LIGHT AND HORMONAL CONTROL OF ROOT FORMATION IN ZEA MAYS CALLUS CULTURES

Callus cultures of Zea mays were used to study the interaction of light with exogenous cytokinin/auxin levels in the initiation, growth and development of roots. Three auxins, indoleacetic acid (IAA), naphthaleneacetic acid (NAA) and 2,4 dichlorophenoxyacetic acid (2,4 D) were remarkably different in their effects on callus growth and root initiation. NAA at concentrations of 5 and 25 μM produced the highest combined yields of callus and roots under low light conditions. No significant morphological effects on roots were observed with the three auxins tested nor did low and intermediate light intensities alter root development.
At intermediate light levels the addition of the cytokinin, zeatin, was also able to influence the differentiation of the callus tissue. Increasing the cytokinin/auxin ratio from low to high shifted the development from callus growth to abundant root formation. High light caused the formation of short, thick roots. This effect could be counteracted in part by zeatin which promoted elongation. These observations suggest that both, the cytokinin/auxin ratio and light play an important role in the development of monocotyledonous roots.     

A MORPHOMETRIC ANALYSIS OF CELLULAR DIFFERENTIATION IN THE ROOT CAP OF ZEA MAYS

In order to quantify the ultrastructural changes associated with cellular differentiation, we have performed a morphometric analysis of the ultrastructure of the calyptrogen, columella, and peripheral cells of the root cap of Zea mays. The relative volumes of the nucleus, nucleolus, and mitochondria in the protoplasm gradually decrease as a cell moves through the root cap. The relative volume of plastids increases 240% during the differentiation of calyptrogen cells into columella cells. This increase is transient, however, since the relative volume of plastids as well as starch in plastids decreases markedly as columella cells differentiate into peripheral cells. Dictyosomes and spherosomes increase more gradually than plastids, peaking in relative volume in the innermost peripheral cells (PCI). The relative volume of the vacuome decreases as calyptrogen cells differentiate into columella cells, after which it increases during the differentiation of peripheral cells. By the time the outermost peripheral cells (PCIII) are sloughed from the cap, the relative volume of the vacuome has almost tripled. These results indicate that each cell type comprising the root cap of Zea mays is characterized by a distinctive ultrastructure. Furthermore, the ultrastructural changes associated with the differentiation of these cells are organelle specific. The results of this study are discussed relative to the function of the various cell types of the root cap.     

THE OCCURRENCE OF WALL PAPILLAE IN ROOT EPIDERMAL CELLS OF AXENICALLY GROWN SEEDLINGS OF ZEA MAYS

Lens-shaped wall papillae, resembling those known to form in response to fungi or mechanical damage, occur in root epidermal cells of axenically grown seedlings of Zea mays. Papillae are most common in the tabular epidermal cells but also occur in younger cells. Not all tabular cells have papillae, and they are more frequent in some seedlings. Where present, there is usually only one papilla per cell and it lies against the outer periclinal wall just proximal to an emerged root hair or near the position where a hair would be expected to form. Electron micrographs show that a papilla is structurally heterogeneous. Papillae fluoresce strongly in the presence of aniline blue even in freeze-substituted material.     

THE ISOLATION AND CULTURE IN VITRO OF THE QUIESCENT CENTER OF ZEA MAYS

Using 3-day-old seedling roots of Zea mays L., cv. Kelvedon 33, it was possible to remove the root cap by a simple surgical manipulation without damage to the root proper. By a further small cut, the quiescent center (QC) itself was isolated. This double-convex lens-shaped tissue piece 100 X 250 μm is composed of 1000–1500 cells representing only 0.25 mm³ in volume. The explant was demonstrated unequivocally by ³H-thymidine incorporation before excision and then by autoradiography to be composed of the specific cells usually designated the quiescent center. Using sterile techniques, the QC's were placed on nutrient agar slants and allowed to grow in culture. Of a number of nutrient media tested, only a medium supplemented with organic nitrogen components, indoleacetic acid, kinetin and inorganic nutrients plus sucrose (S2M + K -2,4-D) was effective in eliciting development. Thirty to 40 percent of the 150 isolated QC's grown on this medium formed elongated roots, up to 2 cm in length in 3–4 weeks. Roots developing on agar medium showed in their proximal portion a vascular pattern with 5–6 metaxylem elements or variations of this pattern, but as the root elongated, the vascular pattern was progressively reduced in complexity at the more distal end to a small central group of metaxylem elements. When agar-grown roots were transferred after one week in culture to a liquid nutrient medium of the same composition, the initially reduced vascular pattern evident in the proximal tissues became progressively more complex in the distal portion of the root and after 2 cm of elongation, showed an essentially normal primary vascular tissue pattern characteristic of the seedling root.     

EFFECTS OF CA AND SR ON ZEA MAYS SEEDLING PRIMARY ROOT GROWTH

Either Ca or Sr in a mineral nutrient medium prevented toxic effects of other nutrient ions on aerated primary roots of maize; other monovalent or divalent, cations substituted for Ca did not. Calcium in the complete nutrient solution, or as CaCl₂ alone, stimulated the division of apical meristem cells in these roots, as compared to division in water alone, but Sr did not. However, the replacement of Ca in the nutrient medium by Sr resulted in the development of additional secondary roots, probably in part by decreasing the rate of cell division in the apical meristem of the primary root and thereby diminishing apical dominance.     

钙调素参与玉米线粒体琥珀酸脱氢酶活性的调节

经DEAE C-32柱纯化的玉米(Zea mays L.)线粒体琥珀酸脱氢酶(SDH),用NAD激酶(NADK)法测定时,无钙调素(CaM)活性,说明不存在游离CaM;而用ELISA法测定总CaM时,却可检测到CaM。纯化的SDH加热处理后,能激活NADK,可能加热释放出游离CaM。纯化SDH的电泳分析表明,天然聚丙烯酰胺凝胶电泳(PAGE)只显示1条主带;而SDS-PAGE则出现67.0kD、30.0kD、16.7kD 3条带,前两条带与SDH的大、小亚基分子量一致,第三条带与CaM电泳迁移率一致。上述结果说明CaM可能与SDH处于结合状态,而且其活性受CaM调节。     

ORGAN INITIATION AND THE DEVELOPMENT OF UNISEXUAL FLOWERS IN THE TASSEL AND EAR OF ZEA MAYS

The development of the unisexual male and female flowers of Zea mays from bisexual initials in both tassels and ears has been reinvestigated with SEM and TEM. The early stages of spikelet branch primordia, spikelet initiation, and early flower development are similar in both flowers, though differences in rates of growth of glumes, lemmas, and palea were detected. In both tassel and ear flowers, a pair of stamens arises opposite the lemmas and a third stamen initiates later at right angles to the first pair but from a point on the meristem below its insertion. Gynoecia develop on both tassel and ear flowers first as a ridge which overgrows the apical meristem giving rise to the stylar canal and the elongate silk. Male flowers arise in the tassel through selective vacuolation and abortion of the cells of the early gynoecium. The single female flower in each ear spikelet arises through the vacuolation and abortion of stamens in the upper flower and the repression of growth of and the eventual regression of the lower flower in each spikelet. The significance of these selective organ abortions for practical applications is discussed.     

渗透胁迫引起玉米根冠处胞间连丝的ATP酶活性下降

利用光镜和电镜研究了短期渗透胁迫下玉米(Zea mays L.)根冠区超微结构和ATP酶活性变化。经历了质壁分离后,在根冠细胞仍然可以观察到许多从“撤退”的周质出发向细胞壁辐射的纤丝。利用ATP酶活性产物(磷酸铅)在原生质膜和细胞壁处沉积的特点,发现这些纤丝是质膜围绕原生质而形成的管状结构;在质壁分离过程中,这些纤丝依然与胞间连丝相连。与对照(未胁迫)相比,受渗透胁迫细胞胞间连丝处ATP酶活性明显下降。能量代谢在局部区段的抑制会影响胞间连丝的生理活性,可能包括胞间连丝的扩散调节能力和分子扩散上限的改变。     

RESPIRATORY METABOLISM IN THE PHLOEM, XYLEM AND CAMBIUM OF CARROT ROOT

Comparisons of respiratory metabolism among the phloem, cambiumand xylem of mature carrot root were carried out and the followingresults were obtained. 1) The activity of O₂ uptake on a dry weight basis in the cambiumwas higher than that in the xylem. The phloem showed the lowestactivity. 2) RQ was close to unity in all the three tissues.3) The inhibition rate of O₂ uptake by malonate was considerablyhigh in the three tissues. The highest inhibition was observedin the cambium. 4) In the phloem and xylem the malonic inhibitionrate of ¹⁴CO₂ release from G-U-¹⁴C was not so high as comparedwith that of O₂ uptake. In the cambium, however, those of O₂uptake and ¹⁴CO₂ output were comparable. 5) Malonate treatmentdid not cause any significant change in RQ. 6) The C₆/C₁ ratiowas highest in the cambium and lowest in the phloem. From these it is concluded that the participation of the TCAcycle in respiration is great in all the three tissues of carrotroot, and among the three the cambium has the highest activityof the cycle. As for the PP pathway, the xylem and phloem havea higher activity than the cambium. (Received April 11, 1967; )     

LIMITATIONS OF PHOTOSYNTHESIS IN DIFFERENT REGIONS OF THE ZEA MAYS LEAF

The progressive development of the photosynthetic apparatus occurring along the length of the Zea mays leaf offers a convenient system with which to examine the limitations to photosynthetic CO₂ assimilation during biogenesis of a C₄ leaf. Changes in light-induced O₂ evolution and CO₂ assimilation, chlorophyll content, activity of PEP-carboxylase, NADP-malic enzyme and the 'R5P system' (consisting of d -ribose-5-phosphate-keto isomerase, ATP- d -ribulose-5 phosphate 1-phosphotransferase and d -ribulose-1,5-bisphosphate carboxylase) and fluorescence emission characteristics were examined along the length of the second leaf of 7-day-old plants grown under a diurnal light regime. The results suggest that the major limitation to CO₂ assimilation in the leaf sheath lies within the chlorenchyma and is either energy supply for carboxylation or the capacity of key photosynthetic enzymes. In the leaf blade stomatal resistance to CO₂ diffusion constitutes a major fraction of the total leaf resistance to CO₂ assimilation implicating the stoma as the major limiting factor to photosynthetic CO₂ assimilation.     

THE ROOT APEX OF LINUM

Several developmental stages of primary roots of 13 species of Linum were studied. The basic pattern of root apex organization in three species consisted of a single tier of cortical initials. Ten species had a basic pattern of two tiers of cortical initials. Variations, manifested by either an increase or a decrease in the tiers of cortical initials, were observed in some roots in those species that had a basic pattern of two tiers of cortical initials. Although these variations were interpreted as being ontogenetic, there was no total reorganization of the root apex. There was anatomical and cytological evidence that a quiescent center is established in Linum roots.     

C-BAND HETEROCHROMATIN AND DNA CONTENT IN ZEA MAYS

The number of mitotic chromosomal C-bands, the percent of the genome comprised of C-band heterochromatin, and genome size (4C DNA content) were determined for 22 North American inbred and open-pollinated lines of Zea mays. The number of C-bands ranged from 0 in Tama Knobless Flint to 18 in Zapolate Grande. The percent C-band heterochromatin ranged from 0% in Tama Knobless Flint to 16.9% in Tx601. Genome size varied over 23%: Gaspe Flint had the lowest DNA content (9.82 pg), and Zapolate Grande had the highest (12.12 pg). Genome size and the amount of heterochromatin were significantly correlated. The corn lines were assigned to five maturity zones encompassing a south-to-north range from Mexico to Canada. Significant negative correlations were detected between the amount of C-band heterochromatin and maturity zones, and between DNA content and maturity zones among the lines. It is speculated that the simultaneous selection by man for earlier maturation and plant size may be related to the lower DNA content of corn varieties adapted to higher latitudes. Such selection for larger plants may have been achieved through selection for more cells, which could result from the shorter mitotic cycle time that correlates with reduced DNA amount.