Notes in MtM II (Protiens)

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Published	11/11/2024	9bfc40734464436ab5fb88f7795a1ade-ao-1
Published	11/11/2024	9bfc40734464436ab5fb88f7795a1ade-ao-2
Published	11/11/2024	9bfc40734464436ab5fb88f7795a1ade-ao-3
Published	11/11/2024	9bfc40734464436ab5fb88f7795a1ade-ao-4
Published	11/11/2024	9bfc40734464436ab5fb88f7795a1ade-ao-5
Published	11/11/2024	9bfc40734464436ab5fb88f7795a1ade-ao-6
Published	11/11/2024	9bfc40734464436ab5fb88f7795a1ade-ao-7
Published	11/11/2024	9bfc40734464436ab5fb88f7795a1ade-ao-8
Published	11/11/2024	3128d8c04ce8472fb75807baa89b3bb9-ao-1
Published	11/11/2024	3128d8c04ce8472fb75807baa89b3bb9-ao-2
Published	11/11/2024	3128d8c04ce8472fb75807baa89b3bb9-ao-3
Published	11/11/2024	3128d8c04ce8472fb75807baa89b3bb9-ao-4
Published	11/11/2024	The primary structure of a protein consists of a linear sequence of {{c1::amino acids}} connected by {{c1::peptide bonds}}.
Published	11/11/2024	The {{c1::R-groups}} determine the {{c2::chemical properties}} of an amino acid in the primary structure of a protein.
Published	11/11/2024	The alpha helix is stabilised by {{c1::hydrogen bonds}} between {{c1::hydrogen}} and {{c1::oxygen}} atoms, and the R groups face {{c1::outward}}.
Published	11/11/2024	In a beta sheets, hydrogen bonding occurs between strands that can be either {{c1::parallel}} or {{c1::anti-parallel}}.
Published	11/11/2024	An example of a beta sheet structure is the {{c1::beta-barrel}}.
Published	11/11/2024	The tertiary structure of a protein is its {{c2::overall 3-dimension}}, stabilised by {{c1::van der waals forces}} and {{c1::hydrogen bonding}}, {{c1:…
Published	11/11/2024	The quaternary structure is made up {{c1::multiple subunits }}.
Published	11/11/2024	Fibrous proteins, such {{c1::collagen}} and {{c1::elastin}}, are {{c2::elongated}} and provide {{c2::strength}} to tissues.
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