed were usually mosaic or aneuploid. The poor developmental potential of G₁ nuclei may relate to lack of a G₁/S check point, as the cells become active in DNA synthesis shortly after exit from mitosis. Together, these data provide at least a partial explanation for the almost complete failure to produce cloned piglets from piPSC.     

Nuclear DNA content of somatic and zygotic embryos ofVitis vinifera cv. Grenache noir at the torpedo stage

Summary A flow cytometric analysis and an in situ DNA microspectrophotometric study were made concomitantly to establish why somatic grapevine (Vitis viniferacv. Grenache noir) embryos showed a low level of conversion into plantlets. In somatic embryos at the torpedo stage and in zygotic embryos at the same stage of development, ploidy level, DNA content per 2 C nucleus, and the cell-cycle state of the shoot apical meristem were examined. The frequency distribution histograms of nuclear DNA values were similar in the two types of embryos. At the torpedo stage both types of embryos had a majority of nuclei with 2 C DNA content equal to 1.6pg. In the shoot apices of somatic and zygotic embryos, DNA microspectrophotometry showed preferential blockage of the cell cycle at the G_0–1 stage; however, 20% of somatic embryo shoot apices were blocked at the G_0–2 stage. Analogies between somatic embryos and their zygotic homologues were shown. The genetical and environmental causes of the low level of conversion of grapevine somatic embryos into plantlets are discussed. Our work suggests that the in vitro culture conditions which were used could be incompatible with normal morphogenesis from the torpedo stage.     

Cell cycles in embryos of the silkworm,Bombyx mori: G2-arrest at diapause stage

Summary In the silkworm, Bombyx mori, diapause occurs at a specific embryonic stage, i.e. after formation of the germ band with cephalic lobes and telson and sequential mesoderm segmentation. As long as the eggs are incubated at 25° C, cell divisions and morphological development of the embryos cease. To examine changes in percentage of embryonic cells in the G₁, S and G₂ phases during embryogenesis, nuclear fractions were isolated from embryos, stained with propidium iodide and then subjected to flow cytometric analysis. The percentages of embryonic cells in G₁, S and G₂ were 10, 35 and 55%, respectively, at the stage of formation of cephalic lobes, whilst 98% of cells were in G₂ at diapause stage. After termination of diapause by acclimation at 5° C or by a combination of chilling and HCl, cell division resumed in the embryos. During this period, the cells rapidly entered S phase through G₁ from G₂, suggesting that their G₁ phase was short. In eggs in which diapause was averted by HCl-treatment after incubation at 25° C for 20 h after oviposition, embryonic development proceeded continuously for 9.5 days at 25° C until hatching. Along with this development, the G₁ fraction increased to levels of about 90%. These results indicate that embryonic cells are arrested in G₂ at diapause and suggest that, concomitant with further embryonic development, cell cycles become slower in proportion to an increasing length of G₁. Finally, most of the cells may be arrested in G₁, while there is only a small fraction of cells continuously cycling. Offprint requests to: T. Yaginuma     

Flow Cytometric Determination of Relative Nuclear DNA Contents in Bicellulate and Tricellulate Pollen

Nuclear DNA content in mature pollen was measured with a flowcytometer Pollen of Lilium longiflorum, Dendranthema grandiflora(syn Chrysanthemum monfolium) and Zea mays was chopped and stainedwith the DNA fluorochrome DAPI DNA levels, expressed as arbitraryC values, were compared with those of nuclei isolated from leafor root material of the same plants In mature tricellulate pollen the generative cell is dividedafter second pollen mitosis into two sperm cells Tricellulatepollen from maize and chrysanthemum gave rise to one large 1Cpeak and, only in the case of chrysanthemum, a much smallerone at the 2C level These results suggest that the haploid nucleiof the vegetative as well as both sperm cells in tricellulatepollen are arrested in the G₁ stage of nuclear division Thesmall 2C peak in the case of chrysanthemum probably arose froma fraction of pollen with the sporophytic chromosome number(2n pollen) In contrast to this, mature bicellulate lily pollengave rise to two identical peaks at the 1C and the 2C levelFrom this result it was concluded that in bicellulate pollen,the 1C peak is caused by the signal of the haploid vegetativenucleus arrested in the G₁ stage of nuclear division, whereasthe 2C peak originates from the haploid generative nucleus whichhas already undergone DNA synthesis and is arrested in G₂ Lilium longiflorumThunb, lily, Dendranthema grandiflora Tzelev (syn Chrysanthemum morifolium Ramat ), chrysanthemum, Zea maysL, maize, male gametophytic cells, vegetative cells, generative cells, sperm cells, unreduced pollen, sporophytic cells, relative nuclear DNA contents, replication stage     

Effects and Absorption of Sethoxydim in Cell Cycle Progression of Corn (Zea mays) and Pea (Pisum sativum)

The mechanisms of selective herbicidal action of sethoxydim were investigated by using cultured root tips of corn (Zea mays L. cv Goldencrossbantam) and pea (Pisum sativum L. cv Alaska). Meristematic cells in the cultured roots were arrested in G₁ and G₂ of the cell division cycle by sucrose starvation and resumed growth and cell division (proliferation) when sucrose was provided. Corn root growth after sucrose addition was inhibited by sethoxydim at concentrations of 0.01 micromolar and greater when roots were treated in the presence of sucrose but was not inhibited at 10 micromolar sethoxydim when they were treated during sucrose starvation. Greater absorption of [¹⁴C]sethoxydim into the meristematic region of corn roots was observed when cells were in proliferative condition but not when they were arrested by sucrose starvation, whereas no greater absorption of the herbicide into pea meristems was observed in either growth condition. In the cell cycle study, greater absorption of [¹⁴C]sethoxydim into the corn root meristem was observed at a certain limited time before S (DNA synthesis) stage. The physiological effects and the greater absorption of sethoxydim clearly depended on cell cycle progression of corn root meristem, whereas fatty acid synthesis, as well as its inhibition by sethoxydim, was not associated with either cell cycle progression or greater absorption of the herbicide.     

Location of heitz's zerstäubungsstadium (dispersion phase) in the mitotic cycle ofPhaseolus coccineus and the concept of Angiosperm endomitosis

Summary DNA microdensitometry and autoradiography after treatment with³H-thymidine were used to study the phase of dispersion of chromocenters (Z phase) in parallel with chromocentric nuclei inPhaseolus coccineus. In all materials studied, two types of chromocentric nuclei were present.In radicle apices of dry seeds, two classes of nuclear DNA contents were measured, 2 C (G₁) and 4 C (G₂). The 2 C DNA class comprised all chromocentric type I nuclei, the 4 C class included Z phases and chromocentric type II nuclei. The 4 C (G₂) condition of Z phases implies that Z phases maintain their nuclear structure for some time after the end of DNA replication. Shoot apices also contain 2 C (G₁) and 4 C (G₂) nuclei but 4 C nuclei (Z phases and chromocentric type II nuclei) are rare.In seedling root apices, Z phases are from 1.02 to 4.08 times as frequent as prophases. This excludes that Z phase is a very early prophase. DNA microdensitometry shows that the chromocentric type I includes 2 C (G₁) nuclei and nuclei in the first part of the S phase, Z phases include 4 C (G₂) nuclei and nuclei in the last stage of the S phase and chromocentric type II includes mainly 4 C (G₂) nuclei and nuclei in the second part of S. After 90 minutes of treatment with³H-thymidine all Z phase nuclei are labeled. This result and the microdensitometric data unequivocally demonstrate that Z phase is located at the end of S.The present results and those of previous authors on Z phase are discussed in relation to Geitler's concept of Angiosperm endomitosis. It is concluded that the term Angiosperm endomitosis must be abandoned and substituted by the term chromosome endoreduplication.     

Reversible accumulation of plant suspension cell cultures in g(1) phase and subsequent synchronous traverse of the cell cycle

The induction of DNA synthesis in Datura innoxia Mill. cell cultures was determined by flow cytometry. A large fraction of the total population of cells traversed the cell cycle in synchrony when exposed to fresh medium. One hour after transfer to fresh medium, 37% of the cells were found in the process of DNA synthesis. After 24 hours of culture, 66% of the cells had accumulated in G₂ phase, and underwent cell division simultaneously. Only 10% of the cells remained in G₀ or G₁. Transfer of cells into a medium, 80% (v/v) of which was conditioned by a sister culture for 2 days, was adequate to inhibit this simultaneous traverse of the cell cycle. A large proportion of dividing cells could be arrested at the G₀ + G₁/S boundary by exposure to 10 millimolar hydroxyurea (HU) for 12 to 24 hours. Inhibition of DNA synthesis by HU was reversible, and when resuspended into fresh culture medium synchronized cells resumed the cell cycle. Consequently, a large fraction of the cell population could be obtained in the G₂ phase. However, reversal of G₁ arrested cells was not complete and a fraction of cells did not initiate DNA synthesis. Seventy-four percent of the cells simultaneously reached 4C DNA content whereas the frequency of cells which remained in G₀ + G₁ phase was approximately 17%. Incorporation of radioactive precursors into DNA and proteins identified a population of nondividing cells which represents the fraction of cells in G₀. The frequency of cells entering G₀ was 11% at each generation. Our results indicate that almost 100% of the population of dividing cells synchronously traversed the cell cycle following suspension in fresh medium.     

DNA replication during differentiation of cortical cells in Allium roots

In the elongation zone of Allium roots a certain fraction of cortical cells undergo DNA replication during transition from newborn non-proliferative cells to mature cells. The percentage of cortical cells in the mature zone with DNA content 2C (G₀₁) and 4C (G₀₂) is roughly 60% and 40%, respectively. We propose that a replication signal whose concentration decreases the farther you go from the root tip, along the root axis, and which acts on cells after their last partitioning, could account for the observed distribution of mature cortical nuclei with different DNA contents.     

Arabidopsis replication factor C4 is critical for DNA replication during the mitotic cell cycle

Replication factor C (RFC) is a conserved eukaryotic complex consisting of RFC1/2/3/4/5. It plays important roles in DNA replication and the cell cycle in yeast and fruit fly. However, it is not very clear how RFC subunits function in higher plants, except for the Arabidopsis (At) subunits AtRFC1 and AtRFC3. In this study, we investigated the functions of AtRFC4 and found that loss of function of AtRFC4 led to an early sporophyte lethality that initiated as early as the elongated zygote stage, all defective embryos arrested at the two‐ to four‐cell embryo proper stage, and the endosperm possessed six to eight free nuclei. Complementation of rfc4‐1/+ with AtRFC4 expression driven through the embryo‐specific DD45pro and ABI3pro or the endosperm‐specific FIS2pro could not completely restore the defective embryo or endosperm, whereas a combination of these three promoters in rfc4‐1/+ enabled the aborted ovules to develop into viable seeds. This suggests that AtRFC4 functions simultaneously in endosperm and embryo and that the proliferation of endosperm is critical for embryo maturation. Assays of DNA content in rfc4‐1/+ verified that DNA replication was disrupted in endosperm and embryo, resulting in blocked mitosis. Moreover, we observed a decreased proportion of late S‐phase and M‐phase cells in the rfc4‐1/–^{FIS2;DD45;ABI3pro::AtRFC4} seedlings, suggesting that incomplete DNA replication triggered cell cycle arrest in cells of the root apical meristem. Therefore, we conclude that AtRFC4 is a crucial gene for DNA replication.     

EFFECTS OF NEAR ULTRAVIOLET AND VISIBLE RADIATIONS ON CELL CYCLE KINETICS IN EXCISED ROOT MERISTEMS OF PISUM SATIVUM

Near-ultraviolet and visible radiations increased the duration of the mitotic cycle in excised pea root meristems primarily by lengthening the duration of the pre-DNA synthetic period (G₁). All radiations tested shortened the duration of the post-DNA synthetic period (G₂). The most pronounced effects were exhibited by green radiation, which lengthened the duration of the cell cycle, G₁, DNA synthesis (S), and mitosis (M), and shortened the duration of G₂. Progression of cells arrested by starvation in G₁ and G₂ into DNA synthesis and mitosis was also affected by light treatments. Green radiation appeared to arrest a group of cells in DNA synthesis as well as in G₁ and G₂. Meristems receiving green and near-ultraviolet radiations exhibited the most rapid progression of G₁ cells through S and G₂.     

Flow Cytometric Determination of Nuclear Replication Stage in Seed Tissues

Flow cytometric determination of DNA levels in embryos of fullymatured seeds of various plant species revealed large amountsof 2C DNA signals, indicating that most cells had arrested thecell cycle at the presynthetic G₁ phase of nuclear division.The accumulation of cells at G₁ was found both in orthodox andin recalcitrant (i.e. Castanea sativa) seed species. As recalcitrantseeds are characterized by the absence of maturation drying,the arrest of the cell cycle in the presynthetic phase may notbe linked to the seed water status. Apart from the 2C signal, 4C values were found in the embryoof some seed species (e.g. Raphanus sativus) indicating thatcells were arrested in G₂ Cells arrested in G₂ were primarilylocated in the root-tip region of the embryo. In addition, combinationsof higher C values (i.e. 8C, 12C, 16C and 64C) were observedin the endosperm of Solanum melongena and Lycopersicon esculentum,and in the root-tip cells of Phaseolus vulgaris and Spinaciaoleracea. These mixtures of polyploid nuclei (also called 'polysomaty')may arise from a developmentally controlled cellular endoreduplicationand indicates that in each cell type of the seed the amountof DNA is regulated both spatially and temporally.Copyright1993, 1999 Academic Press Endive, Cichorium endiva, lettuce, Lactuca sativa, egg-plant, Solanum melongena, pepper, Capsicum annuum, tomato, Lycopersicon esculentum, radish, Raphanus sativus, bean Phaseolus vulgaris, spinach, Spinacia oleracea, chestnut, Castanea sativa, beech, Fagus sylvatica, pine, Pinus nigra, DNA content, flow cytometry, seed, nuclear replication stage, C levels, storage     

Seasonal Changes in the Distribution of Photo-assimilated C in Young Pine Plants

Pinus strobus L. plants in their third year of growth were permitted to photoassimilate ¹⁴CO₂ for about 1 hour at monthly intervals between April and October, and the subsequent distribution of ¹⁴C in these plants was determined 8 hours, 1 month, 2 months or 4 months after photo-assimilation. In this way, the fate of ¹⁴CO₂ photo-assimilated during different months of the growing season was observed.

In the spring, old needles played a significant role in photo-assimilating ¹⁴CO₂ and exporting current photosynthate to the developing new shoots and roots. By July, the new shoot had replaced the old shoot both as the primary photo-assimilating part of the plant and as an exporter, particularly to the root.

The root received current photosynthate from the shoot throughout the entire growing season, although plant analysis only 8 hours after photo-assimilation did not always reveal this. Translocation of recent photosynthate from shoot to root was particularly high in August, September, and October.

The amounts of photo-assimilated ¹⁴C lost from the plants over a 4 month interval, principally through respiration and photorespiration, were about one-half of that absorbed during photo-assimilation, with the greatest loss occurring within the first month.