Richard E. Williamson

Mutation or Drug-Dependent Microtubule Disruption Causes Radial Swelling without Altering Parallel Cellulose Microfibril Deposition in Arabidopsis Root Cells

As critical determinants of growth anisotropy in plants, cortical microtubules are thought to constrain the movement of cellulose synthase complexes and thus align newly deposited cellulose microfibrils. We tested this cellulose synthase constraint model using the temperature-sensitive mor1-1 mutant of Arabidopsis. Contrary to predictions, the disruption of cortical microtubules in mor1-1 root epidermal cells led to left-handed root twisting and radial swelling but did not alter the transverse orientation of cellulose microfibrils. We also found that drug-dependent disassembly or hyperstabilization of cortical microtubules did not alter the parallel order of cellulose microfibrils. By measuring cellulose content in mor1-1 seedlings, we verified that cellulose synthesis is not reduced at the restrictive temperature. The independence of cortical microtubule organization and cellulose microfibril alignment was supported by the observation that double mutants of mor1-1 and rsw1-1, the cellulose-deficient mutant with misaligned microfibrils, had additive phenotypes. Our results suggest that cortical microtubules regulate growth anisotropy by some mechanism other than cellulose microfibril alignment or synthesis.

Orientation of Cortical Microtubules in Interphase Plant Cells

Publisher Summary This chapter examines the orientation of cortical microtubules (MTs) in interphase plant cells and explains the way interphase MTs orient by first establishing salient features of cortical microtubule arrays and then considering hypotheses for alignment against these features. Oriented cortical MTs are highly characteristic of plant cells. They are implicated in two functions of particular importance in plant morphogenesis: (1) the orientation of cellulose microfibrils when present as an interphase array and (2) the determination of the division plane when organized as a preprophase band. Interphase array is the MTs of all cells not actually undergoing mitosis or cytokinesis. These may range from meristematic cells, truly in an interphase among mitoses, to much older cells, which have expanded and differentiated and will not divide again in normal circumstances. It includes cells showing dispersed growth and those showing tip-localized growth. Based on studies using animal tubulins, MT assembly has been viewed as a two-stage process in which the product of a rate-limiting nucleation reaction extends at both ends by the reversible addition of tubulin through an equilibrium reaction. Microtubule-organizing centers (MTOCs) promote nucleation and permit assembly at levels of tubulin too low for a spontaneous assembly.

Fractionation of carbohydrates in Arabidopsis root cell walls shows that three radial swelling loci are specifically involved in cellulose production

Abstract. Three non-allelic radial swelling mutants (rsw1, rsw2 and rsw3) of Arabidopsisthaliana L. Heynh. were shown to be specifically impaired in cellulose production. Fractionation methods that identify, characterise and quantify some of the major cell wall polysaccharides in small quantities of seedlings demonstrated that changes in the production of cellulose are much more pronounced than changes in the production of non-cellulosic polysaccharides. A crude cell wall pellet was sequentially extracted with chloroform methanol (to recover lipids), dimethyl sulphoxide (starch), ammonium oxalate (pectins) and alkali (hemicelluloses). Crystalline cellulose remained insoluble through subsequent treatments with an acetic/nitric acid mixture and with trifluoroacetic acid. Cetyltrimethylammonium bromide precipitation resolved neutral and acidic polymers in the fractions, and precipitation behaviour, monosaccharide composition and glycosidic linkage patterns identified the major polysaccharides. The deduced composition of the walls of wild-type seedlings and the structure and solubility properties of the major polymers were broadly typical of other dicots. The three temperature-sensitive, radial swelling mutants produced less cellulose in their roots than the wild type when grown at their restrictive temperature (31 °C). There were no significant differences at 21 °C where no radial swelling occurs. The limited changes seen in the monosaccharide compositions, glycosidic linkage patterns and quantities of non-cellulosic polysaccharides support the view that the RSW1, RSW2 and RSW3 genes are specifically involved in cellulose synthesis. Reduced deposition of cellulose was accompanied by increased accumulation of starch.

Functional analysis of the cellulose synthase genes CesA1, CesA2, and CesA3 in Arabidopsis.

Polysaccharide analyses of mutants link several of the glycosyltransferases encoded by the 10 CesA genes of Arabidopsis to cellulose synthesis. Features of those mutant phenotypes point to particular genes depositing cellulose predominantly in either primary or secondary walls. We used transformation with antisense constructs to investigate the functions of CesA2(AthA) and CesA3 (AthB), genes for which reduced synthesis mutants are not yet available. Plants expressing antisense CesA1 (RSW1) provided a comparison with a gene whose mutant phenotype (Rsw1−) points mainly to a primary wall role. The antisense phenotypes of CesA1 and CesA3were closely similar and correlated with reduced expression of the target gene. Reductions in cell length rather than cell number underlay the shorter bolts and stamen filaments. Surprisingly, seedling roots were unaffected in both CesA1 and CesA3antisense plants. In keeping with the mild phenotype compared with Rsw1−, reductions in total cellulose levels in antisenseCesA1 and CesA3 plants were at the borderline of significance. We conclude that CesA3, likeCesA1, is required for deposition of primary wall cellulose. To test whether there were important functional differences between the two, we overexpressed CesA3 inrsw1 but were unable to complement that mutants defect in CesA1. The function of CesA2 was less obvious, but, consistent with a role in primary wall deposition, the rate of stem elongation was reduced in antisense plants growing rapidly at 31°C.

Cortical microtubules optimize cell-wall crystallinity to drive unidirectional growth in Arabidopsis.

The shape of plants depends on cellulose, a biopolymer that self-assembles into crystalline, inextensible microfibrils (CMFs) upon synthesis at the plasma membrane by multi-enzyme cellulose synthase complexes (CSCs). CSCs are displaced in directions predicted by underlying parallel arrays of cortical microtubules, but CMFs remain transverse in cells that have lost the ability to expand unidirectionally as a result of disrupted microtubules. These conflicting findings suggest that microtubules are important for some physico-chemical property of cellulose that maintains wall integrity. Using X-ray diffraction, we demonstrate that abundant microtubules enable a decrease in the degree of wall crystallinity during rapid growth at high temperatures. Reduced microtubule polymer mass in the mor1-1 mutant at high temperatures is associated with failure of crystallinity to decrease and a loss of unidirectional expansion. Promotion of microtubule bundling by over-expressing the RIC1 microtubule-associated protein reduced the degree of crystallinity. Using live-cell imaging, we detected an increase in the proportion of CSCs that track in microtubule-free domains in mor1-1, and an increase in the CSC velocity. These results suggest that microtubule domains affect glucan chain crystallization during unidirectional cell expansion. Microtubule disruption had no obvious effect on the orientation of CMFs in dark-grown hypocotyl cells. CMFs at the outer face of the hypocotyl epidermal cells had highly variable orientation, in contrast to the transverse CMFs on the radial and inner periclinal walls. This suggests that the outer epidermal mechanical properties are relatively isotropic, and that axial expansion is largely dependent on the inner tissue layers.

STUNTED PLANT 1, A Gene Required for Expansion in Rapidly Elongating but Not in Dividing Cells and Mediating Root Growth Responses to Applied Cytokinin

To understand the control of spatial patterns of expansion, we have studied root growth in wild type and in the stunted plant 1 mutant, stp1, of Arabidopsis thaliana. We measured profiles of cell length and calculated the distribution of elongation rate. Slow growth of stp1 results both from a failure of dividing cell number to increase and from low elongation rates in the zone of rapid expansion. However, elongation of dividing cells was not greatly affected, and stp1 and wild-type callus grew at identical rates. Thus, rapid cellular expansion differs in mechanism from expansion in dividing cells and is facilitated by the STP1 gene. Additionally, there was no difference between stp1 and wild-type roots for elongation in response to abscisic acid, auxin, ethylene, or gibberellic acid or for radial expansion in response to ethylene; however, stp1 responded to cytokinin much less than wild type. In contrast, both genotypes responded comparably to hormones when explants were cultured; in particular, there was no difference between genotypes in shoot regeneration in response to cytokinin. Thus, effects on root expansion mediated by cytokinin, but not effects mediated by other hormones or effects on other cytokinin-mediated responses, require the STP1 locus.

Wall architecture in the cellulose-deficient rsw 1 mutant of Arabidopsis thaliana: Microfibrils but not microtubules lose their transverse alignment before microfibrils become unrecognizable in the mitotic and elongation zones of roots

SummaryThersw1 mutant ofArabidopsis thaliana has a single amino acid substitution in a putative glycosyl transferase that causes a temperature-dependent reduction in cellulose production. We used recently described methods to examine root growth by surface marker particles, cell wall structure by field emission scanning electron microscopy and microtubule alignment by immunofluorescence after the mutant is transferred to its restrictive temperature. We find that raising the temperature quickly accelerates root elongation in both wild type and mutant, presumably as a result of general metabolic stimulation, but that in the mutant, the rate declines within 7–8 h and elongation almost ceases after 24 h. Radial swelling begins at about 6 h in the mutant and root diameter continues to increase until about 24 h. The normal transverse alignment of microfibrils is severely impaired in the mutant after 8 h, and chemical inhibition of cellulose synthesis by 2,6-dichlorobenzonitrile causes a similar loss of orientation. After 24 h, microfibrils are not clearly visible in the walls of cells that would have been in the mitotic and early-elongation zone of wild-type roots. Changes in older cells are less marked; loss of transverse microfibril orientation occurs without disruption to the transverse orientation of cortical microtubules. The wild type shows none of the changes except for acceleration of elongation, which in its case is sustained. We conclude that microfibril alignment requires the normal functioning of RSW1 and that, in view of the effects of dichlorobenzonitrile, there may be a more general linkage between the rate of cellulose production and its proper alignment.

Morphology of rsw1, a cellulose deficient mutant of Arabidopsis thaliana

SummaryTherswl mutant ofArabidopsis thaliana is mutated in a gene encoding a cellulose synthase catalytic subunit. Mutant seedlings produce almost as much cellulose as the wild type at 21 °C but only about half as much as the wild type at 31 °C. We used this conditional phenotype to investigate how reduced cellulose production affects growth and morphogenesis in various parts of the plant. Roots swell in all tissues at 31 °C, and temperature changes can repeatedly switch them between swollen and slender growth patterns. Dark-grown hypocotyls also swell, whereas cotyledons and rosette leaf blades are smaller, their surfaces are more irregular and their petioles shorter. Leaf trichomes swell and branch abnormally. Plants readily initiate inflorescences at 31 °C which have shorter but not fatter bolts and stomata which bulge above the uneven surface of internodes. Bolts carry the normal number of flowers, but their stigmas protrude beyond the shortened sepals and petals. Anthers dehisce normally, but self-fertilisation is reduced because the stigma is well above the anthers. Anther filaments are short and show a crumpled surface. Viable pollen develops, but female reproductive competence and postpollination development are severely impaired. We conclude that theRSW1 gene is important for cellulose synthesis in many parts of the plant and that reduced cellulose synthesis suppresses organ expansion rather than organ initiation, causes radial swelling only in the root and hypocotyl, but makes the surfaces of many organs uneven. We discuss some possible reasons to explain why different organs vary in their responses. The morphological changes suggest that RSW1 contributes cellulose to primary walls but do not yet exclude a role during secondary-wall deposition.

Arabidopsis dynamin-like protein DRP1A: a null mutant with widespread defects in endocytosis, cellulose synthesis, cytokinesis, and cell expansion

Dynamin-related proteins are large GTPases that deform and cause fission of membranes. The DRP1 family of Arabidopsis thaliana has five members of which DRP1A, DRP1C, and DRP1E are widely expressed. Likely functions of DRP1A were identified by studying rsw9, a null mutant of the Columbia ecotype that grows continuously but with altered morphology. Mutant roots and hypocotyls are short and swollen, features plausibly originating in their cellulose-deficient walls. The reduction in cellulose is specific since non-cellulosic polysaccharides in rsw9 have more arabinose, xylose, and galactose than those in wild type. Cell plates in rsw9 roots lack DRP1A but still retain DRP1E. Abnormally placed and often incomplete cell walls are preceded by abnormally curved cell plates. Notwithstanding these division abnormalities, roots and stems add new cells at wild-type rates and organ elongation slows because rsw9 cells do not grow as long as wild-type cells. Absence of DRP1A reduces endocytotic uptake of FM4-64 into the cytoplasm of root cells and the hypersensitivity of elongation and radial swelling in rsw9 to the trafficking inhibitor monensin suggests that impaired endocytosis may contribute to the development of shorter fatter roots, probably by reducing cellulose synthesis.

Euglenoid movement inEuglena fusca: Evidence for sliding between pellicular strips

SummaryInEuglena fusca, each pellicular strip carries a row of particles on its surface. The relative displacement of particles on adjacent strips was analysed by video-microscopy and evidence was obtained that adjacent pellicular strips slide relative to each other during euglenoid movement.E. fusca shows two types of euglenoid movement, oscillatory bending and rounding-up of the cell body. During oscillatory bending, the maximum velocity of sliding was 0.4 μm/s and the maximum displacement distance between adjacent strips 2.3 μm about their mean position. WhenE. fusca exhibited rounding-up of the cell body, particle displacement again occurred and the angle of the pellicular strips to the long axis of the cell body increased because of pellicular sliding. As a result the distance between the cells anterior and posterior tips was reduced. There was no change in distance either between rows of particles or between particles within the same row. The findings are incompatible with theories of euglenoid movement requiring local contraction of pellicular strips and point to the likely existence of active sliding between adjacent strips.