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Coordination of the cell-specific distribution of the four subunits of glycine decarboxylase and of serine hydroxymethyltransferase in leaves of C3-C4 intermediate species from different genera (1993)

Morgan, C. L. ; Turner, S. R. ; Rawsthorne, S.

Springer

Planta 190 (1993), S. 468-473

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ISSN: 1432-2048

Keywords: C3-C4 intermediate species (Flaveria, Moricandia, Panicum) ; C4 evolution ; Glycine decarboxylase (localization) ; Photorespiration ; Serine hydroxymethyltransferase (localization)

Source: Springer Online Journal Archives 1860-2000

Topics: Biology

Notes: Abstract The cell-specific distribution of the four subunit proteins (P, L, T and H) of glycine decarboxylase (GDC) and of serine hydroxymethyltransferase (SHMT) has been studied in the leaves of C3-C4 intermediate and C4 species of three genera (Flaveria, Moricandia and Panicum) using immunogold localization. Antibodies raised against these proteins from pea leaf mitochondria were used to probe Western blots of total leaf proteins of F. linearis Lag., M. arvensis (L.) DC and P. milioides Nees ex Trin. (C3-C4), and F. trinervia (Spring.) Mohr and P. miliaceum (L.) (C4). For all species, each antibody recognised specifically a protein of similar molecular weight to that in pea leaves. In leaves of M. arvensis the P protein was present in the mitochondria of the bundle-sheath cells but was undetectable in those of the mesophyll, whereas the L, T and H proteins and SHMT were present in both cell types. The density of immunogold labelling of SHMT on the mitochondria of mesophyll cells was less than that on those of the bundle-sheath cells, which correlates with the relative activities of SHMT in these cell types. These data reveal that the lack of functional GDC in the mesophyll cells of M. arvensis, which is the principal biochemical reason for reduced photorespiration in this species, is due to the loss of a single subunit protein. This lack of coordinate expression of the subunit proteins of GDC within a photosynthetic cell represents a clear difference between M. arvensis and other C3 and C3-C4 species. None of the GDC proteins was detectable in the mesophyll cells of the C3-C4 and C4 Flaveria and Panicum species but all were present in the bundle-sheath cells. The differences in the distribution of the GDC proteins in leaves of the C3-C4 species studied are discussed in relation to the evolution of photosynthetic mechanisms.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00224785

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Crosslinking-property relationships in PMR polyimide composites. Part IPart of this work was performed under auspices of the Polymer Composite Branch of the Materials Division, NASA Lewis Research Center, Cleveland, Ohio. (1991)

Pater, R. H. ; Whitley, K. ; Morgan, C. ; [et al.]

Brookfield, Conn. : Wiley-Blackwell

Polymer Composites 12 (1991), S. 126-132

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ISSN: 0272-8397

Keywords: Chemistry ; Chemical Engineering

Source: Wiley InterScience Backfile Collection 1832-2000

Topics: Mechanical Engineering, Materials Science, Production Engineering, Mining and Metallurgy, Traffic Engineering, Precision Mechanics

Notes: This study examines for the first time how matrix crosslinking affects the composite physical and mechanical properties of a graphite fiber reinforced PMR polyimide composite during long-term isothermal aging. Unidirectional composite specimens of Celion 6000/PMR-P1 were isothermally exposed at 288°C in air for various time periods up to 5000 h. The matrix crosslink densities were estimated from the kinetic theory of rubber elasticity and shifts in the glass transition temperatures (Tgs). The Tg, coefficient of thermal expansion, density, weight loss, moisture absorption, and elevated temperature flexural and interlaminar shear properties were also determined. Several linear relationships were found between the matrix crosslink density and composite physical and mechanical properties. The Tg, initial weight loss and density, and elevated temperature interlaminar shear strength increase with an increase in crosslink density. Conversely, the initial moisture absorption and coefficient of thermal expansion decrease with increasing crosslink density. As expected, the elevated temperature flexural strength and modulus show no direct correlations with crosslink density. Further, after achieving the highest matrix crosslink density, several of the composite properties begin to decrease rapidly. These findings suggest that time-temperature dependent nature of attaining the maximum matrix crosslinking is closely linked to the onset of the composite property degradation. Though much more work is needed, a fundamental understanding of the relationships between matrix crosslinking and composite physical and mechanical property can provide a scientific basis for the prediction of the extent of composite service life not only for PMR polyimides but also for other thermosetting matrix resins, such as epoxies and bismaleimides.

Additional Material: 12 Ill.