Everything about Beta Sheet totally explained
The
β sheet (also
β-pleated sheet) is the second form of regular
secondary structure in
proteins consisting of
beta strands connected laterally by three or more
hydrogen bonds, forming a generally twisted, pleated sheet (the most common form of regular secondary structure in proteins is the
alpha helix). A beta strand (also
β-strand) is a stretch of
amino acids typically 5–10 amino acids long whose peptide backbones are almost fully extended. The association of beta sheets has been implicated in the formation of protein aggregates and fibrils observed in many human diseases, notably the
amyloidoses.
Nomenclature
In the most common usage,
β strand refers to a single continuous stretch of amino acids adopting an extended conformation and involved in
hydrogen bonds; by contrast, a
β sheet refers to an
assembly of such strands that are
hydrogen-bonded to each other.
History
The first β sheet structure was proposed by
William Astbury in the 1930s. He proposed the idea of hydrogen bonding between the
peptide bonds of parallel or antiparallel extended β strands. However, Astbury didn't have the necessary data on the bond geometry of the amino acids in order to build accurate models, especially since he didn't then know that the
peptide bond was planar. A refined version was proposed by
Linus Pauling and
Robert Corey in 1951.
Structure and orientation
Geometry
The majority of β strands are arranged adjacent to other strands and form an extensive
hydrogen bond network with their neighbors in which the
N-H groups in the backbone of one strand establish
hydrogen bonds with the
C=O groups in the backbone of the adjacent strands. In the fully extended β strand, successive side chains point straight up, then straight down, then straight up, etc. Adjacent β strands in a β sheet are aligned so that their C
α atoms are adjacent and their side chains point in the same direction. The "pleated" appearance of β strands arises from tetrahedral chemical bonding at the C
α atom; for example, if a side chain points straight up, then the bond to the
are adjacent in two
hydrogen-bonded β strands, then they do
not hydrogen bond to each other; rather, one residue forms hydrogen bonds to the residues that flank the other (but not vice versa). For example, residue
may form hydrogen bonds to residues
and
; this is known as a
wide pair of hydrogen bonds. By contrast, residue
may hydrogen-bond to different residues altogether, or to none at all.
Finally, an individual strand may exhibit a mixed bonding pattern, with a parallel strand on one side and an antiparallel strand on the other. Such arrangements are less common than a random distribution of orientations would suggest, indicating that this pattern is less stable than the antiparallel arrangement.
The
hydrogen bonding of β strands need not be perfect, but can exhibit localized disruptions known as
beta bulges.
The hydrogen bonds lie roughly in the plane of the sheet, with the
peptide carbonyl groups pointing in alternating directions with successive residues; for comparison, successive carbonyls point in the
same direction in the
alpha helix.
Amino acid propensities
Large aromatic residues (Tyr, Phe and Trp) and β-branched amino acids (Thr, Val, Ile) are favored to be found in β strands in the
middle of β sheets. Interestingly, different types of residues (such as Pro) are likely to be found in the
edge strands in β sheets, presumably to avoid the "edge-to-edge" association between proteins that might lead to
aggregation and
amyloid formation.
Common structural motifs
A very simple
structural motif involving β sheets is the
β hairpin, in which two antiparallel strands are linked by a short loop of two to five residues, of which one is frequently a
glycine or a
proline, both of which can assume the unusual dihedral-angle conformations required for a tight
turn. However, individual strands can also be linked in more elaborate ways with long loops that may contain
alpha helices or even entire protein domains.
Greek key motif
The
Greek key motif consists of four adjacent antiparallel strands and their linking loops. It consists of three antiparallel strands connected by hairpins, while the fourth is adjacent to the first and linked to the third by a longer loop. This type of structure forms easily during the protein folding process. It was named after a pattern common to Greek ornamental artwork.
The β-α-β motif
Due to the chirality of their component amino acids, all strands exhibit a "right-handed" twist evident in most higher-order β sheet structures. In particular, the linking loop between two parallel strands almost always has a right-handed crossover chirality, which is strongly favored by the inherent twist of the sheet. This linking loop frequently contains a helical region, in which case it's called a
β-α-β motif. A closely related motif called a β-α-β-α motif forms the basic component of the most common protein
tertiary structure, the
TIM barrel.
β-meander motif
A simple
supersecondary protein topology composed of 2 or more consecutive antiparallel β-strands linked together by
hairpin loops
(External Link
)(External Link). This motif is common in β-sheets and can be found in several structural architectures including
β-barrels and
β-propellers.
Psi-loop motif
The psi-loop, Ψ-loop, motif consists of two antiparallel strands with one strand in between that's connected to both by hydrogen bonds. There are four possible strand topologies for single Ψ-loops as cited by Hutchinson
et al. 1990. This motif is rare as the process resulting in its formation seems unlikely to occur during protein folding. The Ψ-loop was first identified in the
aspartic protease family.
Structural architectures of proteins with beta-sheets
Beta-sheets are present in
all-β,
α+β and
α/β domains according to
Structural Classification of Proteins and in many
peptides or small proteins with poorly defined overal architecture.
All-β domains may form
β barrels,
β sandwiches,
β prisms,
β propellers, and
β-helices.
Structural topology
The
topology of a β sheet describes the order of
hydrogen-bonded β strands along the backbone. For example, the
flavodoxin fold has a five-stranded, parallel β sheet with topology 21345; thus, the edge strands are β strand 2 and β strand 5 along the backbone. Spelled out explicitly, β strand 2 is H-bonded to β strand 1, which is H-bonded to β strand 3, which is H-bonded to β strand 4, which is H-bonded to β strand 5, the other edge strand. In the same system, the Greek key motif described above has a 4123 topology. The
secondary structure of a β sheet can be described roughly by giving the number of strands, their topology, and whether their
hydrogen bonds are parallel or antiparallel.
β sheets can be
open, meaning that they've two edge strands (as in the
flavodoxin fold or the
immunoglobulin fold)) or they can be
closed beta barrels (such as the
TIM barrel).
β-Barrels are often described by their
stagger or
shear. Some open β sheets are very curved and fold over on themselves (as in the
SH3 domain) or form horseshoe shapes (as in the
ribonuclease inhibitor). Open β sheets can assemble face-to-face (such as the
beta-propeller domain or
immunoglobulin fold) or edge-to-edge, forming one big β sheet.
Parallel β helices
A
β helix is formed from repeating structural units consisting of two or three short β strands linked by short loops. These units "stack" atop one another in a helical fashion so that successive repetitions of the same strand hydrogen-bond with each other in a parallel orientation. In
β helices, the strands themselves are nearly planar; the resulting helical surfaces are nearly flat, forming a
triangular prism shape.
The two-strand helix is found in the enzyme pectate lyase. Its two loops are each six residues long and bind stabilizing calcium ions to maintain the integrity of the structure. The more complex three-strand helix contains three linking loops, of which one is consistently two residues long and the others are variable. This structure is found in bacteriophage P22 tailspike protein.
β sheets in pathology
Some proteins that are disordered or helical as monomers, such as amyloid β (see
amyloid plaque) can form β-sheet-rich oligomeric structures associated with pathological states. The amyloid β protein's oligomeric form is implicated as a cause of
Alzheimer's. Its structure has yet to be determined in full, but recent data suggests that it may resemble an unusual two-strand β helix.
The side chains from the amino acid residues found in a β sheet structure may also be arranged such that many of the adjacent sidechains on one side of the sheet are hydrophobic, while many of those adjacent to each other on the alternate side of the sheet are polar or charged (hydrophilic), which can be useful if the sheet is to form a boundary between polar/watery and nonpolar/greasy environments.
Further Information
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