Sucrose Phosphate Synthase Activity Rises in Correlation with High-Rate Cellulose Synthesis in Three Heterotrophic Systems

Cotton (Gossypium hirsutum cv Acala SJ-1) Plant Growth and Culture

For in vitro fiber culture, flowers of cotton (Cotton Germplasm Bank, College Station, TX) were collected 1 DPA from plants grown in the greenhouse. Ovules were excised and cultured at constant 34°C (the optimum for in vitro cultures; Beasley, 1977) as previously described (Haigler et al., 1991). Ovules were floated on a medium containing Glc as the sole carbon source because exogenous Suc causes ovule browning and callus, rather than fibers, to form on the ovules (Beasley, 1971; C.H. Haigler and L.K. Martin, unpublished data). Ovules originating from four to six flowers on each culture day were collected with their attached fibers on 8, 18, 21, 24, and 27 DPA for SPS assay. Ovules with attached fiber were collected on 12, 14, 16, 18, 21, 24, and 27 DPA for determination of cellulose synthesis rate from exogenous [¹⁴C]Glc as previously described (Roberts et al., 1992). These time points were chosen to include both primary and secondary wall deposition in cotton fibers; at warm temperatures, the transition between these two phases begins around 15 DPA (Haigler et al., 1991). Bolls for assay of SPS in plant-grown fibers were collected at 12, 18, 21, and 24 DPA from plants growing in a growth chamber held at constant 28°C, which is an optimum temperature for cotton vegetative growth (Burke et al., 1988) and fiber cellulose synthesis (Roberts et al., 1992).

TE Differentiation in Culture

Mesophyll cells isolated from the first true leaves ofZinnia elegans L. var. Envy (Bodger Seeds Ltd., El Monte, CA) were induced to differentiate into TEs in the dark as previously described with Suc as the carbon source (Fukuda and Komamine, 1980). Cultures represented in the data were begun at various times between 9 and 12 am. The extent and timing of TE differentiation were manipulated by use of three kinds of media. Two of the media, one complex (Fukuda and Komamine, 1980) and one simplified (Roberts and Haigler, 1992), contained sufficient cytokinin (0.2 mg L⁻¹ 6-benzylaminopurine) to induce TE differentiation. The complex inductive medium supported cell division and the production of two sizes of TEs, with differentiation of small TEs peaking at about 60 h and differentiation of larger TEs peaking at about 90 h. The simplified inductive medium suppressed cell division and eliminated the differentiation of large TEs at 90 h. The third medium used did not induce TE differentiation; it differed from the complex inductive medium only by having a lower level of cytokinin (Fukuda and Komamine, 1980). This noninductive medium also allowed cells to be maintained in culture until they lost visible starch grains about 7 d after culture as detected by absence of staining with I₂KI (2% [w/v] KI and 0.2% [w/v] I₂;Gahan 1984). Late TE differentiation was induced in starch-depleted cells by raising the cytokinin concentration to 0.2 mg L⁻¹.

Determining Percent Differentiation and Percent Live TEs inZ. elegans Cultures

Polarization microscopy (for early stage TEs) and bright-field microscopy (for late stage TEs) were used to count TEs among all cells in the culture over the time course of differentiation. Sensitive polarization methods (BH-2 microscope, Olympus, Tokyo) allowed the detection of cellulosic thickenings by their birefringence before they became visible by bright field microscopy. Although the fluorescent brightener Tinopal LPW (CibaGeigy, Greensboro, NC) would have detected TEs (Falconer and Seagull, 1985) approximately 2 h earlier than polarization microscopy (C.H. Haigler, unpublished data) by binding to their patterned cellulosic thickenings, it was not used because polarization microscopy was simpler and adequate to perceive the trends observed in these experiments.

Because it was hypothesized that changes in SPS activity in these cultures would correlate with the percentage of living TEs and not with arbitrary times after the culture, the progress of TE differentiation was monitored prior to SPS assay. At prospective harvest times, the percentage of total TEs and dead TEs was determined in all the available flasks. Percent TEs was calculated as: [total TEs/(total TEs + other cells) × 100]. Evans blue, a dye that permeates only dead cells, was used to quantify TE autolysis as previously described (Roberts and Haigler, 1989). Percent live TEs among all TEs was calculated as: [(total TEs − autolyzed TEs)/total TEs × 100]. Sets of three flasks with similar extent of TE differentiation (±1% for TEs and live TEs) were combined by low-speed centrifugation (20g, 2 min) prior to extraction of SPS.

Growth and Developmental Analysis of Etiolated Hypocotyls

Kidney beans (Phaseolus vulgaris) were purchased from the grocery store and germinated in the dark at 28°C to 30°C in potting soil. They grew into etiolated seedlings characterized by hyperelongation and lack of chlorophyll and leaf development. The etiolated hypocotyls still contained differentiating TEs to support water conduction.

Short (2–3 cm), medium (4–6 cm), and tall (7–8 cm) hypocotyls (about 3, 4–5, and 7–8 d after germination, respectively) were analyzed for the extent of xylem development and dry weight. Hand sections were cut with a razor blade from the base, middle, and top of several hypocotyls in each height class. The sections were stained with safranin (1% [w/v] for anatomical observations) or I₂KI (for starch), and examined in the light microscope to compare the relative amounts of xylem as the hypocotyls elongated. Micrographs were taken by adhering stained sections to the bottom of a slide in a small amount of water and looking through the slide, which enhanced clarity of the anatomy (method of J. Varner, personal communication). Representative areas showing maximum amounts of xylem near the base of the hypocotyls were photographed. Thirty-six hypocotyls of each size were stripped of roots and cotyledons, dehydrated in a 60°C oven for 3 d, and weighed.

Assay of SPS in Cotton Fiber

For both cultured and plant-grown fibers, seeds with attached fibers were snap frozen in liquid nitrogen, frozen fibers were removed from seeds by scraping with an ultracold spatula, and the isolated fibers were ground with a pestle to a fine powder under liquid nitrogen prior to SPS assay. All the fibers of 10 cultured ovules or all the fibers from one locule of the boll were ground together as one sample. SPS assay methods were adapted from those previously published (Kerr et al., 1987; Copeland, 1990). Cotton fiber powder was quickly weighed while frozen, transferred to a 12-mL centrifuge tube, thawed in extraction buffer {50 mm HEPES [4-(2-hydroxyethyl)-1-piperazineethanesulfonic acid], pH. 7.4; 10 mm MgCl₂; 1 mm EDTA; 1 mm EGTA; 10% [v/v] glycerol; and 0.1% [v/v] Triton X-100}, and mixed with buffer by aid of a plastic pestle. Cellular debris was pelleted in a 20-s spin (15,000 rpm), and the supernatant was used to assay SPS. SPS assay proceeded in 70 μL of reaction mixtures for 5 min at 34°C in: 50 mm HEPES, pH 7.4; 8 mm UDP-Glc; 4 mm Fru-6-P; 20 mmGlc-6-P; 10 mm MgCl₂; 1 mm EDTA; 0.4 mm EGTA; 4% (v/v) glycerol; and 0.04% (v/v) Triton X-100]. Forty-two microliters of SPS assay buffer (50 mmHEPES, pH 7.4; 10 mm MgCl₂; 1 mmEDTA; 13.36 mm UDP-Glc; 6.67 mm Fru-6-P; and 33.3 mm Glc-6-P) was prewarmed to the assay temperature and added to tissue supernatant (28 μL) to make the final assay mixture. High substrate concentrations and the presence of the activator Glc-6-P define conditions for assay of V _max SPS activity (Winter and Huber 2000). Three reaction tubes and three blanks (to normalize for possible different amounts of endogenous Suc) were run for each sample. One normal NaOH was added to the blanks before the plant extract. After 5 min, 1 n NaOH was added to stop the reaction, followed by boiling for 10 min to destroy unreacted hexoses. Twelve molar HCL was added to hydrolyze Suc-P and Suc into Fru and Glc, 0.1% (w/v) resorcinol in 100% (v/v) ethanol was added to react with Fru, and A ₅₂₀ of the pink reaction product was measured. A Suc standard curve was run in parallel.

Each cultured fiber extraction was performed two (for 8 and 27 DPA) to six (for 18, 21, and 24 DPA) times, and each extract was assayed with four replications. Assays of cultured fibers were normalized to activity per the unit of fibers growing on one ovule (per ovule). Values for plant-grown fibers are means from six separate extractions (from two sets of plants grown 6 months apart) with each extract assayed in triplicate. Assays of plant-grown fibers were normalized to the fresh weight of the fiber sample (per gram), which reduces the magnitude of the apparent increase over the developmental time course because of the increasing weight of inert, secondary wall cellulose. Dry weight of plant-grown cotton fibers typically increases about 3-fold between 12 and 24 DPA (Stewart, 1986).

Assay of SPS in Z. elegans Cells and Bean Hypocotyls

Three similar flasks of Z. elegans cells in medium were combined and washed three times in 10 mL each of 0.2m mannitol by repeated centrifugation (20g, 2 min) to remove exogenous Suc. An equal volume of SPS extraction buffer (2× concentrated) was added to the cell pellet, and the dense slurry of cells was frozen by drops in liquid nitrogen. The frozen cells could be stored at −80°C for at least 30 d without detrimental effects on SPS activity levels. Immediately prior to SPS assay, the cells were ground while frozen to a fine powder. A prechilled 1.5-mL microfuge tube was half-filled with frozen powder, and 1 mL of extraction buffer at 4°C was added. (For consistent results, the frozen tissue was not allowed to thaw before addition of extraction buffer.) The tube was vortexed for 20 s and stored on ice until the other samples (usually four) being assayed in parallel were ready (≤10 min waiting for any sample). All samples were again vortexed for 20 s, then microfuged (15,000 rpm; 20 s; 4°C). The supernatant was removed to another prechilled tube followed by two times repetition of the microcentrifugation step. The final supernatant was used for SPS assay and for quantitation of protein (Bio-Rad Protein Assay, Hercules, CA).

Bean hypocotyls were grouped into height classes, frozen in liquid nitrogen, and stored intact at −80°C prior to SPS assay. Immediately prior to SPS assay, three similar hypocotyls were ground together to form one sample. The sample was processed as described for Z. elegans cells.

SPS activity for Z. elegans cells and hypocotyls was measured as described for cotton fibers with minor changes: (a) 2% (w/v) polyvinylpolypyrrolidone was added to the extraction buffer, (b) substrate concentrations in the SPS assay were increased to 6 mm Fru-6-P and 10 mm UDP-Glc, and (c) the reactions were run for 10 min. (We proved that the reaction is linear for at least 12.5 min.) Each tissue extract (itself a combination of three culture flasks or three hypocotyls) was assayed in triplicate.

To check if SuSy acting synthetically under our assay conditions was increasing the apparent SPS activity in Z. eleganscells, Fru was substituted in equal amounts for Fru-6-P and an assay was run in parallel with the SPS assay on the same sample (68-hZ. elegans cells with high percentage TEs).

Statistical Analysis

Groups were analyzed for similarity or difference by one-way ANOVA with randomization (1,000 iterations) by use of a subroutine written by R.E. Strauss for Matlab (Natik, MA). The subroutine is called “pairwise” (http://www.biol.ttu.edu/Faculty/FacPages/Strauss/Matlab/matlab.htm).