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Alpha helix

August 25, 2023

An alpha helix (or α-helix) is a sequence of amino acids in a protein that are twisted into a coil (a helix).

Three-dimensional structure of an alpha helix in the protein crambin

The alpha helix is the most common structural arrangement in the secondary structure of proteins. It is also the most extreme type of local structure, and it is the local structure that is most easily predicted from a sequence of amino acids.

The alpha helix has a right hand-helix conformation in which every backbone N−H group hydrogen bonds to the backbone C=O group of the amino acid that is four residues earlier in the protein sequence.

Other names Edit

The alpha helix is also commonly called a:

  • Pauling–Corey–Branson α-helix (from the names of three scientists who described its structure).
  • 3.613-helix because there are 3.6 amino acids in one ring, and there are an average of 13 residues per helical turn, with 13 atoms being involved in the ring formed by the hydrogen bond.


 Protein secondary structureBeta sheetAlpha helix
 
The image above contains clickable links
Interactive diagram of hydrogen bonds in protein secondary structure. Cartoon above, atoms below with nitrogen in blue, oxygen in red (PDB: 1AXC​​)


Discovery Edit

 
Side view of an α-helix of alanine residues in atomic detail. Two hydrogen bonds for the same peptide group are highlighted in magenta; the H to O distance is about 2 Å (0.20 nm). The protein chain runs upward here; that is, its N-terminus is at the bottom and its C-terminus at the top. Note that the sidechains (black stubs) angle slightly downward, toward the N-terminus, while the peptide oxygens (red) point up and the peptide NHs (blue with grey stubs) point down.
 
Top view of the same helix shown above. Four carbonyl groups are pointing upwards toward the viewer, spaced roughly 100° apart on the circle, corresponding to 3.6 amino-acid residues per turn of the helix.

In the early 1930s, William Astbury showed that there were drastic changes in the X-ray fiber diffraction of moist wool or hair fibers upon significant stretching. The data suggested that the unstretched fibers had a coiled molecular structure with a characteristic repeat of ≈5.1 ångströms (0.51 nanometres).

Astbury initially proposed a linked-chain structure for the fibers. He later joined other researchers (notably the American chemist Maurice Huggins) in proposing that:

  • the unstretched protein molecules formed a helix (which he called the α-form)
  • the stretching caused the helix to uncoil, forming an extended state (which he called the β-form).

Although incorrect in their details, Astbury's models of these forms were correct in essence and correspond to modern elements of secondary structure, the α-helix and the β-strand (Astbury's nomenclature was kept), which were developed by Linus Pauling, Robert Corey and Herman Branson in 1951 (see below); that paper showed both right- and left-handed helices, although in 1960 the crystal structure of myoglobin[1] showed that the right-handed form is the common one. Hans Neurath was the first to show that Astbury's models could not be correct in detail, because they involved clashes of atoms.[2] Neurath's paper and Astbury's data inspired H. S. Taylor,[3] Maurice Huggins[4] and Bragg and collaborators[5] to propose models of keratin that somewhat resemble the modern α-helix.

Two key developments in the modeling of the modern α-helix were: the correct bond geometry, thanks to the crystal structure determinations of amino acids and peptides and Pauling's prediction of planar peptide bonds; and his relinquishing of the assumption of an integral number of residues per turn of the helix. The pivotal moment came in the early spring of 1948, when Pauling caught a cold and went to bed. Being bored, he drew a polypeptide chain of roughly correct dimensions on a strip of paper and folded it into a helix, being careful to maintain the planar peptide bonds. After a few attempts, he produced a model with physically plausible hydrogen bonds. Pauling then worked with Corey and Branson to confirm his model before publication.[6] In 1954, Pauling was awarded his first Nobel Prize "for his research into the nature of the chemical bond and its application to the elucidation of the structure of complex substances"[7] (such as proteins), prominently including the structure of the α-helix.

Structure Edit

Geometry and hydrogen bonding Edit

The amino acids in an α-helix are arranged in a right-handed helical structure where each amino acid residue corresponds to a 100° turn in the helix (i.e., the helix has 3.6 residues per turn), and a translation of 1.5 Å (0.15 nm) along the helical axis. Dunitz[8] describes how Pauling's first article on the theme in fact shows a left-handed helix, the enantiomer of the true structure. Short pieces of left-handed helix sometimes occur with a large content of achiral glycine amino acids, but are unfavorable for the other normal, biological L-amino acids. The pitch of the alpha-helix (the vertical distance between consecutive turns of the helix) is 5.4 Å (0.54 nm), which is the product of 1.5 and 3.6. What is most important is that the N-H group of an amino acid forms a hydrogen bond with the C=O group of the amino acid four residues earlier; this repeated i + 4 → i hydrogen bonding is the most prominent characteristic of an α-helix. Official international nomenclature[9][10] specifies two ways of defining α-helices, rule 6.2 in terms of repeating φ, ψ torsion angles (see below) and rule 6.3 in terms of the combined pattern of pitch and hydrogen bonding. The α-helices can be identified in protein structure using several computational methods, one of which is DSSP (Define Secondary Structure of Protein).[11]

 
Contrast of helix end views between α (offset squarish) vs 310 (triangular)

Similar structures include the 310 helix (i + 3 → i hydrogen bonding) and the π-helix (i + 5 → i hydrogen bonding). The α-helix can be described as a 3.613 helix, since the i + 4 spacing adds three more atoms to the H-bonded loop compared to the tighter 310 helix, and on average, 3.6 amino acids are involved in one ring of α-helix. The subscripts refer to the number of atoms (including the hydrogen) in the closed loop formed by the hydrogen bond.[12]

 
Ramachandran plot (φψ plot), with data points for α-helical residues forming a dense diagonal cluster below and left of center, around the global energy minimum for backbone conformation.[13]

Residues in α-helices typically adopt backbone (φψ) dihedral angles around (−60°, −45°), as shown in the image at right. In more general terms, they adopt dihedral angles such that the ψ dihedral angle of one residue and the φ dihedral angle of the next residue sum to roughly −105°. As a consequence, α-helical dihedral angles, in general, fall on a diagonal stripe on the Ramachandran diagram (of slope −1), ranging from (−90°, −15°) to (−70°, −35°). For comparison, the sum of the dihedral angles for a 310 helix is roughly −75°, whereas that for the π-helix is roughly −130°. The general formula for the rotation angle Ω per residue of any polypeptide helix with trans isomers is given by the equation[14][15]

3 cos Ω = 1 − 4 cos2 φ + ψ/2

The α-helix is tightly packed; there is almost no free space within the helix. The amino-acid side-chains are on the outside of the helix, and point roughly "downward" (i.e., toward the N-terminus), like the branches of an evergreen tree (Christmas tree effect). This directionality is sometimes used in preliminary, low-resolution electron-density maps to determine the direction of the protein backbone.[16]

Stability Edit

See also: Stapled peptide

Helices observed in proteins can range from four to over forty residues long, but a typical helix contains about ten amino acids (about three turns). In general, short polypeptides do not exhibit much α-helical structure in solution, since the entropic cost associated with the folding of the polypeptide chain is not compensated for by a sufficient amount of stabilizing interactions. In general, the backbone hydrogen bonds of α-helices are considered slightly weaker than those found in β-sheets, and are readily attacked by the ambient water molecules. However, in more hydrophobic environments such as the plasma membrane, or in the presence of co-solvents such as trifluoroethanol (TFE), or isolated from solvent in the gas phase,[17] oligopeptides readily adopt stable α-helical structure. Furthermore, crosslinks can be incorporated into peptides to conformationally stabilize helical folds. Crosslinks stabilize the helical state by entropically destabilizing the unfolded state and by removing enthalpically stabilized "decoy" folds that compete with the fully helical state.[18] It has been shown that α-helices are more stable, robust to mutations and designable than β-strands in natural proteins,[19] and also in artificially designed proteins.[20]

 
An α-helix in ultrahigh-resolution electron density contours, with oxygen atoms in red, nitrogen atoms in blue, and hydrogen bonds as green dotted lines (PDB file 2NRL, 17–32). The N-terminus is at the top, here.

Visualization Edit

The 3 most popular ways of visualizing the alpha-helical secondary structure of oligopeptide sequences are (1) a helical wheel,[21] (2) a wenxiang diagram,[22] and (3) a helical net.[23] Each of these can be visualized with various software packages and web servers. To generate a small number of diagrams, Heliquest[24] can be used for helical wheels, and NetWheels[25] can be used for helical wheels and helical nets. To programmatically generate a large number of diagrams, helixvis[26][27] can be used to draw helical wheels and wenxiang diagrams in the R and Python programming languages.

Experimental determination Edit

Since the α-helix is defined by its hydrogen bonds and backbone conformation, the most detailed experimental evidence for α-helical structure comes from atomic-resolution X-ray crystallography such as the example shown at right. It is clear that all the backbone carbonyl oxygens point downward (toward the C-terminus) but splay out slightly, and the H-bonds are approximately parallel to the helix axis. Protein structures from NMR spectroscopy also show helices well, with characteristic observations of nuclear Overhauser effect (NOE) couplings between atoms on adjacent helical turns. In some cases, the individual hydrogen bonds can be observed directly as a small scalar coupling in NMR.

There are several lower-resolution methods for assigning general helical structure. The NMR chemical shifts (in particular of the Cα, Cβ and C′) and residual dipolar couplings are often characteristic of helices. The far-UV (170–250 nm) circular dichroism spectrum of helices is also idiosyncratic, exhibiting a pronounced double minimum at around 208 and 222 nm. Infrared spectroscopy is rarely used, since the α-helical spectrum resembles that of a random coil (although these might be discerned by, e.g., hydrogen-deuterium exchange). Finally, cryo electron microscopy is now capable of discerning individual α-helices within a protein, although their assignment to residues is still an active area of research.

Long homopolymers of amino acids often form helices if soluble. Such long, isolated helices can also be detected by other methods, such as dielectric relaxation, flow birefringence, and measurements of the diffusion constant. In stricter terms, these methods detect only the characteristic prolate (long cigar-like) hydrodynamic shape of a helix, or its large dipole moment.

Amino-acid propensities Edit

Different amino-acid sequences have different propensities for forming α-helical structure. Methionine, alanine, leucine, glutamate, and lysine uncharged ("MALEK" in the amino-acid 1-letter codes) all have especially high helix-forming propensities, whereas proline and glycine have poor helix-forming propensities.[28] Proline either breaks or kinks a helix, both because it cannot donate an amide hydrogen bond (having no amide hydrogen), and also because its sidechain interferes sterically with the backbone of the preceding turn – inside a helix, this forces a bend of about 30° in the helix's axis.[12] However, proline is often seen as the first residue of a helix, it is presumed due to its structural rigidity. At the other extreme, glycine also tends to disrupt helices because its high conformational flexibility makes it entropically expensive to adopt the relatively constrained α-helical structure.

Table of standard amino acid alpha-helical propensities Edit

Estimated differences in free energy change, Δ(ΔG), estimated in kcal/mol per residue in an α-helical configuration, relative to alanine arbitrarily set as zero. Higher numbers (more positive free energy changes) are less favoured. Significant deviations from these average numbers are possible, depending on the identities of the neighbouring residues.

Differences in free energy change per residue[29]
Amino acid 3-
letter 		1-
letter 		Helical penalty
kcal/mol kJ/mol
Alanine Ala A 0.00 0.00
Arginine Arg R 0.21 0.88
Asparagine Asn N 0.65 2.72
Aspartic acid Asp D 0.69 2.89
Cysteine Cys C 0.68 2.85
Glutamic acid Glu E 0.40 1.67
Glutamine Gln Q 0.39 1.63
Glycine Gly G 1.00 4.18
Histidine His H 0.61 2.55
Isoleucine Ile I 0.41 1.72
Leucine Leu L 0.21 0.88
Lysine Lys K 0.26 1.09
Methionine Met M 0.24 1.00
Phenylalanine Phe F 0.54 2.26
Proline Pro P 3.16 13.22
Serine Ser S 0.50 2.09
Threonine Thr T 0.66 2.76
Tryptophan Trp W 0.49 2.05
Tyrosine Tyr Y 0.53 2.22
Valine Val V 0.61 2.55

Dipole moment Edit

A helix has an overall dipole moment due to the aggregate effect of the individual microdipoles from the carbonyl groups of the peptide bond pointing along the helix axis.[30] The effects of this macrodipole are a matter of some controversy. α-helices often occur with the N-terminal end bound by a negatively charged group, sometimes an amino acid side chain such as glutamate or aspartate, or sometimes a phosphate ion. Some regard the helix macrodipole as interacting electrostatically with such groups. Others feel that this is misleading and it is more realistic to say that the hydrogen bond potential of the free NH groups at the N-terminus of an α-helix can be satisfied by hydrogen bonding; this can also be regarded as set of interactions between local microdipoles such as C=O···H−N.[31][32]

Coiled coils Edit

Coiled-coil α helices are highly stable forms in which two or more helices wrap around each other in a "supercoil" structure. Coiled coils contain a highly characteristic sequence motif known as a heptad repeat, in which the motif repeats itself every seven residues along the sequence (amino acid residues, not DNA base-pairs). The first and especially the fourth residues (known as the a and d positions) are almost always hydrophobic; the fourth residue is typically leucine – this gives rise to the name of the structural motif called a leucine zipper, which is a type of coiled-coil. These hydrophobic residues pack together in the interior of the helix bundle. In general, the fifth and seventh residues (the e and g positions) have opposing charges and form a salt bridge stabilized by electrostatic interactions. Fibrous proteins such as keratin or the "stalks" of myosin or kinesin often adopt coiled-coil structures, as do several dimerizing proteins. A pair of coiled-coils – a four-helix bundle – is a very common structural motif in proteins. For example, it occurs in human growth hormone and several varieties of cytochrome. The Rop protein, which promotes plasmid replication in bacteria, is an interesting case in which a single polypeptide forms a coiled-coil and two monomers assemble to form a four-helix bundle.

Facial arrangements Edit

The amino acids that make up a particular helix can be plotted on a helical wheel, a representation that illustrates the orientations of the constituent amino acids (see the article for leucine zipper for such a diagram). Often in globular proteins, as well as in specialized structures such as coiled-coils and leucine zippers, an α-helix will exhibit two "faces" – one containing predominantly hydrophobic amino acids oriented toward the interior of the protein, in the hydrophobic core, and one containing predominantly polar amino acids oriented toward the solvent-exposed surface of the protein.

Changes in binding orientation also occur for facially-organized oligopeptides. This pattern is especially common in antimicrobial peptides, and many models have been devised to describe how this relates to their function. Common to many of them is that the hydrophobic face of the antimicrobial peptide forms pores in the plasma membrane after associating with the fatty chains at the membrane core.[33][34]

Larger-scale assemblies Edit

 
The Hemoglobin molecule has four heme-binding subunits, each made largely of α-helices.

Myoglobin and hemoglobin, the first two proteins whose structures were solved by X-ray crystallography, have very similar folds made up of about 70% α-helix, with the rest being non-repetitive regions, or "loops" that connect the helices. In classifying proteins by their dominant fold, the database maintains a large category specifically for all-α proteins.

Hemoglobin then has an even larger-scale quaternary structure, in which the functional oxygen-binding molecule is made up of four subunits.

Functional roles Edit

 
Leucine zipper coiled-coil helices & DNA-binding helices: transcription factor Max (PDB file 1HLO)
 
Bovine rhodopsin (PDB file 1GZM), with a bundle of seven helices crossing the membrane (membrane surfaces marked by horizontal lines)

DNA binding Edit

α-Helices have particular significance in DNA binding motifs, including helix-turn-helix motifs, leucine zipper motifs and zinc finger motifs. This is because of the convenient structural fact that the diameter of an α-helix is about 12 Å (1.2 nm) including an average set of sidechains, about the same as the width of the major groove in B-form DNA, and also because coiled-coil (or leucine zipper) dimers of helices can readily position a pair of interaction surfaces to contact the sort of symmetrical repeat common in double-helical DNA.[35] An example of both aspects is the transcription factor Max (see image at left), which uses a helical coiled coil to dimerize, positioning another pair of helices for interaction in two successive turns of the DNA major groove.

Membrane spanning Edit

α-Helices are also the most common protein structure element that crosses biological membranes (transmembrane protein),[36] it is presumed because the helical structure can satisfy all backbone hydrogen-bonds internally, leaving no polar groups exposed to the membrane if the sidechains are hydrophobic. Proteins are sometimes anchored by a single membrane-spanning helix, sometimes by a pair, and sometimes by a helix bundle, most classically consisting of seven helices arranged up-and-down in a ring such as for rhodopsins (see image at right) and other G protein–coupled receptors (GPCRs). The structural stability between pairs of α-Helical transmembrane domains rely on conserved membrane interhelical packing motifs, for example, the Glycine-xxx-Glycine (or small-xxx-small) motif.[37]

Mechanical properties Edit

α-Helices under axial tensile deformation, a characteristic loading condition that appears in many alpha-helix-rich filaments and tissues, results in a characteristic three-phase behavior of stiff-soft-stiff tangent modulus.[38] Phase I corresponds to the small-deformation regime during which the helix is stretched homogeneously, followed by phase II, in which alpha-helical turns break mediated by the rupture of groups of H-bonds. Phase III is typically associated with large-deformation covalent bond stretching.

Dynamical features Edit

Alpha-helices in proteins may have low-frequency accordion-like motion as observed by the Raman spectroscopy[39] and analyzed via the quasi-continuum model.[40][41] Helices not stabilized by tertiary interactions show dynamic behavior, which can be mainly attributed to helix fraying from the ends.[42]

Helix–coil transition Edit

See also: Helix–coil transition model

Homopolymers of amino acids (such as polylysine) can adopt α-helical structure at low temperature that is "melted out" at high temperatures. This helix–coil transition was once thought to be analogous to protein denaturation. The statistical mechanics of this transition can be modeled using an elegant transfer matrix method, characterized by two parameters: the propensity to initiate a helix and the propensity to extend a helix.

In art Edit

 
Julian Voss-Andreae's Alpha Helix for Linus Pauling (2004), powder coated steel, height 10 ft (3 m). The sculpture stands in front of Pauling's childhood home on 3945 SE Hawthorne Boulevard in Portland, Oregon, USA.

At least five artists have made explicit reference to the α-helix in their work: Julie Newdoll in painting and Julian Voss-Andreae, Bathsheba Grossman, Byron Rubin, and Mike Tyka in sculpture.

San Francisco area artist Julie Newdoll,[43] who holds a degree in microbiology with a minor in art, has specialized in paintings inspired by microscopic images and molecules since 1990. Her painting "Rise of the Alpha Helix" (2003) features human figures arranged in an α helical arrangement. According to the artist, "the flowers reflect the various types of sidechains that each amino acid holds out to the world".[43] This same metaphor is also echoed from the scientist's side: "β sheets do not show a stiff repetitious regularity but flow in graceful, twisting curves, and even the α-helix is regular more in the manner of a flower stem, whose branching nodes show the influence of environment, developmental history, and the evolution of each part to match its own idiosyncratic function."[12]

Julian Voss-Andreae is a German-born sculptor with degrees in experimental physics and sculpture. Since 2001 Voss-Andreae creates "protein sculptures"[44] based on protein structure with the α-helix being one of his preferred objects. Voss-Andreae has made α-helix sculptures from diverse materials including bamboo and whole trees. A monument Voss-Andreae created in 2004 to celebrate the memory of Linus Pauling, the discoverer of the α-helix, is fashioned from a large steel beam rearranged in the structure of the α-helix. The 10-foot-tall (3 m), bright-red sculpture stands in front of Pauling's childhood home in Portland, Oregon.

Ribbon diagrams of α-helices are a prominent element in the laser-etched crystal sculptures of protein structures created by artist Bathsheba Grossman, such as those of insulin, hemoglobin, and DNA polymerase.[45] Byron Rubin is a former protein crystallographer now professional sculptor in metal of proteins, nucleic acids, and drug molecules – many of which featuring α-helices, such as subtilisin, human growth hormone, and phospholipase A2.[46]

Mike Tyka is a computational biochemist at the University of Washington working with David Baker. Tyka has been making sculptures of protein molecules since 2010 from copper and steel, including ubiquitin and a potassium channel tetramer.[47]

See also Edit

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  37. ^ Nash A, Notman R, Dixon AM (2015). "De novo design of transmembrane helix–helix interactions and measurement of stability in a biological membrane". Biochimica et Biophysica Acta (BBA) - Biomembranes. 1848 (5): 1248–57. doi:10.1016/j.bbamem.2015.02.020. PMID 25732028.
  38. ^ Ackbarow T, Chen X, Keten S, Buehler MJ (October 2007). "Hierarchies, multiple energy barriers, and robustness govern the fracture mechanics of alpha-helical and beta-sheet protein domains". Proceedings of the National Academy of Sciences of the United States of America. 104 (42): 16410–5. Bibcode:2007PNAS..10416410A. doi:10.1073/pnas.0705759104. PMC 2034213. PMID 17925444.
  39. ^ Painter PC, Mosher LE, Rhoads C (July 1982). "Low-frequency modes in the Raman spectra of proteins". Biopolymers. 21 (7): 1469–72. doi:10.1002/bip.360210715. PMID 7115900.
  40. ^ Chou KC (December 1983). "Identification of low-frequency modes in protein molecules". The Biochemical Journal. 215 (3): 465–9. doi:10.1042/bj2150465. PMC 1152424. PMID 6362659.
  41. ^ Chou KC (May 1984). "Biological functions of low-frequency vibrations (phonons). III. Helical structures and microenvironment". Biophysical Journal. 45 (5): 881–9. Bibcode:1984BpJ....45..881C. doi:10.1016/S0006-3495(84)84234-4. PMC 1434967. PMID 6428481.
  42. ^ Fierz B, Reiner A, Kiefhaber T (January 2009). "Local conformational dynamics in alpha-helices measured by fast triplet transfer". Proceedings of the National Academy of Sciences of the United States of America. 106 (4): 1057–62. Bibcode:2009PNAS..106.1057F. doi:10.1073/pnas.0808581106. PMC 2633579. PMID 19131517.
  43. ^ a b "Julie Newdoll Scientifically Inspired Art, Music, Board Games". www.brushwithscience.com. Retrieved 2016-04-06.
  44. ^ Voss-Andreae J (2005). "Protein Sculptures: Life's Building Blocks Inspire Art". Leonardo. 38: 41–45. doi:10.1162/leon.2005.38.1.41. S2CID 57558522.
  45. ^ Grossman, Bathsheba. "About the Artist". Bathsheba Sculpture. Retrieved 2016-04-06.
  46. ^ "About". molecularsculpture.com. Retrieved 2016-04-06.
  47. ^ Tyka, Mike. "About". www.miketyka.com. Retrieved 2016-04-06.

Further reading Edit

  • Tooze J, Brändén C (1999). Introduction to protein structure. New York: Garland Pub. ISBN 0-8153-2304-2..
  • Eisenberg D (September 2003). "The discovery of the alpha-helix and beta-sheet, the principal structural features of proteins". Proceedings of the National Academy of Sciences of the United States of America. 100 (20): 11207–10. Bibcode:2003PNAS..10011207E. doi:10.1073/pnas.2034522100. PMC 208735. PMID 12966187.
  • Astbury WT, Woods HJ (1931). "The Molecular Weights of Proteins". Nature. 127 (3209): 663–665. Bibcode:1931Natur.127..663A. doi:10.1038/127663b0. S2CID 4133226.
  • Astbury WT, Street A (1931). "X-ray studies of the structures of hair, wool and related fibres. I. General". Philosophical Transactions of the Royal Society of London Series A. 230: 75–101. Bibcode:1932RSPTA.230...75A. doi:10.1098/rsta.1932.0003.
  • Astbury WT (1933). "Some Problems in the X-ray Analysis of the Structure of Animal Hairs and Other Protein Fibers". Trans. Faraday Soc. 29 (140): 193–211. doi:10.1039/tf9332900193.
  • Astbury WT, Woods HJ (1934). "X-ray studies of the structures of hair, wool and related fibres. II. The molecular structure and elastic properties of hair keratin". Philosophical Transactions of the Royal Society of London Series A. 232 (707–720): 333–394. Bibcode:1934RSPTA.232..333A. doi:10.1098/rsta.1934.0010.
  • Astbury WT, Sisson WA (1935). "X-ray studies of the structures of hair, wool and related fibres. III. The configuration of the keratin molecule and its orientation in the biological cell". Proceedings of the Royal Society of London, Series A. 150 (871): 533–551. Bibcode:1935RSPSA.150..533A. doi:10.1098/rspa.1935.0121.
  • Sugeta H, Miyazawa T (1967). "General Method for Calculating Helical Parameters of Polymer Chains from Bond Lengths, Bond Angles, and Internal-Rotation Angles". Biopolymers. 5 (7): 673–679. doi:10.1002/bip.1967.360050708. S2CID 97785907.
  • Wada A (1976). "The alpha-helix as an electric macro-dipole". Advances in Biophysics: 1–63. PMID 797240.
  • Chothia C, Levitt M, Richardson D (October 1977). "Structure of proteins: packing of alpha-helices and pleated sheets". Proceedings of the National Academy of Sciences of the United States of America. 74 (10): 4130–4. Bibcode:1977PNAS...74.4130C. doi:10.1073/pnas.74.10.4130. PMC 431889. PMID 270659.
  • Chothia C, Levitt M, Richardson D (January 1981). "Helix to helix packing in proteins". Journal of Molecular Biology. 145 (1): 215–50. doi:10.1016/0022-2836(81)90341-7. PMID 7265198.
  • Hol WG (1985). "The role of the alpha-helix dipole in protein function and structure". Progress in Biophysics and Molecular Biology. 45 (3): 149–95. doi:10.1016/0079-6107(85)90001-X. PMID 3892583.
  • Barlow DJ, Thornton JM (June 1988). "Helix geometry in proteins". Journal of Molecular Biology. 201 (3): 601–19. doi:10.1016/0022-2836(88)90641-9. PMID 3418712.
  • Murzin AG, Finkelstein AV (December 1988). "General architecture of the alpha-helical globule". Journal of Molecular Biology. 204 (3): 749–69. doi:10.1016/0022-2836(88)90366-X. PMID 3225849.

External links Edit

  • NetSurfP ver. 1.1 – Protein Surface Accessibility and Secondary Structure Predictions
  • α-helix rotational angle calculator
  • Artist Julie Newdoll's website
  • Artist Julian Voss-Andreae's website

August 25, 2023
alpha, helix, alpha, helix, helix, sequence, amino, acids, protein, that, twisted, into, coil, helix, three, dimensional, structure, alpha, helix, protein, crambinthe, alpha, helix, most, common, structural, arrangement, secondary, structure, proteins, also, m. An alpha helix or a helix is a sequence of amino acids in a protein that are twisted into a coil a helix Three dimensional structure of an alpha helix in the protein crambinThe alpha helix is the most common structural arrangement in the secondary structure of proteins It is also the most extreme type of local structure and it is the local structure that is most easily predicted from a sequence of amino acids The alpha helix has a right hand helix conformation in which every backbone N H group hydrogen bonds to the backbone C O group of the amino acid that is four residues earlier in the protein sequence Contents 1 Other names 2 Discovery 3 Structure 3 1 Geometry and hydrogen bonding 3 2 Stability 3 3 Visualization 4 Experimental determination 5 Amino acid propensities 5 1 Table of standard amino acid alpha helical propensities 6 Dipole moment 7 Coiled coils 8 Facial arrangements 9 Larger scale assemblies 10 Functional roles 10 1 DNA binding 10 2 Membrane spanning 10 3 Mechanical properties 11 Dynamical features 12 Helix coil transition 13 In art 14 See also 15 References 16 Further reading 17 External linksOther names EditThe alpha helix is also commonly called a Pauling Corey Branson a helix from the names of three scientists who described its structure 3 613 helix because there are 3 6 amino acids in one ring and there are an average of 13 residues per helical turn with 13 atoms being involved in the ring formed by the hydrogen bond The image above contains clickable links Interactive diagram of hydrogen bonds in protein secondary structure Cartoon above atoms below with nitrogen in blue oxygen in red PDB 1AXC Discovery Edit Side view of an a helix of alanine residues in atomic detail Two hydrogen bonds for the same peptide group are highlighted in magenta the H to O distance is about 2 A 0 20 nm The protein chain runs upward here that is its N terminus is at the bottom and its C terminus at the top Note that the sidechains black stubs angle slightly downward toward the N terminus while the peptide oxygens red point up and the peptide NHs blue with grey stubs point down Top view of the same helix shown above Four carbonyl groups are pointing upwards toward the viewer spaced roughly 100 apart on the circle corresponding to 3 6 amino acid residues per turn of the helix In the early 1930s William Astbury showed that there were drastic changes in the X ray fiber diffraction of moist wool or hair fibers upon significant stretching The data suggested that the unstretched fibers had a coiled molecular structure with a characteristic repeat of 5 1 angstroms 0 51 nanometres Astbury initially proposed a linked chain structure for the fibers He later joined other researchers notably the American chemist Maurice Huggins in proposing that the unstretched protein molecules formed a helix which he called the a form the stretching caused the helix to uncoil forming an extended state which he called the b form Although incorrect in their details Astbury s models of these forms were correct in essence and correspond to modern elements of secondary structure the a helix and the b strand Astbury s nomenclature was kept which were developed by Linus Pauling Robert Corey and Herman Branson in 1951 see below that paper showed both right and left handed helices although in 1960 the crystal structure of myoglobin 1 showed that the right handed form is the common one Hans Neurath was the first to show that Astbury s models could not be correct in detail because they involved clashes of atoms 2 Neurath s paper and Astbury s data inspired H S Taylor 3 Maurice Huggins 4 and Bragg and collaborators 5 to propose models of keratin that somewhat resemble the modern a helix Two key developments in the modeling of the modern a helix were the correct bond geometry thanks to the crystal structure determinations of amino acids and peptides and Pauling s prediction of planar peptide bonds and his relinquishing of the assumption of an integral number of residues per turn of the helix The pivotal moment came in the early spring of 1948 when Pauling caught a cold and went to bed Being bored he drew a polypeptide chain of roughly correct dimensions on a strip of paper and folded it into a helix being careful to maintain the planar peptide bonds After a few attempts he produced a model with physically plausible hydrogen bonds Pauling then worked with Corey and Branson to confirm his model before publication 6 In 1954 Pauling was awarded his first Nobel Prize for his research into the nature of the chemical bond and its application to the elucidation of the structure of complex substances 7 such as proteins prominently including the structure of the a helix Structure EditGeometry and hydrogen bonding Edit The amino acids in an a helix are arranged in a right handed helical structure where each amino acid residue corresponds to a 100 turn in the helix i e the helix has 3 6 residues per turn and a translation of 1 5 A 0 15 nm along the helical axis Dunitz 8 describes how Pauling s first article on the theme in fact shows a left handed helix the enantiomer of the true structure Short pieces of left handed helix sometimes occur with a large content of achiral glycine amino acids but are unfavorable for the other normal biological L amino acids The pitch of the alpha helix the vertical distance between consecutive turns of the helix is 5 4 A 0 54 nm which is the product of 1 5 and 3 6 What is most important is that the N H group of an amino acid forms a hydrogen bond with the C O group of the amino acid four residues earlier this repeated i 4 i hydrogen bonding is the most prominent characteristic of an a helix Official international nomenclature 9 10 specifies two ways of defining a helices rule 6 2 in terms of repeating f ps torsion angles see below and rule 6 3 in terms of the combined pattern of pitch and hydrogen bonding The a helices can be identified in protein structure using several computational methods one of which is DSSP Define Secondary Structure of Protein 11 Contrast of helix end views between a offset squarish vs 310 triangular Similar structures include the 310 helix i 3 i hydrogen bonding and the p helix i 5 i hydrogen bonding The a helix can be described as a 3 613 helix since the i 4 spacing adds three more atoms to the H bonded loop compared to the tighter 310 helix and on average 3 6 amino acids are involved in one ring of a helix The subscripts refer to the number of atoms including the hydrogen in the closed loop formed by the hydrogen bond 12 Ramachandran plot f ps plot with data points for a helical residues forming a dense diagonal cluster below and left of center around the global energy minimum for backbone conformation 13 Residues in a helices typically adopt backbone f ps dihedral angles around 60 45 as shown in the image at right In more general terms they adopt dihedral angles such that the ps dihedral angle of one residue and the f dihedral angle of the next residue sum to roughly 105 As a consequence a helical dihedral angles in general fall on a diagonal stripe on the Ramachandran diagram of slope 1 ranging from 90 15 to 70 35 For comparison the sum of the dihedral angles for a 310 helix is roughly 75 whereas that for the p helix is roughly 130 The general formula for the rotation angle W per residue of any polypeptide helix with trans isomers is given by the equation 14 15 3 cos W 1 4 cos2 f ps 2The a helix is tightly packed there is almost no free space within the helix The amino acid side chains are on the outside of the helix and point roughly downward i e toward the N terminus like the branches of an evergreen tree Christmas tree effect This directionality is sometimes used in preliminary low resolution electron density maps to determine the direction of the protein backbone 16 Stability Edit See also Stapled peptide Helices observed in proteins can range from four to over forty residues long but a typical helix contains about ten amino acids about three turns In general short polypeptides do not exhibit much a helical structure in solution since the entropic cost associated with the folding of the polypeptide chain is not compensated for by a sufficient amount of stabilizing interactions In general the backbone hydrogen bonds of a helices are considered slightly weaker than those found in b sheets and are readily attacked by the ambient water molecules However in more hydrophobic environments such as the plasma membrane or in the presence of co solvents such as trifluoroethanol TFE or isolated from solvent in the gas phase 17 oligopeptides readily adopt stable a helical structure Furthermore crosslinks can be incorporated into peptides to conformationally stabilize helical folds Crosslinks stabilize the helical state by entropically destabilizing the unfolded state and by removing enthalpically stabilized decoy folds that compete with the fully helical state 18 It has been shown that a helices are more stable robust to mutations and designable than b strands in natural proteins 19 and also in artificially designed proteins 20 An a helix in ultrahigh resolution electron density contours with oxygen atoms in red nitrogen atoms in blue and hydrogen bonds as green dotted lines PDB file 2NRL 17 32 The N terminus is at the top here Visualization Edit The 3 most popular ways of visualizing the alpha helical secondary structure of oligopeptide sequences are 1 a helical wheel 21 2 a wenxiang diagram 22 and 3 a helical net 23 Each of these can be visualized with various software packages and web servers To generate a small number of diagrams Heliquest 24 can be used for helical wheels and NetWheels 25 can be used for helical wheels and helical nets To programmatically generate a large number of diagrams helixvis 26 27 can be used to draw helical wheels and wenxiang diagrams in the R and Python programming languages Experimental determination EditSince the a helix is defined by its hydrogen bonds and backbone conformation the most detailed experimental evidence for a helical structure comes from atomic resolution X ray crystallography such as the example shown at right It is clear that all the backbone carbonyl oxygens point downward toward the C terminus but splay out slightly and the H bonds are approximately parallel to the helix axis Protein structures from NMR spectroscopy also show helices well with characteristic observations of nuclear Overhauser effect NOE couplings between atoms on adjacent helical turns In some cases the individual hydrogen bonds can be observed directly as a small scalar coupling in NMR There are several lower resolution methods for assigning general helical structure The NMR chemical shifts in particular of the Ca Cb and C and residual dipolar couplings are often characteristic of helices The far UV 170 250 nm circular dichroism spectrum of helices is also idiosyncratic exhibiting a pronounced double minimum at around 208 and 222 nm Infrared spectroscopy is rarely used since the a helical spectrum resembles that of a random coil although these might be discerned by e g hydrogen deuterium exchange Finally cryo electron microscopy is now capable of discerning individual a helices within a protein although their assignment to residues is still an active area of research Long homopolymers of amino acids often form helices if soluble Such long isolated helices can also be detected by other methods such as dielectric relaxation flow birefringence and measurements of the diffusion constant In stricter terms these methods detect only the characteristic prolate long cigar like hydrodynamic shape of a helix or its large dipole moment Amino acid propensities EditDifferent amino acid sequences have different propensities for forming a helical structure Methionine alanine leucine glutamate and lysine uncharged MALEK in the amino acid 1 letter codes all have especially high helix forming propensities whereas proline and glycine have poor helix forming propensities 28 Proline either breaks or kinks a helix both because it cannot donate an amide hydrogen bond having no amide hydrogen and also because its sidechain interferes sterically with the backbone of the preceding turn inside a helix this forces a bend of about 30 in the helix s axis 12 However proline is often seen as the first residue of a helix it is presumed due to its structural rigidity At the other extreme glycine also tends to disrupt helices because its high conformational flexibility makes it entropically expensive to adopt the relatively constrained a helical structure Table of standard amino acid alpha helical propensities Edit Estimated differences in free energy change D DG estimated in kcal mol per residue in an a helical configuration relative to alanine arbitrarily set as zero Higher numbers more positive free energy changes are less favoured Significant deviations from these average numbers are possible depending on the identities of the neighbouring residues Differences in free energy change per residue 29 Amino acid 3 letter 1 letter Helical penaltykcal mol kJ molAlanine Ala A 0 00 0 00Arginine Arg R 0 21 0 88Asparagine Asn N 0 65 2 72Aspartic acid Asp D 0 69 2 89Cysteine Cys C 0 68 2 85Glutamic acid Glu E 0 40 1 67Glutamine Gln Q 0 39 1 63Glycine Gly G 1 00 4 18Histidine His H 0 61 2 55Isoleucine Ile I 0 41 1 72Leucine Leu L 0 21 0 88Lysine Lys K 0 26 1 09Methionine Met M 0 24 1 00Phenylalanine Phe F 0 54 2 26Proline Pro P 3 16 13 22Serine Ser S 0 50 2 09Threonine Thr T 0 66 2 76Tryptophan Trp W 0 49 2 05Tyrosine Tyr Y 0 53 2 22Valine Val V 0 61 2 55Dipole moment EditA helix has an overall dipole moment due to the aggregate effect of the individual microdipoles from the carbonyl groups of the peptide bond pointing along the helix axis 30 The effects of this macrodipole are a matter of some controversy a helices often occur with the N terminal end bound by a negatively charged group sometimes an amino acid side chain such as glutamate or aspartate or sometimes a phosphate ion Some regard the helix macrodipole as interacting electrostatically with such groups Others feel that this is misleading and it is more realistic to say that the hydrogen bond potential of the free NH groups at the N terminus of an a helix can be satisfied by hydrogen bonding this can also be regarded as set of interactions between local microdipoles such as C O H N 31 32 Coiled coils EditCoiled coil a helices are highly stable forms in which two or more helices wrap around each other in a supercoil structure Coiled coils contain a highly characteristic sequence motif known as a heptad repeat in which the motif repeats itself every seven residues along the sequence amino acid residues not DNA base pairs The first and especially the fourth residues known as the a and d positions are almost always hydrophobic the fourth residue is typically leucine this gives rise to the name of the structural motif called a leucine zipper which is a type of coiled coil These hydrophobic residues pack together in the interior of the helix bundle In general the fifth and seventh residues the e and g positions have opposing charges and form a salt bridge stabilized by electrostatic interactions Fibrous proteins such as keratin or the stalks of myosin or kinesin often adopt coiled coil structures as do several dimerizing proteins A pair of coiled coils a four helix bundle is a very common structural motif in proteins For example it occurs in human growth hormone and several varieties of cytochrome The Rop protein which promotes plasmid replication in bacteria is an interesting case in which a single polypeptide forms a coiled coil and two monomers assemble to form a four helix bundle Facial arrangements EditThe amino acids that make up a particular helix can be plotted on a helical wheel a representation that illustrates the orientations of the constituent amino acids see the article for leucine zipper for such a diagram Often in globular proteins as well as in specialized structures such as coiled coils and leucine zippers an a helix will exhibit two faces one containing predominantly hydrophobic amino acids oriented toward the interior of the protein in the hydrophobic core and one containing predominantly polar amino acids oriented toward the solvent exposed surface of the protein Changes in binding orientation also occur for facially organized oligopeptides This pattern is especially common in antimicrobial peptides and many models have been devised to describe how this relates to their function Common to many of them is that the hydrophobic face of the antimicrobial peptide forms pores in the plasma membrane after associating with the fatty chains at the membrane core 33 34 Larger scale assemblies Edit The Hemoglobin molecule has four heme binding subunits each made largely of a helices Myoglobin and hemoglobin the first two proteins whose structures were solved by X ray crystallography have very similar folds made up of about 70 a helix with the rest being non repetitive regions or loops that connect the helices In classifying proteins by their dominant fold the Structural Classification of Proteins database maintains a large category specifically for all a proteins Hemoglobin then has an even larger scale quaternary structure in which the functional oxygen binding molecule is made up of four subunits Functional roles Edit Leucine zipper coiled coil helices amp DNA binding helices transcription factor Max PDB file 1HLO Bovine rhodopsin PDB file 1GZM with a bundle of seven helices crossing the membrane membrane surfaces marked by horizontal lines DNA binding Edit a Helices have particular significance in DNA binding motifs including helix turn helix motifs leucine zipper motifs and zinc finger motifs This is because of the convenient structural fact that the diameter of an a helix is about 12 A 1 2 nm including an average set of sidechains about the same as the width of the major groove in B form DNA and also because coiled coil or leucine zipper dimers of helices can readily position a pair of interaction surfaces to contact the sort of symmetrical repeat common in double helical DNA 35 An example of both aspects is the transcription factor Max see image at left which uses a helical coiled coil to dimerize positioning another pair of helices for interaction in two successive turns of the DNA major groove Membrane spanning Edit a Helices are also the most common protein structure element that crosses biological membranes transmembrane protein 36 it is presumed because the helical structure can satisfy all backbone hydrogen bonds internally leaving no polar groups exposed to the membrane if the sidechains are hydrophobic Proteins are sometimes anchored by a single membrane spanning helix sometimes by a pair and sometimes by a helix bundle most classically consisting of seven helices arranged up and down in a ring such as for rhodopsins see image at right and other G protein coupled receptors GPCRs The structural stability between pairs of a Helical transmembrane domains rely on conserved membrane interhelical packing motifs for example the Glycine xxx Glycine or small xxx small motif 37 Mechanical properties Edit a Helices under axial tensile deformation a characteristic loading condition that appears in many alpha helix rich filaments and tissues results in a characteristic three phase behavior of stiff soft stiff tangent modulus 38 Phase I corresponds to the small deformation regime during which the helix is stretched homogeneously followed by phase II in which alpha helical turns break mediated by the rupture of groups of H bonds Phase III is typically associated with large deformation covalent bond stretching Dynamical features EditAlpha helices in proteins may have low frequency accordion like motion as observed by the Raman spectroscopy 39 and analyzed via the quasi continuum model 40 41 Helices not stabilized by tertiary interactions show dynamic behavior which can be mainly attributed to helix fraying from the ends 42 Helix coil transition EditSee also Helix coil transition model Homopolymers of amino acids such as polylysine can adopt a helical structure at low temperature that is melted out at high temperatures This helix coil transition was once thought to be analogous to protein denaturation The statistical mechanics of this transition can be modeled using an elegant transfer matrix method characterized by two parameters the propensity to initiate a helix and the propensity to extend a helix In art Edit Julian Voss Andreae s Alpha Helix for Linus Pauling 2004 powder coated steel height 10 ft 3 m The sculpture stands in front of Pauling s childhood home on 3945 SE Hawthorne Boulevard in Portland Oregon USA At least five artists have made explicit reference to the a helix in their work Julie Newdoll in painting and Julian Voss Andreae Bathsheba Grossman Byron Rubin and Mike Tyka in sculpture San Francisco area artist Julie Newdoll 43 who holds a degree in microbiology with a minor in art has specialized in paintings inspired by microscopic images and molecules since 1990 Her painting Rise of the Alpha Helix 2003 features human figures arranged in an a helical arrangement According to the artist the flowers reflect the various types of sidechains that each amino acid holds out to the world 43 This same metaphor is also echoed from the scientist s side b sheets do not show a stiff repetitious regularity but flow in graceful twisting curves and even the a helix is regular more in the manner of a flower stem whose branching nodes show the influence of environment developmental history and the evolution of each part to match its own idiosyncratic function 12 Julian Voss Andreae is a German born sculptor with degrees in experimental physics and sculpture Since 2001 Voss Andreae creates protein sculptures 44 based on protein structure with the a helix being one of his preferred objects Voss Andreae has made a helix sculptures from diverse materials including bamboo and whole trees A monument Voss Andreae created in 2004 to celebrate the memory of Linus Pauling the discoverer of the a helix is fashioned from a large steel beam rearranged in the structure of the a helix The 10 foot tall 3 m bright red sculpture stands in front of Pauling s childhood home in Portland Oregon Ribbon diagrams of a helices are a prominent element in the laser etched crystal sculptures of protein structures created by artist Bathsheba Grossman such as those of insulin hemoglobin and DNA polymerase 45 Byron Rubin is a former protein crystallographer now professional sculptor in metal of proteins nucleic acids and drug molecules many of which featuring a helices such as subtilisin human growth hormone and phospholipase A2 46 Mike Tyka is a computational biochemist at the University of Washington working with David Baker Tyka has been making sculptures of protein molecules since 2010 from copper and steel including ubiquitin and a potassium channel tetramer 47 See also Edit310 helix Beta sheet Davydov soliton Folding chemistry Knobs into holes packing Pi helix Proteopedia Helices in ProteinsReferences Edit Kendrew JC Dickerson RE Strandberg BE Hart RG Davies DR Phillips DC Shore VC February 1960 Structure of myoglobin A three dimensional Fourier synthesis at 2 A resolution Nature 185 4711 422 7 Bibcode 1960Natur 185 422K doi 10 1038 185422a0 PMID 18990802 S2CID 4167651 Neurath H 1940 Intramolecular folding of polypeptide chains in relation to protein structure Journal of Physical Chemistry 44 3 296 305 doi 10 1021 j150399a003 Taylor HS 1942 Large molecules through atomic spectacles Proceedings of the American Philosophical Society 85 1 1 12 JSTOR 985121 Huggins M 1943 The structure of fibrous proteins Chemical Reviews 32 2 195 218 doi 10 1021 cr60102a002 Bragg WL Kendrew JC Perutz MF 1950 Polypeptide chain configurations in crystalline proteins Proceedings of the Royal Society of London Series A 203 1074 321 Bibcode 1950RSPSA 203 321B doi 10 1098 rspa 1950 0142 S2CID 93804323 Pauling L Corey RB Branson HR April 1951 The structure of proteins two hydrogen bonded helical configurations of the polypeptide chain Proceedings of the National Academy of Sciences of the United States of America 37 4 205 11 Bibcode 1951PNAS 37 205P doi 10 1073 pnas 37 4 205 PMC 1063337 PMID 14816373 The Nobel Prize in Chemistry 1954 Dunitz J 2001 Pauling s Left Handed a Helix Angewandte Chemie International Edition 40 22 4167 4173 doi 10 1002 1521 3773 20011119 40 22 lt 4167 AID ANIE4167 gt 3 0 CO 2 Q PMID 29712120 IUPAC IUB Commission on Biochemical Nomenclature 1970 Abbreviations and symbols for the description of the conformation of polypeptide chains Journal of Biological Chemistry 245 24 6489 6497 doi 10 1016 S0021 9258 18 62561 X Polypeptide Conformations 1 and 2 www sbcs qmul ac uk Retrieved 5 November 2018 Kabsch W Sander C December 1983 Dictionary of protein secondary structure pattern recognition of hydrogen bonded and geometrical features Biopolymers 22 12 2577 637 doi 10 1002 bip 360221211 PMID 6667333 S2CID 29185760 a b c Richardson JS 1981 The anatomy and taxonomy of protein structure Advances in Protein Chemistry 34 167 339 doi 10 1016 S0065 3233 08 60520 3 ISBN 9780120342341 PMID 7020376 Lovell SC Davis IW Arendall WB de Bakker PI Word JM Prisant MG Richardson JS Richardson DC February 2003 Structure validation by Calpha geometry phi psi and Cbeta deviation Proteins 50 3 437 50 doi 10 1002 prot 10286 PMID 12557186 S2CID 8358424 Dickerson RE Geis I 1969 Structure and Action of Proteins Harper New York Zorko Matjaz 2010 Structural Organization of Proteins In Langel Ulo Cravatt Benjamin F Graslund Astrid von Heijne Gunnar Land Tiit Niessen Sherry Zorko Matjaz eds Introduction to Peptides and Proteins Boca Raton CRC Press pp 36 57 ISBN 9781439882047 Terwilliger TC March 2010 Rapid model building of alpha helices in electron density maps Acta Crystallographica Section D 66 Pt 3 268 75 doi 10 1107 S0907444910000314 PMC 2827347 PMID 20179338 Hudgins RR Jarrold MF 1999 Helix Formation in Unsolvated Alanine Based Peptides Helical Monomers and Helical Dimers Journal of the American Chemical Society 121 14 3494 3501 doi 10 1021 ja983996a Kutchukian PS Yang JS Verdine GL Shakhnovich EI April 2009 All atom model for stabilization of alpha helical structure in peptides by hydrocarbon staples Journal of the American Chemical Society 131 13 4622 7 doi 10 1021 ja805037p PMC 2735086 PMID 19334772 Abrusan G Marsh JA 2016 Alpha helices are more robust to mutations than beta strands PLOS Computational Biology 12 12 e1005242 Bibcode 2016PLSCB 12E5242A doi 10 1371 journal pcbi 1005242 PMC 5147804 PMID 27935949 Rocklin GJ et al 2017 Global analysis of protein folding using massively parallel design synthesis and testing Science 357 6347 168 175 Bibcode 2017Sci 357 168R doi 10 1126 science aan0693 PMC 5568797 PMID 28706065 Schiffer M 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projections bioRxiv doi 10 1101 416347 S2CID 92137153 Wadhwa RR Subramanian V Stevens Truss R 2018 Visualizing alpha helical peptides in R with helixvis Journal of Open Source Software 3 31 1008 Bibcode 2018JOSS 3 1008W doi 10 21105 joss 01008 S2CID 56486576 Subramanian V Wadhwa RR Stevens Truss R 2020 Helixvis Visualize alpha helical peptides in Python ChemRxiv Pace CN Scholtz JM July 1998 A helix propensity scale based on experimental studies of peptides and proteins Biophysical Journal 75 1 422 7 Bibcode 1998BpJ 75 422N doi 10 1016 S0006 3495 98 77529 0 PMC 1299714 PMID 9649402 Pace C Nick Scholtz J Martin 1998 A Helix Propensity Scale Based on Experimental Studies of Peptides and Proteins Biophysical Journal 75 1 422 427 Bibcode 1998BpJ 75 422N doi 10 1016 s0006 3495 98 77529 0 PMC 1299714 PMID 9649402 Hol WG van Duijnen PT Berendsen HJ 1978 The alpha helix dipole and the properties of proteins Nature 273 5662 443 446 Bibcode 1978Natur 273 443H doi 10 1038 273443a0 PMID 661956 S2CID 4147335 He JJ Quiocho FA October 1993 Dominant role of local dipoles in stabilizing uncompensated charges on a sulfate sequestered in a periplasmic active transport protein Protein Science 2 10 1643 7 doi 10 1002 pro 5560021010 PMC 2142251 PMID 8251939 Milner White EJ November 1997 The partial charge of the nitrogen atom in peptide bonds Protein Science 6 11 2477 82 doi 10 1002 pro 5560061125 PMC 2143592 PMID 9385654 Kohn Eric M Shirley David J Arotsky Lubov Picciano Angela M Ridgway Zachary Urban Michael W Carone Benjamin R Caputo Gregory A 2018 02 04 Role of Cationic Side Chains in the Antimicrobial Activity of C18G Molecules 23 2 329 doi 10 3390 molecules23020329 PMC 6017431 PMID 29401708 Toke Orsolya 2005 Antimicrobial peptides new candidates in the fight against bacterial infections Biopolymers 80 6 717 735 doi 10 1002 bip 20286 ISSN 0006 3525 PMID 15880793 Branden amp Tooze chapter 10 Branden amp Tooze chapter 12 Nash A Notman R Dixon AM 2015 De novo design of transmembrane helix helix interactions and measurement of stability in a biological membrane Biochimica et Biophysica Acta BBA Biomembranes 1848 5 1248 57 doi 10 1016 j bbamem 2015 02 020 PMID 25732028 Ackbarow T Chen X Keten S Buehler MJ October 2007 Hierarchies multiple energy barriers and robustness govern the fracture mechanics of alpha helical and beta sheet protein domains Proceedings of the National Academy of Sciences of the United States of America 104 42 16410 5 Bibcode 2007PNAS 10416410A doi 10 1073 pnas 0705759104 PMC 2034213 PMID 17925444 Painter PC Mosher LE Rhoads C July 1982 Low frequency modes in the Raman spectra of proteins Biopolymers 21 7 1469 72 doi 10 1002 bip 360210715 PMID 7115900 Chou KC December 1983 Identification of low frequency modes in protein molecules The Biochemical Journal 215 3 465 9 doi 10 1042 bj2150465 PMC 1152424 PMID 6362659 Chou KC May 1984 Biological functions of low frequency vibrations phonons III Helical structures and microenvironment Biophysical Journal 45 5 881 9 Bibcode 1984BpJ 45 881C doi 10 1016 S0006 3495 84 84234 4 PMC 1434967 PMID 6428481 Fierz B Reiner A Kiefhaber T January 2009 Local conformational dynamics in alpha helices measured by fast triplet transfer Proceedings of the National Academy of Sciences of the United States of America 106 4 1057 62 Bibcode 2009PNAS 106 1057F doi 10 1073 pnas 0808581106 PMC 2633579 PMID 19131517 a b Julie Newdoll Scientifically Inspired Art Music Board Games www brushwithscience com Retrieved 2016 04 06 Voss Andreae J 2005 Protein Sculptures Life s Building Blocks Inspire Art Leonardo 38 41 45 doi 10 1162 leon 2005 38 1 41 S2CID 57558522 Grossman Bathsheba About the Artist Bathsheba Sculpture Retrieved 2016 04 06 About molecularsculpture com Retrieved 2016 04 06 Tyka Mike About www miketyka com Retrieved 2016 04 06 Further reading EditTooze J Branden C 1999 Introduction to protein structure New York Garland Pub ISBN 0 8153 2304 2 Eisenberg D September 2003 The discovery of the alpha helix and beta sheet the principal structural features of proteins Proceedings of the National Academy of Sciences of the United States of America 100 20 11207 10 Bibcode 2003PNAS 10011207E doi 10 1073 pnas 2034522100 PMC 208735 PMID 12966187 Astbury WT Woods HJ 1931 The Molecular Weights of Proteins Nature 127 3209 663 665 Bibcode 1931Natur 127 663A doi 10 1038 127663b0 S2CID 4133226 Astbury WT Street A 1931 X ray studies of the structures of hair wool and related fibres I General Philosophical Transactions of the Royal Society of London Series A 230 75 101 Bibcode 1932RSPTA 230 75A doi 10 1098 rsta 1932 0003 Astbury WT 1933 Some Problems in the X ray Analysis of the Structure of Animal Hairs and Other Protein Fibers Trans Faraday Soc 29 140 193 211 doi 10 1039 tf9332900193 Astbury WT Woods HJ 1934 X ray studies of the structures of hair wool and related fibres II The molecular structure and elastic properties of hair keratin Philosophical Transactions of the Royal Society of London Series A 232 707 720 333 394 Bibcode 1934RSPTA 232 333A doi 10 1098 rsta 1934 0010 Astbury WT Sisson WA 1935 X ray studies of the structures of hair wool and related fibres III The configuration of the keratin molecule and its orientation in the biological cell Proceedings of the Royal Society of London Series A 150 871 533 551 Bibcode 1935RSPSA 150 533A doi 10 1098 rspa 1935 0121 Sugeta H Miyazawa T 1967 General Method for Calculating Helical Parameters of Polymer Chains from Bond Lengths Bond Angles and Internal Rotation Angles Biopolymers 5 7 673 679 doi 10 1002 bip 1967 360050708 S2CID 97785907 Wada A 1976 The alpha helix as an electric macro dipole Advances in Biophysics 1 63 PMID 797240 Chothia C Levitt M Richardson D October 1977 Structure of proteins packing of alpha helices and pleated sheets Proceedings of the National Academy of Sciences of the United States of America 74 10 4130 4 Bibcode 1977PNAS 74 4130C doi 10 1073 pnas 74 10 4130 PMC 431889 PMID 270659 Chothia C Levitt M Richardson D January 1981 Helix to helix packing in proteins Journal of Molecular Biology 145 1 215 50 doi 10 1016 0022 2836 81 90341 7 PMID 7265198 Hol WG 1985 The role of the alpha helix dipole in protein function and structure Progress in Biophysics and Molecular Biology 45 3 149 95 doi 10 1016 0079 6107 85 90001 X PMID 3892583 Barlow DJ Thornton JM June 1988 Helix geometry in proteins Journal of Molecular Biology 201 3 601 19 doi 10 1016 0022 2836 88 90641 9 PMID 3418712 Murzin AG Finkelstein AV December 1988 General architecture of the alpha helical globule Journal of Molecular Biology 204 3 749 69 doi 10 1016 0022 2836 88 90366 X PMID 3225849 External links EditNetSurfP ver 1 1 Protein Surface Accessibility and Secondary Structure Predictions a helix rotational angle calculator Artist Julie Newdoll s website Artist Julian Voss Andreae s website Retrieved from https en wikipedia org w index php title Alpha helix amp oldid 1171151875, wikipedia, wiki, book, books, library,

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