Mineral nutrition of plants: a short history of plant physiology.

The development of the knowledge on the mineral nutrition of plants begins between the 17th and 18th centuries when some European naturalists gave the first experimental evidences of what had been empirically known for about two millennia. The works of Hales and Ingenhousz were of absolute importance in relation to the transport of water and solutes, and assimilation of "fixed air" (carbon dioxide), respectively. The early chemistry introduced by Lavoisier benefited the first physiologists Senebier and De Saussure to reject the "theory of humus", which imposed the soil as the unique source of carbon. During the first half of the 19th century, Sprengel and Liebig investigated on the problems related to some indispensable mineral salts, while Boussingault and Ville attempted to prove the nitrogen fixation from air without giving any convincing evidence. Liebig was the pioneer of the agricultural chemistry: he epitomised the knowledge of that period by imposing the so-called "law of the minima", already acknowledged by Sprengel, and patronised the use of mineral fertilisers in Europe by devising several formulas of mineral manure. He, however, did not recognise the needs of external supplies of nitrogen salts for the crops, in open dispute with the English school of Lawes and Gilbert, who were instead convinced assertors of such needs. At the end of the 19th century Hellriegel showed that leguminous plants presenting peculiar nodules on their roots could really fix the gaseous nitrogen. From these nodules Beijerinck and Prazmowski isolated for the first time some bacteria which were recognised as the real agents fixing nitrogen. This discovery was of fundamental importance for plant nutrition, only second to the discovery of photosynthesis. Another basic contribution came from early research of Sachs on plants grown on aqueous solutions: these techniques allowed to impose the concept of "essential elements", which was fixed as a principle by Arnon and Stout in 1939. This principle benefited further research concerning the effects of states of deficiency on plant growth and development through investigation on the anatomical, histologic and biochemical nutritional disorders of plants.     

Some notes on complexity in vegetation

Abstract. Vegetation is considered as a complex system with many subsystems. The system functions by using solar radiation as energy source and producing biomass and biodiversity. The different subsystems are connected by feedback loops and interact in a process of self-organisation. It appears impossible to characterize this system with mathematical expressions, because most of the basic processes are non-linear. Instead, vegetation can be described with dynamical models. Selection, competition as well as positive interactions can occur. The model accounts for the general dynamics, particularly fluctuations (when the system is in a steady state) and the climax situation. Many problems remain open: e.g. arbitrary limits of the system and its subsystems, macrostate/microstate relationships, thresholds and attractors. Single aspects of the subsystems can be linearized, but not the system as a whole and consequently its behaviour remains unpredictable.     

Some observations on the physiology ofPseudomonas natriegens nov. spec.

Summary Pseudomonas natriegens, nov. spec. which requires Na⁺ for growth, has been found to produce a considerable quantity of acid by the dissimilation of glucose in aerobic cultures. The products of glucose catabolism have been identified as CO₂ and acetic, pyruvic and lactic acids. Acid production is very rapid as well in broth cultures containing sodium glucuronate, but not in cultures containing galacturonate. Growth of this bacterium was not inhibited by saturating quantities of 2,4-diamino-6,7-diisopropyl pteridine. This property indicates that the isolate is more likely to be appropriately placed in the genusPseudomonas than in the genusVibrio. Induction of enzymes in resting cells for the oxidation of glucuronate was inhibited by chloramphenicol added at various intervals during the first 2 hrs of incubation. Supported by research grants G-7128 and G-9865 from the National Science Foundation and by Equipment Loan Contract NR-103-398 with the Office of Naval Research. Contribution no. 26 from the University of Georgia Marine Institute at Sapelo Island.     

Some notes on the terminology of brassinosteroids

In this paper the definitions of brassinolide, brassinolide activity andbrassins are reviewed, and definitions for the terms brassin, naturalbrassinosteroids and brassinosteroid analogues, based on biosynthetic reasoningand structure similarity are proposed.     

Diving physiology of birds: a history of studies on polar species

Our knowledge of avian diving physiology has been based primarily on research with polar species. Since Scholander's 1940 monograph, research has expanded from examination of the 'diving reflex' to studies of free-diving birds, and has included laboratory investigations of oxygen stores, muscle adaptations, pressure effects, and cardiovascular/metabolic responses to swimming exercise. Behavioral and energetic studies at sea have shown that common diving durations of many avian species exceed the calculated aerobic diving limits (ADL). Current physiological research is focused on factors, such as heart rate and temperature, which potentially affect the diving metabolic rate and duration of aerobic diving.