Cell lineage analysis of maize bundle sheath and mesophyll cells

Maize leaves are divided into repeated longitudinal units consisting of vascular tissue, bundle sheath (BS), and mesophyll (M) cells. We have carried out a cell lineage analysis of these cell types using six spontaneous striping mutants of maize. We show that certain cell division patterns are preferentially utilized, but not required, to form the characteristic arrangement of cell types. Our data suggest that early in development a central cell layer is formed, most frequently by periclinal divisions in the adaxial subepidermal layer of the leaf primordium. Lateral and intermediate veins are initiated in this central layer, most often by divisions which contribute daughter cells to both the procambium and the ground meristem. These divisions generate "half vein" units which comprise half of the bundle sheath cells around a vein and a single adjacent M cell. We show that intermediate veins are multiclonal both in this transverse direction and along their lengths. BS cells are more closely related to M cells in the middle layer of the leaf than to those in the upper and lower subepidermal layers. An examination of sector boundaries has shown that photosynthetic differentiation in M cells is affected by the phenotype of neighboring BS cells.     

Early Development and Ultrastructure of the Major Veins and Their Sheath Tissues in the Maize Leaves

The report described the ultrastructural changes that occurred in the major veins and their associated bundle sheaths (BS) of the maize ( Zea mays L. ) leaf blade in the process of their differentiation from three adjacent cells in the middle layer of the ground meristem, the minimal number of cells involved with the initiation of a procambial strand and the associated BS. The inner cell underwent two successive unequal periclinal divisions: a smaller cell that later differentiated into the adaxial BS cell precursor, and a larger one that divided once again periclinally yielding an abaxial BS cell precursor and a centrally located procambial initial cell. One of the two lateral cells immediately adjacent to either side of the inner cell also divided periclinally; these derivatives, along with another lateral cell of the original three-celled unit formed the precursor cells of the lateral BS. Prior to the initiation of protophlcem differentiation, all of the procambial cells showed ultrastructural characteristics basically similar to the procambial initial. They possessed a prominent nucleus with electron-dense aggregates of heterochromatin, a dense cytoplasm rich in ribosomes, proplastids and mitochondria; also a thin wall containing numerous plasmodesmata. In many cases, only short pieces of rough endoplasmic reticulum cistemae and a few small sized vacuoles were present. In adclifton, evidence of cytoplasmic disintegration leading to new vacuole formation was noted in the process of proeambium development. It was observed that certain endoplasmic reticulum was engaged in the sequestration and lysis of cytoplasm. No apparent uhrastmctuml difference was found between the BS cell precursors and the procambial initials, that was, the distinction between the procambium and the surrounding BS cells occurred gradually after vein initiation, The major ultrastmctural changes which occurred during the differentiation of the meristematic BS cells into the vacuolated cells were (1) a proplastid to chloroplast transformation going through a prolamellar body stage, and (2) the appearance of the multi-concentric membrane complex which might play a role in the degradation of some ribosomes and other cytoplasmic components during the differentiation of BS cells.     

木立芦荟叶的发育解剖学研究

应用植物解剖学方法研究了木立芦荟（Aloe arborescens Mill.)叶的发育过程。研究结果表明,叶原基在发育早期其形态是不对称的,内部为同形细胞组成,但很快分化成原表皮,原形成层束和基本分生组织。以后,原表皮发育成表皮,位于原表皮下的2－5层基本分生组织细胞发民同化薄壁组织,而位于中央的基本分生组织细胞则发育成储水薄壁组织,原形成层束发育成维管束。维管束由维管束鞘、木质部、韧皮部和大型薄壁细胞组成。大型薄壁细胞起源于原形成层束,位于韧皮部内,其发育迟于筛管、伴胞,为芦荟属植物叶的结构特征。     

Leaf permease1 gene of maize is required for chloroplast development.

Adjacent bundle sheath and mesophyll cells cooperate for carbon fixation in the leaves of C4 plants. Mutants with compromised plastid development should reveal the degree to which this cooperation is obligatory, because one can assay whether mesophyll cells with defective bundle sheath neighbors retain C4 characteristics or revert to C3 photosynthesis. The leaf permease1-mutable1 (lpe1-m1) mutant of maize exhibits disrupted chloroplast ultrastructure, preferentially affecting bundle sheath choroplasts under lower light. Despite the disrupted ultrastructure, the metabolic cooperation of bundle sheath and mesophyll cells for C4 photosynthesis remains intact. To investigate this novel mutation, the Activator transposon-tagged allele and cDNAs corresponding to the Lpe1 mRNA from wild-type plants were cloned. The Lpe1 gene encodes a polypeptide with significant similarity to microbial pyrimidine and purine transport proteins. An analysis of revertant sectors generated by Activator excision suggests that the Lpe1 gene product is cell autonomous and can be absent up to the last cell divisions in the leaf primordium without blocking bundle sheath chloroplast development.     

Genetic analyses of cell death in maize (Zea mays, Poaceae) leaves reveal a distinct pathway operating in the camouflage1 mutant

Controlled cell death is vital for many physiological processes in plants, such as xylem development, the hypersensitive response (HR), and senescence; however, the pathways governing cell death are incompletely understood. Studies of mutants that display a cell-death phenotype have greatly contributed to our knowledge of how this process is regulated. The maize camouflage1 (cf1) mutant displays the novel phenotype of cell-specific death of bundle sheath (BS) cells in discrete yellow leaf tissues. To investigate the BS cell death in cf1 mutants, we characterized potential underlying factors. Hydrogen peroxide (H(2)O(2)) is known to be involved in many cell-death events in plants, including the HR. However, in vivo staining found no accumulation of H(2)O(2) in cf1 mutant leaves. Additionally, genetic analyses determined that functional chloroplasts are required for cf1 BS cell death. These results demonstrate that cf1 BS cell death occurs via a distinct pathway from that seen in a functionally related maize mutant or in the HR, suggesting that cell death in maize leaves can be caused by multiple mechanisms.     

Cell differentiation in the longitudinal veins and formation of commissural veins in rice (Oryza sativa) and maize (Zea mays)

Vascular development is a central theme in plant science. However, little is known about the mechanism of vascular development in monocotyledons (compared with dicotyledons). Therefore, we investigated sequential processes of differentiation into various different vascular cells by carrying out detailed observations using serial sections of the bases of developing leaves of rice and maize. The developmental process of the longitudinal vascular bundles was divided into six stages in rice and five stages in maize. The initiation of differentiation into procambial progenitor cells forming the commissural vein arose in a circular layer cell that was adjacent to both a metaxylem vessel and one or a few phloem cells in stage V longitudinal vascular bundles. In most cases the differentiation of ground meristem cells into procambial progenitor cells extended in one direction, toward the next longitudinal vascular bundle, and subsequent periclinal divisions and further differentiation produced a vessel element, two companion cells and a sieve element to form a commissural vein. These results suggest the presence of an intercellular signal(s) that induces differentiation of the circular layer cell and the ground meristem cells into procambial progenitor cells, forming a commissural vein sequentially.     

The argentia mutation delays normal development of photosynthetic cell-types in Zea mays

Photosynthesis in C4-type grasses such as maize involves the interaction of two cell types (bundle sheath (BS) and mesophyll (M)) which both contain cell-specific photosynthetic enzymes. Malate dehydrogenase, phosphoenolpyruvate carboxylase and pyruvate phosphate dikinase are located in the M cells and malic enzyme and ribulose bisphosphate carboxylase are found in the BS cells. We have studied photosynthetic development in leaves of the temperature-sensitive greening mutant argentia (ar). We have determined that with the exception of malate dehydrogenase, levels of C4 enzymes are lower in ar leaves than in normal leaves. Malate dehydrogenase accumulates identically in both. Using in situ immunolocalization techniques with normal and ar leaves, we have observed a developmental pattern of C4 protein accumulation. In normal leaves protein was detected first in cells surrounding the median vein, then in cells surrounding other major veins, and finally in cells surrounding minor veins. In ar leaves, C4 enzymes accumulate in the correct cell type and in this same order but their appearance is delayed. Furthermore, BS cell development is delayed with respect to M cell development. The observed pattern of photosynthetic development reflects an earlier manifested pattern of vascular development yet the timing of vascular differentiation in ar mutants appears to be normal.     

Alanine synthesis by bundle sheath cells of maize

Because in the phloem sap of maize (Zea mays L.) leaves a quarter of the total amino nitrogen can be found as alanine, the capacity of a de novo synthesis of alanine from 3-phosphoglycerate (3-PGA) was studied with isolated bundle sheath (BS) strands of maize. Inasmuch as these cells have retained their plasmodesmatic openings, it was possible to study the formation of alanine from 3-PGA when glutamate and ADP were being added. Alanine synthesis required the existence of the intact cell structure. From the formation of the intermediates, partially released to the medium, the activities of the enzymes of the reaction chain from 3-PGA to alanine could be measured in the intact cells. The results show that in the BS cells the rate of alanine production from pyruvate (0.5 micromole/minute per milligram BS chlorophyll) is more than sufficient to produce one-fourth of the assimilated nitrogen as alanine. As the activity of pyruvate kinase in intact bundle sheath cells in the light was found to be only 0.2 micromole/minute per milligram BS chlorophyll, it is concluded that in the light part of the conversion of 3-PGA to pyruvate may not occur via pyruvate kinase reaction, but via phosphoeno/pyruvate carboxylase, NADP-malate dehydrogenase, and NADP-malic enzyme in the mesophyll and BS cells.     

Fluorescence and Delayed Light Emission from Mesophyll and Bundle Sheath Cells in Leaves of Normal and Salt-Treated Panicum miliaceum

A modified fluorescence microscope system was used to measure chlorophyll fluorescence and delayed light emission from mesophyll and bundle sheath cells in situ in fresh-cut sections from leaves of Panicum miliaceum L. The fluorescence rise in 3-(3,4-dichlorophenyl)-1, 1-dimethylurea (DCMU)-treated leaves and the slow fluorescence kinetics in untreated leaves show that mesophyll chloroplasts have larger photosystem II unit sizes than do bundle sheath chloroplasts. The larger photosystem II units imply more efficient noncyclic electron transport in mesophyll chloroplasts. Quenching of slow fluorescence also differs between the cell types with mesophyll chloroplasts showing complex kinetics and bundle sheath chloroplasts showing a relatively simple decline. Properties of the photosynthetic system were also investigated in leaves from plants grown in soil containing elevated NaCl levels. As judged by changes in both fluorescence kinetics in DCMU-treated leaves and delayed light emission in leaves not exposed to DCMU, salinity altered photosystem II in bundle sheath cells but not in mesophyll cells. This result may indicate different ionic distributions in the two cell types or, alternatively, different responses of the two chloroplast types to environmental change.     

Localization of nitrite and sulfite reductase in bundle sheath and mesophyll cells of maize leaves

The distribution of nitrite reductase (EC 1.7.7.1) and sulfite reductase (EC 1.8.7.1) between mesophyll ceils and bundle sheath cells of maize ( Zea mays L. cv. Seneca 60) leaves was examined. This examination was complicated by the fact that both of these enzymes can reduce both NO-₂ and SO^2-₃ In crude extracts from whole leaves, nitrite reductase activity was 6 to 10 times higher than sulfite reductase activity. Heat treatment (10 min at 55°C) caused a 55% decrease in salfite reductase activity in extracts from bundle sheath cells and mesophyll cells, whereas the loss in nitrite reductase activity was 58 and 82% in bundle sheath cells and mesophyll cell extracts, respectively. This result was explained, together with results from the literature, by the hypothesis that sulfite reductase is present in both bundle sheath cells and mesophyll cells, and that nitrite reductase is restricted to the mesophyll cells. This hypothesis was tested i) by comparing the distribution of nitrite reductase activity and sulfite reductase activity between bundle sheath and mesophyll cells with the presence of the marker enzymes ribulose-l, 5-bisphosphate carboxylase (EC 4.1.1.39) and phosphoe-nolpyruvate carboxylase (EC 4.1.1.32), ii) by examining the effect of cultivation of maize plants in the dark without a nitrogen source on nitrite reductase activity and sulfite reductase activity in the two types of cells, and iii) by studying the action of S^2-on the two enzyme activities in extracts from bundle sheath and mesophyll cells. The results from these experiments are consistent with the above hypothesis.     

Localization of antioxidant enzymes in the cellular compartments of sorghum leaves

The localization of antioxidant enzymes between the mesophyll and bundle sheath cells were determined in sorghum (Sorghum vulgare L.) leaves. The activity of antioxidant enzymes like superoxide dismutase (SOD), catalase (CAT), guaiacol peroxidase (POD), ascorbate peroxidase (APX) and glutathione reductase (GR) were assayed in whole leaf, mesophyll and bundle sheath fractions of sorghum leaves subjected to water-limited conditions. Drought was imposed by withholding water and the plants were maintained at different water potentials ranging from 0.5–2.0 MPa. The purity of the isolates was tested using the marker enzymes like RuBPcase and PEPcase. GR was mostly localized in mesophyll fraction, while SOD, APX and peroxidase were located in bundle sheath cells. Catalase was found to be equally distributed between the two cell types. Under water stress conditions, most of the SOD activity was found in the bundle sheath tissues. Little or no activity of the enzymes CAT, APX or POD was found in the mesophyll extracts when exposed to water stress. GR activity increased when exposed to low water regimes. From this study, it is clear that antioxidants are differentially distributed between the mesophyll and bundle sheath cells in sorghum leaves. Under water stress conditions, the mesophyll cells showed less damage from oxidative stress when compared to the bundle sheath cells. This is critical for determining the sensitivity of sorghum to extreme climatic conditions.     

Bundle sheath cells of small veins in maize leaves are the location of uptake from the xylem.

Rb(+) as a tracer for K(+) was used to test the hypothesis that uptake of K(+) from xylem vessels of small veins into the symplast of maize leaves occurs at the xylem/bundle sheath cell interface. 22.5 min after immersing cut leaves into 20 mM RbCl+1 mM KCl, Rb(+) appeared in the cells of the leaves. Sections of these leaves were freeze-dried. In cryo-thin sections (5 microm), (85)Rb(+) and (41)K(+) content was determined by laser microprobe mass analysis with a large resolution of about 1 microm. Determining the ratio of (85)Rb(+) to (41)K(+) in the cell walls and cytosols of bundle sheath cells, mesophyll cells, and in the cells between the xylem elements resulted in the following picture: In small veins, Rb(+) entered the symplast directly at the xylem/bundle sheath cell interface.     

Low bundle sheath carbonic anhydrase is apparently essential for effective c(4) pathway operation

Bundle sheath cells from leaves of a variety of C₄ species contained little or no carbonic anhydrase activity. The proportion of total leaf carbonic anhydrase in extracts of bundle sheath cells closely reflected the apparent mesophyll cell contamination of bundle sheath cell extracts as measured by the proportion of the mesophyll cell marker enzymes phosphoenolpyruvate carboxylase and pyruvate,Pi dikinase. Values of about 1% or less of the total leaf activity were obtained for all three enzymes. The recorded bundle sheath carbonic anhydrase activity was compared with a calculated upper limit of carbonic anhydrase activity that would still permit efficient functioning of the C₄ pathway; that is, a carbonic anhydrase level allowing a sufficiently high steady state [CO₂] to suppress photorespiration. Even before correcting for mesophyll cell contamination the activity in bundle sheath cell extracts was substantially less than the calculated upper limit of carbonic anhydrase activity consistent with effective C₄ function. The results accord with the notion that a deficiency of carbonic anhydrase in bundle sheath cells is vital for the efficient operation of the C₄ pathway.     

Evidence for phloem loading via the abaxial bundle sheath cells in maize leaves

Leaves are asymmetric, with different functions for adaxial and abaxial tissue. The bundle sheath (BS) of C₃ barley (Hordeum vulgare) is dorsoventrally differentiated into three types of cells: adaxial structural, lateral S-type, and abaxial L-type BS cells. Based on plasmodesmatal connections between S-type cells and mestome sheath (parenchymatous cell layer below bundle sheath), S-type cells likely transfer assimilates toward the phloem. Here, we used single-cell RNA sequencing to investigate BS differentiation in C₄ maize (Zea mays L.) plants. Abaxial BS (^abBS) cells of rank-2 intermediate veins specifically expressed three SWEET sucrose uniporters (SWEET13a, b, and c) and UmamiT amino acid efflux transporters. SWEET13a, b, c mRNAs were also detected in the phloem parenchyma (PP). We show that maize has acquired a mechanism for phloem loading in which ^abBS cells provide the main route for apoplasmic sucrose transfer toward the phloem. This putative route predominates in veins responsible for phloem loading (rank-2 intermediate), whereas rank-1 intermediate and major veins export sucrose from the PP adjacent to the sieve element companion cell complex, as in Arabidopsis thaliana. We surmise that ^abBS identity is subject to dorsoventral patterning and has components of PP identity. These observations provide insights into the unique transport-specific properties of ^abBS cells and support a modification to the canonical phloem loading pathway in maize.     

EFFECTS OF 2,3,5-TRIIODOBENZOIC ACID ON THE STRUCTURE OF SOYBEAN LEAVES

The effects of 2,3,5-triiodobenzoic acid (TIBA) on soybean leaves (Glycine max. [L.] Merrill ‘Harosoy‘) include thickening with intensification of color and some raised intercostal regions, giving a wrinkled appearance. These effects are not restricted to early stages of leaf development but are pronounced during and after unfolding of the leaf. Proliferation of tracheary elements, increased procambial activity, and hypertrophy of bundle sheath extension cells occurred in the leaflet midvein of the youngest expanded leaf treated with 50 ppm or 100 ppm of TIBA. The youngest treated leaves exhibited differential growth rates and expansion within the palisade and spongy layers. Hypertrophy of spongy cells in these leaves occurred independently or simultaneously with elongation of the upper and lower palisade layers. The palisade and spongy tissues had undergone cell division and expansion at a greater pace than the epidermal layers. This, along with hypertrophy in the bundle sheath extension cells, would explain the wrinkled appearance of the lamina. The treated leaf became thicker than the control as a result of the increased number of cells in the spongy layer and elongation in the palisade layer. The observed aberrations in leaf structure suggest that TIBA interferes with some auxin-translocating system within the plant.     

Structure and distribution of chloroplasts and other organelles in leaves with various rates of photosynthesis

The ultrastructure and distribution of chloroplasts, mitochondria, peroxisomes, and other cellular constituents have been examined in cross sections of leaves from plants with either high or low photosynthetic capacity. Photosynthetic capacity of a given plant cannot be correlated with the presence or absence of grana in bundle sheath cell chloroplasts, the presence or absence of starch grains in bundle sheath or mesophyll cell chloroplasts, the chloroplast size in bundle sheath or mesophyll cells, or the location of chloroplasts within bundle sheath cells. We conclude that the number and concentration of chloroplasts, mitochondria, and peroxisomes in bundle sheath cells is the most reliable anatomical criterion presently available for determining the photosynthetic capacity of a given plant.     

Ectopic divisions in vascular and ground tissues of Arabidopsis thaliana result in distinct leaf venation defects

Leaf venation patterns vary considerably between species and between leaves within a species. A mechanism based on canalization of auxin transport has been suggested as the means by which plastic yet organized venation patterns are generated. This study assessed the plasticity of Arabidopsis thaliana leaf venation in response to ectopic ground or procambial cell divisions and auxin transport inhibition (ATI). Ectopic ground cell divisions resulted in vascular fragments between major veins, whereas ectopic procambial cell divisions resulted in additional, abnormal vessels along major veins, with more severely perturbed lines forming incomplete secondary and higher-order venation. These responses imply limited vascular plasticity in response to unscheduled cell divisions. Surprisingly, a combination of ectopic ground cell divisions and ATI resulted in massive vascular overgrowth. It is hypothesized that the vascular overproduction in auxin transport-inhibited wild-type leaves is limited by simultaneous differentiation of ground cells into mesophyll cells. Ectopic ground cell divisions may negate this effect by providing undifferentiated ground cells that respond to accumulated auxin by differentiation into vascular cells.     

Cell position and light influence C4 versus C3 patterns of photosynthetic gene expression in maize.

C4 plants such as maize partition photosynthetic activities in two morphologically distinct cell types, bundle sheath (BS) and mesophyll (M), which lie as concentric layers around veins. We show that both light and cell position relative to veins influence C4 photosynthetic gene expression. A pattern of gene expression characteristic of C3 plants [ribulose bisphosphate carboxylase (RuBPCase) and light-harvesting chlorophyll a/b binding protein in all photosynthetic cells] is observed in leaf-like organs such as husk leaves, which are sparsely vascularized. This pattern of gene expression reflects direct fixation of CO2 in the C3 photosynthetic pathway, as determined by O2 inhibition assays. Light induces a switch from C3-type to C4-type gene expression patterns in all leaves, primarily in cells that are close to a vein. We propose that light causes repression of RuBPCase expression in M cells, by a mechanism associated with the vascular system, and that this is an essential step in the induction of C4 photosynthesis.     

Calcium,Calcium Oxalate Crystals,and Leaf Differentiation in the Common Bean (Phaseolus vulgaris L.)*

Young plants of Phaseolus vulgaris were grown in nutrient solutions at different levels of calcium concentration. When the calcium concentration was low more palisade parenchyma and less extended bundle sheath was formed at the adaxial side of minor veins of the leaves as compared to leaves of plants grown with higher calcium supply. The number of calcium oxalate crystals in the bundle sheath extensions was positively correlated to the amount of calcium fed to the plants. The ion induces additional cell divisions in the bundle sheath extensions. A high supply of calcium leads to the formation of a second type of crystal in the bundle sheath.     

Pyruvate, pi dikinase in bundle sheath strands as well as in mesophyll cells in maize leaves

Mesophyll protoplasts and bundle sheath strands were isolated from maize leaves. Light microscopic observation showed the preparations were pure and without cross contamination. Protein blot analysis of mesophyll and bundle sheath cell soluble protein showed that the concentration of pyruvate orthophosphate dikinase (EC 2.7.9.1) is about one-tenth as much in the bundle sheath cells as in mesophyll cells, but about eight times greater than that found in wheat leaves, on the basis of soluble protein. Phosphoenolpyruvate carboxylase (EC 4.1.1.31) was barely detectable in the bundle sheath cells, while ribulose-1,5-bisphosphate carboxylase (EC 4.1.1.39) and NADP-dependent malic enzyme (EC 1.3.1.37) were exclusively present in the bundle sheath cells and were absent in the mesophyll cells. Whereas pyruvate, Pi dikinase was previously considered localized only in mesophyll cells of C₄ plants, these results clearly demonstrate the presence of appreciable quantities of the enzyme in the bundle sheath cells of the C₄ species maize.