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==Inorganic polymers==
==Inorganic polymers==
[[File:PmdsStructure.png|230px|right|Polydimethylsiloxane is classified as an "[[inorganic polymer]]", because the backbone lacks carbon.|thumb]]
[[File:PmdsStructure.svg|230px|right|Polydimethylsiloxane is classified as an "[[inorganic polymer]]", because the backbone lacks carbon.|thumb]]
[[Siloxane]]s are a premier example of an inorganic polymer, even though they have extensive organic substituents. Their backbond is composed of alternating silicon and oxygen atoms, i.e. Si-O-Si-O... The silicon atoms bear two substituents, usually [[methyl]] as in the case of [[polydimethylsiloxane]]. Some uncommon but illustrative inorganic polymers include [[polythiazyl]] ((SN)x) with alternating S and N atoms, and polyphosphates ((PO<sub>3</sub><sup>−</sup>)<sub>n</sub>).
[[Siloxane]]s are a premier example of an inorganic polymer, even though they have extensive organic substituents. Their backbond is composed of alternating silicon and oxygen atoms, i.e. Si-O-Si-O... The silicon atoms bear two substituents, usually [[methyl]] as in the case of [[polydimethylsiloxane]]. Some uncommon but illustrative inorganic polymers include [[polythiazyl]] ((SN)x) with alternating S and N atoms, and polyphosphates ((PO<sub>3</sub><sup>−</sup>)<sub>n</sub>).
==Biopolymers==
==Biopolymers==
Major families of biopolymers are [[polysaccharide]]s (carbohydrates), [[peptide]]s, and [[polynucleotide]]s. Many variants of each are known.<ref name=Voet16>{{cite book |first1=Donald |last1=Voet |first2=Judith G. |last2=Voet |first3=Charlotte W. |last3=Pratt |title=Fundamentals of Biochemistry: Life at the Molecular Level |url=https://books.google.com/books?id=9T7hCgAAQBAJ |date=2016 |publisher=Wiley |edition=5th |isbn=978-1-118-91840-1}}V</ref>
Major families of biopolymers are [[polysaccharide]]s (carbohydrates), [[peptide]]s, and [[polynucleotide]]s. Many variants of each are known.<ref name=Voet16>{{cite book |first1=Donald |last1=Voet |first2=Judith G. |last2=Voet |first3=Charlotte W. |last3=Pratt |title=Fundamentals of Biochemistry: Life at the Molecular Level |url=https://books.google.com/books?id=9T7hCgAAQBAJ |date=2016 |publisher=Wiley |edition=5th |isbn=978-1-118-91840-1}}V</ref>
===Proteins and peptides===
===Proteins and peptides===
Proteins are characterized by [[Peptide bond|amide linkages]] (-N(H)-C(O)-) formed by the condensation of [[amino acid]]s. The sequence of the amino acids in the polypeptide backbone is known as the [[Protein primary structure|primary structure]] of the protein. Like almost all polymers, protein fold and twist, forming into the [[Protein secondary structure|secondary structure]], which is rigidified by [[hydrogen bonding]] between the [[Carbonyl group|carbonyl]] oxygens and amide hydrogens in the backbone, i.e. C=O---HN. Further interactions between residues of the individual amino acids form the protein's [[Protein tertiary structure|tertiary structure]]. For this reason, the primary structure of the amino acids in the polypeptide backbone is the map of the final structure of a protein, and it therefore indicates its biological function.<ref>{{cite book |vauthors=Berg JM, Tymoczko JL, Stryer L |chapter=3.2 Primary Structure: Amino Acids Are Linked by Peptide Bonds to Form Polypeptide Chains |chapter-url=https://www.ncbi.nlm.nih.gov/books/NBK22364/ |id=NBK22364 |title=Biochemistry |publisher=W.H. Freeman |edition=5th |year=2002 |isbn=0-7167-3051-0 |url=https://www.ncbi.nlm.nih.gov/books/NBK21154/}}</ref><ref name=Voet16 /> Spatial positions of backbone atoms can be reconstructed from the positions of alpha carbons using computational tools for the backbone reconstruction.<ref>{{Cite journal|last=Badaczewska-Dawid|first=Aleksandra E.|last2=Kolinski|first2=Andrzej|last3=Kmiecik|first3=Sebastian|title=Computational reconstruction of atomistic protein structures from coarse-grained models|journal=Computational and Structural Biotechnology Journal|volume=18|pages=162–176|doi=10.1016/j.csbj.2019.12.007|pmid=31969975|pmc=6961067|issn=2001-0370|year=2020}}</ref>
[[File:Sucrose condensation.svg|thumb|A simplified example of condensation showing the ''alpha'' and ''beta'' classification. [[Glucose]] and [[fructose]] form [[sucrose]]. The synthesis of glycogen in the body is driven by the enzyme [[glycogen synthase]] which uses a [[uridine diphosphate]] (UDP) leaving group.]]Proteins are characterized by [[Peptide bond|amide linkages]] (-N(H)-C(O)-) formed by the condensation of [[amino acid]]s. The sequence of the amino acids in the polypeptide backbone is known as the [[Protein primary structure|primary structure]] of the protein. Like almost all polymers, protein fold and twist, forming into the [[Protein secondary structure|secondary structure]], which is rigidified by [[hydrogen bonding]] between the [[Carbonyl group|carbonyl]] oxygens and amide hydrogens in the backbone, i.e. C=O---HN. Further interactions between residues of the individual amino acids form the protein's [[Protein tertiary structure|tertiary structure]]. For this reason, the primary structure of the amino acids in the polypeptide backbone is the map of the final structure of a protein, and it therefore indicates its biological function.<ref>{{cite book |vauthors=Berg JM, Tymoczko JL, Stryer L |chapter=3.2 Primary Structure: Amino Acids Are Linked by Peptide Bonds to Form Polypeptide Chains |chapter-url=https://www.ncbi.nlm.nih.gov/books/NBK22364/ |id=NBK22364 |title=Biochemistry |publisher=W.H. Freeman |edition=5th |year=2002 |isbn=0-7167-3051-0 |url=https://www.ncbi.nlm.nih.gov/books/NBK21154/|archive-url=https://web.archive.org/web/20101210225405/http://www.ncbi.nlm.nih.gov/books/NBK21154/|url-status=dead|archive-date=December 10, 2010}}</ref><ref name=Voet16 /> Spatial positions of backbone atoms can be reconstructed from the positions of alpha carbons using computational tools for the backbone reconstruction.<ref>{{Cite journal|last=Badaczewska-Dawid|first=Aleksandra E.|last2=Kolinski|first2=Andrzej|last3=Kmiecik|first3=Sebastian|title=Computational reconstruction of atomistic protein structures from coarse-grained models|journal=Computational and Structural Biotechnology Journal|volume=18|pages=162–176|doi=10.1016/j.csbj.2019.12.007|pmid=31969975|pmc=6961067|issn=2001-0370|year=2020}}</ref>
[[File:Sucrose condensation.svg|thumb|A simplified example of condensation showing the ''alpha'' and ''beta'' classification. [[Glucose]] and [[fructose]] form [[sucrose]]. The synthesis of glycogen in the body is driven by the enzyme [[glycogen synthase]] which uses a [[uridine diphosphate]] (UDP) leaving group.]]
=== Carbohydrates ===
=== Carbohydrates ===
[[File:DNA condensation.svg|thumb|Condensation of [[adenine]] and [[guanine]] forming a [[phosphodiester bond]], the [[Nucleoside triphosphate|triphosphorylated ribose]] of the incoming nucleotide is attacked by the 3' [[Hydroxy group|hydroxyl]] of the polymer, releasing [[pyrophosphate]].]]
Carbohydrates arise by condensation of [[monosaccharide]]s such as [[glucose]]. The polymers can be classified into [[oligosaccharide]]s (up to 10 residues) and [[polysaccharide]]s (up to about 50,000 residues). The backbone chain is characterized by an ether bond between individual monosaccharides. This bond is called the [[Glycosidic bond|glycosidic linkage]].<ref>{{Cite journal|last=Buschiazzo|first=Alejandro|year=2004|title=Crystal structure of glycogen synthase: homologous enzymes catalyze glycogen synthesis and degradation|journal=The EMBO Journal |volume=23|issue=16|pages=3196–3205|doi=10.1038/sj.emboj.7600324|pmc=514502|pmid=15272305}}</ref> These backbone chains can be unbranched (containing one linear chain) or branched (containing multiple chains). The glycosidic linkages are designated as [[Anomer|''alpha'' or ''beta'']] depending on the relative [[stereochemistry]] of the [[anomer]]ic (or most [[oxidized]]) carbon. In a [[Fischer projection|Fischer Projection]], if the glycosidic linkage is on the same side or face as carbon 6 of a common biological saccharide, the carbohydrate is designated as ''beta'' and if the linkage is on the opposite side it is designated as ''alpha''. In a traditional "[[Cyclohexane conformation|chair structure]]" projection, if the linkage is on the same plane (equatorial or axial) as carbon 6 it is designated as ''beta'' and on the opposite plane it is designated as ''alpha''. This is exemplified in [[sucrose]] (table sugar) which contains a linkage that is ''alpha'' to glucose and ''beta'' to [[fructose]]. Generally, carbohydrates which our bodies break down are ''alpha''-linked [[Glycogen|(example: glycogen)]] and those which have structural function are ''beta''-linked (example: [[cellulose]]).<ref name=Voet16 /><ref>{{cite book |vauthors=Bertozzi CR, Rabuka D |chapter=Structural Basis of Glycan Diversity |chapter-url=https://www.ncbi.nlm.nih.gov/books/NBK1955/ |veditors=Varki A, Cummings RD, Esko JD, et al |title=Essentials of Glycobiology |publisher=Cold Spring Harbor Laboratory Press |year=2009 |isbn=9780879697709 |edition=2nd |url=https://www.ncbi.nlm.nih.gov/books/NBK1908/ |pmid=20301274}}</ref>
Carbohydrates arise by condensation of [[monosaccharide]]s such as [[glucose]]. The polymers can be classified into [[oligosaccharide]]s (up to 10 residues) and [[polysaccharide]]s (up to about 50,000 residues). The backbone chain is characterized by an ether bond between individual monosaccharides. This bond is called the [[Glycosidic bond|glycosidic linkage]].<ref>{{Cite journal|last=Buschiazzo|first=Alejandro|year=2004|title=Crystal structure of glycogen synthase: homologous enzymes catalyze glycogen synthesis and degradation|journal=The EMBO Journal |volume=23|issue=16|pages=3196–3205|doi=10.1038/sj.emboj.7600324|pmc=514502|pmid=15272305}}</ref> These backbone chains can be unbranched (containing one linear chain) or branched (containing multiple chains). The glycosidic linkages are designated as [[Anomer|''alpha'' or ''beta'']] depending on the relative [[stereochemistry]] of the [[anomer]]ic (or most [[oxidized]]) carbon. In a [[Fischer projection|Fischer Projection]], if the glycosidic linkage is on the same side or face as carbon 6 of a common biological saccharide, the carbohydrate is designated as ''beta'' and if the linkage is on the opposite side it is designated as ''alpha''. In a traditional "[[Cyclohexane conformation|chair structure]]" projection, if the linkage is on the same plane (equatorial or axial) as carbon 6 it is designated as ''beta'' and on the opposite plane it is designated as ''alpha''. This is exemplified in [[sucrose]] (table sugar) which contains a linkage that is ''alpha'' to glucose and ''beta'' to [[fructose]]. Generally, carbohydrates which our bodies break down are ''alpha''-linked [[Glycogen|(example: glycogen)]] and those which have structural function are ''beta''-linked (example: [[cellulose]]).<ref name=Voet16 /><ref>{{cite book |vauthors=Bertozzi CR, Rabuka D |chapter=Structural Basis of Glycan Diversity |chapter-url=https://www.ncbi.nlm.nih.gov/books/NBK1955/ |veditors=Varki A, Cummings RD, Esko JD, et al |title=Essentials of Glycobiology |publisher=Cold Spring Harbor Laboratory Press |year=2009 |isbn=9780879697709 |edition=2nd |url=https://www.ncbi.nlm.nih.gov/books/NBK1908/ |pmid=20301274}}</ref>
=== Nucleic acids ===
=== Nucleic acids ===
[[File:DNA condensation.svg|thumb|Condensation of [[adenine]] and [[guanine]] forming a [[phosphodiester bond]], the [[Nucleoside triphosphate|triphosphorylated ribose]] of the incoming nucleotide is attacked by the 3' [[Hydroxy group|hydroxyl]] of the polymer, releasing [[pyrophosphate]].]]
[[Deoxyribonucleic acid]] (DNA) and [[RiboNucleic Acid|ribonucleic acid]] (RNA) are the main examples of [[polynucleotide]]s. They arise by condensation of nucleotides. Their backbones form by the condensation of a hydroxy group on a [[ribose]] with the [[phosphate]] group on another ribose. This linkage is called a [[phosphodiester bond]]. The condensation is catalyzed by [[enzyme]]s called [[polymerase]]s. DNA and RNA can be millions of nucleotides long thus allowing for the [[genetic diversity]] of life. The bases project from the pentose-phosphate polymer backbone and are [[hydrogen bond]]ed in pairs to their [[Complementary nucleotide|complementary]] partners (A with T and G with C). This creates a [[Nucleic acid double helix|double helix]] with pentose phosphate backbones on either side, thus forming a [[Protein secondary structure|secondary structure]].<ref>{{cite book |vauthors=Alberts B, Johnson A, Lewis J, et al |chapter=DNA Replication Mechanisms |chapter-url=https://www.ncbi.nlm.nih.gov/books/NBK26850/ |id=NBK26850 |title=Molecular Biology of the Cell |publisher=Garland Science |edition=4th |year=2002 |isbn=0-8153-3218-1 |url=https://www.ncbi.nlm.nih.gov/books/NBK21054/}}</ref><ref name=Voet16 /><ref>{{cite book |vauthors=Lodish H, Berk A, Zipursky SL, et al |chapter=4.1, Structure of Nucleic Acids |chapter-url=https://www.ncbi.nlm.nih.gov/books/NBK21514/ |title=Molecular Cell Biology |publisher=W.H. Freeman |edition=4th |year=2000 |isbn=0-7167-3136-3 |url=https://www.ncbi.nlm.nih.gov/books/NBK21475/ |archive-url=https://web.archive.org/web/20101210172801/http://www.ncbi.nlm.nih.gov/books/NBK21475/ |url-status=dead |archive-date=December 10, 2010 |id=NBK21514}}</ref>
[[Deoxyribonucleic acid]] (DNA) and [[RiboNucleic Acid|ribonucleic acid]] (RNA) are the main examples of [[polynucleotide]]s. They arise by condensation of nucleotides. Their backbones form by the condensation of a hydroxy group on a [[ribose]] with the [[phosphate]] group on another ribose. This linkage is called a [[phosphodiester bond]]. The condensation is catalyzed by [[enzyme]]s called [[polymerase]]s. DNA and RNA can be millions of nucleotides long thus allowing for the [[genetic diversity]] of life. The bases project from the pentose-phosphate polymer backbone and are [[hydrogen bond]]ed in pairs to their [[Complementary nucleotide|complementary]] partners (A with T and G with C). This creates a [[Nucleic acid double helix|double helix]] with pentose phosphate backbones on either side, thus forming a [[Protein secondary structure|secondary structure]].<ref>{{cite book |vauthors=Alberts B, Johnson A, Lewis J, et al |chapter=DNA Replication Mechanisms |chapter-url=https://www.ncbi.nlm.nih.gov/books/NBK26850/ |id=NBK26850 |title=Molecular Biology of the Cell |publisher=Garland Science |edition=4th |year=2002 |isbn=0-8153-3218-1 |url=https://www.ncbi.nlm.nih.gov/books/NBK21054/}}</ref><ref name=Voet16 /><ref>{{cite book |vauthors=Lodish H, Berk A, Zipursky SL, et al |chapter=4.1, Structure of Nucleic Acids |chapter-url=https://www.ncbi.nlm.nih.gov/books/NBK21514/ |title=Molecular Cell Biology |publisher=W.H. Freeman |edition=4th |year=2000 |isbn=0-7167-3136-3 |url=https://www.ncbi.nlm.nih.gov/books/NBK21475/ |id=NBK21514}}</ref>
Main chain or Backbone That linear chain to which all other chains, long or short or both, may be regarded as being pendant.
Note: Where two or more chains could equally be considered to be the main chain, that one is selected which leads to the simplest representation of the molecule.[1]
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In polymer science, the polymer chain or simply backbone of a polymer is the main chain of a polymer. Polymers are often classified according to the elements in the main chains. The character of the backbone, i.e. its flexibility, determines the properties of the polymer (such as the glass transition temperature). For example, in polysiloxanes (silicone), the backbone chain is very flexible, which results in a very low glass transition temperature of Template:Cvt.[2] The polymers with rigid backbones are prone to crystallization (e.g. polythiophenes) in thin films and in solution. Crystallization in its turn affects the optical properties of the polymers, its optical band gap and electronic levels.[3]
Common synthetic polymers have main chains composed of carbon, i.e. C-C-C-C.... Examples include polyolefins such as polyethylene ((CH2CH2)n) and many substituted derivative ((CH2CH(R))n) such as polystyrene (R = C6H5), polypropylene (R = CH3), and acrylates (R = CO2R').
Other major classes of organic polymers are polyesters and polyamides. They have respectively -C(O)-O- and -C(O)-NH- groups in their backbones in addition to chains of carbon. Major commercial products are polyethyleneterephthalate ("PET"), ((C6H4CO2C2H4OC(O))n) and nylon-6 ((NH(CH2)5C(O))n).
Siloxanes are a premier example of an inorganic polymer, even though they have extensive organic substituents. Their backbond is composed of alternating silicon and oxygen atoms, i.e. Si-O-Si-O... The silicon atoms bear two substituents, usually methyl as in the case of polydimethylsiloxane. Some uncommon but illustrative inorganic polymers include polythiazyl ((SN)x) with alternating S and N atoms, and polyphosphates ((PO3−)n).
Proteins are characterized by amide linkages (-N(H)-C(O)-) formed by the condensation of amino acids. The sequence of the amino acids in the polypeptide backbone is known as the primary structure of the protein. Like almost all polymers, protein fold and twist, forming into the secondary structure, which is rigidified by hydrogen bonding between the carbonyl oxygens and amide hydrogens in the backbone, i.e. C=O---HN. Further interactions between residues of the individual amino acids form the protein's tertiary structure. For this reason, the primary structure of the amino acids in the polypeptide backbone is the map of the final structure of a protein, and it therefore indicates its biological function.[5][4] Spatial positions of backbone atoms can be reconstructed from the positions of alpha carbons using computational tools for the backbone reconstruction.[6]
Carbohydrates arise by condensation of monosaccharides such as glucose. The polymers can be classified into oligosaccharides (up to 10 residues) and polysaccharides (up to about 50,000 residues). The backbone chain is characterized by an ether bond between individual monosaccharides. This bond is called the glycosidic linkage.[7] These backbone chains can be unbranched (containing one linear chain) or branched (containing multiple chains). The glycosidic linkages are designated as alpha or beta depending on the relative stereochemistry of the anomeric (or most oxidized) carbon. In a Fischer Projection, if the glycosidic linkage is on the same side or face as carbon 6 of a common biological saccharide, the carbohydrate is designated as beta and if the linkage is on the opposite side it is designated as alpha. In a traditional "chair structure" projection, if the linkage is on the same plane (equatorial or axial) as carbon 6 it is designated as beta and on the opposite plane it is designated as alpha. This is exemplified in sucrose (table sugar) which contains a linkage that is alpha to glucose and beta to fructose. Generally, carbohydrates which our bodies break down are alpha-linked (example: glycogen) and those which have structural function are beta-linked (example: cellulose).[4][8]
