DNA synthesis, cell division and specific cytodifferentiation in cultured pea root cortical explants

Pea root segments cut 10–11 mm behind the tip of germinating seedlings were prepared by removal of the central cylinders with a tissue punch. These cortical explants were cultured aseptically on nutrient medium containing auxin with and without added cytokinin. In the absence of kinetin, the cortical cells enlarged and separated but failed to show DNA synthesis, mitosis, cell division or subsequent cytodifferentiation. In the presence of 1 ppm kinetin, cortical nuclei showed ³H-thymidine incorporation beginning between 24 and 32 hr; mitoses began about 48 hr, reaching a maximum of 6% at 60 hr. From an initial number of 8000 cells per segment, the cell count increased to 37,000 by day 7 and 140,000 by day 21. At the outset all mitoses were tetraploid; with time the proportion of tetraploid mitotic cells decreased and an octaploid population increased. A frequency of less than 10% diploid mitoses was observed after day 5. Only 25% of the cortical cells showed initial labeling. Beginning on day 7 tracheary elements differentiated from cortical derivatives. By day 14 about 25% and by day 21 about 35% of the total cell population had formed tracheary elements. As a system for analysis in biochemical and cytological terms, pea cortical explants represent an excellent system for the study of cytodifferentiation.     

Hormonal Control of Cell Proliferation and Xylem Differentiation in Cultured Tissues of Glycine max var. Biloxi

The relationship between tracheary element differentiation, cell proliferation and growth hormones was examined in agar-grown soybean callus. The time course of cell division and tracheary element formation in tissues grown on a medium containing 5 x 10(-7)m kinetin and 10(-5)m NAA was determined by means of maceration technique. After a slight lag period, a logarithmic increase in cell number was observed through the twelfth day of the culture period. Cell numbers increased at a considerably slower rate after the twelfth day. The rate of tracheary element formation varied with the rate of cell proliferation. Tracheary elements increased logarithmically during the log phase of growth. As the rate of cell division decreased after the twelfth day of culture, the rate of tracheary element formation also decreased. In the presence of 10(-5)m NAA, cell number increased as the kinetin concentration was increased between 10(-9) and 10(-6)m. However, tracheary element formation was not initiated unless the kinetin concentration was 5 x 10(-8)m or above. When the Biloxi callus was subcultured repeatedly on media containing 10(-8)m kinetin, a tracheary element-free population of cells was obtained. This undifferentiated tissue produced tracheary elements upon transfer to a medium containing 5 x 10(-7)m kinetin. In the presence of 5 x 10(-7)m kinetin, NAA stimulated cell proliferation between 10(-7) and 10(-5)m, but no tracheary elements were formed without auxin, or with 10(-7)m NAA. Neither NAA nor kinetin at any concentration tested stimulated tracheary element formation in the absence of an effective level of the other hormone. However, 2,4-D at 10(-7) or 10(-6)m promoted both cell proliferation and tracheary element differentiation in the absence of an exogenous cytokinin.     

Interaction of auxin, cytokinin, and gibberellin on cell division and xylem differentiation in cultured explants of Jerusalem artichoke.

Dark-cultured explants of parenchymatous cells isolated fromJerusalem artichoke tubers were induced to divide and differentiateas tracheary elements on Murashige and Skoog medium containingdifferent combinations of plant growth-hormones such as auxin(IAA), cytokinin (zeatin), and gibberellin (GA₃). Addition ofauxin to the growth-medium induced after a short lag period,very rapid cell division which was followed by differentiationof some of the divided cells as tracheary elements. At the optimallevel of IAA (5.0 mg/liter), the percentage of tracheids differentiatedwith respect to the total number of cell population was 13.54.When the explants were cultured in the presence of both auxin(IAA 5.0 mg/liter) and one cytokinin (zeatin 0.1 mg/liter),not only a strong interaction on cell division and trachearyelement formation was observed but also an increase in the percentageof tracheids differentiated in relation to the total cell population.Auxin-gibberellin and auxin-gibberellin-cytokinin treatmentsalso produced interaction on cell division and cytodifferentiation.In explants treated with the three growth-hormones about 20%of the total cell population differentiated as tracheary elements.Further, all the hormonal treatments gave different patternsof cytodifferentiation which reflected meristematic patterns. ¹ This research was supported by a grant from C. N. R. Italy. (Received April 18, 1973; )     

Hormonal control of deoxyribonucleic Acid and protein syntheses in pea root cortical explants

The hormonal control of DNA and protein syntheses in cortical explants taken at 10 to 11 mm from the tip of 3-day-old seedling roots (Pisum sativum cv. Little Marvel) was examined. On the auxin medium, S2M, the cortical cells began to enlarge at day 4 in culture, with no DNA synthesis or cell division throughout the 7-day culture period. With the addition of kinetin to this medium, S2M + K, the DNA content of the explants increased about three times by day 3, with further increases thereafter. This DNA increase was followed by cell division activity and subsequent tracheary element differentiation initiated at day 5. At least two divisions per parent cortical cell were required prior to this cytodifferentiation. The absolute hormonal requirements for the DNA synthesis and cell division responses were substantiated by the lack of either response in explants cultured on basal (S2M medium minus auxins) or basal + K medium for 7 days. On the auxin medium, there was no protein accumulation in the cortical explants over the 7-day period. On S2M + K medium, protein accumulation began after day 2 with a steady rate of increase until day 4, and some fluctuation thereafter. The pattern of increasing uptake of ¹⁴C-leucine was similar for days 0 to 4 in explants on either medium. After day 4 on S2M, the uptake continued to increase coincident with cell enlargement initiation, whereas on S2M + K there was a decline. Incorporation of ¹⁴C-leucine into trichloroacetic acid-precipitates of the total buffered homogenate from explants on both media exhibited a similar pattern, i.e. an increase during days 0 to 3 and then a decline to a level about three times higher than day 0. Incorporation into the homogenate soluble fraction also showed a similar pattern in explants cultured with or without kinetin. From the differences in net protein accumulation and the incorporation data, speculation on a cytokinin effect on protein synthesis and degradation rates is presented.     

Is DNA synthesis required for the induction of differentiation in quiescent root cortical parenchyma?

Cortical parenchyma of pea roots normally does not divide nor differentiate as tracheary elements. After excision from the root these cells can be induced to undergo cell division followed by differentiation of tracheary elements in the presence of cytokinin. 5-Fluorodeoxyuridine prevents cell replication and cytodifferentiation. The thymidine analog, 5-bromodeoxyuridine, specifically prevents cytodifferentiation with little or no effect on the rate of cell replication. Thymidine can also prevent cytodifferentiation with little effect on cell replication. Thymidine reverses the effect of 5-bromodeoxyuridine (BrdU) or 5-fluorodeoxyuridine (FdU) when given simultaneous with or subsequent to either BrdU or FdU. BrdU given with FdU allows up to one round of cell replication but no cytodifferentiation. Differentiation is rarely observed unless the entire cell population has undergone the equivalent of two cell generations. These results are combined with those of other investigators to present an hypothesis that implicates DNA replication but not cytokinesis in the regulation of certain types of differentiation.     

HORMONE-INDUCED ENDOREDUPLICATION PRIOR TO MITOSIS IN CULTURED PEA ROOT CORTEX CELLS

One-mm-thick cortical explants excised aseptically from 10-11 mm behind the tip of 3-day-old roots of the garden pea, Pisum sativum, cv. ‘Little Marvel’ were cultured on a synthetic nutrient medium supplemented with auxin or auxin and cytokinin. Nuclear DNA contents were measured in cells of the explants at the outset and at specified times during culture up to seven days. Fixed and sectioned preparations were stained with the Feulgen method using the DNA-specific dye auramin-O. Fluorescent microspectro-photometric measurements of individual nuclei were made from each cortical population. At day zero all cortical nuclei measured were either 2c or 4c with respect to their DNA content. In the presence of the auxins, indoleacetic acid and 2,4-dichlorophenoxyacetic acid, and the cytokinin, kinetin, DNA values increased to multiples of the 2c level with populations at the 8c and 16c level predominating after three days of culture as well as at seven days. In the presence of auxins alone no change in DNA values was observed during three days. Kinetin concentrations as low as 0.01 ppm were already effective. The data are interpreted to show that cytokinin, in the presence of auxin, induces two rounds of DNA synthesis prior to the first mitoses, the first round being connected with chromosome doubling by endoreduplication and the second one with normal mitosis. From this we inferred that tetraploid cells in leguminous root nodules might have arisen in the same way, i.e., by endoreduplication prior to the first mitoses induced by the rhizobial division stimulus, unless the chromosome number of root cortical cells had already been doubled by endoreduplication in the normally differentiating root systems.     

Hormonal Control of Xylogenesis in Pith Parenchyma Explants of Lactuca

The time course of xylem differentiation was determined in explantsof lettuce pith parenchyma (Lactuca sativa L. cv. Romana) culturedon Murashige and Skoog (1962) medium using different concentrationsof auxin (IAA) and one cytokinin (zeatin or kinetin). Increasinglevels of auxin from I mg 1^–1 to 15 mg 1^–1 in thepresence of a constant level of a cytokinin (zeatin or kinetin)yielded up to 10 mg 1^–1 IAA, an increase in the numberof tracheary element formations. Cytokinin concentrations aboveand below o.1 mg 1^–1 interacting with an optimal xylogenicamount of auxin inhibited xylogenesis. The IAA (10 mg 1^–1)-zeatin(0.1 mg ^1–1) treatment produced the greatest number oftracheids, while kinetin compared to zeatin did not producesuch an effect. The different effectiveness of zeatin and kinetinin inducing tracheary element formations was not due to a differentcapacity of the two cytokinins to stimulate cell division butit seems likely that zeatin, because of interaction with IAA,is more active than kinetin in the determination of the dividingcells in a specific type of cytodifferentiation. The IAA (10mg 1^–1)-zeatin (0.1 mg 1^–1) treatment produced about6.9 per cent tracheids with respect to cell division while IAA(10 mg 1^–1)-kinetin (0.1 mg 1^–1) produced 4.2 percent. These results are discussed with reference to the problemsof hormonal control of xylem differentiation.     

Direct Evidence for Cytodifferentiation to Tracheary Elements without Intervening Mitosis in a Culture of Single Cells Isolated from the Mesophyll of Zinnia elegans

A serial observation of the process of tracheary element differentiation from single cells isolated from the mesophyll of Zinnia elegans L. cv. Canary bird provided the first direct evidence for the cytodifferentiation without intervening mitosis. Percentage of the tracheary elements formed without cell division was about 60% of total tracheary elements formed on the 4th day of culture. The number of tracheary elements formed without intervening mitosis was not reduced in the presence of colchicine at the concentrations blocking cell division. These facts clearly indicate that cell division is not a prerequisite for tracheary element differentiation in this system.     

Effects of auxin on the spatial distribution of cell division and xylogenesis in lettuce pith explants

Summary Cylinders of pith parenchyma were tissue-cultured with their opposite ends on media which differed only in content of the morphogens auxin (IAA), sucrose, or zeatin. A range of concentrations of each of these morphogens applied at one end (none at the other end) resulted in distribution patterns of cell division and xylogenesis that were attributable to interaction between inductive levels and morphogen mobility. Auxin was crucial for tracheary patterns: large tracheary elements formed by direct differentiation of pith cells near the auxin source, smaller but still roughly isodiametric tracheary elements formed after cell division, and tracheary strands developed where, presumably, auxin transport had become polarized and then canalized. Xylogenesis was confined to regions within millimeters of the auxin source, and [¹⁴C]IAA studies showed a steep logarithmic concentration gradient along the cylinder. Patterns of tracheary strands and rings revealed that the pith explants retained some polarity from the stem from which they had been excised. However, the direction of flow of applied auxin was more effective than original polarity in controlling the orientation of tracheary strands and their constituent tracheary elements. It seems that, in tissues with little or no polarity, diffusive flow of auxin gradually induces polar flow in the same direction, together with an associated bioelectric current, and that this orients the cortical microtubules that in turn determine the orientations of cell elongation and of the secondary wall banding in tracheary elements.Abbreviations IAA indoleacetic acid - NAA naphthaleneacetic acid - TIBA triiodobenzoic acid Dedicated to the memory of Professor John G. Torrey     

Relationship between tracheary element differentiation and the cell cycle in single cells isolated from the mesophyll of Zinnia elegans

A relationship between tracheary element differentiation and the cell cycle was studied in single cells isolated from the mesophyll of Zinnia elegans L. cv. Canary bird. Almost all nuclei of isolated mesophyll cells were at the 2 C level of DNA, indicating that almost all cells were initially in the G₁ phase and that somatic polyploidy was absent. Cultured cells underwent partially synchronous DNA replication at 42 h and mitosis at 54 h of culture, and the first cell cycle time was approximately 58 h.
The occurrence and timing of DNA replication and mitosis during cytodifferentiation to tracheary elements were investigated using microspectrophotometry, microfluorometry, tritiated thymidine autoradiography, and serial observation. More than 55% of the nuclei of the immature tracheary elements were at the 2 C level of DNA and were not labeled by continuous feeding with tritiated thymidine, providing clear evidence that these cells differentiated without interventing DNA replication. Some tracheary elements (approximately 30%) were formed after one round of the cell cycle, and others (less than 5%) were formed after passing through the S phase, but without intervening mitosis. All types of tracheary elements appeared simultaneously after 58 h of culture, and their patterns of increase in number were similar. From the results, we propose a hypothesis concerning the relationship between cytodifferentiation and the cell cycle.     

Pattern of cell division and wound vessel member differentiation in coleus pith explants

When pith parenchyma explants are taken from Coleus blumei plants and cultured on an agar medium containing sucrose and indoleacetic acid wound vessel members differentiate in 10 days. The time course of wound xylem appearance and an auxin requirement suggest that this uncomplicated system is responding in a manner comparable to wounded Coleus plants and cultured stem segments.

Histological examination and cell size comparisons confirm that parenchyma cells divide before differentiating. When colchicine is used to prevent mitosis no tracheary elements differentiate. Following the time course of this cytodifferentiation histologically shows that xylem differentiates from cells that are the products of several cell divisions.

     

Hormonal induction and antihormonal inhibition of tracheary element differentiation in Zinnia cell cultures

Mechanically isolated mesophyll cells of Zinnia elegans L. cv Envy differentiate to tracheary elements when cultured in inductive medium containing sufficient auxin and cytokinin. Tracheary element differentiation was induced by the three auxins (alpha-naphthaleneacetic acid, indole-3-acetic acid, and 2,4-dichlorophenoxyacetic acid) and four cytokinins (6-benzyladenine, kinetin, 2-isopentenyladenine and zeatin) tested. Tracheary element formation is inhibited or delayed if the inductive medium is supplemented with an anticytokinin, antiauxin, or inhibitor of auxin transport.     

Ultrastructural changes in cells of pea root cortical explants culturedIn vitro

Summary Root cortical explants from seedlings ofPisum sativum L., cv. Little Marvel were cultured on a sterile nutrient medium in the presence of auxins or auxins and cytokinin. Explants were fixed (and subsequently processed for electron microscopic observation) at the outset and after 30, 60, and 72 hours of culture under the two hormonal conditions. In the presence of auxin alone, the cell walls of the cortical parenchyma showed distinctive structural changes involving the deposition of a new, diffusely fibrillar primary wall. A considerable increase of rough ER in the adjacent cytoplasm was associated with the new wall synthesis. These wall changes are interpreted as auxin-induced and prelude to cell enlargement and later cell separation. No dramatic changes occurred in other cytoplasmic organelles or in the nucleus. In the presence of cytokinin and auxin, the striking cytological events observed included marked nuclear changes and greater cytoplasmic density due to increased organelles associated with the onset of DNA synthesis, mitosis and cytokinesis. New cell walls formed from the developed phragmoplasts, cleaving the original parenchyma cells into smaller cellular compartments with no accompanying cell enlargement. No marked changes in the original primary cell walls were observed in cytokinin-auxin-treated explants. By 72 hours some cells already had completed two successive cell divisions. No ultrastructural evidence was obtained suggesting that these cells were committed to their known fate of differentiating into mature tracheary elements in the subsequent 2–4 days. At 72 hours each explant represented a population of actively dividing, still considerably vacuolated meristematic cells.     

Effects of Sequential Exposure to Auxin and Cytokinin on Xylogenesis in Cultured Explants of Jerusalem Artichoke (Helianthus tuberosus L.)

During the course of a 4-d culture period, explants of Jerusalemartichoke tuber were exposed to auxin (0.2 mg 1^–1 2, 4-dichlorophenoxyaceticacid), and cytokinin (5.0 mg 1^–1 benzyl-amino purine),under a range of sequential regimes, to study the influenceof each hormone on tracheary element formation. The resultsindicate that auxin was necessary early in the culture periodand was primarily involved in cell proliferation. Cytokininstimulated xylogenesis when present late in the culture period,concomitant with the phase of cytodifferentiation, but not whenrestricted to the early period. The implications for a sustainedperiod of commitment to differentiation are discussed. Xylem differentiation, Jerusalem artichoke, auxin, cytokinin, tissue culture     

Hormone regulation of development in plant cells

Summary Hormonal stimulation of dedifferentiation and redifferentiation can be studied in explanted, cultured plant tissues. Some of the questions about development which one would like to answer with such a system revolve around the role of quiescence in the stabilization of the differentiated state, the role of replication in the stimulation of redifferentiation and the means by which cells are brought out of the quiescent state. Such a system also offers the potential for revealing the level(s) at which plant hormones operate in the stimulation of replication and differentiation since the responses to hormones can be achieved in vitro. The pea-root cortical parenchyma system has been utilized as a model system in the study of cytokinin plus auxin stimulation of redevelopment of mature, quiescent root cells. The first detected response of the root parenchyma to excision and culture with both of these hormones is an enhanced rate of RNA synthesis between 9 and 12 hr after the initiation of culture. DNA synthesis is stimulated 36 to 39 hr after RNA synthesis (after 48 hr in culture). During this 48-hr period various cytological changes have been observed which are compatible with renewed nucleic acid synthesis, but cytological changes have not been observed prior to the onset of hormone-stimulated RNA synthesis. The first mitoses and cytokineses occur after 60 and 72 hr, respectively. Terminally differentiated tracheary elements are first formed in these cultures after 120 to 168 hr when both the cytokinin and auxin are present at adequate levels. Studies employing inhibitors suggest that tracheary element differentiation is dependent upon the DNA replication that normally accompanies cell replication. Temperature probes of the period between the initiation of cultures and the appearance of the terminally differentiated tracheary elements have been initiated and, in conjunction with previous studies employing inhibitors and analogues, may allow one to distinguish between a variety of potential models of hormone-stimulated redifferentiation. Presented in the Opening Symposium on Nutritional Factors and Differentiation at the 28th Annual Meeting of the Tissue Culture Association, New Orleans, Louisiana, June 6–9, 1977. Supported in part by grants from the National Science Foundation (GB 36948) and the Public Health Service (RR 07092).     

Possible involvement of DNA-repair events in the transdifferentiation of mesophyll cells ofZinnia elegans into tracheary elements

In cultures of isolated mesophyll cells ofZinnia elegans, transdifferentiation into tracheary elements is induced by a combination of auxin and cytokinin and is blocked by inhibitors of DNA synthesis and poly (ADP-ribose) synthesis. During transdifferentiation, a very low level of synthesis of nuclear DNA was found in some cultured cells by microautoradiography after pulse-labeling with [³H]thymidine. Density profiles of nuclear DNA that had been double-labeledin vivo with bromodeoxyuridine (BrdU) and [³H]thymidine indicated that this DNA synthesis was repair-type synthesis. The sedimentation velocity of nucleoids increased during the culture of isolated mesophyll cells and the increase was dependent on phytohormones. This phenomenon may reflect the rejoining of DNA strand breaks after repair-type DNA synthesis during transdifferentiation. Treatment of cells with inhibitors of DNA synthesis or of poly(ADP-ribose) synthesis prevented the increase in the sedimentation velocity of nucleoids. The data suggest the involvement of DNA-repair events in the transdifferentiation of mesophyll cells into tracheary elements.     

Tracheary Element Formation from Single Isolated Cells in Culture

Friable callus tissue of Centaurea cyanus L. was grown on a solidified synthetic nutrient medium (EBM-1) to produce a tissue with a low frequency of differentiated tracheary elements. Tissues were then suspended in liquid nutrient medium with agitation to produce a suspension which was filtered and the single-cell suspension resulting was used as inoculum for either cell suspension cultures or for plating of cells into solidified medium in Petri plates. Media for the suspension cultures were selected to favor cytodifferentiation of tracheary elements. Differentiated tracheary elements formed as early as 10 days and numbers of tracheary elements increased with time roughly in relation to the increase in total cell number. From plating experiments it was shown conclusively that single isolated parenchyma cells differentiated directly into single isolated tracheary elements, although this event was rare. More usual was the division of isolated cells to form small colonies and then the differentiation of one, several or all of the cells into tracheary elements. Comparisons are made between results with cell plating experiments and cell suspension cultures. Optimism is expressed for finding a cell suspension culture system for studying cytodifferentiation.     

Transition of G1 to early S phase may be required for zinnia mesophyll cells to trans-differentiate to tracheary elements

We have used the Zinnia elegans mesophyll cell system, in which single isolated leaf mesophyll cells can be induced to trans-differentiate into tracheary elements in vitro, to study the relationship between the cell division cycle and cell differentiation. Almost all cells go through several rounds of division before characteristic features of tracheary element formation are observed. The addition of aphidicolin, a DNA synthesis inhibitor, blocks cell division but not cell differentiation in the zinnia system. Low concentrations of aphidicolin, which possibly delay cells in the early S phase, can significantly enhance levels of tracheary element formation. In contrast, roscovitine, an inhibitor of cyclin-dependent kinase activity, decelerates the cell division cycle and inhibits tracheary element formation with similar dose responses. Cells blocked in S phase and then transferred to roscovitine-containing medium can divide once, indicating that roscovitine may target the G1/S transition, but do not differentiate. Cells inhibited in G1/S in roscovitine-containing medium that are subsequently blocked in S phase by transfer to aphidicolin-containing medium, do not divide but do differentiate. Taken together, our results indicate that cells may be required to transit the G1/S checkpoint and enter early S phase to acquire competence to trans-differentiate to tracheary elements.     

Biochemical responses of pea root tissue to cytokinin: enhanced rates of RNA synthesis

Rates of RNA synthesis were studied in cultured pea (Pisum sativum) root segments and cortical explants which require the hormone cytokinin for DNA replication and cell proliferation. Rate calculations were based on the specific radioactivity of the extracted RNA and the specific radioactivity of the extracted ATP pool after a pulse with ³H-adenosine. The kinetics of RNA synthesis was studied after 24 hours of culture with or without kinetin. We found that kinetin stimulated a 2- to 4-fold enhancement in the rate of RNA synthesis after 24 hours of culture as compared to controls. A similar order of magnitude of stimulation of RNA synthesis was found when RNA was isolated by cesium chloride centrifugation. Pulses during the first 24 hours indicate that kinetin stimulates the rate of RNA synthesis as early as 9 hours after treatment has begun. During the first 24 hours of culture, kinetin did not affect the specific radioactivity of the ATP pool. The ATP pool equilibrated slowly with the exogenous label (³H-adenosine) in the presence or absence of kinetin. After 3 days in culture, we found kinetin to cause an expansion of the extractable ATP pool and a corresponding reduction in the ATP pool specific radioactivity. We interpret these results to indicate a stimulation in the rate of RNA synthesis due to kinetin treatment prior to any other known response.     

Involvement of Poly(ADP-Ribose) Synthesis in Transdifferentiation of Isolated Mesophyll Cells of Zinnia elegans into Tracheary Elements

The relationship between poly(ADP-ribose) synthesis and cytodifferentiationwas studied in the well characterized Zinnia system, in whichisolated mesophyll cells of Zinnia elegans transdifferentiateinto tracheary elements (TE) in a suspension culture in thepresence of both auxin and cytokinin. The rate of poly(ADP-ribose)synthesis was measured in nuclei isolated from cells that hadbeen induced to undergo transdifferentiation, and activationof such synthesis was observed before the appearance of TE duringculture. In cultures without auxin or cytokinin, poly-(ADP-ribose)synthesis appeared to proceed much more slowly. Treatment of cells with a potent inhibitor of poly-(ADP-ribose)polymerase, namely, 6(5H)-phenanthridinone (PT), resulted inthe blockage of TE formation and a decrease in the frequencyof cell division. PT was very effective in interfering withtransdifferentiation, in particular, when supplied between the24th hour and the 36th hour of culture. Repair-type DNA synthesis,which has been proposed to participate in transdifferentiation,was suppressed by the treatment with PT. These results suggestthat poIy(ADP-ribose) synthesis and subsequent repair-type DNAsynthesis might play a critical role in the transdifferentiationof Zinnia cells. ³Present address: Botanical Gardens, Faculty of Science, Universityof Tokyo, Hakusan, Bunkyo-ku, Tokyo, 112 Japan. ⁴Present address: Department of Chemical and Biological Sciences,Faculty of Science, Japan Women's University, Mejirodai, Bunkyo-ku,Tokyo, 112 Japan.