Why are nearly all amino acids in organisms left-handed (exception is glycine which has no isomer) when abiotic samples typical have an even mix of left- and right-handed molecules?

  • $\begingroup$ It's no answer, but Radiolab had a great discussion of chirality and the issue you've brought up. Worth a listen: radiolab.org/2011/apr/18/mirror-mirror $\endgroup$
    – yamad
    Jan 11 '12 at 22:42
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    $\begingroup$ @yamad. The site you link to contains the line 'all living molecules are left-handed'. This, of course, is nonsense. $\endgroup$
    – user338907
    Apr 9 '16 at 8:13
  • $\begingroup$ @TomD ha, fair enough. Oversimplifications aside, though, I still like the piece because my memory is that they do a good job giving an intuitive feel for what chirality is and its effects. Of course, its likely that they make more frustrating oversimplifications and I missed them or forgave them in my rapture that a popular show was willing to dig pretty deeply into an idea like chirality for entertainment purposes. Sometimes Radiolab makes major missteps, but in general, I think their stuff is pretty solid as far as popular accounts of tricky scientific concepts go. $\endgroup$
    – yamad
    Apr 11 '16 at 17:10

I know that you are referring to the commonly ribosome-translated L-proteins, but I can't help but add that there are some peptides, called nonribosomal peptides, which are not dependent on the mRNA and can incorporate D-amino acids. They have very important pharmaceutical properties. I recommend this (1) review article if you are interested in the subject. It is also worth mentioning that D-alanine and D-glutamine are incorporated into the peptidoglycane of bacteria.

I read several papers (2, 3, 4) that discuss the problem of chirality but all of them conclude that there is no apparent reason why we live in the L-world. The L-amino acids should not have chemical advantages over the D-amino acids, as biocs already pointed out.

Reasons for the occurrence of the twenty coded protein amino acids (2) has an informative and interesting outline. This is the paragraph on the topic of chirality:

This is related to the question of the origin of optical activity in living organisms on which there is a very large literature (Bonner 1972; Norden 1978; Brack and Spack 1980). We do not propose to deal with this question here, except to note that arguments presented in this paper would apply to organisms constructed from either D or L amino acids.

It might be possible that both L and D lives were present (L/D-amino acids, L/D-enzymes recognizing L/D-substrates), but, by random chance the L-world outcompeted the D-world.

I also found the same question in a forum where one of the answers seems intriguing. I cannot comment on the reliability of the answer, but hopefully someone will have the expertise to do so:

One, our galaxy has a chiral spin and a magnetic orientation, which causes cosmic dust particles to polarize starlight as circularly polarized in one direction only. This circularly polarized light degrades D enantiomers of amino acids more than L enantiomers, and this effect is clear when analyzing the amino acids found on comets and meteors. This explains why, at least in the milky way, L enantiomers are preferred.

Two, although gravity, electromagnetism, and the strong nuclear force are achiral, the weak nuclear force (radioactive decay) is chiral. During beta decay, the emitted electrons preferentially favor one kind of spin. That's right, the parity of the universe is not conserved in nuclear decay. These chiral electrons once again preferrentially degrade D amino acids vs. L amino acids.

Thus due to the chirality of sunlight and the chirality of nuclear radiation, L amino acids are the more stable enantiomers and therefore are favored for abiogenesis.


  2. Reasons for the occurrence of the twenty coded protein amino acids

  3. Molecular Basis for Chiral Selection in RNA Aminoacylation

  4. How nature deals with stereoisomers

  5. The adaptation of diastereomeric S-prolyl dipeptide derivatives to the quantitative estimation of R- and S-leucine enantiomers. Bonner WA, 1972

  6. The asymmetry of life. Nordén B, 1978

  7. Beta-Structures of polypeptides with L- and D-residues. Part III. Experimental evidences for enrichment in enantiomer. Brack A, Spach G, 1980

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    $\begingroup$ Thanks Gergana. I'll follow some of this up. I can comment on the astronomy angle later. $\endgroup$
    – Poshpaws
    Jan 12 '12 at 14:46
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    $\begingroup$ Hope these papers are helpful. Let me know what you have found. $\endgroup$ Jan 12 '12 at 19:19
  • $\begingroup$ The difference between L and D amino acids does not affect the tertiary structure? $\endgroup$
    – frеdsbend
    Jan 12 '14 at 23:20
  • $\begingroup$ Because I was bored, I found and added links to the citations from "Reasons for the occurrence of the twenty coded protein amino acids" $\endgroup$
    – tel
    Apr 9 '16 at 6:37

The ribosome holds the peptide-bound tRNA and aminoacyl-tRNA in the right orientation to catalyze the peptidyltransferase reaction.


If the incoming aminoacyl-tRNA was the other enantiomer, the amino acid moiety would not fit properly into the ribosome active site. In other words, the shape of the ribosome selects for specific amino acid enantiomers. In abiotic mixes, the creation of amino acids and their polymerization is non-catalytic, and so there is no specificity or selection for certain enantiomers.

If you're asking the "biogenesis" question, then I think the answer is that we don't know the original selection, and it may just be chance. But once biochemistry began making and using them, of course they were all the same. But frankly "why not D-amino acids" makes about as much sense as "why not 22 amino acids, or 23, or 24, or 25?" Because that's what happened.

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    $\begingroup$ Thanks for the answer @KAM. However, i don't buy your criticism of the biogenesis aspect to the question! Sure,it may have been that "by chance" L-amino acids got selected, but the fact that all life now only uses L-aminos is intriguing. Given an equal probability of L and D aminos, this suggests that life only arose one from L-aminos, or that L-amino life managed to outcompete and eradicate D-amino life. Either possibility sends us in interesting directions. $\endgroup$
    – Poshpaws
    Jan 11 '12 at 17:51
  • $\begingroup$ But, you still get an upvote ;-) $\endgroup$
    – Poshpaws
    Jan 11 '12 at 17:52

As far as I know, it is unknown why we only see left-handed and not right–handed amino acids. A recent article speculates that the weak force could be responsible for a tiny asymmetry in energy levels between the stereo-isomers. However, if the effect is tiny, its hard to see why it should have biological implications. In 2004, Tamura and Schimmel showed that RNA has a preference for L-amino acids, whereas mirrored RNA has a preference for D-amino acids. They conclude:

These results suggest the possibility that the selection of L-amino acids for proteins was determined by the stereochemistry of RNA.

So the next question is: Why do we observe only one kind of RNA? It could just be by chance, that a polymer of one RNA configuration became self-replicating.

  • $\begingroup$ The chirality of RNA enforces the chirality of amino acids, neat. I wonder if there is mirror RNA out there, because the penalty for being mirrored is lower? (is it lower?) $\endgroup$
    – Resonating
    Nov 20 '13 at 17:29

The normal results of an attempt to assemble proteins with mixed chiral amino acids is a protein that fails to fold.

The general assumption due to this result is a choice has to be made very early on to use all right-handed or all left-handed amino acids. There doesn't seem to be any particular reason to choose one way over the other except for prevalence.


Using only 1 chirality for the ecosystem simplifies protein formation and folding frameworks. In theory, you could have a codon system with 40 distinct values (and 24 redundant values): glycine, stop codon, and left/right variations of each other amino acid. However, the proteins and nano-"machinery" required to support this would be crazy complex. It's much more efficient to build around 1 chirality and stick with it.

Alternately, you could have enzymes specifically designed to flip proteins of the "wrong" chirality depending on species.

With that in mind, an ecosystem with different species having different amino acid chirality would be digestive chaos. If you eat a dextro-protein steak, your digestion will break the proteins into... dextro amino acids. Best outcome: they fail to absorb and get flushed down the toilet. Worst outcome: they get absorbed and your cells use them to make proteins - causing severe folding errors, nonfunctional proteins, and a host of untraceable health problems that would likely get misdiagnosed as a spirochaete infection (wide-ranging health problems that aren't limited to a specific region and have no discernible pattern).

  • $\begingroup$ Addendum: your immune cells might identify nonfunctional/malformed proteins produced from consuming dextro-amino acids as dangerous foreign matter/invaders, causing widespread allergies $\endgroup$ Aug 8 '17 at 22:06

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