Photosynthesis: 1900-1930.

During the second half of the 19th century Julius von Sachs established the main principles of the photosynthetic production of sugars. From then, a growing number of biochemists and physiologists attended to the process, that appeared like a "black box", in order to detect what came in and what went out of it. The English group of Frederick Blackman gave a remarkable contribution in individuating the close connection between temperature, light and CO2 concentration. Later, the great importance of light was stressed by Otto Warburg, who evaluated the radiant energy necessary to the process in terms of quantum theory. The biochemical mechanism of photosynthesis was interpreted by the main European schools on the basis of Adolf Baeyer's suggestion which posed formaldehyde as the core of the process. Formaldehyde's theory hold engaged the biochemists for about fifty years although some voices rose up against it. However, nobody could put forward more coherent theories until the 1940s, when Sam Ruben and Martin Kamen individuated the cyclic pattern of the process. Ultimately, the first thirty years of the 20th century must be seen as a preliminary stage studded with light and shade even if, in spite of controversial trends, several findings of remarkable interest became to disclose that "black box" as we know today chlorophyll photosynthesis.     

Ke, B. Photosynthesis: photobiochemistry and photobiophysics

This volume is the tenth in the major series on photosynthesis,Advances in photosynthesis, and departs from the usually multi-authorvolumes, being by a single author. Bacon Ke has produced a valuableaddition to the review literature covering the reactions thatoccur in the process between 10^–12 and 10^–13 seconds.These fundamental processes are basically the transfer of theenergy of photons to the pigments of the biological system,producing     

Limiting Factors in Photosynthesis: IV. Iron Stress-Mediated Changes in Light-Harvesting and Electron Transport Capacity and its Effects on Photosynthesis in Vivo

Using iron stress to reduce the total amount of light-harvesting and electron transport components per unit leaf area, the influence of light-harvesting and electron transport capacity on photosynthesis in sugar beet (Beta vulgaris L. cv F58-554H1) leaves was explored by monitoring net CO₂ exchange rate (P) in relation to changes in the content of Chl.

In most light/CO₂ environments, and especially those with high light (≥1000 microeinsteins photosynthetically active radiation per square meter per second) and high CO₂ (≥300 microliters CO₂ per liter air), P per area was positively correlated with changes in Chl (a + b) content (used here as an index of the total amount of light-harvesting and electron transport components). This positive correlation of P per area with Chl per area was obtained not only with Fe-deficient plants, but also over the normal range of variation in Chl contents found in healthy, Fe-sufficient plants. For example, light-saturated P per area at an ambient CO₂ concentration close to normal atmospheric levels (300 microliters CO₂ per liter air) increased by 36% with increase in Chl over the normal range, i.e. from 40 to 65 micrograms Chl per square centimeter. Iron deficiency-mediated changes in Chl content did not affect dark respiration rate or the CO₂ compensation point. The results suggest that P per area of sugar beet may be colimited by light-harvesting and electron transport capacity (per leaf area) even when CO₂ is limiting photosynthesis as occurs under field conditions.

     

Limiting Factors in Photosynthesis: VI. Regeneration of Ribulose 1,5-Bisphosphate Limits Photosynthesis at Low Photochemical Capacity

Earlier work (SE Taylor, N Terry [1984] Plant Physiol 75: 82-86) has shown that the rate of photosynthesis may be colimited by photosynthetic electron transport capacity, even at low intercellular CO₂ concentrations. Here we monitored leaf metabolites diurnally and the activities of key Calvin cycle enzymes in the leaves of three treatment groups of sugar beet (Beta vulgaris L.) plants representing three different in vivo photochemical capacities, i.e. Fe-sufficient (control) plants, moderately Fe-deficient, and severely Fe-deficient plants. The results show that the decrease in photosynthesis with Fe deficiency mediated reduction in photochemical capacity was through a reduction in ribulose 1,5-bisphosphate (RuBP) regeneration and not through a decrease in ribulose 1,5-bisphosphate carboxylase/oxygenase activity. Based on measurements of ATP and NADPH and triose phosphate/3-phosphoglycerate ratios in leaves, there was little evidence that photosynthesis and RuBP regeneration in Fe-deficient leaves were limited directly by the supply of ATP and NADPH. It appeared more likely that photochemical capacity influenced RuBP regeneration through modulation of enzymes in the photosynthetic carbon reduction cycle between fructose-6-phosphate and RuBP; in particular, the initial activity of ribulose-5-phosphate kinase was strongly diminished by Fe deficiency. Starch and sucrose levels changed independently of one another to some extent during the diurnal period (both increasing in the day and decreasing at night) but the average rates of starch or sucrose accumulation over the light period were each proportional to photochemical capacity and photosynthetic rate.     

Microclimate, Canopy Structure and Photosynthesis in Canopies of Three Contrasting Temperate Forage Grasses: III. Canopy Photosynthesis, Individual Leaf Photosynthesis and the Distribution of Current Assimilate

The rates of canopy and individual leaf photosynthesis and ¹⁴Cdistribution for three temperate forage grasses Lolium perennecv. S24, L. perenne cv. Reveille and Festuc'a arundinacea cv.SI70 were determined in the field during a summer growth period.Canopy photosynthesis declined as the growth period progressed,reflecting a decline in the photosynthetic capacity of successiveyoungest fully expanded leaves. The decline in the maximum photosyntheticcapacity of the canopies was correlated with a decline in theirquantum efficiencies at low irradiance. Changes in canopy structureresulted in changes in canopy net photosynthesis and dark respiration.No clear relationships between changes in the environment andchanges in canopy net photosynthesis and dark respiration wereestablished. The relative distributions of ¹⁴C in the shootsof the varieties gave a good indication of the amount of drymatter per ground area in the varieties.     

Photosynthesis in Tall Fescue : IV. Carbon Assimilation Pattern in two Genotypes of Tall Fescue Differing in Net Photosynthesis Rates

We previously reported that the net photosynthetic rate of a decaploid genotype (I-16-2) of tall fescue (Festuca arundinacea Schreb.) was 32 to 41 versus 22 milligrams CO₂ per square decimeter per hour in a hexaploid genotype (V6-802) (Randall, Nelson, Asay Plant Physiol 59: 38-41). The high rate was later correlated with increases in total ribulose 1,5-bisphosphate carboxylase protein (17%) and activity (27%) (Joseph, Randall, Nelson Plant Physiol 68: 894-898). This report characterizes photosynthesis with respect to light saturation and early products of photosynthesis in an attempt to identify regulatory metabolic site(s) in these two genotypes. Analysis of the early products of photosynthesis indicated that both genotypes fixed CO₂ via the Calvin-Benson cycle with phosphoglyceric acid as the initial primary product. Both genotypes had similar ¹⁴C-labeled intermediates. Sucrose was the primary sink of ¹⁴CO₂ assimilation. After 10 min of ¹⁴CO₂ assimilation with attached leaves, sucrose accounted for 89% (decaploid) and 81% (hexaploid) of the total ¹⁴C incorporated. In 10 min, this amounted to 1.3 (decaploid) and 0.8 (hexaploid) μmol [¹⁴C]sucrose formed g fresh weight⁻¹ and reflected the observed differences in photosynthetic rates. There was limited labeling of starch (1%) and fructan (1%). Results of total nonstructural carbohydrates and P_i analysis also demonstrated sucrose was the predominant carbohydrate in fescue leaves. Quantitative differences in sucrose and P_i between the two genotypes may reflect changes in partitioning and this possibility is discussed.     

Photosynthesis: Molecular biology and bioenergetics

Book Review

Photosynthesis: Molecular biology and bioenergeticsG.S. Singhal, J. Barber, R.A. Dilley, Govindjee, R. Haselkorn and P. Mohanty (Eds), Proceedings of the International Workshop on Application of Molecular Biology and Bioenergetics of Photosynthesis. Berlin, Heidelberg, New York, London, Paris, Tokyo, Hong Kong and Narosa: Springer-Verlag, 1989. xiv+441 pages. DM 148,00. ISBN 3-540-50451-6     

Photosynthesis and the Web: 2008

The World Wide Web has become an important resource for public awareness and for educating the world’s population, including its political leaders, students, researchers, teachers, and ordinary citizens seeking information. Relevant information on photosynthesis-related web sites is grouped into several categories: (1) group sites, (2) sites by subject, (3) individual researcher’s sites, (4) sites for educators and students, and (5) other useful sites.     

Photosynthesis and the Web: 2001

First, a brief history of the Internet and the World Wide Web is presented. This is followed by relevant information on photosynthesis-related web sites grouped into several categories: (1) large group sites, (2) comprehensive overview sites, (3) specific subject sites, (4) individual researcher sites, (5) kindergarten through high school (K-12) educational sites, (6) books and journals, and, 7) other useful sites. A section on searching the Web is also included. Finally, we have included an appendix with all of the web sites discussed herein as well as other web sites that space did not allow. Readers are requested to send comments, corrections and additions to gov@uiuc.edu. This revised version was published online in June 2006 with corrections to the Cover Date.