Your search keyword '"Brown, CS"' showing total 19 results

1. Changes in vacuolation in the root apex cells of soybean seedlings in microgravity.

Author

Klymchuk DO, Kordyum EL, Vorobyova TV, Chapman DK, and Brown CS

Subjects

Calcium metabolism, Dose-Response Relationship, Drug, Ethylenes metabolism, Microscopy, Electron, Osmotic Pressure, Plant Growth Regulators metabolism, Plant Root Cap drug effects, Plant Root Cap growth & development, Plant Root Cap metabolism, Potassium Permanganate pharmacology, Seedlings drug effects, Seedlings growth & development, Seedlings metabolism, Glycine max drug effects, Glycine max growth & development, Glycine max metabolism, Plant Root Cap ultrastructure, Seedlings ultrastructure, Glycine max ultrastructure, Space Flight, Vacuoles physiology, Weightlessness

Abstract

Changes in the vacuolation in root apex cells of soybean (Glycine max L. [Merr.]) seedlings grown in microgravity were investigated. Spaceflight and ground control seedlings were grown in the absence or presence of KMnO4 (to remove ethylene) for 6 days. After landing, in order to study of cell ultrastructure and subcellular free calcium ion distribution, seedling root apices were fixed in 2.5% (w/v) glutaraldehyde in 0.1 M cacodylate buffer and 2% (w/v) glutaraldehyde, 2.5% (w/v) formaldehyde, 2% (w/v) potassium antimonate K[Sb(OH)6] in 0.1 M K2HPO4 buffer with an osmolarity (calculated theoretically) of 0.45 and 1.26 osmol. The concentrations of ethylene in all spaceflight canisters were significantly higher than in the ground control canisters. Seedling growth was reduced in the spaceflight-exposed plants. Additionally, the spaceflight-exposed plants exhibited progressive vacuolation in the root apex cells, particularly in the columella cells, to a greater degree than the ground controls. Plasmolysis was observed in columella cells of spaceflight roots fixed in solutions with relatively high osmolarity (1.26 osmol). The appearance of plasmolysis permitted the evaluation of the water status of cells. The water potential of the spaceflight cells was higher than the surrounding fixative solution. A decrease in osmotic potential and/or an increase in turgor potential may have induced increases in cell water potential. However, the plasmolysed (i.e. non-turgid) cells implied that increases in water potential were accompanied with a decrease in osmotic potential. In such cells changes in vacuolation may have been involved to maintain turgor pressure or may have been a result of intensification of other vacuolar functions like digestion and storage., (c2003 COSPAR. Published by Elsevier Ltd. All rights reserved.)

Published

2003

2. Composition and physical properties of starch in microgravity-grown plants.

Author

Kuznetsov OA, Brown CS, Levine HG, Piastuch WC, Sanwo-Lewandowski MM, and Hasenstein KH

Subjects

Amylopectin metabolism, Amylose metabolism, Cotyledon enzymology, Cotyledon growth & development, Cotyledon metabolism, Hypocotyl enzymology, Hypocotyl growth & development, Hypocotyl metabolism, Plant Physiological Phenomena, Plastids, Solanum tuberosum enzymology, Solanum tuberosum growth & development, Glycine max enzymology, Glycine max growth & development, Starch physiology, alpha-Amylases metabolism, Magnetics, Solanum tuberosum metabolism, Glycine max metabolism, Space Flight, Starch metabolism, Weightlessness

Abstract

The effect of spaceflight on starch development in soybean (Glycine max L., BRIC-03) and potato (Solanum tuberosum, Astroculture-05) was compared with ground controls by biophysical and biochemical measurements. Starch grains from plants from both flights were on average 20-50% smaller in diameter than ground controls. The ratio delta X/delta rho (delta X --difference of magnetic susceptibilities, delta rho--difference of densities between starch and water) of starch grains was ca. 15% and 4% higher for space-grown soybean cotyledons and potato tubers, respectively, than in corresponding ground controls. Since the densities of particles were similar for all samples (1.36 to 1.38 g/cm3), the observed difference in delta X/delta rho was due to different magnetic susceptibilities and indicates modified composition of starch grains. In starch preparations from soybean cotyledons (BRIC-03) subjected to controlled enzymatic degradation with alpha-amylase for 24 hours, 77 +/- 6% of the starch from the flight cotyledons was degraded compared to 58 +/- 12% in ground controls. The amylose content in starch was also higher in space-grown tissues. The good correlation between the amylose content and delta X/delta rho suggests, that the magnetic susceptibility of starch grains is related to their amylose content. Since the seedlings from the BRIC-03 experiment showed elevated post-flight ethylene levels, material from another flight experiment (GENEX) which had normal levels of ethylene was examined and showed no difference to ground controls in size distribution, density, delta X/delta rho and amylose content. Therefore the role of ethylene appears to be more important for changes in starch metabolism than microgravity., (c2001 COSPAR. Published by Elsevier Science Ltd. All rights reserved.)

Published

2001

3. Cytochemical localization of calcium in soybean root cap cells in microgravity.

Author

Klymchuk DO, Brown CS, Chapman DK, Vorobyova TV, and Martyn GM

Subjects

Antimony pharmacology, Cell Nucleus metabolism, Cell Nucleus ultrastructure, Chemical Precipitation, Cytoplasm metabolism, Cytoplasm ultrastructure, Ethylenes antagonists & inhibitors, Meristem metabolism, Meristem ultrastructure, Microscopy, Electron, Plant Root Cap metabolism, Plastids metabolism, Plastids ultrastructure, Glycine max ultrastructure, Vacuoles metabolism, Vacuoles ultrastructure, Calcium metabolism, Plant Root Cap ultrastructure, Glycine max metabolism, Space Flight, Weightlessness

Abstract

The antimonate precipitation technique was used to evaluate the effects of microgravity and ethylene on the cellular and subcellular distribution of free calcium ions in soybean root apices. Soybean (Glycine max L. [Merr.]) dry seeds were launched, activated by hydration, and germinated in the presence of KMnO4 (to remove ethylene) and in its absence onboard the space shuttle Columbia during the STS-87 mission. Primary root apices of 6-day old seedlings were fixed for electron microscopy after landing. Ultrastructural studies indicated that antimonate precipitation appeared as individual electron-dense particles which were more or less round in shape and varied in diameter from 10 nm (minimum size beginning from which the particles were well identified) to 90 nm. It was revealed that analyzed root cap cells varied in both the precipitate particle sizes and the amount particles per unit of the cellular area. In both flight and ground control treatments, antimonate precipitation level increases from apical meristem cells to peripheral (secretory) cells of root apices. In root cap statocytes, subcellular localization of precipitate particles was revealed in the cytoplasm, nucleus and small vacuoles. The quantitative analysis showed a reduction of precipitate density in the cytoplasm and the nucleus, and an increase in precipitate density in the vacuoles from statocytes of both spaceflight treatments in comparison with ground controls., (c 2001 COSPAR. Published by Elsevier Science Ltd. All rights reserved.)

Published

2001

4. Microgravity mediated changes in phytoferritin accumulation in soybean root cap cells.

Author

Klymchuk DO, Kordyum EL, Vorobyova TV, Brown CS, and Chapman DK

Subjects

Ethylenes pharmacology, Ferritins drug effects, Organelles metabolism, Plant Growth Regulators pharmacology, Plant Root Cap drug effects, Plant Shoots drug effects, Plant Shoots metabolism, Plastids metabolism, Glycine max drug effects, Ferritins metabolism, Plant Root Cap metabolism, Glycine max metabolism, Space Flight, Weightlessness

Abstract

Phytoferritin is an iron-protein complex analogous to the ferritin found in mammalian, bacteria and fungi cells. Phytoferritin molecules are large proteins, about 10.5 nm in diameter, visualised in an electron microscope as discrete, electron dense particles with iron-containing core, where several thousand atoms of iron lie within the proteinaceous shell (apoferritin). In higher plants, a plastid stroma is the site of phytoferritin storage. Phytoferritin is seen in all types of plastids. It is considered to be a mechanism used by cells to store iron in a non-toxic form. Phytoferritin-bound iron may subsequently be used to form iron-containing components. It was shown that low levels of phytoferritin are synthesised in normal green leaves, whereas chlorotic leaves do not have a measurable amount of phytoferritin and leaves of iron-loaded seedlings contain a high level of total iron, and phytoferritin well-filled by iron. Phytoferritin accumulation was observed in photosynthetic inactivity chloroplasts during senescence and disease. In this study we analised the effects of microgravity and ethylene on production of phytoferritin in the root cap columella cells of soybean seedlings.

Published

2000

5. Electron-cytochemical study of Ca2+ in cotyledon cells of soybean seedlings grown in microgravity.

Author

Nedukha O, Brown CS, Kordyum E, and Piastuch WC

Subjects

Calcium analysis, Cotyledon cytology, Peroxides pharmacology, Plant Growth Regulators pharmacology, Plastids, Glycine max cytology, Glycine max drug effects, Starch analysis, Thylakoids, Vacuoles physiology, Cotyledon drug effects, Cotyledon ultrastructure, Ethylenes pharmacology, Glycine max ultrastructure, Space Flight, Weightlessness

Abstract

Microgravity and horizontal clinorotation are known to cause the rearrangement of the structural-functional organization of plant cells, leading to accelerated aging. Altered gravity conditions resulted in an increase in the droplets volume in cells and the destruction of chloroplast structure in Arabidopsis thaliana plants, an enhancement of cytosolic autophagaous processes, an increase in the respiration rate and a greater number of multimolecular forms of succinate- and malate dehydrogenases in cells of the Funaria hygrometrica protonema and Chlorella vulgaris, and changes in calcium balance of cells. Because ethylene is known to be involved in cell aging and microgravity appears to speed the process, and because soybean seedlings grown in space produce higher ethylene levels we asked: 1) does an acceleration of soybean cotyledon cell development and aging occur in microgravity? 2) what roles do Ca2+ ions and the enhanced ethylene level play in these events? Therefore, the goal of our investigation was to examine of the interaction of microgravity and ethylene on the localization of Ca2+ in cotyledon mesophyll of soybean seedlings.

Published

1999

6. Ultrastructural organization of cells in soybean root tips in microgravity.

Author

Klymchuk DO, Brown CS, and Chapman DK

Subjects

Microscopy, Electron, Plant Root Cap metabolism, Plant Roots cytology, Plant Roots growth & development, Plant Roots ultrastructure, Plant Shoots, Plastids physiology, Plastids ultrastructure, Glycine max cytology, Glycine max growth & development, Starch metabolism, Vacuoles physiology, Plant Root Cap ultrastructure, Glycine max ultrastructure, Space Flight, Weightlessness

Abstract

Root apex cells of higher plants have unique structure and functions. In particular, the central cells of root cap are considered as the site of gravity perception in roots and are characterised by structural polarity, including directional sedimentation of amyloplasts with to gravity. Past studies have shown that root growth, structural organisation of the cells, and structural polarity of statocytes were affected in microgravity. Microgravity-grown plants also exhibited enhanced production of ethylene and decreased production of starch relative to ground controls. In this paper, the effects of microgravity and ethylene on ultrastructural organisation of the cells in soybean root apices are presented.

Published

1999

7. Ground-based studies and space experiment with potato leaf explants.

Author

Tibbitts TW, Croxdale JC, Brown CS, Wheeler RM, and Goins GD

Subjects

Culture Techniques, Light, Lighting, Plant Leaves growth & development, Plant Leaves metabolism, Plant Stems growth & development, Plant Stems metabolism, Research Design, Solanum tuberosum metabolism, Starch metabolism, Temperature, Environment, Controlled, Solanum tuberosum growth & development, Space Flight instrumentation, Weightlessness

Abstract

This article details the extensive preflight research required to make a plant experiment conform to the constraints imposed by the spaceflight system. Potato explants, each consisting of a leaf, an axillary bud, and small stem section, were flown on USML-2 in the ASTROCULTURE (TM) flight hardware to study tuber formation from the axillary bud during the 16 days of flight. To obtain acceptable explant materials: 1) parent plants had to be grown under reduced light (150 micromoles m-2 s-1 PPF) to ensure uniform bud and tuber development, 2) leaves had to be trimmed to fit the small size of the flight growth chamber, and 3) only young, fully expanded leaves from plants 5-7 weeks old could be used. After six scrubs, the experiment was flown successfully October 20 to November 5 and produced tubers and accumulated starch similar to that produced on ground controls.

Published

1999

8. Changes in Arabidopsis leaf ultrastructure, chlorophyll and carbohydrate content during spaceflight depend on ventilation.

Author

Musgrave ME, Kuang A, Brown CS, and Matthews SW

Subjects

Arabidopsis metabolism, Arabidopsis ultrastructure, Environment, Controlled, Microscopy, Electron, Plant Leaves metabolism, Plastids, Starch, Carbohydrate Metabolism, Chlorophyll metabolism, Plant Leaves ultrastructure, Space Flight, Ventilation, Weightlessness

Abstract

Leaf structure and function under spaceflight conditions have received little study despite their important implications for biological life support systems using plants. Previous reports described disruption of the membrane apparatus for photosynthesis and a general decrease in carbohydrate content in foliage. During a series of three short-duration experiments (Chromex-03, -04, -05) on the US space shuttle (STS-54, STS-51, STS-68), we examined Arabidopsis thaliana leaves. The plants were at the rosette stage at the time of loading onto the space shuttle, and received the same light, temperature, carbon dioxide and humidity regimes in the orbiter as in ground controls. The experiments differed according to the regime provided in the headspace around the plants: this was either sealed (on mission STS-54); sealed with high levels of carbon dioxide (on mission STS-51) or vented to the cabin air through a filtration system (on mission STS-68). Immediately post-flight, leaf materials were fixed for microscopy or frozen in liquid nitrogen for subsequent analyses of chlorophyll and foliar carbohydrates. At the ultrastructural level, no aberrations in membrane structure were observed in any of the experiments. When air-flow was provided, plastids developed large starch grains in both spaceflight and ground controls. In the experiments with sealed chambers, spaceflight plants differed from ground controls with regard to measured concentrations of carbohydrate and chlorophyll, but the addition of airflow eliminated these differences. The results point to the crucial importance of consideration of the foliage microenvironment when spaceflight effects on leaf structure and metabolism are studied.

Published

1998

9. Development and growth of potato tubers in microgravity.

Author

Cook ME, Croxdale JL, Tibbitts TW, Goins G, Brown CS, and Wheeler RM

Subjects

Life Support Systems, Organ Culture Techniques, Plant Stems cytology, Solanum tuberosum cytology, Starch, Environment, Controlled, Plant Stems growth & development, Solanum tuberosum growth & development, Space Flight, Weightlessness

Abstract

A potato explant consisting of a leaf, its axillary bud, and a small segment of stem will develop a tuber in 10-14 days when grown on earth. The tubers develop from the axillary buds and accumulate starch derived from sugars produced through photosynthesis and/or mobilized from leaf tissue. Potato explants were harvested and maintained in the Astroculture (TM) unit, a plant growth chamber designed for spaceflight. The unit provides an environment with controlled temperature, humidity, CO2 level, light intensity, and a nutrient delivery system. The hardware was loaded onto the space shuttle Columbia 24 hours prior to the launch of the STS-73 mission. Explant leaf tissue appeared turgid and green for the first 11 days of flight, but then became chlorotic and eventually necrotic by the end of the mission. The same events occurred to ground control explants with approximately the same timing. At the end of the 16-day mission, tubers were present on each explant. The size and shape of the space-grown tubers were similar to the ground-control tubers. The arrangement of cells in the tuber interior and at the exterior in the periderm was similar in both environments. Starch and protein were present in the tubers grown in space and on the ground. The range in starch grain size was similar in tubers from both environments, but the distribution of grains into size classes differed somewhat, with the space-grown tubers having more small grains than the ground control tubers. Proteinaceous crystals were found in tubers formed in each condition.

Published

1998

10. Structure of potato tubers formed during spaceflight.

Author

Croxdale J, Cook M, Tibbitts TW, Brown CS, and Wheeler RM

Subjects

Culture Techniques, Microscopy, Electron, Plant Leaves growth & development, Plant Leaves metabolism, Plant Leaves ultrastructure, Plant Stems growth & development, Plant Stems metabolism, Solanum tuberosum metabolism, Solanum tuberosum ultrastructure, Starch metabolism, Plant Stems ultrastructure, Solanum tuberosum growth & development, Space Flight, Weightlessness

Abstract

Potato (Solanum tuberosum L. cv. Norland) explants, consisting of a leaf, axillary bud, and small stem segment, were used as a model system to study the influence of spaceflight on the formation of sessile tubers from axillary buds. The explants were flown on the space shuttle Columbia (STS-73, 20 October to 5 November 1995) in the ASTROCULTURE (TM) flight package, which provided a controlled environment for plant growth. Light and scanning electron microscopy were used to compare the precisely ordered tissues of tubers formed on Earth with those formed during spaceflight. The structure of tubers produced during spaceflight was similar to that of tubers produced in a control experiment. The size and shape of tubers, the geometry of tuber tissues, and the distribution of starch grains and proteinaceous crystals were comparable in tubers formed in both environments. The shape, surface texture, and size range of starch grains from both environments were similar, but a greater percentage of smaller starch grains formed in spaceflight than on Earth. Since explant leaves must be of given developmental age before tubers form, instructions regarding the regular shape and ordered tissue geometry of tubers may have been provided in the presence of gravity. Regardless of when the signalling occurred, gravity was not required to produce a tuber of typical structure.

Published

1997

11. Plastid distribution in columella cells of a starchless Arabidopsis mutant grown in microgravity.

Author

Hilaire E, Paulsen AQ, Brown CS, and Guikema JA

Subjects

Arabidopsis genetics, Arabidopsis growth & development, Arabidopsis ultrastructure, Cell Division, Image Processing, Computer-Assisted, Mutation, Seeds ultrastructure, Starch, Arabidopsis cytology, Plastids, Weightlessness

Abstract

Wild-type and starchless Arabidopsis thaliana mutant seedlings (TC7) were grown and fixed in the microgravity environment of a U.S. Space Shuttle spaceflight. Computer image analysis of longitudinal sections from columella cells suggest a different plastid positioning mechanism for mutant and wild-type in the absence of gravity.

Published

1997

12. Potato tuber formation in the spaceflight environment.

Author

Brown CS, Tibbitts TW, Croxdale JG, and Wheeler RM

Subjects

Biomass, Carbohydrates, Carbon Dioxide metabolism, Photoperiod, Plant Stems metabolism, Solanum tuberosum metabolism, Ecological Systems, Closed, Environment, Controlled, Life Support Systems, Plant Stems growth & development, Solanum tuberosum growth & development, Space Flight, Weightlessness

Abstract

Five potato (Solanum tuberosum L.) leaf cuttings were flown on STS-73 in late October, 1995 as part of the 16-day USML-2 mission. Preflight studies were conducted to study tuber growth, determine carbohydrate concentrations, and examine the developing starch grains within the tuber. In these tests, tubers attained a fresh weight of 1.4 g tuber-1 after 13 days. Tuber fresh mass was significantly correlated to tuber diameter. Greater than 60% of the tuber dry mass was starch and the starch grains varied in size from 2 to 40 micrometers in the long axis. For the flight experiment, cuttings were obtained from 7-week-old Norland potato plants, kept at 5 degrees C for 12 h then planted into arcillite in the ASTROCULTURE(TM) flight hardware. The flight package was loaded on-board the orbiter 22 h prior to launch. During the mission, the flight hardware maintained an environment around the cuttings of 22 +/- 2 degrees C, 81 +/- 7% RH, and a 12-h photoperiod using red and blue light-emitting diodes at a photosynthetic photon flux of 150 micromol m-2 s-1. CO2 concentration exceeded 4000 ppm during the dark period and was controlled during the light period to approximately 400 ppm. Video downlinking of images of the plants and CO2 exchange data during the flight demonstrated plant vitality for the first 12 days of the mission followed by senescence of the leaves. The flight package was received 4 h after landing at the Kennedy Space Center and postflight processing of the samples was completed within 3 h. Four out of the five space-grown cuttings produced tubers that were similar in appearance and dimension to the ground control tubers. This is an important finding if potatoes are to be used as part of a bioregenerative life support system for long-term space exploration.

Published

1997

13. Cortical microtubules in sweet clover columella cells developed in microgravity.

Author

Hilaire E, Paulsen AQ, Brown CS, and Guikema JA

Subjects

Fabaceae cytology, Fabaceae growth & development, Microscopy, Electron, Plant Roots cytology, Plant Roots growth & development, Plant Shoots cytology, Plant Shoots growth & development, Tissue Fixation, Cytoskeleton ultrastructure, Fabaceae ultrastructure, Microtubules ultrastructure, Plant Roots ultrastructure, Plant Shoots ultrastructure, Plants, Medicinal, Space Flight, Weightlessness

Abstract

Electron micrographs of columella cells from sweet clover seedlings grown and fixed in microgravity revealed longitudinal and cross sectioned cortical microtubules. This is the first report demonstrating the presence and stability of this network in plants in microgravity.

Published

1995

14. Effects of clinorotation and microgravity on sweet clover columella cells treated with cytochalasin D.

Author

Hilaire E, Paulsen AQ, Brown CS, and Guikema JA

Subjects

Actin Cytoskeleton physiology, Cell Nucleus drug effects, Cell Nucleus physiology, Cell Polarity, Cytoskeleton drug effects, Cytoskeleton physiology, Endoplasmic Reticulum drug effects, Endoplasmic Reticulum physiology, Fabaceae cytology, Fabaceae drug effects, Gravitation, Gravity Sensing, Microscopy, Electron, Plant Root Cap cytology, Plant Root Cap drug effects, Plastids drug effects, Plastids physiology, Weightlessness Simulation, Actin Cytoskeleton drug effects, Cytochalasin D pharmacology, Fabaceae ultrastructure, Nucleic Acid Synthesis Inhibitors pharmacology, Plant Root Cap ultrastructure, Plants, Medicinal, Rotation, Space Flight, Weightlessness

Abstract

The cytoskeleton of columella cells is believed to be involved in maintaining the developmental polarity of cells observed as a reproducible positioning of cellular organelles. It is also implicated in the transduction of gravitropic signals. Roots of sweet clover (Melilotus alba L.) seedlings were treated with a microfilament disrupter, cytochalasin D, on a slowly rotating horizontal clinostat (2 rpm). Electron micrographs of treated columella cells revealed several ultrastructural effects including repositioning of the nucleus and the amyloplasts and the formation of endoplasmic reticulum (ER) whorls. However, experiments performed during fast clinorotation (55 rpm) showed an accumulation (but no whorling) of a disorganized ER network at the proximal and distal pole and a random distribution of the amyloplasts. Therefore, formation of whorls depends upon the speed of clinorotation, and the overall impact of cytochalasin D suggests the necessity of microfilaments in organelle positioning. Interestingly, a similar drug treatment performed in microgravity aboard the US Space Shuttle Endeavour (STS-54, January 1993) caused a displacement of ER membranes and amyloplasts away from the distal plasma membrane. In the present study, we discuss the role of microfilaments in maintaining columella cell polarity and the utility of clinostats to simulate microgravity.

Published

1995

15. Microgravity and clinorotation cause redistribution of free calcium in sweet clover columella cells.

Author

Hilaire E, Paulsen AQ, Brown CS, and Guikema JA

Subjects

Antimony, Chemical Precipitation, Fabaceae growth & development, Fabaceae metabolism, Fabaceae physiology, Gravitation, Microscopy, Electron, Plant Root Cap growth & development, Plant Root Cap metabolism, Plant Roots growth & development, Plant Roots metabolism, Plastids physiology, Calcium metabolism, Fabaceae ultrastructure, Plant Root Cap ultrastructure, Plant Roots ultrastructure, Plants, Medicinal, Rotation, Space Flight, Weightlessness

Abstract

In higher plants, calcium redistribution is believed to be crucial for the root to respond to a change in the direction of the gravity vector. To test the effects of clinorotation and microgravity on calcium localization in higher plant roots, sweet clover (Melilotus alba L.) seedlings were germinated and grown for two days on a slow rotating clinostat or in microgravity on the US Space Shuttle flight STS-60. Subsequently, the tissue was treated with a fixative containing antimonate (a calcium precipitating agent) during clinorotation or in microgravity and processed for electron microscopy. In root columella cells of clinorotated plants, antimonate precipitates were localized adjacent to the cell wall in a unilateral manner. Columella cells exposed to microgravity were characterized by precipitates mostly located adjacent to the proximal and lateral cell wall. In all treatments some punctate precipitates were associated with vacuoles, amyloplasts, mitochondria, and euchromatin of the nucleus. A quantitative study revealed a decreased number of precipitates associated with the nucleus and the amyloplasts in columella cells exposed to microgravity as compared to ground controls. These data suggest that roots perceive a change in the gravitational field, as produced by clinorotation or space flights, and respond respectively differently by a redistribution of free calcium.

Published

1995

16. The Fluid Processing Apparatus: from flight hardware to electron micrographs.

Author

Hilaire E, Brown CS, and Guikema JA

Subjects

Calcium metabolism, Equipment Design, Microscopy, Electron, Plant Roots metabolism, Plastids ultrastructure, Seeds growth & development, Spacecraft instrumentation, Tissue Fixation, Plant Roots cytology, Plant Roots ultrastructure, Space Flight instrumentation, Weightlessness

Published

1995

17. Effects of microgravity and clinorotation on stress ethylene production in two starchless mutants of Arabidopsis thaliana.

Author

Gallegos GL, Hilaire EM, Peterson BV, Brown CS, and Guikema JA

Subjects

Arabidopsis genetics, Arabidopsis growth & development, Carbon Dioxide metabolism, Mutation, Starch deficiency, Weightlessness Simulation, Arabidopsis metabolism, Ethylenes metabolism, Gravitation, Rotation adverse effects, Space Flight, Weightlessness adverse effects

Published

1995

18. Effects of stress ethylene inhibitors on sweet clover (Melilotus alba L.) seedling growth in microgravity.

Author

Gallegos GL, Peterson BV, Brown CS, and Guikema JA

Subjects

Aminooxyacetic Acid pharmacology, Carbon Dioxide metabolism, Chromatography, Gas, Enzyme Inhibitors pharmacology, Ethylenes antagonists & inhibitors, Silver Nitrate pharmacology, Ethylenes metabolism, Plant Development, Plants metabolism, Space Flight, Weightlessness adverse effects

Published

1995

19. Porous Tube Plant Nutrient Delivery System development: a device for nutrient delivery in microgravity.

Author

Dreschel TW, Brown CS, Piastuch WC, Hinkle CR, and Knott WM

Subjects

Capillary Action, Ecological Systems, Closed, Equipment Design, Evaluation Studies as Topic, Hydroponics instrumentation, Solanum lycopersicum, Membranes, Artificial, Solanum tuberosum, Triticum, Water Supply, Crops, Agricultural growth & development, Environment, Controlled, Hydroponics methods, Space Flight instrumentation, Weightlessness

Abstract

The Porous Tube Plant Nutrient Delivery System or PTPNDS (U.S. Patent #4,926,585) has been under development for the past six years with the goal of providing a means for culturing plants in microgravity, specifically providing water and nutrients to the roots. Direct applications of the PTPNDS include plant space biology investigations on the Space Shuttle and plant research for life support in Space Station Freedom. In the past, we investigated various configurations, the suitability of different porous materials, and the effects of pressure and pore size on plant growth. Current work is focused on characterizing the physical operation of the system, examining the effects of solution aeration, and developing prototype configurations for the Plant Growth Unit (PGU), the flight system for the Shuttle mid-deck. Future developments will involve testing on KC-135 parabolic flights, the design of flight hardware and testing aboard the Space Shuttle.

Published

1994