A 3₁₀ helix is a type of

secondary structure Protein secondary structure is the local spatial conformation of the polypeptide backbone excluding the side chains. The two most common Protein structure#Secondary structure, secondary structural elements are alpha helix, alpha helices and beta ...

found in

protein Proteins are large biomolecules and macromolecules that comprise one or more long chains of amino acid residue (biochemistry), residues. Proteins perform a vast array of functions within organisms, including Enzyme catalysis, catalysing metab ...

s and polypeptides. Of the numerous protein secondary structures present, the 3₁₀-helix is the fourth most common type observed; following α-helices, β-sheets and reverse turns. 3₁₀-helices constitute nearly 10–15% of all helices in protein secondary structures, and are typically observed as extensions of α-helices found at either their N- or C- termini. Because of the α-helices tendency to consistently fold and unfold, it has been proposed that the 3₁₀-helix serves as an intermediary conformation of sorts, and provides insight into the initiation of α-helix folding.

Discovery

Max Perutz Max Ferdinand Perutz (19 May 1914 – 6 February 2002) was an Austrian-born British molecular biologist, who shared the 1962 Nobel Prize for Chemistry with John Kendrew, for their studies of the structures of haemoglobin and myoglobin. He went ...

, the head of the Medical Research Council

Laboratory of Molecular Biology The Medical Research Council (MRC) Laboratory of Molecular Biology (LMB) is a research institute in Cambridge, England, involved in the revolution in molecular biology which occurred in the 1950–60s. Since then it has remained a major medical r ...

at the

University of Cambridge The University of Cambridge is a Public university, public collegiate university, collegiate research university in Cambridge, England. Founded in 1209, the University of Cambridge is the List of oldest universities in continuous operation, wo ...

, wrote the first paper documenting the elusive 3₁₀-helix. Together with

Lawrence Bragg Sir William Lawrence Bragg (31 March 1890 – 1 July 1971) was an Australian-born British physicist who shared the 1915 Nobel Prize in Physics with his father William Henry Bragg "for their services in the analysis of crystal structure by m ...

and John Kendrew, Perutz published an exploration of polypeptide chain configurations in 1950, based on cues from noncrystalline diffraction data as well as from small molecule crystal structures such as crystalline found in hair. Their proposals included what is now known as the 3₁₀ helix, but did not include the two most common structural motifs now known to occur. The following year,

Linus Pauling Linus Carl Pauling ( ; February 28, 1901August 19, 1994) was an American chemist and peace activist. He published more than 1,200 papers and books, of which about 850 dealt with scientific topics. ''New Scientist'' called him one of the 20 gre ...

predicted both of those motifs, the

alpha helix An alpha helix (or α-helix) is a sequence of amino acids in a protein that are twisted into a coil (a helix). The alpha helix is the most common structural arrangement in the Protein secondary structure, secondary structure of proteins. It is al ...

and the

beta sheet The beta sheet (β-sheet, also β-pleated sheet) is a common motif of the regular protein secondary structure. Beta sheets consist of beta strands (β-strands) connected laterally by at least two or three backbone hydrogen bonds, forming a gene ...

, in work which is now compared in significance to

Francis Crick Francis Harry Compton Crick (8 June 1916 – 28 July 2004) was an English molecular biologist, biophysicist, and neuroscientist. He, James Watson, Rosalind Franklin, and Maurice Wilkins played crucial roles in deciphering the Nucleic acid doub ...

and James D. Watson's publication of the

DNA double helix In molecular biology, the term double helix refers to the structure formed by double-stranded molecules of nucleic acids such as DNA. The double helical structure of a nucleic acid complex arises as a consequence of its secondary structure, a ...

. Pauling was highly critical of the helical structures proposed by Bragg, Kendrew, and Perutz, taking a triumphal tone in declaring them all implausible. Perutz describes in his book ''I wish I'd made you angry sooner'' the experience of reading Pauling's paper one Saturday morning: Later that day, an idea for an experiment to confirm Pauling's model occurred to Perutz, and he rushed to the lab to carry it out. Within a few hours, he had the evidence to confirm the alpha helix, which he showed to Bragg first thing on Monday. Perutz' confirmation of the alpha helix structure was published in ''

Nature Nature is an inherent character or constitution, particularly of the Ecosphere (planetary), ecosphere or the universe as a whole. In this general sense nature refers to the Scientific law, laws, elements and phenomenon, phenomena of the physic ...

'' shortly afterwards. The principles applied in the 1950 paper to theoretical polypeptide structures, true of the 3₁₀ helix, included: * The chains are held together by

hydrogen bonding In chemistry, a hydrogen bond (H-bond) is a specific type of molecular interaction that exhibits partial covalent character and cannot be described as a purely electrostatic force. It occurs when a hydrogen (H) atom, Covalent bond, covalently b ...

between the hydrogen and oxygen atoms of different by nearby

amide In organic chemistry, an amide, also known as an organic amide or a carboxamide, is a chemical compound, compound with the general formula , where R, R', and R″ represent any group, typically organyl functional group, groups or hydrogen at ...

(peptide) links formed as the

amino acid Amino acids are organic compounds that contain both amino and carboxylic acid functional groups. Although over 500 amino acids exist in nature, by far the most important are the 22 α-amino acids incorporated into proteins. Only these 22 a ...

s condense to form the polypeptide chain. These form helical arrangements that cannot be uncoiled without breaking the hydrogen bonds. * Those structures in which all available NH and CO groups are hydrogen bonded are inherently more probable, because their free energy is presumably lower. The 3₁₀ helix was eventually confirmed by Kendrew in his 1958 structure of

myoglobin Myoglobin (symbol Mb or MB) is an iron- and oxygen-binding protein found in the cardiac and skeletal muscle, skeletal Muscle, muscle tissue of vertebrates in general and in almost all mammals. Myoglobin is distantly related to hemoglobin. Compar ...

, and was also found in Perutz' 1960 determination of the structure of

haemoglobin Hemoglobin (haemoglobin, Hb or Hgb) is a protein containing iron that facilitates the transportation of oxygen in red blood cells. Almost all vertebrates contain hemoglobin, with the sole exception of the fish family Channichthyidae. Hemoglobi ...

and in subsequent work on both its deoxygenated and oxygenated forms. The 3₁₀ helix is now known to be the third principal structure to occur in

globular protein In biochemistry, globular proteins or spheroproteins are spherical ("globe-like") proteins and are one of the common protein types (the others being fibrous, disordered and membrane proteins). Globular proteins are somewhat water-soluble (form ...

s, after the α-helix and β-sheet. They are almost always short sections, with nearly 96% containing four or fewer amino acid residues, appearing in places such as the "corners" where α-helices change direction in the myoglobin structure, for example. Longer sections, in the range of seven to eleven residues, have been observed in the voltage sensor segment of

voltage-gated potassium channel Voltage-gated potassium channels (VGKCs) are potassium channel, transmembrane channels specific for potassium and Voltage-gated ion channel, sensitive to voltage changes in the cell's membrane potential. During action potentials, they play a ...

s in the

transmembrane domain A transmembrane domain (TMD, TM domain) is a membrane-spanning protein domain. TMDs may consist of one or several alpha-helices or a transmembrane beta barrel. Because the interior of the lipid bilayer is hydrophobic, the amino acid residues in ...

of certain helical proteins.

Structure

The amino acids in a 3₁₀-helix are arranged in a right-handed helical structure. Each amino acid corresponds to a 120° turn in the helix (i.e., the helix has three residues per turn), and a translation of along the helical axis, and has 10 atoms in the ring formed by making the hydrogen bond. Most importantly, the N-H group of an amino acid forms a

hydrogen bond In chemistry, a hydrogen bond (H-bond) is a specific type of molecular interaction that exhibits partial covalent character and cannot be described as a purely electrostatic force. It occurs when a hydrogen (H) atom, Covalent bond, covalently b ...

with the C=O group of the amino acid ''three'' residues earlier; this repeated ''i'' + 3 → ''i'' hydrogen bonding defines a 3₁₀-helix. Similar structures include the

α-helix An alpha helix (or α-helix) is a sequence of amino acids in a protein that are twisted into a coil (a helix). The alpha helix is the most common structural arrangement in the Protein secondary structure, secondary structure of proteins. It is al ...

(''i'' + 4 → ''i'' hydrogen bonding) and the π-helix ''i'' + 5 → ''i'' hydrogen bonding. Residues in long 3₁₀-helices adopt (''φ'', ''ψ'') dihedral angles near (−49°, −26°). Many 3₁₀-helices in proteins are short, so deviate from these values. More generally, residues in long 3₁₀-helices adopt dihedral angles such that the ''ψ'' dihedral angle of one residue and the ''φ'' dihedral angle of the ''next'' residue sum to roughly −75°. For comparison, the sum of the dihedral angles for an α-helix is roughly −105°, whereas that for a π-helix is roughly −125°. The general formula for the rotation angle ''Ω'' per residue of any polypeptide helix with ''trans'' isomers is given by the equation: :

3 \cos \Omega = 1 - 4 \cos^ \left(\frac \right)

and since ''Ω'' = 120° for an ideal 3₁₀ helix, it follows that ''φ'' and ''ψ'' should be related by: :

\cos \left(\frac \right) = \frac,

consistent with the observed value of ''φ'' + ''ψ'' near −75°. The dihedral angles in the 3₁₀ helix, relative to those of the α helix, could be attributed to the short lengths of these helices – anywhere from 3 to 5 residues long, compared with the 10 to 12 residue lengths of their α-helix contemporaries. 3₁₀-helices often arise in transitions, leading to typically short residue lengths that result in deviations in their main-chain torsion angle distributions and thus irregularities. Their hydrogen bond networks are distorted when compared with α-helices, contributing to their instability, though the frequent appearance of the 3₁₀-helix in natural proteins demonstrate their importance in transitional structures.

Stability

Through research carried out by Mary Karpen, Pieter De Haseth and Kenneth Neet, factors in the partial stability in 3₁₀-helices were uncovered. The helices are most noticeably stabilized by an aspartate residue at the nonpolar ''N''-terminus that interacts with the amide group at the helical ''N''-cap. This electrostatic interaction stabilizes the peptide dipoles in a parallel orientation. Much like the contiguous helical hydrogen bonds that stabilize α-helices, high levels of aspartate are just as equally important in the survival of the 3₁₀-helix. High frequency of aspartate in both 3₁₀-helix and α-helices is indicative of its helix initiation, but at the same time suggests that it favors stabilization of the 3₁₀-helix by inhibiting the propagation of α-helices.

Discovery

Structure

Stability

See also

References

Other readings