Jeanne M. Lang scite author profile

Two marine bacterial isolates differ considerably in their uptake rates of extracellular products produced by the alga Skeletonema costatum: 0.4 x 10WR pg 0 cell-l hr-l for spirillum 7697; 16 x lo-' ,ug C cell-l hr-l for pscudomonad HNY. These disparate uptake rates are used to interpret the growth patterns of the bacteria in the presence of the alga on a seawater inorganic enrichment medium. Pseudomonad HNY grows well with the alga in both batch and continuous culture, in the latter attaining a steady state population two orders of magnitude greater than achieved in the absence of the alga, Spirillum 7697, however, grows poorly in the presence of growing algal cells and appears to be inhibited to some cxtcnt under such conditions.Such observations suggest that dominant bacterial populations associated with algal blooms arc a result of both stimulation and inhibition mediated by the release of extracellular products.

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Reorganization of cortical microtubules and cellulose deposition during leaf formation in Graptopetalum paraguayense

Hardham

Green

Lang

1980

Planta

107

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In the "regeneration" of a shoot from a leaf of the succulent, Graptopetalum paraguayense E. Walther the first new organs are leaf primordia. The original arrangement of cellulose microfibrils and of microtubules (MTs) in the epidermis of the leaf-forming site is one of parallel, straight lines. In the new primordium both structures still have a congruent arrangement but it is roughly in the form of concentric circles that surround the new cylindrical organ. The regions which undergo the greatest shift in orientation (90°) were studied in detail. Departures from the original cellulose alignment are detected in changes in the polarized-light image. Departures from the original cortical MT arrangement are detected using electron microscopy. The over-all reorganization of the MT pattern is followed by the tally of MT profiles, the various regions being studied in two perpendicular planes of section. This corrects for the difference in efficiency in counting transverse versus longitudinal profiles of MTs. Reorientation takes place sporadically, cell by cell, for both the cellulose microfibrils and the MTs, indicating a coordinated reorientation of the two structures. That MTs and cellulose microfibrils reorient jointly in individual cells was shown by reconstruction of the arrays of cortical MTs in paradermal sections of individual cells whose recent change in the orientation of cellulose deposition had been detected with polarized light. Closeness of the two alignments was also indicated by images where the MT and microfibril alignments co-varied within a single cell. The change-over in alignment of the MTs appears to involve stages where arrays of contrasting orientation co-exist to give a criss-cross image. During this critical reorganization, the frequency of the MTs is high. It falls during subsequent enlargement of the organ. It was found that the rearrangement of the cortical MTs to approximate a series of concentric circles on the residual meristem occurred before the emergence of leaf primordia. Through their apparent influence on microfibril alignments, the changes in MT disposition, described here, have the potential to generate major biophysical changes that accompany organogenesis.

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Toward a biophysical theory of organogenesis: Birefringence observations on regenerating leaves in the succulent, Graptopetalum paraguayense E. Walther

Green

Lang

1981

Planta

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Polarity shifts occur during organogenesis. The histological criterion for polarity is the direction of cell division. The biophysical criterion is the orientation of reinforcing cellulose microfibrils which lie normal to the organ axis and which determine the preferred growth direction. Using cell pattern to deduce cell lineage, and polarized light to study cellulose alignment, both aspects of polarity were examined in the epidermis of regenerating G. paraguayense. In this system new leaves and a stem arise from parallel cell files on a mature leaf. Large (90°) shifts in polarity occur in regions of the epidermis to give the new organs radial symmetry in the surface plane (files radiating from a pole). Study of the shifts in the epidermis showed that, during certain stages, shifts in the division direction are accompanied by shifts in the cellulose deposition direction, as expected. The new cellulose orientation is parallel to the new cross wall. During normal organ extension, however, shifts in division direction do not bring on changes in cellulose pattern. Thus the coupling between the two kinds of polarity is facultative. This variable relation is used in a biophysical model which can account for the reorganization of cell file pattern and cellulose reinforcement pattern into the radial symmetry of the new organ.

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Jeanne M. Lang

Effects of ethylene on the orientation of microtubules and cellulose microfibrils of pea epicotyl cells with polylamellate cell walls

Selective stimulation of marine bacteria by algal extracellular products1

Reorganization of cortical microtubules and cellulose deposition during leaf formation in Graptopetalum paraguayense

Toward a biophysical theory of organogenesis: Birefringence observations on regenerating leaves in the succulent, Graptopetalum paraguayense E. Walther

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