Priyavadan A. Joshi

Nodulation of white clover (Trifolium repens) in the absence ofRhizobium

SummarySpontaneous nodules developed on the roots of white clover (Trifolium repens cv. Ladino) in the absence ofRhizobium. A small subpopulation of uninoculated clover plants (0.2%) exhibited white, single-to-multilobed elongated structures on their root systems when grown without fixed nitrogen. Clonal propagation using aseptic stolons confirmed the genetic stability of the observation. Few if any viable bacteria of unknown origin were recovered from surfacesterilized structures. Nodule contents were incapable of eliciting nodulation. Histological observations showed that these structures possessed all the characteristic features of indeterminate nodules, such as active meristem, cortex, endodermal layer, vascular strands, and a central zone with parenchyma cells. Infection threads, intercellular or intracellular bacteria were absent. Instead, numerous starch grains were observed in the central zone, a feature absent in normal nitrogen-fixing nodules. Our observation broadens the concept of spontaneous nodulation, believed to be restricted to alfalfa (Medicago sativa), to other legumes, and suggests a degree of generality among indeterminately nodulated legumes displaying natural heterozygosity.

Ontogeny and ultrastructure of spontaneous nodules in alfalfa (Medicago sativa)

SummaryThe development of spontaneous nodules, formed in the absence ofRhizobium and combined nitrogen, on alfalfa (Medicago sativa L. cv. Vernal) was investigated at the light and electron microscopic level and compared to that ofRhizobium-induced normal nodules. Spontaneous nodules were initiated from cortical cell divisions in the inner cortex next to the endodermis, i.e., the site of normal nodule development. These nodules, on uninoculated roots, were white multilobed structures, histologically composed of nodule meristems, cortex, endodermis, central zone and vascular strands. Nodules were devoid of intercellular or intracellular bacteria confirming microbiological tests. Early development of spontaneous nodules was initiated by series of anticlinal followed by periclinal divisions of dedifferentiated cells in the inner cortex of the root. These cells formed the nodular meristem from which the nodule developed. The cells in the nodule meristems divided unequally and differentiated into two distinct cell types, one larger type being filled with numerous membrane-bound starch grains, and the other smaller type with very few starch grains. There were no infection threads or bacteria in the spontaneous nodules at any stage of development. This size differentiation is suggestive of the different cell sizes seen inRhizobium-induced nodules, where the larger cell type harbours the invading bacteria and the smaller type is essential in supportive metabolic roles. The ontogenic studies further support the claim that these structures are nodules rather than aberrant lateral roots, and that plant possess all the genetic information needed to develop a nodule with distinct cell types. Our results suggest that bacteria and therefore theirnod genes are not necessarily involved in the ontogeny and morphogenesis of spontaneous and normal nodules in alfalfa.

Spontaneous nodules induce feedback suppression of nodulation in alfalfa

A small subpopulation of alfalfa (Medicago saliva L.) plants grown without fixed nitrogen can develop root nodules in the absence of Rhizobium. Cytological studies showed that these nodules were organized structures with no inter- or intracellular bacteria but with the histological characteristics of a normal indeterminate nodule. Few if any viable bacteria were recovered from the nodules after surface sterilization, and when the nodular content was used to inoculate alfalfa roots no nodulation was observed. These spontaneous nodules were formed mainly on the primary roots in the region susceptible to Rhizobium infection between 4 and 6 d after seed imbibition. Spontaneous nodules appeared as early as 10 d after germination and emerged at a rate comparable to normal nodules. The formation of spontaneous nodules on the primary root suppressed nodulation in lateral roots after inoculation with R. meliloti RCR2011. Excision of spontaneous nodules at inoculation eliminated the suppressive response. Our results indicate that the presence of Rhizobium is not required for nodule organogenesis and the elicitation of feedback regulation of nodule formation in alfalfa.

Anatomical analysis of nodule development in soybean reveals an additional autoregulatory control point

Abstract The region of the root of soybean ( Glycine max [L.] Merr. cv. Bragg) susceptible to nodule initiation by Bradyrhizobium japonicum Jordan USDA110 was examined by serial section and light microscopy to study the control of nodule development. Three successive susceptible regions separated by 24-h intervals were examined. Infection foci were catalogued within defined stages of nodule development (as defined by Calvert et al., Can. J. Bot., 62 (1984) 2375–2384) and their number and location determined after short (72 h) and long (13 days) post-inoculation periods. The overall distributions of cell division stages were similar for both short and long periods, indicating that regulatory mechanisms were active throughout root development. Early cell division foci with no visible meristems (stages I–II) appeared with similar frequency in each susceptible region. In contrast, the frequency of more mature cell division events showing developing meristems (stagesIII–IV) was decreased in the third susceptible region for both periods. The constant frequency of cell division stages I–II within the feedback regulated reduction coupled with the reduction of later stages implies that nodule initiation is slowed and that the transition from cell division stage II to stage III is also regulated.

Ultrastructural localization of ATPase activity in cotton fiber during elongation

SummaryThe ultrastructural distribution of potassium chloride stimulated adenosine triphosphatase activity was investigated in the outer integument of a linted cultivar of cotton and a lintless (naked seed) mutant from one day preanthesis to eight days postanthesis by using a heavy metal simultaneous capture reaction technique. No enzyme activity other than in mitochondria was observed in the lintless mutant. In the linted cultivar no ATP-specific enzyme activity was seen in non-elongating epidermal cells, subepidermal cells of the outer integuments or any controls. As fiber initials started elongating, enzyme activity gradually appeared on the tonoplasts of enlarging vacuoles. Heavier lead phosphate deposits were observed on the membrane of small vacuoles compared to the tonoplast. This activity continued at least to eight days postanthesis. The enzyme inhibitor, N,N-dicyclohexylcarbodiimide inhibited, while KCl stimulated, tonoplast ATPase activity. The gradual increase of ATPase activity on the tonoplast of expanding fibers, but not on the tonoplasts of non-fiber cells, suggests the active transport of osmotically active compounds, presumably potassium and malate, into the vacuoles of expanding fibers. Fusion of smaller vacuoles with the large central vacuole indicates that these structures contribute additional membrane components along with their enzyme activity to the tonoplast of expanding fibers. The occurrence of ATPase activity, of ER-derived vesicular structures, and the organized pattern of deposition of these structures on the tonoplast indicate ER-originated ATPase activity. This study supports the theory of osmoregulation in cotton fiber where ATPase provides the energy for active accumulation of osmotically active compounds, (K+, malate) into the vacuoles, thereby generating and maintaining the turgor pressure required for fiber expansion.

Novel Fixation of Plant Tissue, Staining through Paraffin with Alcian Blue and Hematoxylin, and Improved Slide Preparation

Onion (Allium cepa) root tips were fixed in a proprietary solution without aldehyde, toxic metals or acetic acid. Fixed specimens were embedded in paraffin, sectioned on a rotary microtome and mounted on detergent-washed slides without adhesive. Slides with ribbon segments affixed were immersed in 0.2% aqueous alcian blue 8GX in screw-capped Coplin jars in a water bath at 50 C for 1 hr. Excess alcian blue was rinsed off under cold running tap water and the slides were immersed in quick-mixed hematoxylin at room temperature for 15 min. Stained slides were deparaffinized, rinsed with isopropanol, air dried, and coverslips were affixed with resin. Thus, the traditional paraffin microtechnique has been modified at all steps from fixation to finishing slides with coverslips.

Immunohistochemical localisation of ubiquitin and the proteasome in sunflower (Helianthus annuus cv. Giganteus).

Abstract. This study provides an immunohistochemical demonstration of the involvement of the ubiquitin- and proteasome-dependent pathway during differentiation and organogenesis in plants. The localisation of ubiquitin and the proteasome was studied in meristems, leaves, stems and roots of sunflower (Helianthus annuus L. cv. Giganteus). By using a new technique that enhances very low antigen signals, we obtained information on the structural distribution of the ubiquitin- and proteasome-dependent pathway, and of the importance of this pathway during organogenesis and plant development. Ubiquitin and the proteasome showed overall similarities in their cellular localisation. The highest antigenic signal was observed in the root and shoot apical meristems, in leaf primordia and vascular tissue. The cambium showed less expression than the apical meristems. During adventitious root formation in cuttings, no sign of increased expression was observed within dedifferentiating tissue, but as organogenesis progressed, the antigenic signal of ubiquitin and the proteasome gradually increased in the developing roots. Comparison of immunochemical results and Western blots demonstrated that important changes in the cellular antigen signal could only be detected by immunochemistry.

The ultrastructure of hemocytes inDactylopius confusus (Cockerell), and the role of granulocytes in the synthesis of cochineal dye

SummaryThe ultrastructural study of free circulating hemocytes in the adult cochineal scale,Dactylopius confusus (Cockerell), demonstrated five cell types: prohemocytes, typical granulocytes (T-granulocytes), oenocytoids, plasmatocytes, and granulocytes with modified sub-cellular structure to perform a special synthetic and secretory function, which we refer to as “modified granulocytes” (M-granulocytes). Prohemocytes showed undifferentiated sub-cellular structure of the basic stem cell type (i.e., high cytoplasmic density with numerous ribosomes, centrally located large nucleus with a distinct nucleolus, and poorly developed endoplasmic reticulum). The commonly observed typical granulocytes (T-granulocytes) had several smooth endoplasmic reticulum (SER) with dilated cisternae and many SER-derived membrane bounded granules of different sizes and electron density. Oenocytoids were identified by the presence of many crystals, RER-originated fine secretory granules, and an eccentric nucleus. Plasmatocytes were easily characterized by their variable shapes and irregular outline with pseudopodia-like cytoplasmic extensions, possession of an elongated lobed nucleus, multivesicular bodies, RER-derived membrane bounded, electron-dense, lysosomelike vacuoles, well-developed SER cisternae, and numerous pinocytic and SER-originated vesicles of different sizes along the peripheral region. M-granulocytes comprised the largest proportion of hemocytes in all samples observed. M-granulocytes were distinguished not only by the presence of membrane bounded granules of different sizes and electron density, but by the possession of large nuclei with distinct nucleoli, many mitochondria, and a highly developed network of rough endoplasmic reticulum (RER). M-granulocytes had abundant, rosette-shaped, RER-derived chains of fine secretory granules, which accumulated in the cytoplasm and vacuoles, and were ultimately deposited into the hemolymph by exocytosis. These fine granules gave a positive result with periodic acid-Schiff (PAS) test. Based on RER-synthesized fine secretory granules (M-granulocytes), their ultimate deposition into hemolymph, the red pigmentation of hemolymph, positive PAS histochemical test of these granules, and the high population of these hemocytes, no such cell type has been described in previous studies in insects. The sub-cellular structure of the granulocyte in this insect has been modified to perform a special synthetic and secretory function (i.e., possibly the synthesis of the red pigment found in hemolymph, which has been the source of commercially important cochineal dye).

Nodule Morphogenesis in the Absence of Rhizobium

It is generally assumed that Rhizobium and Bradyrhizobium bacteria are the causative agent for nodulation in legumes. The analysis of bacterial genes and their products is focused on the elucidation of the signal-transduction pathway leading to cell division, differentiation and infection (Caetano-Anolles, Gresshoff, 1991a). Bacteria are chemoattracted to the root surface (Bauer, Caetano-Anolles, 1990) where plant flavonoids induce bacterial gene expression (Peters, Verma, 1990) and secretion of factors that trigger the first morphological responses in the host, root hair curling and cortical cell division (Denarie et al. 1992). Concurrent anticlinal and periclinal cell divisions, usually beneath the infection site, initiate a nodule primordium that forms a persistent nodule meristem in its distal end and gives rise to a central tissue with infected and uninfected cells.

Localization of β-glycerophosphatase activity in cotton fiber during differentiation

SummaryThe distribution of β-glycerophosphatase activity in the outer integument of cotton (Gossypium hirsutum L.) ovules was determined histochemically at the electron microscope level. Both a linted cultivar and a lintless mutant line were examined from 1 day preanthesis to 3 days postanthesis. No enzyme activity was observed in the lintless line at any stage. In the linted cultivar there was no enzyme activity before anthesis, but as fibers were initiated on the day of anthesis, activity was observed in the expanding fiber cell wall and nucleus. As the fibers started elongating, enzyme activity was particularly concentrated in the cytoplasm and wall where directional growth towards the micropyle occurs. By 2 days postanthesis, β-glycerophosphatase activity was decreasing in the cell wall and nucleus, but was increasing in the nucleolus. Enzyme activity in the nucleolus was highest at 3 days post-anthesis, but nuclear β-glycerophosphatase activity was not observed then. These results indicate that β-glycerophosphatase activity was associated with differentiating fiber cells, specifically with those sites where distinct anatomical, and perhaps catabolic, changes were occurring. The significance of the results is discussed in relation to possible mechanisms of cotton fiber differentiation.