UDP-Glucose: (1-->3)-beta-Glucan Synthases from Mung Bean and Cotton: Differential Effects of Ca and Mg on Enzyme Properties and on Macromolecular Structure of the Glucan Product

A re-examination of the kinetic properties of UDP-glucose: (1→3)-β-glucan (callose) synthases from mung bean seedlings (Vigna radiata) and cotton fibers (Gossypium hirsutum) shows that these enzymes have a complex interaction with UDP-glucose and various effectors. Stimulation of activity by micromolar concentrations of Ca²⁺ and millimolar concentrations of β-glucosides or other polyols is highest at low (<100 micromolar) UDP-glucose concentrations. These effectors act both by raising the V_max of the enzyme, and by lowering the apparent K_m for UDP-glucose from >1 millimolar to 0.2 to 0.3 millimolar. Mg²⁺ markedly enhances the affinity of the mung bean enzyme for Ca²⁺ but not for β-glucoside; with saturating Ca²⁺, Mg²⁺ only slightly stimulates further production of glucan. However, the presence of Mg²⁺ during synthesis, or NaBH₄ treatment after synthesis, changes the nature of the product from dispersed, alkali-soluble fibrils to highly aggregated, alkali-insoluble fibrils. Callose synthesized in vitro by the Ca²⁺, β-glucoside-activated cotton fiber enzyme, with or without Mg²⁺, is very similar in size to callose isolated from cotton fibers, but is a linear (1→3)-β-glucan lacking the small amount of branches at C-0-6 found in vivo. We conclude that the high degree of aggregation of the fibrils synthesized with Mg²⁺in vitro is caused either by an alteration of the glucan at the reducing end or, indirectly, by an effect of Mg²⁺ on the conformation of the enzyme. Rate-zonal centrifugation of the solubilized mung bean callose synthase confirms that divalent cations can affect the size or conformation of this enzyme.     

beta]-Glucan Synthesis in the Cotton Fiber (IV. In Vitro Assembly of the Cellulose I Allomorph)

In vitro assembly of cellulose from plasma membrane extracts of the cotton (Gossypium hirsutum) fiber was enriched by a combination of 3-(N-morpholino)propanesulfonic acid extraction buffer and two independent digitonin solubilization steps consisting of 0.05% digitonin (SE1) followed by 1% digitonin (SE2). Glucan synthase activity assays revealed that, although the SE2 fraction possessed higher activity, only 8.6% of the in vitro product survived acetic/nitric acid treatment. On the other hand, the SE1 fraction was less active, but 32.1% of the total glucan in vitro product was resistant to acetic/nitric acid. In vitro products synthesized from the SE1 fraction contained [beta]-1,3-glucan and fibrillar cellulose I, whereas the SE2 fraction produced [beta]-1,3-glucan and cellulose II. Both celluloses assembled in vitro were labeled with cellobiohydrolase I-gold complex, and the electron diffraction patterns of both products from SE1 and SE2 revealed cellulose I and cellulose II, respectively. Contamination of native cellulose was ruled out by extensive evidence from autoradiography of the ethanol-insoluble and acetic/nitric acid-insoluble materials, including three different controls.     

Interaction between Auxin–binding Protein–I and RNA Polymerase II

Interactions between auxin–binding protein–I (ABP–I), purified from etiolated mung bean seedlings, and nuclear components from mung bean tissues were investigated. When NaCI–solubilized components of chromatin were put on an affinity column of ABP–I–Iinked Sepharose 4B, a small amount of the material was retained on the affinity column and was eluted with 1 M NaCl. RNA polymerase II activity was detected in the eluted fraction. Partially purified RNA polymerase II from mung bean nuclei and purified RNA polymerase II from wheat germ also bound to ABP–I. Indole–3–acetic acid was not necessary for the binding of RNA polymerase II to ABP–I. Acid–denatured ABP–I did not bind to RNA polymerase II from wheat germ. The addition of ABP–I to the reaction mixture for RNA synthesis in vitro caused a stimulation of the activity of wheat germ RNA polymerase.     

Surface area and porosity of acid hydrolyzed cellulose nanowhiskers and cellulose produced by Gluconacetobacter xylinus

The physical parameters of cellulose such as surface area and porosity are important in the development of cellulose composites which may contain valuable additives which bind to cellulose. In this area, the use of acid hydrolyzed nano-dimensional cellulose nanowhiskers (CNWs) has attracted significant interest, yet the surface area and porosity of these materials have not been explored experimentally. The objective of this work was to characterize the surface area and porosity of CNWs from different origins (plant cotton/bacterium Gluconacetobacter xylinus) and different acid treatments (H₂SO₄/HCl) by N₂ adsorption; as well as to compare surface area and porosity of bacterial cellulose synthesized by static and agitated cultures. Our results showed that CNWs produced from H₂SO₄/HCl exhibited significantly increased surface area and porosity relative to starting material cotton fiber CF11. Micropores were generated in HCl hydrolyzed CNWs but not in H₂SO₄ hydrolyzed CNWs. Bacterial CNWs exhibited larger surface area and porosity compared to plant CNWs. Cellulose synthesized by G. xylinus ATCC 700178 from agitated cultures also exhibited less surface area and porosity than those from static cultures.     

Ethylene is a modulator of gibberellic acid-induced antheridiogenesis in <Emphasis Type="Italic">Anemia phyllitidis</Emphasis> gametophytes

In fern (Anemia phyllitidis) gametophytes cellulose in the walls of the antheridial zone cells which was organized in clusters and spots was transformed via dispersed form to fibrillar arrangement (layered in oblique and perpendicular array in relation to the transverse direction of cell expansion) during antheridiogenesis induced by gibberellic acid (GA₃) and/or enhanced by 1-aminocyclopropane-1-carboxylic acid (ACC). In the ACC-treated gametophytes, where antheridia were not induced, the cellulose was arranged in the same manner. Aminooxyacetic acid (AOA), which inhibits antheridiogenesis and development of fern gametophytes, produced in the cell walls both random and longitudinal type of organization of cellulose microfibrils, however, in the GA₃/AOA-treated plants the oblique type was also observed. The total numbers of cells with perpendicular and/or oblique type of cellulose microfibrils in the GA₃-, GA₃/ACC-and GA₃/AOA-treated gametophytes corresponded to the average number of antheridia formed. Moreover, it was found that the extracts from the gametophytes treated with GA₃ or with the mixture of GA₃ and ACC contained significantly less soluble sugars but more α-amylase-and endoglucanase-released sugars than the extracts from the gametophytes of the other series. Thin layer chromatography of the samples from the cell wall extracts hydrolyzed by endoglucanase contained xylose and cellobiose which suggested that these sugars built the xyloglucans, hemicellulose polymers responsible for tethering of walls of fern gametophyte cells like in higher plants.     

THE COMPOSITION AND PHYLOGENETIC SIGNIFICANCE OF THE MOUGEOTIA (CHAROPHYCEAE) CELL WALL1

The two-layered, fibrillar cell wall of Mougeotia C. Agardh sp. consisted of 63.6% non-cellulosic carbohydrates and 13.4% cellulose. The orientation of cellulose microfibrils in the native cell wall agrees with the multinet growth hypothesis, which has been employed to explain the shift in microfibril orientation from transverse (inner wall) toward axial (outer wall). Monosaccharide analysis of isolated cell walls revealed the presence of ten sugars with glucose, xylose and galactose most abundant. Methylation analysis of the acid-modified, 1 N NaOH insoluble residue fraction showed that it was composed almost exclusively of 4-linked glucose, confirming the presence of cellulose. The major hemicellulosic carbohydrate was semi-purified by DEAE Sephacel (Cl^?) anion-exchange chromatography of the hot 1 N NaOH soluble fraction. This hemicellulose was a xylan consisting of a 4-xylosyl backbone and 2,4-xylosyl branch points. The major hot water soluble neutral polysaccharide was identified as a 3-linked galactan. Mougeotia cell wall composition is similar to that of (Charophyceae) and has homologies with vascular plant cell walls. Our observations support transtructural evidence which suggests that members of the Charophyceae represent the phylogenetic line that gave rise to vascular plants. Therefore, the primary cell walls of vascular plants many have evolved directly from structures typical of the filamentous green algal cell walls found in the Charophyceae.     

Altered matrix polysaccharides in cell walls of pocket galls formed by an aphid on Distylium racemosum leaves

The present work reports the results of a study on the isolation and characterization of matrix polysaccharides in the cell walls of galls formed by an aphid (Neothoracaphis yanonis) on Distylium racemosum leaves. Cell walls were isolated from both healthy Distylium leaf and gall tissues and then extracted sequentially with cyclohexane‐trans‐1,2‐diaminetetra‐acetate (CDTA), Na₂CO₃, 1 m KOH, and 4 m KOH. The amount of pectin solubilized from gall cell walls was approximately 2.6‐fold higher than the pectin solubilized from leaf cell walls, whereas the amount of hemicellulose solubilized from gall cell walls was 1.4‐fold higher than that from normal leaf cell walls. When the polysaccharides were fractionated by anion‐exchange chromatography, considerable increases in arabinose and galactose were observed in CDTA‐soluble pectic polymer (fraction PI‐1) from gall cell walls, whereas the gall cell walls had less xylose in 1 m KOH‐soluble hemicellulosic polymers (fractions HI‐2, HI‐3, and HI‐4) than did the cell walls from the healthy leaf. The hemicellulosic polymers of the gall cell walls exhibited distinctly different patterns of molecular mass, compared with the healthy leaf cell walls. These results suggest that an extensive change occurs in the matrix polysaccharide structure of the cell walls of Distylium galls formed by an aphid. In addition, many glycosylhydrolase activities were detected in the protein fraction solubilized with strong saline solution from the gall cell walls, and the activities of β‐galactosidase, β‐xylosidase and α‐l ‐arabinofuranosidase were considerably increased under gall formation.     

Particulate cytochromes of mung bean seedlings

Efforts have been made to solubilize cytochrome components from particulate fractions of etiolated mung bean seedlings. Low temperature spectrophotometry reveals that the cytochrome composition of mitochondria isolated from whole seedlings is the same as that reported by Bonner for mung bean hypocotyls. On the basis of the identity in position of the α-bands in low temperature difference spectra for mitochondria, for a partially purified haemoprotein from mitochondria, and for purified cytochrome b-555, it is suggested that cytochrome b-555 is an intrinsic component of mung bean mitochondria. Difference spectra show that both the mitochondrial and microsomal fractions contain at least 2 b-type cytochromes. Cytochrome b-555 is almost certainly present in the microsomes, since the low temperature difference spectrum for the cytochrome is identical with the spectrum for this particulate fraction.

By freezing and thawing mung bean mitochondria in 4% cholate and centrifuging, cytochrome oxidase activity can be concentrated in the supernatant fraction, although it is not completely solubilized. The oxidase is inhibited by high concentrations of cytochrome c. A particle-bound cytochrome c can be obtained from mitochondria by digestion with snake venom. However, the autoxidizability of the preparation indicates that the cytochrome has been solubilized in a modified form. A CO-binding pigment can be obtained from mung bean microsomes by digestion with snake venom.

     

Almost Pure Iα Cellulose in the Cell Wall of Glaucocystis

Crystalline features of cellulose microfibrils in the cell walls of Glaucocystis (Glaucophyta) were studied by combined spectroscopy and diffraction techniques, and the results were compared with those of Oocystis (Chlorophyta). Although these algae are grouped into two different classes, by the composition of their chloroplasts for instance, their cell walls are quite similar in size and morphology. The most striking features of their cellulose crystallites are that they have the highest cellulose I_α contents reported to date. In particular, the I_α fraction of cellulose from Glaucocystis was found to be as high as 90% from ¹³C NMR analysis. The mode of preferential orientation of cellulose crystallites in their cell walls is also interesting; equatorial 0.53-nm lattice planes were oriented parallel to the cell surface in the case of Glaucocystis, while the 0.62-nm planes were parallel to the Oocystis cell surface. Such a structural variation provides another link to the evolution of cellulose structure, biosynthesis, and its biocrystallization mechanism.     

Differences in the Thermostability and Subunit Species of Cytochrome c Oxidase among Tissues

Cytochrome c oxidase associated with the mitochondrial innermembrane of the overground or underground organs of mung beanwas more stable at 40–55?C than that of the correspondingorgans of pea. In both plants, the enzyme in the overgroundorgans was more resistant to heat inactivation than that inthe underground organs. When the enzyme was solubilized andpartially purified from mung bean hypocotyls or roots, the enzymebecame more labile and was stabilized by exogenous phospholipid.The enzyme partially purified from mung bean hypocotyls wasmore resistant to inactivation than that from its roots eitherin the presence or absence of phospholipid. A subunit (subunitVa) of cytochrome c oxidase in mung bean hypocotyls differedimmunologically from that in the roots. We propose that at leastin mung bean, a nuclear-encoded subunit of cytochrome c oxidaseis synthesized tissue-specifically, which may cause the differencein the thermostability of the enzyme. (Received August 7, 1988; Accepted August 22, 1988)     

Purification and characterization of high salt-soluble vicilin from mung bean (Vigna radiata)

We report a method for the purification of vicilin from mung bean (Vigna radiata) mainly on the basis of solubility of mung bean vicilin even in high salt. Mung bean vicilin remains in solution even after 90% relative saturation of ammonium sulphate. The resulting supernatant after dialysis was subjected to gel filtration (Sephadex G-150) to remove other contaminant polypeptides, and finally the protein was purified by DEAE cellulose chromatography. This purified fraction exhibited 3 bands on SDS-PAGE compared with vicilin from other legumes which exhibite more than 3 bands generally. The results raise the possibility that the presence of the two small polypeptides in vicilin preparations is the breakdown product of the major larger one of mol.wt. 52 K and that vicilin may be a tetramer of four subunits of Mr 52000. That the high salt-soluble protein containing 52 K subunit is vicilin has been determined by several criteria.     

Ferulic acid impairs rhizogenesis and root growth,and alters associated biochemical changes in mung bean (Vigna radiata) hypocotyls

The present study investigated the effect of ferulic acid (FA; 0–1000 µM) on early growth, and rhizogenesis in mung bean (Vigna radiata) hypocotyls and associated biochemical changes. FA severely affected the radicle elongation and number of secondary roots after 72 h. The root and shoot length, number and length of secondary roots, and seedling dry weight of one-week-old seedlings of mung bean were decreased by 64%. The rooting potential (percent rooting, number and length of adventitious roots) of mung bean hypocotyls under in vitro conditions was significantly inhibited in response to 1–100 µM FA. At 1000 µM there was complete cessation of rooting. FA caused a reduction in the contents of water-soluble proteins and endogenous total phenolics, whereas the activities of proteases, peroxidases, and polyphenol peroxidases increased. The study concludes that FA inhibits root growth and development, and in vitro rooting process in mung bean by interfering with biochemical processes that are crucial for root formation.     

A CELLULOSE SYNTHASE (CESA) GENE FROM THE RED ALGA PORPHYRA YEZOENSIS (RHODOPHYTA)1

The cell walls of Porphyra species, like those of land plants, contain cellulose microfibrils that are synthesized by clusters of cellulose synthase enzymes (“terminal complexes”), which move in the plasma membrane. However, the morphologies of the Porphyra terminal complexes and the cellulose microfibrils they produce differ from those of land plants. To characterize the genetic basis for these differences, we have identified, cloned, and sequenced a cellulose synthase (CESA) gene from Porphyra yezoensis Ueda strain TU‐1. A partial cDNA sequence was identified in the P. yezoensis expressed sequence tag (EST) index using a land plant CESA sequence as a query. High‐efficiency thermal asymmetric interlaced PCR was used to amplify sequences upstream of the cDNA sequence from P. yezoensis genomic DNA. Using the resulting genomic sequences as queries, we identified additional EST sequences and a full‐length cDNA clone, which we named PyCESA1. The conceptual translation of PyCESA1 includes the four catalytic domains and the N‐ and C‐terminal transmembrane domains that characterize CESA proteins. Genomic PCR demonstrated that PyCESA1 contains no introns. Southern blot analysis indicated that P. yezoensis has at least three genomic sequences with high similarity to the cloned gene; two of these are pseudogenes based on analysis of amplified genomic sequences. The P. yezoensis CESA peptide sequence is most similar to cellulose synthase sequences from the oomycete Phytophthora infestans and from cyanobacteria. Comparing the CESA genes of P. yezoensis and land plants may facilitate identification of sequences that control terminal complex and cellulose microfibril morphology.     

beta-1,3-Glucan in Developing Cotton Fibers: Structure, Localization, and Relationship of Synthesis to That of Secondary Wall Cellulose

Evidence is presented for the existence of a noncellulosic β-1,3-glucan in cotton fibers. The glucan can be isolated as distinct fractions of varying solubility. When fibers are homogenized rigorously in aqueous buffer, part of the total β-1,3-glucan is found as a soluble polymer in homogenates freed of cell walls. The proportion of total β-1,3-glucan which is found as the soluble polymer varies somewhat as a function of fiber age. The insoluble fraction of the β-1,3-glucan remains associated with the cell wall fraction. Of this cell wall β-1,3-glucan, a variable portion can be solubilized by treatment of walls with hot water, a further portion can be solubilized by alkaline extraction of the walls, and 17 to 29% of the glucan remains associated with cellulose even after alkaline extraction. A portion of this glucan can also be removed from the cell walls of intact cotton fibers by digestion with an endo-β-1,3-glucanase. The glucan fraction which can be isolated as a soluble polymer in homogenates freed of cell walls is not associated with membranous material, and we propose that it represents glucan which is also extracellular but not tightly associated with the cell wall. Enzyme digestion studies indicate that all of the cotton fiber glucan is β-linked, and methylation analyses and enzyme studies both show that the predominant linkage in the glucan is 1 → 3. The possibility of some minor branching at C-6 can also be deduced from the methylation analyses. The timing of deposition of the β-1,3-glucan during fiber development coincides closely with the onset of secondary wall cellulose synthesis. Kinetic studies performed with ovules and fibers cultured in vitro show that incorporation of radioactivity from [¹⁴C]glucose into β-1,3-glucan is linear with respect to time almost from the start of the labeling period; however, a lag is observed before incorporation into cellulose becomes linear with time, suggesting that these two different glucans are not polymerized directly from the same substrate pool. Pulse-chase experiments indicate that neither the β-1,3-glucan nor cellulose exhibits significant turnover after synthesis.     

Broadline proton magnetic resonance study of cellulose,pectin, and bean cell walls

We have used broadline proton magnetic resonance to study molecular motion in cellulose, a sodium pectate solution, a calcium pectate gel, and isolated bean cell walls. All samples were prepared in D₂O to minimize the contribution of water to the observed signals. For each sample, a free induction decay was obtained, and the second moment, spin-lattice relaxation, and dipolar relaxation were measured. Our results show that the large majority of protons in cellulose are immobile. Rigid and mobile domains were also observed in the pectate samples. We have shown that gelation induces large-scale changes in the free induction decay, the second moment, and the relaxation behavior of the pectate. As with the other samples, rigid and more mobile domains were found in bean cell walls. The fraction in the rigid domains is much larger than the fraction of cellulose in the sample, suggesting that the noncellulosic wall components are also organized into rigid and mobile domains.     

Isolation and culture of cotton ovule epidermal protoplasts (prefiber cells) and analysis of the regenerated wall

Culture protocols were developed and characterization of the regenerated cell walls was performed for protoplasts of cotton (Gossypium hirsutum L., L., var. Acala SJ-2) ovule epidermal cells. This work was undertaken in order to extend studies concerning nutritional effects and regulation of nucleotide sugar incorporation into -1,3- and -1,4-glucan components of cotton fiber cell walls. Protein and carbohydrate polymers and recovered from the culture medium. Analysis of a cellular fraction indicated that the majority of ¹⁴C incorporated from [¹⁴C] glucose was present in the hot-water-soluble fraction of the cells. The majority of label incorporated into cell wall material could be solubilized with acetic-nitric reagent, indicative of noncellulosic material, and characterized as -1,3-linked glucans. Only 5 to 15% of the regenerated cell wall could be characterized as -1,4-linked glucose indicative of cellulose.     

CELL WALL CARBOHYDRATE EPITOPES IN THE GREEN ALGA OEDOGONIUM BHARUCHAE F. MINOR (OEDOGONIALES,CHLOROPHYTA)1

Cell wall changes in vegetative and suffultory cells (SCs) and in oogonial structures from Oedogonium bharuchae N. D. Kamat f. minor Vélez were characterized using monoclonal antibodies against several carbohydrate epitopes. Vegetative cells and SCs develop only a primary cell wall (PCW), whereas mature oogonial cells secrete a second wall, the oogonium cell wall (OCW). Based on histochemical and immunolabeling results, (1→4)‐β‐glucans in the form of crystalline cellulose together with a variable degree of Me‐esterified homogalacturonans (HGs) and hydroxyproline‐rich glycoprotein (HRGP) epitopes were detected in the PCW. The OCW showed arabinosides of the extensin type and low levels of arabinogalactan‐protein (AGP) glycans but lacked cellulose, at least in its crystalline form. Surprisingly, strong colabeling in the cytoplasm of mature oogonia cells with three different antibodies (LM‐5, LM‐6, and CCRC‐M2) was found, suggesting the presence of rhamnogalacturonan I (RG‐I)–like structures. Our results are discussed relating the possible functions of these cell wall epitopes with polysaccharides and O‐glycoproteins during oogonium differentiation. This study represents the first attempt to characterize these two types of cell walls in O. bharuchae, comparing their similarities and differences with those from other green algae and land plants. This work represents a contribution to the understanding of how cell walls have evolved from simple few‐celled to complex multicelled organisms.     

Inhibition of the biosynthesis of plant cell wall materials, especially cellulose biosynthesis, by coumarin

Coumarin in a concentration range from of 10–100 ppm inhibitedthe growth of rice, mung bean, lettuce and clover seedlings.These growth inhibitions were accompanied by remarkable tissueswelling in the stem-base and root tip zones. Microscopic observationof the swollen tissue showed that there was no increase in cellnumber, but swelling of individual cells was observed. In aconcentration range of 25–100 ppm, coumarin increasedthe fresh weight of plumular hook sections of mung bean, butdecreased the dry weight. This phenomenon indicates that abnormalwater-imbibition by cells occurs as an effect of coumarin. Inaddition, 25 ppm of coumarin noticeably induced wilting in thenewly developing leaves of rice plants. With plumular hook sectionsof mung bean, 100 ppm of coumarin did not affect the incorporationof ¹⁴C-glucose into the cytoplasm, but did inhibit its incorporationinto the cell wall by about 30%. Of the inhibition ratios for¹⁴C-glucose incorporation into the cell wall fraction, thatinto cellulose was conspicuous at about 70%, while ratios intoother cell wall fractions were less than 10%. It has also beendemonstrated that the inhibition of ¹⁴C-glucose incorporationinto cellulose by coumarin is due to the inhibition of its biosynthesisand not to a stimulation of its breakdown. The relation of theinhibition of cellulose biosynthesis by coumarin to the inductionof cell swelling is discussed, illustrating coumarin's effecton isolated root cells of soybean. ¹Present address: International Rice Research Institute, P.O. Box 1300, M. C. C, Makati, Philippines. ²Present address: Nippon Roche Research Center, Kamakura, Japan. (Received July 12, 1972; )     

Effects of 2-benzoxazolinone on the germination, early growth and morphogenetic response of mung bean (Phaseolus aureus)

2‐Benzoxazolinone (BOA), a type of hydroxamic acid present in cereals and implicated in allelopathy, is now being viewed as a potential candidate for the development of natural herbicides. A study was conducted to determine the effect of BOA on mung bean (Phaseolus aureus) through a multitude of bioassays to understand its physiological and biochemical action. It was observed that BOA significantly decreased the germination of mung bean and its early growth (measured in terms of seedling length and dry weight). A typical dose–response relationship was observed with BOA treatment, and I₅₀ values (concentrations at which 50% inhibition occurs) for germination, seedling length and seedling dry weight were calculated to be 4.3, 0.71 and 0.77 mM , respectively. There was therefore a greater inhibitory effect on seedling growth than on germination. Treated seedlings were characterised by a loss of chlorophyll and decreased respiratory activity, indicating a possible adverse effect of BOA on photosynthetic and respiratory metabolism. Mitotic activity in root‐tip cells of onion (Allium cepa) was completely arrested in response to BOA treatment, and the cells exhibited abnormality in shape and size. BOA also adversely affected rhizogenesis in hypocotyl cuttings of mung bean, indicating an impact on morphogenetic potential. It was associated with significant changes in the protein content and activities of proteases and polyphenol oxidases during the root development phase. This study concludes that BOA interfered with essential biochemical processes in mung bean. Such studies provide useful information on the biochemical and physiological modes of actions of BOA, with a view to its use as a herbicidal compound.     

Phytotoxicity of selected herbicides to mung bean (Phaseolus aureus Roxb.)

Mung bean (Phaseolus aureus Roxb.) is grown after harvest of wheat during the fallow period. Herbicides such as metsulfuron, atrazine and isoxaflutole are recommended to control weeds in wheat–rice cropping system including weeds of fallow crop. The effects of three herbicides with different modes of action—atrazine, photosystem II inhibitor; metsulfuron, acetolactate synthase inhibitor; and isoxaflutole, 4-hydroxyphenylpyruvatedioxygenase inhibitor—on shoot height, chlorophyll concentrations and cellular damage in herbicide-treated mung bean were studied. While isoxaflutole inhibited shoot growth and chlorophyll concentration of mung bean, atrazine and metsulfuron did not cause reduction in the shoot growth of mung bean. Metsulfuron (226, 452, 1356 and 2260 μg/kg soil) and isoxaflutole (452, 1356 and 2260 μg/kg soil) in soil reduced the concentration of leaf chlorophyll of mung bean compared to the control. Atrazine in soil did not affect the total chlorophyll concentration of mung bean leaves. Electron micrographs showed that untreated mung bean had elongated chloroplasts, thylakoids organized as intact grana, distinct starch grains and a small number of plastoglubuli. Mesophyll cells of atrazine-treated mung bean leaves had swollen chloroplasts and thylakoids with disorganized grana. Leaves of metsulfuron-treated mung bean had swollen chloroplasts with a large number of starch grains. Starch grains were not observed in leaves of mung bean treated with either atrazine or isoxaflutole. Complete disruption of thylakoids was observed in isoxaflutole-treated mung bean leaves. Leaves of atrazine-treated mung bean showed detached microfibrils along with distorted and degenerated secondary walls. Metsulfuron-treated mung bean leaves showed aggregated microfibrils with completely dissolved secondary walls, while isoxaflutole-treated leaves had completely degenerated secondary walls with complete loss of microfibrils. We conclude that isoxaflutole at higher doses, influence mung bean at the morphological, physiological and cellular levels.