Photosynthesis
Generically, in the biological process of photosynthesis, a large number of organisms (e.g., plants, algae and particular bacteria) capture the energy of photons in sunlight, using that radiant energy to drive the synthesis of biochemical energy-rich molecules, through a series of physico-chemical reactions with the primary starting materials, water and carbon dioxide, and certain minerals and other inorganic matter, abundant in their environment. The photosynthesizing organisms, and organisms that feed on them, use those energy-rich molecules as building blocks and energy sources, enabling the cellular functions that maintains nearly every living system on Earth in the living state. Living systems on Earth, with notable exceptions, are solar powered.
Inasmuch as the etymological definition of photosynthesis, "synthesis with light", can apply to other light generating phenomena outside biology, a succinct core definition of photosynthesis might well be:
Photosynthesis is a process in which light energy is captured and stored by an organism, and the stored energy is used to drive cellular processes. [1]
This article will classify the differing types of photosynthesizing organisms, and describe the details of the differing photosynthetic mechanisms employed by them. It will also discuss the implications of photosynthesis in the sciences of biology, geology, oceanography, climatology, and other areas of importance to the life of planet Earth, since without photosynthesis nearly every species on Earth would perish.
Preliminarily, the reader might refer to the following:[1] [2] [3] [4] [5] [6] [7] [8]
Overview
Without photosynthesis the luxuriant, awe-inspiring variety of living systems we see everywhere in the terrestrial and marine world about us would not exist. Nearly all living systems on Earth depend directly or indirectly on the energy captured by photosynthesis from light energy radiating to our planet from our sun (see below). For us humans photosynthesis indirectly provides essentially all of our food-energy, as well the bulk of our non-food energy resources, inasmuch as ancient photosynthesizing organisms produced the energy-rich carbon-containing molecules we combust as fossil fuels — oil, natural gas, coal and wood — to generate electricity and other forms of energy we use to support human activity.
Nearly every oxygen atom that we inhale from the atmosphere emerged through photosynthetic liberation from a water molecule, among the countless water molecules covering 70% of the Earth´s surface. The chemical energy our bodies generate using that oxygen in biochemically combusting our food represents, almost literally, the energy that photosynthesis secured from the energy in sunlight.[9] Likewise, the energy we generate with that oxygen in combusting fuels — oil, coal, wood, natural gas — owes its origin to photosynthetic capture of the energy of sunlight. The sun offers the energy of life, and the living process of photosynthesis accepts the offer and distributes it.
In the biological process of photosynthesis in green plants, the leaves capture energy from photons in sunlight, using it to energize electrons, the captured and transformed energy the essential primary energy source driving a set of biochemical reactions that converts carbon dioxide (CO2) and water (H2O) to a carbohydrate compound, a triose, a 3-carbon sugar, and a largely 'waste' product, oxygen (O2) — thus defining 'oxygenic' photosynthesis.[10]. Triose, as triose phosphates, exit the leaf cell's organelles that synthesizes them — viz., a chloroplast, condense themselves into six-carbon hexose phosphates, ultimately forming dimers like sucrose, or polymers like starch or cellulose, the so-called reduced forms of carbon, reduced in the chemical sense of enrichment in the electrons energized by the captured photons, thus forming energy-rich carbon compounds that, as mentioned, the photosynthesizing organisms and their predators need to perform the cellular work that maintains them in the living state.
The photosynthetic process effectively stores energy in a variety of energy-rich molecules the photosynthetic organism can metabolize to generate adenosine triphosphate (ATP), the universal recirculating and recyclable energy currency of cells, so-called because it can provide the energy needed to drive many of the biochemical reactions necessary to synthesize the macromolecules and molecular intermediates required to maintain the cell in a living state. The process also produces other recyclable forms of circulating energy currency (e.g., NADPH). Photosynthesizing cells thus convert light energy to the life-sustaining chemical energy that drives life-sustaining cellular processes, to paraphrase the words of Professor Blankenship quoted above.
Organisms that photosynthesize operate as autotrophs — viz., organisms that generate their own source of food-energy — specifically referred to as photoautotrophs. They draw on minerals and other inorganic compounds from the environment and produce an ultimately photon-energy-derived complement of carbohydrates, proteins and lipids that self-organize the photoautotophic organism. In doing so they directly, though blindly, offer themselves as a source of food-energy (e.g., as vegetables, fruits) for consumption by us humans and other organisms, so-called heterotrophs — viz., organisms that feed on other organisms or on their energy-rich structural components — and indirectly provide a source of food-energy in the form of the non-human heterotrophs that we humans consume (e.g., chicken, fish and other animals). Photosynthesizing cells also supply the sufficient amounts of oxygen they and we need to generate ATP and NADPH, and they consume the 'waste' CO2 produced in the process of generating ATP.
Not all photosynthesizing organisms produce oxygen. The specific physico-chemical reactions of those that do biologists refer to as oxygenic photosynthesis, and those that do not as 'anoxygenic' photosynthesis. As noted above, oxygenic photosynthesis accounts for nearly all of the oxygen in the atmosphere.
References Cited and Notes in Text
- ↑ 1.0 1.1 Blankenship RE. (2002) Molecular Mechanisms of Photosynthesis. Wiley-Blackwell. ISBN 0632043210 (ISBN-10); ISBN 978-0632043217 (ISBN-13) (pbk)
- ↑ Farabee MJ. (2007) What is photosynthesis? Online Biology Book
- Detailed teatment of photosynthesis in an online biology course textbook. Includes an illustrated glossary.
- ↑ Photosynthesis Encyclopedia Britannica Free Full-Text Article
- ↑ John Whitmarsh, Govindjee. THE PHOTOSYNTHETIC PROCESS In: "Concepts in Photobiology: Photosynthesis and Photomorphogenesis", Edited by GS Singhal, G Renger, SK Sopory, K-D Irrgang and Govindjee, Narosa Publishers/New Delhi; and Kluwer Academic/Dordrecht, pp. 11-51. The online text is a revised and modified version of "Photosynthesis" by J. Whitmarsh and Govindjee (1995), published in Encyclopedia of Applied Physics (Vol. 13, pp. 513-532) by VCH Publishers, Inc.
- A comprehensive treatment of photosynthesis in a book chapter online. Includes history and research aspects. Detailed.
- ↑ Vermaas W. An Introduction to Photosynthesis and Its Applications
- An introduction to photosynthesis readily accessible to the general reader.
- ↑ Raven PH, Evert RF, Eichhorn SE. (1999) Photosynthesis, Light, and Life. Chapter 7. In: Biology of Plants. 6th ed. New York: W.H. Freeman. ISBN 1-57259-041-6; ISBN 1-57259-611-2 (comp).
- ↑ Kiang, NC, Siefert J, Govindjee, Blankenship RE. (2007) Special Paper. Spectral Signatures of Photosynthesis. I. Review of Earth Organisms. Astrobiology 7:222-251.
- ’’’From the Abstract:’’’ We provide (1) a brief review of how photosynthesis works, (2) an overview of the diversity of photosynthetic organisms, their light harvesting systems, and environmental ranges, (3) a synthesis of photosynthetic surface spectral signatures, and (4) evolutionary rationales for photosynthetic surface reflectance spectra with regard to utilization of photon energy and the planetary light environment.
- ↑ Morton O. (2008) Eating the Sun: How Plants Power the Planet. HarperColins. ISBN 0007163649 , ISBN 978-0007163649 (hbks).
- ↑ Weiss HM. (2008) Appreciating Oxygen. The Journal of Chemical Education 85(9):1218-1219.
- [Oxygen's] importance as an energy source is commonly overlooked. It is more common to speak of fossil fuels, hydrogen, or carbohydrates as the major energy sources in chemistry and biology but these compounds are some of the most stable organic molecules found in nature. These compounds are made of strong bonds and have little tendency to combine with any other molecules. Indeed, hydrocarbons were known as paraffins because of their low affinity for reaction. However, oxygen is a diradical held together with a bond energy of just 496 kJ mol‒1 (Bond energies are taken from Atkins, P.; Jones, L. Chemistry: Molecules, Matter, and Change, 3rd ed.; W. H. Freeman: New York, 1996.). By contrast, the oxygen atom forms two strong bonds in each of the combustion products [e.g., of glucose]; carbon dioxide (799 kJ mol‒1) and water (926 kJ mol‒1). As a result, every mole of oxygen that reacts releases, on average [over a large number of organic compounds], 460 kJ. It is the uniquely weak bonding in the oxygen molecule that makes combustion one of the most exothermic reactions in chemistry. By contrast, the bond strengths of the organic molecules are very similar to the bond strengths of the combustion products. Thus, in a chemical sense, the oxygen molecule is the energy source and the other "fuels" are merely vehicles to allow each oxygen atom to form strong bonds in the combustion products.
- ↑ Note: Summary equations typically depict glucose as the carbohydrate end-product of photosynthesis, whereas photosynthesizing cells generate very little glucose per se; the three-carbon trioses represent the more immediate photosynthetic carbohydrate.