Cotton ovule culture: A tool for basic biology, biotechnology and cotton improvement

Summary Nearly 30 years ago the conditions for culturing immature cotton ovules were established to serve as a working research tool for investigating the physiology and biochemistry of fiber development. Not only has this tissue culture method been employed to characterize the biochemistry of plant cell expansion and secondary cell wall synthesis, but ovule cultures have contributed to numerous other aspects of plant cell physiology and development as well. In addition to basic studies on fiber development, cotton ovule cultures have been used to examine plant-fungal interactions, to model low temperature stress responses, to elucidate the pathways responsible for pigment formation in naturally pigmented fiber and to probe how cytoskeletal elements regulate cell wall organization. Success in rescuing Gossypium interspecific hybrids was dependent on ovule culture media formulations that could support early embryo development in ovulo. As tissues produced in culture are analyzed by increasingly more sophisticated techniques, there appear to be some differences between ovule growth in planta and ovule growth in vitro. Discerning how ovule culture fiber development is different from fiber development in field-grown plants can contribute valuable information for crop improvement. Cotton ovule cultures are an especially attractive model system for studying the effects of gravity on cell elongation, cellulose biosynthesis and embryo development and are excellent targets for examining transient expression of introduced gene constructs. With only minor modification, the procedure originally described by C. A. Beasley and I. P. Ting for growing cotton ovules in vitro will continue to be useful research tool for the foreseeable future.     

Analysis of cell-wall polymers during cotton fiber development

Although the fibers of cotton (Gossypium hirsutum L.) are single cells with a secondary wall composed primarily of cellulose, the cell-wall polymers of the fibers are technically difficult to characterize with respect to molecular weights. This limitation hinders understanding how the fiber wall composition changes during development, particularly with respect to genotypic variations, and how the molecular composition is related to physical properties. We analyzed cell-wall polymers from cotton fibers (cultivar, Texas Marker-1) at several developmental stages (8–60 days post-anthesis; DPA) by gel-permeation chromatography of components soluble in dimethyl acetamide and lithium chloride. This procedure solubilizes fiber cell-wall components directly without prior extraction or derivatization, processes that could lead to degradation of high-molecular-weight components. Cellwall polymers from fibers at primary cell-wall stages had lower molecular weights than the cellulose from fibers at the secondary wall stages; however, the high-molecularweight cellulose characteristic of mature cotton was detected as early as 8 DPA. High-molecular-weight material decreased during the period of 10–18 DPA with concomitant increase in lower-molecular-weight wall components, possibly indicating hydrolysis during the later stages of elongation.Abbreviations DMAC dimethyl acetamide - DP degree of polymerization - DPA days post anthesis - GPC gel-permeation chromatography - MW molecular weight - MWD molecular-weight distribution - TM-1 Texas Marker 1     

Effect of Boron on the Incorporation of Glucose from UDP-Glucose into Cotton Fibers Grown in Vitro

Boron is required for fiber growth and development in cotton ovules cultured in vitro. Incorporation of [¹⁴C]glucose by such fiber from supplied UDP-[¹⁴C]glucose into the hot alkali-insoluble fraction is rapid and linear for about 30 minutes. Incorporation of [¹⁴C]glucose from such substrate by fibers grown in boron-deficient ovule cultures is much less than in the case with fibers from ovules cultured with boron in the medium. Total products (alkali-soluble plus alkali-insoluble fractions) were also greater in fibers from ovules cultured with boron. The fraction insoluble in acetic-nitric reagent was a small part of the total glucans; however, in the boron-sufficient fibers, there was significantly more of this fraction than in fibers from boron-deficient ovule cultures. The hot water-soluble glucose polymers from the labeled fibers had a significant fraction of the total [¹⁴C]glucose incorporated from UDP-[¹⁴C]glucose. Both β-1,4- and β-1,3- water-soluble polymers were formed in the boron-sufficient fibers, whereas the same water-soluble fraction from the boron-deficient fibers was predominantly β-1,3-polymers. The incorporation of [¹⁴C]glucose from GDP-[¹⁴C]glucose by the fibers attached to the ovules was insignificant.     

Hormonal regulation of cotton ovule and fiber growth: Effects of bromodeoxyuridine,AMO-1618 and p-chlorophenoxyisobutyric acid

The effects of 5-bromo-2-deoxyuridine (BUdR, thymidine analogue), AMO-1618 (2-isopropyl-4-dimethylamino-5-methylphenyl-1-piperidine carboxylate methyl chloride), a growth retardant, and p-chlorophenoxyisobutyric acid (PCIB, an antiauxin) on growth (dry weight increase) and fiber development in unfertilized cotton (Gossypium hirsutum L.) ovules grown in vitro have been studied. BUdR (5 M) causes about 70% inhibition of fiber production, with little effect on ovule growth, if applied during the first 6 d of culture in the presence of GA₃ and IAA. AMO-1618, when used with GA₃ alone, causes only a small reduction in both dry weight and fiber production, but when used with IAA alone reduces both fiber production and dry weight, the effect on the latter being predominant. In the presence of both IAA and GA₃, AMO-1618 causes a small decrease in fiber production but a major decrease in dry weight. PCIB completely inhibits fiber growth but has little effect on dry weight, especially when GA₃ is present. These results indicate that GA₃ mainly promotes ovule growth while IAA is largerly responsible for fiber growth.Abbreviations AMO-1618 2-isopropyl-4-dimethylamino-5-methylphenyl-1-piperidine carboxylate methyl chloride - BUdR 5-bromo-2-deoxyuridine - GA₃ gibberellic acid - IAA indole-3-acetic acid - PCIB p-chlorophenoxyisobutyric acid - TFU total fiber units     

Changes in the sugar composition and molecular mass distribution of matrix polysaccharides during cotton fiber development

Cotton (Gossypium herbaceum L.) fiber development consists of a fiber elongation stage (up to 20 d post-anthesis) and a subsequent cell wall thickening stage. Cell wall analysis revealed that the extractable matrix (pectic and hemicellulosic) polysaccharides accounted for 30-50% of total sugar content in the fiber elongation stage but less than 3% in the cell wall thickening stage. By contrast, cellulose increased dramatically after the fiber elongation ceased. The amounts of extractable xyloglucans and arabinose- and galactose-containing polymers per seed increased in the early fiber elongation stage and decreased thereafter. The amounts of extractable acidic polymers and non-cellulosic beta-glucans (mainly composed of beta-1,3-glucans) increased in parallel with fiber elongation and then decreased. The molecular masses of extractable non-cellulosic beta-glucans, and arabinose- and galactose-containing polymers decreased during both fiber elongation and cell wall thickening stages. The molecular mass of extractable xyloglucans also decreased during the fiber elongation stage, but this decrease ceased during the cell wall thickening stage. Conversely, the molecular size of acidic polymers in the extractable pectic fraction increased during both stages. Thus, not only the amounts but also the molecular size of the extractable matrix polysaccharides showed substantial changes during cotton fiber development.     

Cotton fibers can undergo cell division

Ovular culture was used to determine the cell cycle aspects of cotton fiber cells. Each ovule (Gossypium hirsutum, cultivar, MD51 ne) grown under the conditions used has ~10 000 fiber cells at 4 d postanthesis. About 25% of these cells divide when ovules are cultured at 34C. Mitosis occurs after fiber cells differentiate, producing multicelled fibers. The basal and tip cells of multicelled fibers have the same characteristics as the polar ends of single-celled fibers. Most cell division occurs in ovules cultured at 2-3 d postanthesis. Multicelled fibers are rare in ovules cultured at 1 d postanthesis and absent if cultured at 7 d postanthesis. No multicelled fibers are detectable on ovules sampled from the plant regardless of age. Fiber cell division occurs in the absence of exogenous hormones. The addition of IAA and GA3 to the medium lowers the frequency of multicelled fibers. IAA alone further reduces their frequency, while GA3 by itself has no effect. The number of fiber cells per cultured ovule ranges between 9462 and 11 087 and is not significantly different from the 9892 seen in the plant at 4 d postanthesis. These findings show that a subpopulation of fiber cells, fully differentiated in appearance, retain cell cycle functions up to 4 d postanthesis.     

Adding gelling agents to cotton ovule culture media leads to subtle changes in fiber development

Summary Young cotton (Gossypium hirsutum) ovules will produce fiber in vitro when floated on a defined culture medium. Our laboratory is interested in examining the effects of altered gravity environments on fiber development as a model for the effects of gravity on cell expansion and cellulose biosynthesis. Since liquid culture media are unsuitable for altered gravity experiments, addition of gelling agents to cotton ovule culture media is necessary. In this study we have systematically examined the effects of four gelling agents at several concentrations on fiber production in culture. A rapid screening method using toluidine blue O staining indicated that after 3 wk in culture, fiber growth on 0.15% (wt/vol) Phytagel™ medium was similar to fiber growth on liquid medium. More detailed analysis of fiber development revealed that fiber length was not influenced by the addition of Phytagel™. Accumulation of cellulose, however, was reduced 50–60% compared with fibers produced in liquid media after 3 wk in culture. The fiber cellulose content rose with additional time in culture for both solid and liquid media treatments. By 4 wk in culture, the difference in cellulose content of fiber cell walls grown on solid versus liquid media was less than 20%. This variance in growth response on gelled media could be due to differences in media matric potential, to the immobility of ions trapped within the gel, or to toxicity of contaminants copurifying with Phytagel™. By identifying why ovule growth and fiber cellulose biosynthesis are reduced in cultures grown on gelled media, it will be possible to reveal new information about these processes in system that is less complicated than physiological systems at the whole plant level. Names of companies or commercial products are given solely for the purpose of providing specific information; their mention does not imply recommendation or endorsement by the U.S. Department of Agriculture over others not mentioned.     

Slime of Myxococcus virescens

The slime excreted by two strains of Myxococcus virescens during growth in liquid casitone medium was studied. Strain S1H, unable to grow in dispersion, excreted slime during growth later than strain D11, which grows in dispersion. Slime was precipitated from the cell-free culture solution with ethanol and the crude precipitate fractionately dissolved using first pH 5,4 and then pH 9.0 for the remainder of the precipitate. Comparatively more material from strain S1H than from strain D11 belonged to the pH 9.0 fraction. The fractions thus obtained were dialyzed and then lyophilized. The composition of the slime preparations varied with the density of the harvested cultures. The slime fraction dissolved at low pH contained 12–18 % (w/w) Folin reactive material, 2–4% lipid and 5–30% anthrone positive material (glucose equivalents). The fraction soluble at pH 9.0 was richer in Folin positive material. About 25% of the proteolytic activity in the culture solution was recovered in the slime preparations. No DNA was detected in the slime, unless the cultures were harvested daring the phase of decline. The high polymers of the slime were separated from material of low molecular weight and coprecipitated media constituents by gel filtration on Sepharose 2B. The relative amount of the high polymers increased during growth, although they seemed to be degraded in the culture during the phase of decline. The polymer had a molecular weight of about 20 million. In most preparations: it was Folin positive.     

A novel cottong ovule culture: Induction, growth, and characterization of submerged cotton fibers (Gossypium hirsutum L.)

Summary The growth of submerged cotton (Gossypium hirsutum L.) fibers from cultured ovules has been investigated. The results indicate that exogenous plant hormone levels regulate the induction of submerged fiber growth. The age of ovules at induction is also important. Cell diameter, wall thickness, and cell length of submerged fibers were measured and compared with air-grown fibers and fibers grown in vivo (produced by cotton plants grown in the greenhouse). Various cellwall thickening patterns were observed among submerged fibers, while only one predominant cell-wall deposition pattern was produced in air-grown fibers and in fibers produced in vivo. The diameter of submerged fibers was about the same as that of air-grown fibers but about 22% less than that of fibers grown, in vivo. It appears that the secondary cell wall thickenings are initiated earlier in submerged fibers. The cell-wall thickness of submerged fibers, at 41 d post anthesis (DPA), was 51% greater than that of fibers grown in vivo, whereas the cell-wall thickness of air-grown fibers was 42% less than that of fibers produced in vivo. The cell length of submerged fibers was approximately half that of fibers grown in vivo. and the air-grown fiber length was about two-thirds of fibers grown in vivo. The age of ovules at induction affects the outcome of the air-grown fiber-cell length, but does not appear to affect the length of submerged fiber cells. To produce submerged fiber growth, we found that the optimal age of ovules at induction was 0 DPA, and the optimal medium (with a GA₃ of 0.5 μM and an IAA range of 5-20 μM) depends on the time of ovule induction (−2 to+2DPA). We conclude that conditions leading to submerged cotton fiber growth have great potential for (a) direct monitoring of growth and making precise, detailed measurements during fiber growth and development; (b) producing cellulose and fibers in vitro more efficiently than earlier ovule-culture methods; and (c) using these unique cultures to obtain a better understanding of signal transduction and gene expression leading to growth, development, and programmed cell death in the life history of the cotton fiber.     

Chronology of the differentiation of cotton (Gossypium hirsutum L.) fiber cells

Cotton fibers are single elongated cells that develop from epidermal cells of the ovule. The chronology of fiber differentiation was investigated using cultured ovules. Epidermal cells differentiate into fiber cells approx. 3 d before anthesis. When ovules were cultured on a defined medium, fiber growth could be initiated on ovules any time between 2 d preanthesis and the time of anthesis by adding indole-3-acetic acid and gibberellic acid to the medium. In the absence of phytohormones, fibers did not grow, and when ovules between 2 d preanthesis and anthesis were cultured without hormones past the day of anthesis and hormones then added, most ovules failed to produce fibers. The results define the timing of fiber differentiation from epidermal cells, and also define a window of time when differentiated cells are capable of further development. During this window, fiber cells are latent awaiting appropriate stimulation which in the intact plant is apparently associated with anthesis.Abbreviations GA₃ gibberellic acid - IAA indole-3-acetic acid     

Digital image analysis of expansion growth of cultured cotton ovules with fibers and their responses to ABA

Cotton ovule cultures have obvious advantages over whole plants when experimental protocols call for inhibitors, radio-labeled precursors or controlled environmental conditions to be tested. The responses of ovule expansion growth and attached fiber elongation to external factors require accurate measurement techniques. This paper presents a new method for digital image analysis of the growth area of cotton ovules with fibers at high resolution. The method was characterized under constant conditions and during dynamic responses to different levels of ABA (abscisic acid) treatment. The growth area was treated as area occupied within the outline of the Petri dish image of the growing ovule with fibers. Growth area increase showed the same trends as fiber length increase and was significantly correlated with the fiber length increase under different levels of ABA treatment (r ² = 0.97). This new analysis method provides a simple, noninvasive, and more accurate approach for growth analysis in the cotton ovule culture system. Using this method, the effects of ABA on expansion growth of ovule with fibers were characterized.     

Cotton-fiber germin-like protein. II: Immunolocalization,purification, and functional analysis

Cotton (Gossypium hirsutum L.) contains a germin-like protein (GLP), GhGLP1, that shows tissue-specific accumulation in fiber. The fiber GLP is an oligomeric, glycosylated protein with a subunit size of approximately 25.5 kDa. Accumulation of GhGLP1 occurs during the period of fiber elongation [4–14 days post-anthesis (DPA)]. During early phases of fiber development (2–4 DPA), GhGLP1 localizes to cytoplasmic vesicles as shown by confocal immunofluorescent microscopy. In slightly older fibers (7–10 DPA), GhGLP1 localizes to the apoplast. In other plants, germins and GLPs have been reported to have enzymatic activities including oxalate oxidase (OxO), superoxide dismutase, and ADP-glucose pyrophosphatase. Cotton fiber extracts did not contain OxO activity, nor did intact fibers stain for OxO activity. A four-step purification protocol involving ammonium sulfate precipitation of a 1.0 M NaCl extract, ion-exchange chromatography on DEAE-Trisacryl M, lectin-affinity chromatography, and gel filtration chromatography resulted in electrophoretically pure GhGLP1. While 1.0 M NaCl extracts from 10–14 DPA fiber contained superoxide dismutase and phosphodiesterase activities, GhGLP1 could be separated from both enzyme activities by the purification protocol. Although a GLP accumulates in the cotton fiber apoplast during cell elongation, the function of this protein in fiber growth and development remains unknown.Abbreviations ABP Auxin binding protein - AGPPase ADP-Glucose pyrophosphatase/phosphodiesterase - bis-PNPP Bis-p-nitrophenol phosphate - ConA Concanavalin A - DOA Day of anthesis - DPA Days post-anthesis - GLP Germin-like protein - Mn-SOD Manganese superoxide dismutase - OxO Oxalate oxidase - PBS Phosphate-buffered saline     

Ovule and suspension culture of a cotton fiber development mutant

Summary Growth and development of cotton fibers in a developmental mutant, Ligon-lintless, and its near isogenic wild type, Texas Marker-1, were compared in ovule and cell suspension cultures. In both organ and cell cultures the pattern of growth of fiber cells from the two genotypes mimicked the pattern ofin vivo growth. The timing of fiber cell initiation soon after anthesis in Ligon-lintless suggests that the fiber cells on this mutant are analogous to the commercially important lint fibers. Length distributions of elongated cells from cell suspension culture of Ligon-lintless and Texas Marker-1 indicate that the length attained in culture is affected by the genotype of the explant tissue.     

The Enzymatic Synthesis of Rubber Polymer in Parthenium argentatum Gray

Washed rubber particles isolated from stem homogenates of Parthenium argentatum Gray by ultracentrifugation and gel filtration on columns of LKB Ultrogel AcA34 contain rubber transferase which catalyzes the polymerization of isopentenyl pyrophosphate into rubber polymer. The polymerization reaction requires Mg²⁺ isopentenyl pyrophosphate, and an allylic pyrophosphate. The K_m values for Mg²⁺, isopentenyl pyrophosphate, and dimethylallyl pyrophosphate were 5.2 × 10⁻⁴ molar, 8.3 × 10⁻⁵ molar, and 9.6 × 10⁻⁵ molar, respectively. The molecular characteristics of the rubber polymer synthesized from [¹⁴C]isopentenyl pyrophosphate were examined by gel permeation chromatography on three linear columns of 1 × 10⁶ to 500 Ångstroms Ultrastyragel in a Waters 150C Gel Permeation Chromatograph. The peak molecular weight of the radioactive polymer increased from 70,000 in 15 minutes to 750,000 in 3 hours. The weight average molecular weight of the polymer synthesized over a 3 hour period was 1.17 × 10⁶ compared to 1.49 × 10⁶ for the natural rubber polymer extracted from the rubber particles. Over 90% of the in vitro formation of the rubber polymer was de novo from dimethylallyl pyrophosphate and isopentenyl pyrophosphate. Treatment of the washed rubber particles with 3-[(3-cholamidopropyl)dimethylammonio]-1-propanesulfonate solubilized the rubber transferase. The solubilized enzyme(s) catalyzed the polymerization of isopentenyl pyrophosphate into rubber polymer with a peak molecular weight of 1 × 10⁵ after 3 hours of incubation with Mg²⁺ and dimethylallyl pyrophosphate. The data support the conclusion that the soluble preparation of rubber transferase is capable of catalyzing the formation of a high molecular weight rubber polymer from an allylic pyrophosphate initiator and isopentenyl pyrophosphate monomer.     

Changes in the level of tubulin subunits during development of cotton (Gossypium hirsutum) fiber

The levels of tubulin protein in developing cotton ( Gossypium hirsutum L. cv. Stoneville 825) fibers were measured from 8 to 28 days post-anthesis using commercially available monoclonal antibodies against alpha- and beta-tubulin. As the monoclonal antibodies against alpha- and beta-tubulin were prepared from yeast tubulin and chick brain tubulin, respectively, indirect immunofluorescence microscopy was used to establish that the two monoclonal antibodies recognized microtubule structures in cotton fibers. Western blots of electrophoretically separated proteins in crude extracts of cotton roots and fibers showed that single polypeptides with the expected apparent molecular weight for tubulin subunits were recognized by the antisera. An enzyme-linked immunosorbent assay was used to quantify tubulin levels. From 10 to 20 days post-anthesis the level of tubulin protein increases approximately three-fold. After 20 days post-anthesis, the amount of tubulin relative to total fiber protein reaches a plateau or decreases slightly. The rapid rise in tubulin is correlated with the elongation of the fiber and an increase in cellulose synthesis.