The Energetics of Freshwater Algae; Energy Requirements for Biosynthesis and Volume Regulation

Raven, John A.

doi:10.1111/j.1469-8137.1982.tb03358.x

Cited by 81 publications

(117 citation statements)

References 62 publications

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“…A value of 0.25 μm was estimated from transmission electron micrographs of Coleochaete cell walls (20). Measured turgor pressures can vary from 0.2 MPa to over 1 MPa (21,24,25). We have assumed a turgor pressure of 0.5 MPa.…”

Section: Simplified Morphology Of Coleochaete Allows Quantification Ofmentioning

confidence: 99%

Coordination of plant cell division and expansion in a simple morphogenetic system

Dupuy

Mackenzie

Haseloff

2010

Proc. Natl. Acad. Sci. U.S.A.

129

107

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Morphogenesis in plants arises from the interplay of genetic and physical interactions within a growing network of cells. The physical aspects of cell proliferation and differentiation are genetically regulated, but constrained by mechanical interactions between the cells. Higher plant tissues consist of an elaborate three-dimensional matrix of active cytoplasm and extracellular matrix, where it is difficult to obtain direct measurements of geometry or cell interactions. To properly understand the workings of plant morphogenesis, it is necessary to have biological systems that allow simple and direct observation of these processes. We have adopted a highly simplified plant system to investigate how cell proliferation and expansion is coordinated during morphogenesis. Coleocheate scutata is a microscopic fresh-water green alga with simple anatomical features that allow for accurate quantification of morphogenetic processes. Image analysis techniques were used to extract precise models for cell geometry and physical parameters for growth. This allowed construction of a deformable finite element model for growth of the whole organism, which incorporated cell biophysical properties, viscous expansion of cell walls, and rules for regulation of cell behavior. The study showed that a simple set of autonomous, cell-based rules are sufficient to account for the morphological and dynamic properties of Coleochaete growth. A variety of morphogenetic behavior emerged from the application of these local rules. Cell shape sensing is sufficient to explain the patterns of cell division during growth. This simplifying principle is likely to have application in modeling and design for engineering of higher plant tissues.biophysics | Coleochaete | dynamics | morphogenesis microscopy

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Section: Simplified Morphology Of Coleochaete Allows Quantification Ofmentioning

confidence: 99%

Coordination of plant cell division and expansion in a simple morphogenetic system

Dupuy

Mackenzie

Haseloff

2010

Proc. Natl. Acad. Sci. U.S.A.

129

107

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“…A tough cell wall enables microorganisms to better withstand hypoosmotic shock (Hellebust 1985), which is suggested to be a reason why diatoms are so abundant in sea ice (Arrigo & Thomas 2004). However, for rapidly growing organisms, the metabolic costs of operating contractile vacuoles are much lower than those of synthesizing a stronger organic cell wall (Raven 1982), which suggests a strategy for fast-growing opportunistic chlorophytes in decaying sea ice.This research provides insight into the succession of microbial communities in areas seasonally covered by sea ice. High concentrations of Chlamydomonas sp.…”

mentioning

confidence: 99%

Characterization and growth response to temperature and salinity of psychrophilic, halotolerant Chlamydomonas sp. ARC isolated from Chukchi Sea ice

Eddie

Krembs

Neuer

2008

Mar. Ecol. Prog. Ser.

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Sea ice provides a habitat for a diverse community of microorganisms, which comprise a substantial portion of primary production in ice-covered seas. Organisms immured in sea ice have to withstand strong changes in temperature and salinity. We report on the growth rate response to salinity and temperature of the chlorophyte Chlamydomonas sp. ARC, isolated from land-fast sea ice in the Chukchi Sea, Alaska. We found it to be a euryhaline psychrophile capable of growth at temperatures as low as -5°C and at salinities from 2.5 to 100 ‰. The maximum growth rate of 0.41 d -1 (± 0.027) was found at 5°C and a salinity of 30 ‰. The salinity growth range of this organism indicates that it is well adapted to the variable salinity environment associated with brine channels in sea ice, as well as the hypotonic conditions associated with melting ice. Based upon morphology and molecular phylogenetic reconstructions using the 18S ribosomal ribonucleic acid (rRNA) gene and the ribulose 1, 5-bisphosphate carboxylase/oxygenase large subunit (rbcL) gene, this Arctic Chlamydomonas falls into a distinct clade containing other as yet unassigned psychrophilic Chlamydomonas strains isolated from Arctic and Antarctic environments, pointing to a bi-polar distribution of this clade. It is also very closely related to the brackish water mesophile Chlamydomonas kuwadae Gerloff, and is capable of growth above the psychrophilic range in low-salinity medium, indicating that it may represent an intermediate between mesophilic and psychrophilic lifestyles.KEY WORDS: Chlamydomonas · Chlorophyta · Arctic sea ice · Chukchi Sea · Psychrophile · Euryhaline · Phylogeny 354: 107-117, 2008 temperatures, ice algae growing in the brine channels need to be tolerant of widely varying salinities. Resale or republication not permitted without written consent of the publisherMar Ecol Prog SerIn physiological studies testing the adaptation of Antarctic ice algae to low temperature and high salinity, Bartsch (1989) found that cell division was observed at temperatures as cold as -5.5°C and a salinity of 90 ‰. Aletsee & Jahnke (1992) reported growth of the marine diatoms Nitzschia frigida Grunow and Thalassiosira antarctica Comber at temperatures as low as -8 and -6°C and at salinities of 145 and 109 ‰, respectively. In general, sea-ice diatoms are often euryhaline and thrive in conditions from 10 to 60 ‰ (Grant & Horner 1976).Diatoms have been the focus of most studies on seaice algae, because they are considered the most abundant phototrophs in sea ice (Horner 1985, Lizotte 2003. Green algae are usually a relatively minor component, but the chlorophyte Chlamydomonas spp. has been found repeatedly in Arctic sea ice (see 'Discussion'). Chlamydomonas species may play a disproportionably large role in the initial colonization of sea ice. Weissenberger (1998) found Chlamydomonas sp. to dominate newly formed ice for the first 3 mo in a tank experiment inoculated with an enrichment culture from sea-ice brine. Despite their ubiquity in Arctic sea ice, most ...

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“…Table 1. Elemental composition of molecular components of biomass and yield coefficients for their synthesis based on ATP and NADPH requirements [28,29]. The compositions of the distinct molecular classes were derived from the molecular structures of the compounds.…”

Section: Biomass Composition and Metabolic Costsmentioning

confidence: 99%

“…Data given by Raven [29] concerning the ATP and NADPH requirement per carbon atom in different molecular components of microalgal cells were used to calculate yield coefficients for all molecules considered in the model except for pigments, RNA and DNA. In this manner, the yield coefficients for lipids, proteins and carbohydrates were calculated as inverse of the NADPH or ATP requirements for the synthesis of 1 g of the respective molecule.…”

Section: Biomass Composition and Metabolic Costsmentioning

confidence: 99%

A Linear Programming Approach for Modeling and Simulation of Growth and Lipid Accumulation of Phaeodactylum tricornutum

Dillschneider

Posten

2013

Energies

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Abstract:The unicellular microalga Phaeodactylum tricornutum exhibits the ability to accumulate triacylglycerols to a high specific content when nutrients are limited in the culture medium. Therefore, the organism is a promising candidate for biodiesel production. Mathematical modeling can substantially contribute to process development and optimization of algae cultivation on different levels. In our work we describe a linear programming approach to model and simulate the growth and storage molecule accumulation of P. tricornutum. The model is based on mass and energy balances and shows that the organism realizes the inherent drive for maximization of energy to biomass conversion and growth. The model predicts that under nutrient limiting conditions both storage carbohydrates and lipids are synthesized simultaneously but at different rates. The model was validated with data gained from batch growth experiments. Keywords

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The Energetics of Freshwater Algae; Energy Requirements for Biosynthesis and Volume Regulation

Cited by 81 publications

References 62 publications

Coordination of plant cell division and expansion in a simple morphogenetic system

Coordination of plant cell division and expansion in a simple morphogenetic system

Characterization and growth response to temperature and salinity of psychrophilic, halotolerant Chlamydomonas sp. ARC isolated from Chukchi Sea ice

A Linear Programming Approach for Modeling and Simulation of Growth and Lipid Accumulation of Phaeodactylum tricornutum

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