Prebiotic Soup--Revisiting the Miller Experiment [biogenesis]

Science Magazine ^ | May 2003 | Jeffrey L. Bada and Antonio Lazcano

[PatrickHenry]

"Isn't life wonderful?" sang Alma Cogan and Les Howard in their almost forgotten 1953 hit. That same year, Stanley L. Miller raised the hopes of understanding the origin of life when on 15 May, Science published his paper on the synthesis of amino acids under conditions that simulated primitive Earth's atmosphere (1). Miller had applied an electric discharge to a mixture of CH4, NH3, H2O, and H2--believed at the time to be the atmospheric composition of early Earth. Surprisingly, the products were not a random mixture of organic molecules, but rather a relatively small number of biochemically significant compounds such as amino acids, hydroxy acids, and urea. With the publication of these dramatic results, the modern era in the study of the origin of life began.

Since the late 19th century, the belief in a natural origin of life had become widespread. It was generally accepted that life's defining properties could be understood through physico-chemical characterization of "protoplasm," a term used to describe the viscous translucent colloid found in all living cells (2). Expressions like "primordial protoplasmic globules" were used not only by scientists but also in fiction, from Gilbert and Sullivan's Pooh-Bah in The Mikado (1885) to Thomas Mann's somber imaginary character Adrian Leverkühn in Doktor Faustus (1947). But few dared to be explicit, even in novels. Questioned about the origin of life, a chemist in Dorothy L. Sayers' novel The Documents in the Case (1930) states that "it appears possible that there was an evolution from inorganic or organic through the colloids. We can't say much more, and we haven't--so far--succeeded in producing it in the laboratory."

Some were willing to fill in the details. At the turn of the 20th century, many scientists favored the idea of primordial beings endowed with a plant-like (autotrophic) metabolism that would allow them to use CO2 as their source of cellular carbon. However, some scientists--including A. I. Oparin, J. B. S. Haldane, C. B. Lipman, and R. B. Harvey--had different ideas (3). The most successful and best-known proposal was that by Oparin, who, from a Darwinian analysis, proposed a series of events from the synthesis and accumulation of organic compounds to primordial life forms whose maintenance and reproduction depended on external sources of reduced carbon.

The assumption of an abiotic origin of organic compounds rested on firm grounds. In 1828, F. Wöhler had reported the first chemical synthesis of a simple organic molecule (urea) from inorganic starting materials (silver cyanate and ammonium chloride).

After a large body of research on the synthesis of simple organic compounds accumulated in the 19th century (see figure above), W. Löb achieved the chemical syntheses of simple amino acids such as glycine by exposing wet formamide to a silent electrical discharge and to ultraviolet light (4).

These efforts to produce simple organic compounds from simple reagents heralded the dawn of prebiotic organic chemistry. However, there is no indication that the scientists who carried out these studies were interested in how life began on Earth, or in the synthesis of organic compounds under possible prebiotic conditions. This is not surprising, because the abiotic synthesis of organic compounds was not considered to be a necessary prerequisite for the emergence of life.

From the 1950s, chemists were drawn toward the origin of life. Driven by his interest in evolutionary biology, Melvin Calvin tried to simulate the synthesis of organic compounds under primitive Earth conditions with high-energy radiation sources. He and his group had limited success: the irradiation of CO2 solutions with the Crocker Laboratory's 60-inch cyclotron led only to formic acid, albeit in fairly high yields (5). Miller's publication 2 years later showed how compounds of biochemical importance could be produced in high yields from a mixture of reduced gases.

The origin of Miller's experiment can be traced to 1950, when Nobel laureate Harold C. Urey, who had studied the origin of the solar system and the chemical events associated with this process, began to consider the emergence of life in the context of his proposal of a highly reducing terrestrial atmosphere. Urey presented his ideas in a lecture at the University of Chicago in 1951, followed by the publication of a paper on Earth's primitive atmosphere in the Proceedings of the National Academy of Sciences(6).

Almost a year and a half after Urey's lecture, Miller, a graduate student in the Chemistry Department who had been in the audience, approached Urey about the possibility of doing a prebiotic synthesis experiment using a reducing gas mixture. After overcoming Urey's initial resistance, they designed three apparatuses meant to simulate the ocean-atmosphere system on primitive Earth (3). The first experiment used water vapor produced by heating to simulate evaporation from the oceans; as it mixed with methane, ammonia, and hydrogen, it mimicked a water vapor-saturated primitive atmosphere, which was then subjected to an electric discharge (see the figure below). The second experiment used a higher pressure, which generated a hot water mist similar to that of a water vapor-rich volcanic eruption into the atmosphere, whereas the third used a so-called silent discharge instead of a spark.

Miller began the experiments in the fall of 1952. By comparison with contemporary analytical tools, the paper chromatography method available at the time was crude. Still, after only 2 days of sparking the gaseous mixture, Miller detected glycine in the flask containing water. When he repeated the experiment, this time sparking the mixture for a week, the inside of the sparking flask soon became coated with an oily material and the water turned a yellow-brown color. Chromatographic analysis of the water flask yielded an intense glycine spot; several other amino acids were also detected. Experiments with the second apparatus produced a similar distribution and quantities of amino acids and other organic compounds, whereas the third apparatus with silent discharge showed lower overall yields and much fewer amino acids (primarily sarcosine and glycine).

After Miller showed the impressive results to Urey, they decided to submit them to Science. Urey declined Miller's offer to coauthor the report because otherwise Miller would receive little or no credit. Knowing that a graduate student could have a difficult time getting a paper like this published, Urey contacted the Science editorial office to explain the importance of the work and ask that the paper be published as soon as possible. Urey kept mentioning the results in his lectures, drawing considerable attention from the news media.

The manuscript was sent to Science in early February of 1953. Several weeks went by with no news. Growing impatient, Urey wrote to Howard Meyerhoff, chairman of AAAS's Editorial Board, on 27 February to complain about the lack of progress (7). Then, on 8 March 1953, the New York Times reported in a short article entitled, "Looking Back Two Billion Years" that W. M. MacNevin and his associates at Ohio State University had performed several experiments simulating the primitive Earth--including a discharge experiment with methane wherein "resinous solids too complex for analysis" were produced. The next day, Miller sent Urey a copy of the clipping with a note saying "I am not sure what should be done now, since their work is, in essence, my thesis. As of today, I have not received the proof from Science, and in the letter that was sent to you, Meyerhoff said that he had sent my note for review."

Infuriated by this news, Urey had Miller withdraw the paper and submit it to the Journal of the American Chemical Society. Ironically, at the same time (11 March), Meyerhoff, evidently frustrated by Urey's actions, wrote to Miller that he wanted to publish the manuscript as a lead article and that he wanted Miller--not Urey--to make the final decision about the manuscript. Miller immediately accepted Meyerhoff's offer, the paper was withdrawn from the Journal of the American Chemical Society and returned to Science, and was published on 15 May 1953.

On 15 December 1952, well before the Miller paper was sent to Science, K. Wilde and co-workers had submitted a paper on the attempted electric arc synthesis of organic compounds using CO2 and water to the same journal. They reported that no interesting reduction products, such as formaldehyde, were synthesized above the part-per-million level. This result supported the surmise of Miller and Urey that reducing conditions were needed for effective organic syntheses to take place. Surprisingly, when the paper by Wilde et al. was published in Science on 10 July 1953, it did not mention Miller's paper, although the authors did note that their results had "implications with respect to the origin of living matter on earth."

Miller's paper was published only a few weeks after Watson and Crick reported their DNA double-helix model in Nature. The link between the two nascent fields began to develop a few years later, when Juan Oró demonstrated the remarkable ease by which adenine, one of the nucleobases in DNA and RNA, could be produced through the oligomerization of hydrogen cyanide (8). It would eventually culminate in the independent suggestions of an "RNA world" by Carl Woese, Leslie Orgel, and Francis Crick in the late 1960s and by Walter Gilbert in 1986.

The impact of the Miller paper was not limited to academic circles. The results captured the imagination of the public, who were intrigued by the use of electric discharges to form the prebiotic soup. Fascination with the effects of electricity and spark discharges on biological systems started with the work of L. Galvani in 1780 with frog legs and the discovery of "animal electricity." And an everlasting impression was left in the public's imagination by Mary W. Shelley's Frankenstein (1818), in which Eramus Darwin gained a place for his advocacy of therapies based on electric discharges.

Although in 1953, few envisioned the possibility of Frankenstein monsters crawling out of Miller's laboratory vessels, the public's imagination was captivated by the outcome of the experiment. By the time that the results were corroborated by an independent group 3 years later (9), the metaphor of the "prebiotic soup" had found its way into comic strips, cartoons, movies, and novels, and continues to do so. In Harry Mulisch's novel The Procedure (1998), one of the central characters encounters disaster while paving his way to the glittering halls of Stockholm for achieving the artificial synthesis of life from a primitive soup.

But is the "prebiotic soup" theory a reasonable explanation for the emergence of life? Contemporary geoscientists tend to doubt that the primitive atmosphere had the highly reducing composition used by Miller in 1953. Many have suggested that the organic compounds needed for the origin of life may have originated from extraterrestrial sources such as meteorites. However, there is evidence that amino acids and other biochemical monomers found in meteorites were synthesized in parent bodies by reactions similar to those in the Miller experiment. Localized reducing environments may have existed on primitive Earth, especially near volcanic plumes, where electric discharges (10) may have driven prebiotic synthesis.

In the early 1950s, several groups were attempting organic synthesis under primitive conditions. But it was the Miller experiment, placed in the Darwinian perspective provided by Oparin's ideas and deeply rooted in the 19th-century tradition of synthetic organic chemistry, that almost overnight transformed the study of the origin of life into a respectable field of inquiry.

[Illustrations and footnotes in the original.]

[js1138]

I am neither George, nor Right. I am BatBoy. Fear me.

[VadeRetro]

Never understood that "Bat Boy found in cave" business anyway. Everyone knows Bat Boys are found in ball parks.

[VadeRetro]

Found!

[js1138]

I've seen the musical. It was doing quite well in NY, but the theater was closed due to 911.

[VadeRetro]

Saw a few shows up there on a trip in 94. It would be fun to do again but it's a bit out of my beaten path.

[PatrickHenry]

Meanwhile, on the planet Mongo:

[VadeRetro]

Auuggh!! Ardent for Arden! (Except she won't even be born until the 25th century. That inconvenient fact would make any lust for her extremely politically incorrect, pedophilia to the nth degree.)

[VadeRetro]

OTOH, if she looked like that in 1940, she'd be how old now? I'm confused.

[PatrickHenry]

Cross-chrono perversion is the very worst kind. It's not only the mutations, and the unknowable possibility of incest, but the temporal paradoxes! You are truly a sicko.

[carlo3b]

Geeeze, I thought it was going to tell us that we are from noodle soup.. :(

[PatrickHenry]

Jean Rogers as Dale Arden in Flash Gordon
(Her expression is presumably triggered by learning that Vade lusts after her.)

[PatrickHenry]

... from noodle soup

Nope. Pond scum is much more nutritious.

[js1138]

I never knew Flash was name for his performance issue.

[PatrickHenry]

Look what I found:

[VadeRetro]

(Her expression is presumably triggered by learning that Vade lusts after her.)

Hmmmmm. I suppose if I were to be a weakling and give in to a silly old irrational, mindless, reproductive urge, I might want to do so with Dale Arden/Jean Rogers. Until her her brains pushed her ear wax out.

[VadeRetro]

I suppose you ate all the Cracker Jack already?

[Loc123]

Please notice that I said "highly improbable."

Also please notice I didn't used any specific language; I used mathematical symbols (specifically geometry, which can hopefully be understood universally). You are correct that an alien intellince might not understand x-12, etc. At least the Voyager designers predicted aliens could understand math.

And we don't live in a universe where mathematical symbols behave like particles, occasionally combining and decomposing to form randomness.

Complex molecules self-organize in an energy gradient? To a point perhaps...but the energy gradient on Earth would have to be perfectly calibrated to allow for complex molecules to form in the presence of that gradient. Even the highest endothermic complex molecule will decompose given enough "activation energy."

[Loc123]

Do I really need to explain the fundamentals of chemistry to you? Valence shell collapse--either through complete filling, partial filling, or evacuation of the valence shell--is the basis for all of chemistry and is an extension of the second law of thermodynamics (that the overall change of the universe is towards disorder). Collapse means the potential energy decreases dramatically and non-linearly once those conditions are met.

Hydrogen loses its electron in its s orbital and hence has an unrestrained z effective (nuclear charge). It is essentially a proton that will be attracted to a region with an overall negative charge (as in an anion or polar molecule).

And are implying there is any evidence that a catalyst--a highly complex molecule that is not self-replicating--"evolved" along side a potentially self-replicating molecule by pure chance? And also that these two discrete molecules would someday meet? That is far-fetched to me.

That is why I suggested there must be an energy gradient (don't get upset over that word--JS used it too). However, then please look at my reply to JS for why a energy gradient is quite finicky.

What are the two types of polymerization. 1) Dehydration: basically a simple molecule is "booted" from an end of a carbon-based monomer on two molecules and the resulting opposite polarities (on the two ends of the two monomers) join together. I don't exactly know the cause of this for inorganic chem, but for organic chem it is usually a catalyst that performs this (IE in DNA's replication process a catalyst goes down the strands and separates their hydrogen bonds). Dehydration, as far as I know (and I will ask my professor, Dr. Martin Zanni, tomorrow), cannot occur in the presense of water.

2) Addition: you start of with a surplus of some doubled bonded (C=C) organic molecules. You then add a free radical of your choice (has an unpaired single electron). It contacts with the recess (think female component) of the organic molecule, breaks the double bond (by "stealing" the pie bond electrons) and causes the attached carbon (also part of that former double bond) to have an unpaired electron). Now, this carbon is a free radical of sorts and will do the same thing to neighboring carbons in a cascade. You stop this procedure by adding another free radical to bond with the radicalized carbons (and neutralize the cascade). Examples of this type of polymerization are making long synthetic polymers. This is not used in cellular metabolism or composition (hence why it is essentially irrelevant to this topic).

VadeRetro, your self-justification for not understanding chemistry amuses me greatly. Even the simplest of chemical concepts (entropy, polymerization (both kinds), bonding physics) are unfamiliar to you--so you call them babble or nonsense. Trust me, a simple google search won't teach you chemistry. Attend a university and take the science route. It is certainly not to late--especially if you are motivated to learn it.

I don't know why this has turned into a personal issue for you. Despite your claims, I have never "scream[ed]," "pouted," or shown any such negative emotions. If I have and am unaward, please quote me. Despite what donh says, this is not a "battleground" for my "creationist" ambitions; I am here to apply what I've learned to the topic. This topic perked my interest because it seemed so out of place, with its points being either irrelevant or archane.

Believe me, I never wanted to assail any of you--that would be quite against my morals.

That all said, I no longer have time to devote the 1+ hours to this topic per night. You might choose not to believe me, but I do study science and mathematics very hard at the University of Wisconsin-Madison. I am currently in a very demanding class (Chem 109--Advanced Chem) and I have a lab and exam coming up shortly. As much as I enjoy relaying what I have already modelled (aka conceptualized) from class, it really seems unnecessary to do in this debate. This is especially true when you close your mind to learning and instead prefer mocking. I'm sorry, but I don't have more time to teach basic chemistry.

Good luck to all of you (including Patrick Henry). The one parting advice I have for this thread is this: don't merely remember someone else's generalizations or a talking points; conceptualize and understand the mechanics of the system in question (ie energy ---> complex molecules). This is the true way to learn and apply what you are taught. If you don't do this, you are essentially just remembering someone's words.

Godspeed guys,

Loc123

[js1138]

Why don't you go for broke and ask Dr. Zanni whether the laws of chemistry forbid evolution or abiogenesis under any and all possible conditions. I'll be holding my breath to hear what he has to say. By the way which Dr. Zanni is it?

[PatrickHenry]

Meanwhile, events on Mongo are heating up: