Botany Photo of the Day and the Nitrogen Cycle

 
Check out the Botany Photo of the Day and learn what this plant has to do with Australia, Argentina, Uruguay and The Nitrogen Cycle.

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The Guelph Creationists

 
The University of Guelph is located in southern Ontario (Canada) about 2 hours west of Toronto. It has recently gotten a lot of attention because of the presence of several Intelligent Design Creationists among its staff and students.

Here are the main players.

David K.Y. Chiu is Professor of Computing and Information Science and Professor of Biophysics Interdepartmental Group. He has a Ph.D. in Systems Design Engineering from the University of Waterloo (Canada).

Professor Chiu is head of the Pattern Learning Research Group. Most of his recent papers have to do with recognizing patterns in bioinformatics data.

Durston, K.K., D.K.Y. Chiu, D.L. Abel and J.T. Trevors (2007) Measuring the functional sequence complexity of proteins", Theoretical Biology and Medical Modelling 4:47. [doi:10.1186/1742-4682-4-47]

Chiu, D.K.Y. and K. Zhang (2007) Biomolecular data analysis: a post-genomic reflection. Biomolecular Engineering, 24:319-320.

Chiu, D.K.Y. and Y. Wang (2006) Multipattern consensus regions in multiple aligned protein sequences and their segmentation. EURASIP Journal on Bioinformatics and Systems Biology, Vol.2006:1-8.

Ma, P.C.H., K.C.C. Chan, X. Yao and Chiu, D.K.Y. (2006) An evolutionary clustering algorithm for gene expression microarray data analysis. IEEE Trans. on Evolutionary Computation 10:296-314.

Hwang, C., Chiu, D.K.Y. and Sohn, I. (2005) Analysis of exon structure using PCA and ICA of short-time Fourier transform. L. Wang, K. Chen, and Y.S. Ong (Eds.): ICNC LNCS 3611, pp.306-315, 2005, Springer-Verlag Berlin Heidelberg 2005.(also Second Intern. Conf. on Fuzzy Systems and Knowledge Discovery, joint ICNC'05-FSKD'05, 27-29 Aug. 2005, Changsha, China.)

Durston, K. and Chiu, D.K.Y. (2005) A functional entropy model for biological sequences. in supplementary volume of the journal, Dynamics of Continuous, Discrete and Impulsive Systems, Series B, 2005 (also Proc. 4th Intern. Conf. on Engineering Applications and Computational Algorithms), pp.722-725.

Professor Chiu is a Fellow of the International Society for Complexity, Information, and Design. Other fellows include Michael Behe, Paul Nelson, Guillermo Gonzalez, William Dembski, Jonathan Wells and Scott Minnich.

Kirk Durston is National Director of the New Scholars Society whose aim is to "be a resource to those faculty and scholars who have an interest in developing the spiritual area of their lives from a Christian perspective." Durston has a B.Sc. in Physics from the University of Manitoba (Canada), a B.Sc. in Mechanical Engineering from the University of Manitoba (Canada) and an M.A. in Philosophy from the University of Manitoba (Canada). He is currently a Ph.D. candidate in the Biophysics Interdepartmental Group at the University of Guelph [Kirk Durston].

Durston's supervisor is David Chiu (see above). This is not a simple case of a graduate student falling under the influence of his supervisor since Durston was a well-known creationist even before he joined Chiu's group. It's just a coincidence that student and supervisor share the same views on religion and evolution since to suggest otherwise would be like accusing Chiu of selecting a student based on his religious views and not on the normal criteria. Intelligent Design Creationists are vehemently opposed to that kind of discrimination.

I'm sure Durston's previous degrees in physics, mechanical engineering, and philosphy made him well qualified to do Ph.D. research on the evolution of proteins in a bioinformatics lab.

Jack Trevors is a Professor in the Dept. of Environmental Biology [Jack Trevors] and he's also a member of the Biophysics Interdepartmental Group [Jack Trevors].

Professor Trevors has a B.Sc. and an M.Sc. from Acadia University (Canada) and a Ph.D. from the University of Waterloo (Canada). Most of his many publications are on various aspects of microbiology diversity and industrial applications but he is also interested in "Bacterial evolution with an emphasis on the origin and of the first bacterial cells and functional genetic instructions."

Trevors is famous in creationist circles for two papers he has published with David Abel, Director of The Gene Emergence Project at The Origin-of-Life Foundation, Inc. in Greenbelt, MD (USA). These papers are widely quoted as evidence that the origin of life cannot be explained by natural processes.

Abel and Trevors have also just published a paper with creationists Durston and Chiu.

Abel, D.L. and J.T. Trevors. (2006) Self-organization vs. self-ordering events in life-origin models. Physics of Life Reviews 3:211-228. [doi:10.1186/1742-4682-2-29]

Trevors, J.T. and Abel, D.L. (2004) Chance and necessity do not explain the origin of life. Cell Biology International 28:729-739. [doi:10.1016/j.cellbi.2004.06.006]

Durston, K.K., D.K.Y. Chiu, D.L. Abel and J.T. Trevors (2007) Measuring the functional sequence complexity of proteins. Theoretical Biology and Medical Modelling 4:47. [doi:10.1186/1742-4682-4-47]

Jack Trevors is not a creationist according to this profile at the University of Guelph. He's a "self-proclaimed atheist."

Take that question about the origins of life. It's hardly a new line of inquiry for Trevors, who was about 10 when he began wondering about the existence of God. He's still wondering. Indeed, it's a question that has consumed a fair amount of his own life recently, albeit now voiced in the language of a professional scientist: Where and how did the genetic code and its instructions arise?

No small question. “The origin of genetic instructions in the DNA is the most pressing question in science,” he says. “Genetic instructions don't write themselves, any more than a software program writes itself.”

He adds that the issue goes far beyond deciphering the recipes for making proteins. Given that our genetic material constitutes the stuff of our own identity, “it's the search for ourselves, our origins,” he says.

Call it looking for God in our DNA — or at least that's how a person of faith might phrase it. Trevors, a self-proclaimed atheist, is more circumspect. “If you're a religious person, you say God. If you're an evolutionist, you say evolution.”

He notes, however, that not even evolution deigns to tell us where or how life itself first came about or how DNA's instructions came to be. Perhaps the birthplace of those instructions — like the very creation of the universe itself — is, in Trevors' words, both “unknowable and ‘undecidable' at this point in time.”

The same profile article describes his association with David Abel ...

It's a million-dollar question, literally. That's the size of the prize in a contest being run by the Origin-of-Life Foundation based near NASA's Goddard Space Flight Centre in Maryland. All the winner needs to do to claim the reward — actually annual instalments of $50,000 for 20 years — is to explain how the initial genetic code arose — or, in the words of the contest rules, provide "a highly plausible mechanism for the spontaneous rise of genetic instructions in nature sufficient to give rise to life."

The Gene Emergence Project is a program of the foundation, a scientific and educational body of about 200 scientists in 40 countries.

"We want the international scientific community to help us prove that genetic instructions don't write themselves," says Trevors, who got involved by contacting David Abel, the project's program director, two years ago.

"Jack relentlessly looks for evolutionary explanations for everything we observe in biology," says Abel, adding that his Guelph colleague helps ensure that "life-origin theory" remains empirically responsible, or answerable to the test of repeated observation. "He likes to include the full gamut of microbiological phenomena to make sure our models are explaining all aspects of genetic control."

Trevors has written on the topic, including a paper last year with Abel called: "Chance and Necessity Do Not Explain the Origin of Life." There and in a more recent piece, they frame the genesis-of-life discussion in terms that might resonate with a computer programmer, including referring to genes as linear strings of digital instructions and describing DNA's four nucleotide building blocks as four-way switches. If genes are merely algorithms, albeit highly sophisticated ones, another obvious question occurs, says Trevors. “Computer programs don't write themselves. Why would scientists or anyone else think genetic programs write themselves? The question has to be asked and examined from a scientific perspective.”

I don't know about the rest of you but I don't often hear atheists say things like that. Maybe he's thinking of aliens who write genetic programs? I also don't know too many atheists who would publish papers with known creationists who use the data to support their religious agenda.

The Origin-of-Life Prize has a complicated set of rules that must be followed in order to claim victory. The organization has posted a list of suggested texts that candidates should be familiar with (see sidebar on their website). That list is very revealing. There are books by well-known scientists like Michael Behe, Hubert P. Yockey, Walter James ReMine, William Dembski, and David Berlinski.

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First Sex?

 
Here's the opening paragraphs from a news item on the National Geographic website ["First Sex" Found in Australian Fossils?].

Sex is part of the "oldest profession" and often called the subject of the "world's oldest joke." Now scientists think they've found evidence of the oldest known creatures to engage in sexual reproduction.

A new study suggests that nature's first sexual encounter took place among tubular invertebrates called Funisia dorothea, which lived about 565 million years ago.

This is an example of bad science writing. Sexual reproduction is a phenomenon seen in many bacteria and in all eukaryotes (with minor exceptions). Animals are not the only eukaryotes that have sex. Plants, do it; fungi do it; and so do all single-cell eukaryotes.

The ancestors of these tube worms were having sex for at least a billion years before the Neoproterozoic. The idea that these organisms were "nature's first sexual encounter" is silly.

Who is responsible for this misrepresentation of the evolution of sex? The paper by Droser and Gehling (2008) was published in Science last week. The only reference to sex in the peer-reviewed paper is the following ....

The branching patterns and rarity of branching of Funisia is consistent with metazoan asexual budding. The consistency of tube widths on individual bedding surfaces (Fig. 1, A, I, and J), the densely packed nature of the attachment structures, and the clustering pattern of developmental stages of attachment structures on individual bedding planes suggests that the juveniles settled as aggregates in a series of limited cohorts.

These solitary organisms thus exhibit growth by addition of serial units to tubes and by the division of tubes, and dispersed propagation by the production of spats. Among living organisms, spat production is almost ubiquitously the result of sexual reproduction but is known to occur rarely in association with asexual reproduction (8). Hence, despite its morphological simplicity the Neoproterozoic F. dorothea provides evidence of a variety of growth modes and a complex arrangement for the propagation of new individuals. In living organisms, synchronous aggregate growth may result from a variety of factors—including response to competition, sediment disturbance, and heterogeneity of the substrate—and has the advantage of reducing competition for space between clones and can also decrease gamete wastage (9, 10).

There's nothing in the paper about these organisms being the first to reproduce sexually—that wouldn't have survived the reviews. The only remaining question is why did the author (Droser) allow herself to be quoted in a press release when she must have known that it was misrepresenting the paper?

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Droser, M.L. and Gehling, J.G. (2008) Synchronous Aggregate Growth in an Abundant New Ediacaran Tubular Organism. Science 319:1660-1662. DOI: 10.1126/science.1152595

Nobel Laureate: Fritz Haber

 

The Nobel Prize in Chemistry 1918.

"for the synthesis of ammonia from its elements"


Fritz Haber (1868 - 1934) was awarded the 1918 Nobel Prize in Chemistry for working out a method to synthesize ammonia (NH₃) from nitrogen (N₂) and hydrogen (H₂). This process, now known as the Haber-Bosch process, is an essential step in the production of artificial fertilizer. At the time, it was not known how long the natural sources of nitrogen such as Chile saltpetre (sodium nitrate) would last. Harber worked at the Kaiser-Wilhelm-Institut (now Fritz-Haber-Institut) für physikalische Chemie und Electrochemie in Berlin-Dahlem, Germany

Many species of bacteria can fix nitrogen into ammonia in a reaction catalyzed by the enzyme nitrogenase [The Nitrogen Cycle]. The Haber-Bosch process involves heating nitrogen and hydrogen to a temperature of 450°C under 200 atm of pressure in the presence of an iron catalyst. Bacteria do it at 20°C or less at atmospheric pressure.

The 1918 prize was announced in November 1919 and the prize wasn't awarded until June 1920. Part of the delay was due to the fact that Fritz Haber was head of the German Chemical Warfare Service during the war. He was responsible for initiating mustard gas attacks on the allied lines.

The presentation speech was delivered by Doctor Å.G. Ekstrand, President of the Royal Swedish Academy of Sciences. No member of the Swedish Royal family was present at the ceremony because of the death of crown-princess Margaret.THEME:

Nobel Laureates

The Royal Swedish Academy of Sciences has decided to confer the Nobel Prize in Chemistry for 1918 upon the Director of the Kaiser Wilhelm Institute at Dahlem near Berlin, Geheimrat Professor Dr. Fritz Haber, for his method of synthesizing ammonia from its elements, nitrogen and hydrogen.

In accordance with Nature's plan of economy, soil fertility under normal circumstances is maintained at an even level if the waste products from the crop are returned to the soil; if, however, substantially increased productivity is required from the soil, then additional fertilizer must be used. Since meanwhile a large proportion of the annual harvest is consumed by the yearly increasing population of towns, and since the towns' waste products are returned to land under cultivation only to a very incomplete extent, the inevitable consequence is that the soil becomes exhausted and the harvest yield diminishes. This has, in turn, led to the manufacture of artificial fertilizers which has also increased year by year in importance to such an extent that, at least in Europe, hardly a country exists which can do entirely without them.

Among these substances nitrogenous compounds occupy an important position, since usually the soil does not possess a large store of these to be released to suit the plants' needs by weathering as in the case of phosphoric acid and potash; added to which there is the fact that part of the effective nitrogen turns into inactive atmospheric nitrogen during the cyclic process. Admittedly a part of this loss is compensated by rainfall and through the activity of bacteria, but so far experience has shown that intensive cultivation cannot be maintained without artificial nitrogenous fertilizers. This applies, above all, to one of today's most important crops, sugar-beet.

For many years only two artificial nitrogenous compounds existed, namely potassium nitrate and ammonium chloride. The older methods by which these were made, however, ceased to play a part, at least in Europe and America, when Chile saltpetre (sodium nitrate) came into the picture and use was made of the by-products from dry distillation of mineral coal for this purpose.

The consumption of Chile saltpetre, calculated in terms of nitrogen, amounts to about 500,000 or more tons per annum. Under normal circumstances the vast majority of this saltpetre is used for fertilizer purposes. The burning question, therefore, has long been: how long will the saltpetre deposits in Chile last? The Chilean authorities give very widely varying estimates, and experts in Europe are of the opinion that at current production rates the deposits will be exhausted within the foreseeable future.

Be that as it may. The protracted World War has sufficiently demonstrated to every country the need of organizing, wherever possible, production of essential commodities within its own borders in sufficient quantities to meet its own needs.

Now, since saltpetre is among the most important of these substances, particularly in those countries which possess neither large mineral coal deposits nor cheap hydro-electric power, the artificial production of ammonia and nitric acid has reached an unprecedented degree of importance.

A substance on the borderline between natural and artificial products is the ammonia obtained by dry distillation of bituminous and brown coal. This ammonia comes from the nitrogen content of these minerals, amounting to approximately 1.3 % by weight, of which however the largest portion (around 85%) remains behind in the coke or is liberated as nitrogen during distillation.

During the first ten years of this century several methods were published, based on binding the nitrogen from the air, but few of these survived the trial stage. The first of these was Frank-Caro's cyanamide method. Indeed it appears that calcium cyanamide did not come fully up to expectations as a fertilizer, but since its nitrogen content can be converted to ammonia relatively easily, this has not so far proved to be an obstacle to the application of the method to an ever-increasing extent.

Using the main principles of thermodynamics every quantitative condition with regard to the combustion of atmospheric nitrogen to produce nitric oxide can be calculated. Birkeland and Eyde were, of course, the first to apply this technically with successful results.

Until 1904 nobody had been able to bring about a direct combination of nitrogen and hydrogen to form ammonia without the help of dark electrical discharge, although the experiments of Berthelot and Thomson proved that the combination occurred exothermically. With the experience we now have we can easily see that this negative result was due to the slowness of the reaction at low temperatures, and unfavourable equilibrium conditions at high temperatures. Admittedly, in 1884 Ramsay and Young had conducted some experiments on this, using iron fillings as a catalyst, but these yielded only uncertain results.

In 1904 Haber and van Oordt began a methodical study of this relevant field, based on modern physico-chemical methods, after a single previous experiment had given Haber a hope of finding a technical solution to the problem. They worked at a temperature of about 1,000° C and normal pressure, using iron as a catalyst. From these experiments it emerged that from red heat onwards, and also at higher pressures, only traces of ammonia could be formed.

During this work it was also shown experimentally for the first time that a real state of equilibrium existed in the system
N2+ 3H2 → NH3, which is in fact the real basis for the synthesis of ammonia.

In the "Zeitschrift für Elektrochemie" of 1913 can be found the treatment of this question, by Haber and Le Rossignol which has the most important practical meaning: "Über die technische Darstellung von Ammoniak aus Elementen" (On the technical production of ammonia from the elements). This treatise provided the groundwork for the development of the method on a factory scale at the "Badische Anilin- und Sodafabrik" in Ludwigshafen, the main development occurring under the guidance of Dr. C. Bosch.

Earlier experiments had shown the pointlessness of exceeding dark red heat, i.e. about 600° C. On the other hand, the reaction formula showed that combination occurs with a contraction of from 4 to 2 volumes.

From the law of equilibrium it follows that the higher the pressure is the more the equilibrium must shift to the ammonia side. This provided the basic principles. A temperature of about 500° C had to be used at the highest possible pressure, which in practice meant at about 150-200 atmospheres. It could also be assumed that this high pressure speeded up the reaction. But work with a flow of gas in a circulation system at such high pressure and at a temperature approaching red heat posed very severe difficulties and up to then had never been tried. It was, however, completely successful. The treatise in question contains detailed drawings of the equipment used with which, using iron as a catalyst, about 250 grams of ammonia were produced per hour and per litre of contact volume; with uranium or osmium as a catalyst considerably more was produced.

The heating is done electrically. Since however the heat escaping from the equipment is largely regenerated in the entrant gases the required temperature can largely be maintained by the regenerated heat and by the heat liberated during the formation of ammonia. A very important point in Haber's observations is that the gases can be given a greater flow rate during the reaction which of course substantially increases the amount of ammonia produced per unit of time.

Haber found the best catalyst to be osmium, followed by uranium or uranium carbide. According to tests conducted mostly at the factories of the "Badische", the activity of the catalyst may be increased by oxides or certain salts of alkalis and alkaline earth metals, just as it may be decreased by catalytic poisons. Gradually more active catalysts have been discovered, and by this means it has been found possible to reduce substantially the pressure in the chamber.

In 1910 construction work was begun on the first large factory near Oppau in the neighbourhood of Frankfurt am Main, with an estimated annual output of 30,000 tons of ammonia.

The basic materials, nitrogen and hydrogen, are produced by standard methods.

Power consumption in the ammonia process is very low, amounting to no more than 0.5 kilowatt-hours per kilogram of ammonia. Per kilowattyear, therefore, no less than 10,000 kilograms of nitrogen are bound.

Since the position of the equilibrium of the reaction depends, among other things, upon the heat of formation of ammonia and its specific heat, Haber in a series of seven articles in the "Zeitschrift für Elektrochemie" of 1914-1915, has extensively described experiments carried out to confirm these figures with the greatest possible accuracy.

As, according to Ostwald's modified method, ammonia can be converted into nitric acid and the latter into calcium nitrate, the ratio between the overall costs of producing calcium nitrate is, according to the available calculations, approximately as follows:

Norwegian Hydro: 100
Haber: 103
Frank-Caro: 117

in other words, they are the same for the first two methods but approximately 15% higher for the last.

Since, however, of the three existing nitrogen methods, Haber's is the only one capable of operating independently of any available source of cheap hydroelectric power it can in future be applied in all countries; since furthermore it can be utilized on any convenient scale and because it can produce ammonia very much more cheaply and nitrate equally as cheaply as any other method, as explained above, it is of universal significance for the improvement of human nutrition and so of the greatest benefit to mankind.

German Haber factories, especially the recently built Leuna Works near Merseburg, are also in full production, providing the vast majority of all nitrogenous fertilizers obtainable in Germany. Moreover, the method has already been extensively applied in the United States of America.

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A Politically Incorrect Commercial

 
This is bad form on the part of Mercedes-Benz. Somebody forgot to tell them that it's only men who are supposed to be stupid in TV commercials.

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[Hat Tip: Pretty shaved ape at Canadian Cynic

The Nitrogen Cycle

From Horton et al. (2006).

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The nitrogen needed for amino acids (and for the heterocyclic bases of nucleotides) comes from two major sources: nitrogen gas in the atmosphere and nitrate (NO₃^⊖) in soil and water. Atmospheric N₂ which constitutes about 80% of the atmosphere, is the ultimate source of biological nitrogen. This molecule can be metabolized, or fixed, by only a few species of bacteria. N₂ and NO₃^⊖ must be reduced to ammonia in order to be used in metabolism. The ammonia produced is incorporated into amino acids via glutamate, glutamine, and carbamoyl phosphate.

N₂ is chemically unreactive because of the great strength of the triple bond (N≡N). Some bacteria have a very specific, sophisticated enzyme—nitrogenase¹—that can catalyze the reduction of N₂ to ammonia in a process called nitrogen fixation. In addition to biological nitrogen fixation there are two additional nitrogen-converting processes. During lightning storms, high-voltage discharges cause the oxidation of N₂ to nitrate and nitrite (NO₂^⊖). Industrially, nitrogen is converted to ammonia for use in plant fertilizers by an energetically expensive process that requires high temperature and pressure as well as special catalysts to drive the reduction of N₂ by H₂. The availability of biologically useful nitrogen is often a limiting factor for plant growth, and the application of nitrogenous fertilizers is important for obtaining high crop yields. Although only a small percentage of the nitrogen undergoing metabolism comes directly from nitrogen fixation, this process is the only way that organisms can use the huge pool of atmospheric N₂.

The overall scheme for the interconversion of the major nitrogen-containing compounds is shown in Figure 17.1. The flow of nitrogen from N₂ to nitrogen oxides, ammonia, and nitrogenous biomolecules and then back to N₂ is called the nitrogen cycle. Most of the nitrogen shuttles between ammonia and nitrate. Ammonia from decayed organisms is oxidized by soil bacteria to nitrate. This formation of nitrate is called nitrification. Some anaerobic bacteria can reduce nitrate or nitrite to N₂ (denitrification). Most green plants and some microorganisms contain nitrate reductase and nitrite reductase, enzymes that together catalyze the reduction of nitrogen oxides to ammonia.
This ammonia is used by plants, which supply amino acids to animals. Reduced ferredoxin (formed in the light reactions of photosynthesis) is the source of the reducing power in plants and photosynthetic bacteria.

Let’s examine the enzymatic reduction of N₂. Most nitrogen fixation in the biosphere is carried out by bacteria that synthesize the enzyme nitrogenase. This multisubunit protein catalyzes the conversion of each molecule of N₂ to two molecules of NH₃ (ammonia). Nitrogenase is present in various species of Rhizobium and Bradyrhizobium that live symbiotically in root nodules of many leguminous plants, including soybeans, peas, alfalfa, and clover (Figure 17.2). N₂ is also fixed by freeliving soil bacteria such as Agrobacteria, Azotobacter, Klebsiella, and Clostridium and by cyanobacteria (mostly Trichodesmium spp.) found in the ocean. Most plants require a supply of fixed nitrogen from sources such as decayed animal and plant tissue, nitrogen compounds excreted by bacteria, and fertilizers. Vertebrates obtain fixed nitrogen by ingesting plant and animal matter.

Nitrogenase is a protein complex that consists of two different polypeptide subunits with a relatively complicated electron-transport system. One polypeptide (called iron protein) contains a [4 Fe–4 S] cluster, and the other (called iron–molybdenum protein) has two oxidation–reduction centers, one containing iron in an [8 Fe–7 S] cluster, and the other containing both iron and molybdenum. Nitrogenases must be protected from oxygen because the metalloproteins are highly susceptible to inactivation by O₂. For example, strict anaerobes carry out nitrogen fixation only in the absence of O₂. Within the root nodules of leguminous plants, the protein leghemoglobin (a homolog of vertebrate myoglobin) binds and thereby keeps its concentration sufficiently low in the immediate environment of the nitrogen-fixing enzymes of rhizobia. Nitrogen fixation in cyanobacteria is carried out in specialized cells (heterocysts) whose thick membranes inhibit entry of O₂.


A strong reducing agent—either reduced ferredoxin or reduced flavodoxin (a flavoprotein electron carrier in microorganisms)—is required for the enzymatic reduction of N₂ to NH₃. An obligatory reduction of 2 H^⊕ to H₂ accompanies the reduction of N₂. For each electron transferred by nitrogenase, at least two ATP molecules must be converted to ADP and P_i (inorganic phosphate) so the six-electron reduction of a single molecule of N₂ (plus the two-electron reduction of 2 H^⊕) consumes a minimum of 16 ATP.


In order to obtain the reducing power and ATP required for this process, symbiotic nitrogen-fixing microorganisms rely on nutrients obtained through photosynthesis carried out by the plants with which they are associated.

©Laurence A. Moran and Pearson/Prentice Hall

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1. Monday's Molecule #66

[Nitrogenase Image Credit: Dixon and Kahn (2004) based on the structure PDB 1n2c by Schindelin et al. (1997)]

Dixon, R. and Kahn, D. (2004) Genetic regulation of biological nitrogen fixation. Nature Reviews Microbiology 2, 621-631. doi:10.1038/nrmicro954

Horton, H.R., Moran, L.A., Scrimgeour, K.G., perry, M.D. and Rawn, J.D. (2006) Principles of Biochemisty. Pearson/Prentice Hall, Upper Saddle River N.J. (USA)

Schindelin, H., Kisker, C., Schlessman, J.L., Howard, J.B. and Rees, D.C. (1997) Structure of ADP x AIF4(-)-stabilized nitrogenase complex and its implications for signal transduction. Nature 387: 370-376 [PubMed]

Tales from a New Encyclopedia

 
Centre for Inquiry's CELEBRATION OF SCIENCE AND FREETHOUGHT

ATHEISTS, HERETICS and UNBELIEVERS have fought at the forefront of every major civil rights movement of that last 300 years, including the Enlightenment, universal suffrage, abolitionism and minority civil rights. As the aggressive 'New Atheists' make headlines, the public tends to forget the legacy from which they stem.

In celebration we present:

TALES FROM A NEW ENCYCLOPEDIA

A presentation by Tom Flynn, Fri, April 4, 7pm
Tom Flynn, editor of FREE INQUIRY, leading secular humanist magazine, discusses the challenges he faced - and some of the surprising things he learned - during his five years editing THE NEW ENCYCLOPEDIA OF UNBELIEF. It covers in unprecedented detail the freethought, atheist, and humanist traditions and histories across the world. Flynn will share insights from research unearthing a once-vibrant freethought tradition in Toronto.

$5 general, $4 students, FREE for Friends of the Centre of Inquiry.
Join today ($60 regular, $20 students & low income)

The event is at CFI located just south of St. George & College at 216 Beverley St.-Canada's first home for those whose worldview is based on science, secularism and rationality. All are invited

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Send Email Back in Time

 

Google announced a new service starting today. You can now send email messages back in time using your gmail account. Unfortunately you can only go back four years to the day that gmail was launched. See Gmail Custom Time.

Is there a limit to how far back I can send email?

Yes. You'll only be able to send email back until April 1, 2004, the day we launched Gmail. If we were to let you send an email from Gmail before Gmail existed, well, that would be like hanging out with your parents before you were born -- crazy talk.

Think carefully before using this new feature. Each person only gets ten messages.

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For Once, Chris Mooney Talks Sense

 
Read Chris Mooney's latest posting on The Intersection where he addresses the framing controversy [A Dialogue on Framing, the F-Word, and the Future of ScienceBlogs, Part I: Framer Culpa].

When I teamed up with Matthew Nisbet a year ago to talk about the subject of framing science--which I still believe to be a very important one--it was not my goal to alienate or outrage a group that I consider one of my most important audiences, namely, ScienceBlogs bloggers and readers. And yet when you look at the latest blowup over what I have posted, Sheril has posted, and Nisbet has posted about Expelled, it's undeniable that there is now an audience that reacts very negatively even to any basic mention of the concept of framing.

And there's just no other way to spin it--this is a painfully ironic communication failure on the part of those of us who wanted to introduce what I view as a very important communication tool to the science world. If we can't explain something so useful to an important segment of our own audience, how can we possibly hope to use it to counter the other side?

Good for you Chris. The irony has been apparent to many of us and it's really good to see you confess to having created the problem. My respect for you just went up several notches.

Let me just correct one little thing. There are plenty of science bloggers out there who don't like your views on framing science. Not all of us belong to the ScienceBlogs^TM consortium.

Now, to be sure, the concept of framing has been quite influential already for many people who care about science, but who are not seemingly well represented on ScienceBlogs. When I go around lecturing with Matt Nisbet, we constantly encounter enthusiastic, receptive scientist-laden audiences at universities. There is simply nothing like the response that we've seen here over the last week. Indeed, I believe the reactions at lectures may have skewed my perceptions, and made me neglect or dismiss, to a significant extent, the way our ideas were faring in the science blogosphere.

But no success on the lecture circuit can change the fact that somehow--and I'll have ideas about how it happened in later posts--the concept of framing has been blackened on Scienceblogs, which I consider a truly tragic occurrence. And while I'm hardly the only guilty party here, I certainly played a role in that, whether actively or by omission.

It's very common for people on the lecture circuit to get an exaggerated—and false—impression of their message. This is because the only people who come to your talks are the true believers. When dissenters do show up it's often hard for them to debate the speaker just by posing questions from the audience.

I'm not surprised that the Nisbet/Mooney road show fooled you into thinking that your ideas were widely accepted in the scientific community. The other way of fooling yourself is to organize a conference where the only people invited are those who agree with you. This is what Nisbet did at AAAS.

Allow me to re-iterate the point I made earlier. It's not just on ScienceBlogs^TM that the concept of framing has been blackened. I've met many scientists who think that your views on framing¹ are an unacceptable way to teach science. A good many of those scientists have never read a single posting on any ScienceBlogs^TM blog and, furthermore, they have never even heard of Seed and the group it supports.

I admire the fact that you confess to poor framing of your ideas. Now. how about discussing whether they are even correct? Up to now all you've done is reject any criticism on the ground that we don't really understand framing. Maybe we do, but we're still opposed. Have you ever thought of that?

Your message still seems to be that you just made the mistake of not presenting your ideas correctly. In other words, you didn't frame properly. I hope that subsequent postings won't continue in that vein. It's time to realize that it was not only the medium that was flawed but also the message.

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1. Framing is deliberately altering what you want to say in order to make it more acceptable to your audience.

Is Faith Inevitable?

 
Last Thursday evening I watched a panel discuss the question "Is Faith Inevitable?" Unlike previous shows on TV Ontario, this one had a balance of believers and non-believers.

Two of the non-believers, Robert Buckman and Ronald de Sousa, are well-known in Canada (see below). You can watch the entire show at The Agenda.

I agree with the comments made by an undergraduate here at the University of Toronto when he says that the discussion got sidetracked [The Unexamined Life ...]. The real question is not whether faith is valuable, it's whether there is a God that you should have faith in.

Furthermore, I was very disappointed in Buckman and de Sousa because both of them bought into the line that we have evolved a need for religion. This is ridiculous. There is no gene for believing in supernatural beings and there's no reason to think that atheists need to overcome their genetic makeup in order to reject the notion of God. I wish we could put an end to this silly meme before it spreads any further.

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Gene Genie #28

 
The 28th edition of Gene Genie has been posted at Greg Laden's Blog [Gene Genie #24]. (It really is number 28, in spite of what Greg says. See Gene Genie.)

Welcome to Gene Genie #24: with a heavy emphasis on Personal Genetics.

The beautiful logo was created by Ricardo at My Biotech Life.

The purpose of this carnival is to highlight the genetics of one particular species, Homo sapiens.

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Canada Wins World Championship!

 
I'm sure you've already heard the news. The Canadian women's team of Dawn Askin (lead), Jill Officer (second), Cathy Overton-Clapham (third) and Jennifer Jones (skip) beat China yesterday to win the World¹ Women's Curling Championship.

Most of you were probably watching the game so I don't need to remind you how exciting it was.

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1. Just to clarify for my American friends ... this was not a tournament where only teenagers in colleges like UNC could play and it was not a tournament confined to a single country. This is a world title. The USA didn't even make the playoffs.

[Photo Credit: Ford World Women's Curling Championship]

Stuff White People Like

 
Check out the blog Stuff White People Like, especially, Paris, San Francisco, and Having Gay Friends.

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[Hat Tip: Jane at Beer with Chocolate.]

Monday's Molecule #66

 
This is a very important enzyme. Most living organisms on this planet could not survive if this enzyme didn't do its job. Very few species have this enzyme but we depend on those few species for our very existence.

Your task for today is to identify the enzyme (1) and the species from which this particular enzyme was isolated (2). You also have to write out the complete reaction that is catalyzed by this enzyme (3).

In addition you have to identify the Nobel Laureate who is associated with the reaction that is catalyzed by the enzyme. (Hint: the Nobel Laureate studied the chemical reaction, not the biological one.)

The first person to correctly identify the enzyme and species, write the chemical equation, and name the Nobel Laureate. wins a free lunch at the Faculty Club. Previous winners are ineligible for one month from the time they first collected the prize. There is only one ineligible candidate for this week's reward.

THEME:

Nobel Laureates
Send your guess to Sandwalk (sandwalk (at) bioinfo.med.utoronto.ca) and I'll pick the first email message that correctly answers the questions and names the Nobel Laureate(s). Note that I'm not going to repeat Nobel Laureates so you might want to check the list of previous Sandwalk postings.

Correct responses will be posted tomorrow along with the time that the message was received on my server. I may select multiple winners if several people get it right.

Comments will be blocked for 24 hours. Comments are now open.

UPDATE: We have a winner! The enzyme is nitrogenase from Azotobacter vinelandii. It fixes atmospheric nitrogen into ammonia by catalyzing the following reaction ...

The Nobel Laureate is Fritz Haber (1918) who worked out a chemical method of synthesizing ammonia from nitrogen.

Bryant Ing of the University of Toronto was the first person to get it right.

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[Image Credit: Dixon and Kahn (2004) based on the structure PDB 1n2c by Schindelin et al. (1997)]

Dixon, R. and Kahn, D. (2004) Genetic regulation of biological nitrogen fixation. Nature Reviews Microbiology 2, 621-631. doi:10.1038/nrmicro954

Schindelin, H., Kisker, C., Schlessman, J.L., Howard, J.B. and Rees, D.C. (1997) Structure of ADP x AIF4(-)-stabilized nitrogenase complex and its implications for signal transduction. Nature 387: 370-376 [PubMed]

Make Your Own Phylogenetic Tree

 
Sandra Porter at Discovering Biology in a Digital World has prepared a short video presentation on how to make your very own phylogenetic tree from DNA sequences [A beginner's guide to making a phylogenetic tree].

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