fbpx
Wikipedia

Biomolecule

January 20, 2023

A biomolecule or biological molecule is a loosely used term for molecules present in organisms that are essential to one or more typically biological processes, such as cell division, morphogenesis, or development.[1] Biomolecules include large macromolecules (or polyelectrolytes) such as proteins, carbohydrates, lipids, and nucleic acids, as well as small molecules such as primary metabolites, secondary metabolites and natural products. A more general name for this class of material is biological materials. Biomolecules are an important element of living organisms, those biomolecules are often endogenous,[2] produced within the organism[3] but organisms usually need exogenous biomolecules, for example certain nutrients, to survive.

A representation of the 3D structure of myoglobin, showing alpha helices, represented by ribbons. This protein was the first to have its structure solved by X-ray crystallography by Max Perutz and Sir John Cowdery Kendrew in 1958, for which they received a Nobel Prize in Chemistry

Biology and its subfields of biochemistry and molecular biology study biomolecules and their reactions. Most biomolecules are organic compounds, and just four elementsoxygen, carbon, hydrogen, and nitrogen—make up 96% of the human body's mass. But many other elements, such as the various biometals, are also present in small amounts.

The uniformity of both specific types of molecules (the biomolecules) and of certain metabolic pathways are invariant features among the wide diversity of life forms; thus these biomolecules and metabolic pathways are referred to as "biochemical universals"[4] or "theory of material unity of the living beings", a unifying concept in biology, along with cell theory and evolution theory.[5]

Types of biomolecules

A diverse range of biomolecules exist, including:

Nucleosides and nucleotides

Main articles: Nucleosides and Nucleotides

Nucleosides are molecules formed by attaching a nucleobase to a ribose or deoxyribose ring. Examples of these include cytidine (C), uridine (U), adenosine (A), guanosine (G), and thymidine (T).

Nucleosides can be phosphorylated by specific kinases in the cell, producing nucleotides. Both DNA and RNA are polymers, consisting of long, linear molecules assembled by polymerase enzymes from repeating structural units, or monomers, of mononucleotides. DNA uses the deoxynucleotides C, G, A, and T, while RNA uses the ribonucleotides (which have an extra hydroxyl(OH) group on the pentose ring) C, G, A, and U. Modified bases are fairly common (such as with methyl groups on the base ring), as found in ribosomal RNA or transfer RNAs or for discriminating the new from old strands of DNA after replication.[6]

Each nucleotide is made of an acyclic nitrogenous base, a pentose and one to three phosphate groups. They contain carbon, nitrogen, oxygen, hydrogen and phosphorus. They serve as sources of chemical energy (adenosine triphosphate and guanosine triphosphate), participate in cellular signaling (cyclic guanosine monophosphate and cyclic adenosine monophosphate), and are incorporated into important cofactors of enzymatic reactions (coenzyme A, flavin adenine dinucleotide, flavin mononucleotide, and nicotinamide adenine dinucleotide phosphate).[7]

DNA and RNA structure

Main articles: DNA and Nucleic acid structure

DNA structure is dominated by the well-known double helix formed by Watson-Crick base-pairing of C with G and A with T. This is known as B-form DNA, and is overwhelmingly the most favorable and common state of DNA; its highly specific and stable base-pairing is the basis of reliable genetic information storage. DNA can sometimes occur as single strands (often needing to be stabilized by single-strand binding proteins) or as A-form or Z-form helices, and occasionally in more complex 3D structures such as the crossover at Holliday junctions during DNA replication.[7]

 
Stereo 3D image of a group I intron ribozyme (PDB file 1Y0Q); gray lines show base pairs; ribbon arrows show double-helix regions, blue to red from 5' to 3'[when defined as?] end; white ribbon is an RNA product.

RNA, in contrast, forms large and complex 3D tertiary structures reminiscent of proteins, as well as the loose single strands with locally folded regions that constitute messenger RNA molecules. Those RNA structures contain many stretches of A-form double helix, connected into definite 3D arrangements by single-stranded loops, bulges, and junctions.[8] Examples are tRNA, ribosomes, ribozymes, and riboswitches. These complex structures are facilitated by the fact that RNA backbone has less local flexibility than DNA but a large set of distinct conformations, apparently because of both positive and negative interactions of the extra OH on the ribose.[9] Structured RNA molecules can do highly specific binding of other molecules and can themselves be recognized specifically; in addition, they can perform enzymatic catalysis (when they are known as "ribozymes", as initially discovered by Tom Cech and colleagues).[10]

Saccharides

Monosaccharides are the simplest form of carbohydrates with only one simple sugar. They essentially contain an aldehyde or ketone group in their structure.[11] The presence of an aldehyde group in a monosaccharide is indicated by the prefix aldo-. Similarly, a ketone group is denoted by the prefix keto-.[6] Examples of monosaccharides are the hexoses, glucose, fructose, Trioses, Tetroses, Heptoses, galactose, pentoses, ribose, and deoxyribose. Consumed fructose and glucose have different rates of gastric emptying, are differentially absorbed and have different metabolic fates, providing multiple opportunities for two different saccharides to differentially affect food intake.[11] Most saccharides eventually provide fuel for cellular respiration.

Disaccharides are formed when two monosaccharides, or two single simple sugars, form a bond with removal of water. They can be hydrolyzed to yield their saccharin building blocks by boiling with dilute acid or reacting them with appropriate enzymes.[6] Examples of disaccharides include sucrose, maltose, and lactose.

Polysaccharides are polymerized monosaccharides, or complex carbohydrates. They have multiple simple sugars. Examples are starch, cellulose, and glycogen. They are generally large and often have a complex branched connectivity. Because of their size, polysaccharides are not water-soluble, but their many hydroxy groups become hydrated individually when exposed to water, and some polysaccharides form thick colloidal dispersions when heated in water.[6] Shorter polysaccharides, with 3 to 10 monomers, are called oligosaccharides.[12] A fluorescent indicator-displacement molecular imprinting sensor was developed for discriminating saccharides. It successfully discriminated three brands of orange juice beverage.[13] The change in fluorescence intensity of the sensing films resulting is directly related to the saccharide concentration.[14]

Lignin

Lignin is a complex polyphenolic macromolecule composed mainly of beta-O4-aryl linkages. After cellulose, lignin is the second most abundant biopolymer and is one of the primary structural components of most plants. It contains subunits derived from p-coumaryl alcohol, coniferyl alcohol, and sinapyl alcohol[15] and is unusual among biomolecules in that it is racemic. The lack of optical activity is due to the polymerization of lignin which occurs via free radical coupling reactions in which there is no preference for either configuration at a chiral center.

Lipid

Lipids (oleaginous) are chiefly fatty acid esters, and are the basic building blocks of biological membranes. Another biological role is energy storage (e.g., triglycerides). Most lipids consist of a polar or hydrophilic head (typically glycerol) and one to three non polar or hydrophobic fatty acid tails, and therefore they are amphiphilic. Fatty acids consist of unbranched chains of carbon atoms that are connected by single bonds alone (saturated fatty acids) or by both single and double bonds (unsaturated fatty acids). The chains are usually 14-24 carbon groups long, but it is always an even number.

For lipids present in biological membranes, the hydrophilic head is from one of three classes:

  • Glycolipids, whose heads contain an oligosaccharide with 1-15 saccharide residues.
  • Phospholipids, whose heads contain a positively charged group that is linked to the tail by a negatively charged phosphate group.
  • Sterols, whose heads contain a planar steroid ring, for example, cholesterol.

Other lipids include prostaglandins and leukotrienes which are both 20-carbon fatty acyl units synthesized from arachidonic acid. They are also known as fatty acids

Amino acids

Amino acids contain both amino and carboxylic acid functional groups. (In biochemistry, the term amino acid is used when referring to those amino acids in which the amino and carboxylate functionalities are attached to the same carbon, plus proline which is not actually an amino acid).

Modified amino acids are sometimes observed in proteins; this is usually the result of enzymatic modification after translation (protein synthesis). For example, phosphorylation of serine by kinases and dephosphorylation by phosphatases is an important control mechanism in the cell cycle. Only two amino acids other than the standard twenty are known to be incorporated into proteins during translation, in certain organisms:

Besides those used in protein synthesis, other biologically important amino acids include carnitine (used in lipid transport within a cell), ornithine, GABA and taurine.

Protein structure

Main articles: Protein structure, Protein primary structure, Protein secondary structure, Protein tertiary structure, and Protein quaternary structure

The particular series of amino acids that form a protein is known as that protein's primary structure. This sequence is determined by the genetic makeup of the individual. It specifies the order of side-chain groups along the linear polypeptide "backbone".

Proteins have two types of well-classified, frequently occurring elements of local structure defined by a particular pattern of hydrogen bonds along the backbone: alpha helix and beta sheet. Their number and arrangement is called the secondary structure of the protein. Alpha helices are regular spirals stabilized by hydrogen bonds between the backbone CO group (carbonyl) of one amino acid residue and the backbone NH group (amide) of the i+4 residue. The spiral has about 3.6 amino acids per turn, and the amino acid side chains stick out from the cylinder of the helix. Beta pleated sheets are formed by backbone hydrogen bonds between individual beta strands each of which is in an "extended", or fully stretched-out, conformation. The strands may lie parallel or antiparallel to each other, and the side-chain direction alternates above and below the sheet. Hemoglobin contains only helices, natural silk is formed of beta pleated sheets, and many enzymes have a pattern of alternating helices and beta-strands. The secondary-structure elements are connected by "loop" or "coil" regions of non-repetitive conformation, which are sometimes quite mobile or disordered but usually adopt a well-defined, stable arrangement.[16]

The overall, compact, 3D structure of a protein is termed its tertiary structure or its "fold". It is formed as result of various attractive forces like hydrogen bonding, disulfide bridges, hydrophobic interactions, hydrophilic interactions, van der Waals force etc.

When two or more polypeptide chains (either of identical or of different sequence) cluster to form a protein, quaternary structure of protein is formed. Quaternary structure is an attribute of polymeric (same-sequence chains) or heteromeric (different-sequence chains) proteins like hemoglobin, which consists of two "alpha" and two "beta" polypeptide chains.

Apoenzymes

An apoenzyme (or, generally, an apoprotein) is the protein without any small-molecule cofactors, substrates, or inhibitors bound. It is often important as an inactive storage, transport, or secretory form of a protein. This is required, for instance, to protect the secretory cell from the activity of that protein. Apoenzymes become active enzymes on addition of a cofactor. Cofactors can be either inorganic (e.g., metal ions and iron-sulfur clusters) or organic compounds, (e.g., [Flavin group|flavin] and heme). Organic cofactors can be either prosthetic groups, which are tightly bound to an enzyme, or coenzymes, which are released from the enzyme's active site during the reaction.

Isoenzymes

Isoenzymes, or isozymes, are multiple forms of an enzyme, with slightly different protein sequence and closely similar but usually not identical functions. They are either products of different genes, or else different products of alternative splicing. They may either be produced in different organs or cell types to perform the same function, or several isoenzymes may be produced in the same cell type under differential regulation to suit the needs of changing development or environment. LDH (lactate dehydrogenase) has multiple isozymes, while fetal hemoglobin is an example of a developmentally regulated isoform of a non-enzymatic protein. The relative levels of isoenzymes in blood can be used to diagnose problems in the organ of secretion .

See also

References

  1. ^ Bunge, M. (1979). Treatise on Basic Philosophy, vol. 4. Ontology II: A World of Systems, p. 61-2. link.
  2. ^ Voon, C. H.; Sam, S. T. (2019). "2.1 Biosensors". Nanobiosensors for Biomolecular Targeting. Elsevier. ISBN 978-0-12-813900-4.
  3. ^ endogeny. (2011) Segen's Medical Dictionary. The Free Dictionary by Farlex. Farlex, Inc. Accessed June 27, 2019.
  4. ^ Green, D. E.; Goldberger, R. (1967). Molecular Insights into the Living Process. New York: Academic Press – via Google Books.
  5. ^ Gayon, J. (1998). "La philosophie et la biologie". In Mattéi, J. F. (ed.). Encyclopédie philosophique universelle. Vol. IV, Le Discours philosophique. Presses Universitaires de France. pp. 2152–2171. ISBN 9782130448631 – via Google Books.
  6. ^ a b c d Slabaugh, Michael R. & Seager, Spencer L. (2007). Organic and Biochemistry for Today (6th ed.). Pacific Grove: Brooks Cole. ISBN 978-0-495-11280-8.
  7. ^ a b Alberts B, Johnson A, Lewis J, Raff M, Roberts K, Wlater P (2002). Molecular biology of the cell (4th ed.). New York: Garland Science. pp. 120–1. ISBN 0-8153-3218-1.
  8. ^ Saenger W (1984). Principles of Nucleic Acid Structure. Springer-Verlag. ISBN 0387907629.
  9. ^ Richardson JS, Schneider B, Murray LW, Kapral GJ, Immormino RM, Headd JJ, Richardson DC, Ham D, Hershkovits E, Williams LD, Keating KS, Pyle AM, Micallef D, Westbrook J, Berman HM (2008). "RNA Backbone: Consensus all-angle conformers and modular string nomenclature". RNA. 14 (3): 465–481. doi:10.1261/rna.657708. PMC 2248255. PMID 18192612.
  10. ^ Kruger K, Grabowski PJ, Zaug AJ, Sands J, Gottschling DE, Cech TR (1982). "Self-splicing RNA: autoexcision and autocyclization of the ribosomal RNA intervening sequence of Tetrahymena". Cell. 31 (1): 147–157. doi:10.1016/0092-8674(82)90414-7. PMID 6297745. S2CID 14787080.
  11. ^ a b Peng, Bo & Yu Qin (June 2009). "Fructose and Satiety". Journal of Nutrition: 6137–42.
  12. ^ Pigman, W.; D. Horton (1972). The Carbohydrates. Vol. 1A. San Diego: Academic Press. p. 3. ISBN 978-0-12-395934-8.
  13. ^ Jin, Tan; Wang He-Fang & Yan Xiu-Ping (2009). "Discrimination of Saccharides with a Fluorescent Molecular Imprinting Sensor Array Based on Phenylboronic Acid Functionalized Mesoporous Silica". Anal. Chem. 81 (13): 5273–80. doi:10.1021/ac900484x. PMID 19507843.
  14. ^ Bo Peng & Yu Qin (2008). "Lipophilic Polymer Membrane Optical Sensor with a Synthetic Receptor for Saccharide Detection". Anal. Chem. 80 (15): 6137–41. doi:10.1021/ac800946p. PMID 18593197.
  15. ^ K. Freudenberg; A.C. Nash, eds. (1968). Constitution and Biosynthesis of Lignin. Berlin: Springer-Verlag.
  16. ^ Richardson, JS (1981). "The Anatomy and Taxonomy of Proteins". Advances in Protein Chemistry. 34: 167–339. doi:10.1016/S0065-3233(08)60520-3. PMID 7020376.

External links

  • provider of a forum for education and information exchange among professionals within drug discovery and related disciplines.

January 20, 2023
biomolecule, biomolecule, biological, molecule, loosely, used, term, molecules, present, organisms, that, essential, more, typically, biological, processes, such, cell, division, morphogenesis, development, include, large, macromolecules, polyelectrolytes, suc. A biomolecule or biological molecule is a loosely used term for molecules present in organisms that are essential to one or more typically biological processes such as cell division morphogenesis or development 1 Biomolecules include large macromolecules or polyelectrolytes such as proteins carbohydrates lipids and nucleic acids as well as small molecules such as primary metabolites secondary metabolites and natural products A more general name for this class of material is biological materials Biomolecules are an important element of living organisms those biomolecules are often endogenous 2 produced within the organism 3 but organisms usually need exogenous biomolecules for example certain nutrients to survive A representation of the 3D structure of myoglobin showing alpha helices represented by ribbons This protein was the first to have its structure solved by X ray crystallography by Max Perutz and Sir John Cowdery Kendrew in 1958 for which they received a Nobel Prize in Chemistry Biology and its subfields of biochemistry and molecular biology study biomolecules and their reactions Most biomolecules are organic compounds and just four elements oxygen carbon hydrogen and nitrogen make up 96 of the human body s mass But many other elements such as the various biometals are also present in small amounts The uniformity of both specific types of molecules the biomolecules and of certain metabolic pathways are invariant features among the wide diversity of life forms thus these biomolecules and metabolic pathways are referred to as biochemical universals 4 or theory of material unity of the living beings a unifying concept in biology along with cell theory and evolution theory 5 Contents 1 Types of biomolecules 2 Nucleosides and nucleotides 2 1 DNA and RNA structure 3 Saccharides 4 Lignin 5 Lipid 6 Amino acids 6 1 Protein structure 6 1 1 Apoenzymes 6 1 2 Isoenzymes 7 See also 8 References 9 External linksTypes of biomolecules EditA diverse range of biomolecules exist including Small molecules Lipids fatty acids glycolipids sterols monosaccharides Vitamins Hormones neurotransmitters Metabolites Monomers oligomers and polymers Biomonomers Bio oligo Biopolymers Polymerization process Covalent bond name between monomersAmino acids Oligopeptides Polypeptides proteins hemoglobin Polycondensation Peptide bondMonosaccharides Oligosaccharides Polysaccharides cellulose Polycondensation Glycosidic bondIsoprene Terpenes Polyterpenes cis 1 4 polyisoprene natural rubber and trans 1 4 polyisoprene gutta percha PolyadditionNucleotides Oligonucleotides Polynucleotides nucleic acids DNA RNA Phosphodiester bondNucleosides and nucleotides EditMain articles Nucleosides and Nucleotides Nucleosides are molecules formed by attaching a nucleobase to a ribose or deoxyribose ring Examples of these include cytidine C uridine U adenosine A guanosine G and thymidine T Nucleosides can be phosphorylated by specific kinases in the cell producing nucleotides Both DNA and RNA are polymers consisting of long linear molecules assembled by polymerase enzymes from repeating structural units or monomers of mononucleotides DNA uses the deoxynucleotides C G A and T while RNA uses the ribonucleotides which have an extra hydroxyl OH group on the pentose ring C G A and U Modified bases are fairly common such as with methyl groups on the base ring as found in ribosomal RNA or transfer RNAs or for discriminating the new from old strands of DNA after replication 6 Each nucleotide is made of an acyclic nitrogenous base a pentose and one to three phosphate groups They contain carbon nitrogen oxygen hydrogen and phosphorus They serve as sources of chemical energy adenosine triphosphate and guanosine triphosphate participate in cellular signaling cyclic guanosine monophosphate and cyclic adenosine monophosphate and are incorporated into important cofactors of enzymatic reactions coenzyme A flavin adenine dinucleotide flavin mononucleotide and nicotinamide adenine dinucleotide phosphate 7 DNA and RNA structure Edit Main articles DNA and Nucleic acid structure DNA structure is dominated by the well known double helix formed by Watson Crick base pairing of C with G and A with T This is known as B form DNA and is overwhelmingly the most favorable and common state of DNA its highly specific and stable base pairing is the basis of reliable genetic information storage DNA can sometimes occur as single strands often needing to be stabilized by single strand binding proteins or as A form or Z form helices and occasionally in more complex 3D structures such as the crossover at Holliday junctions during DNA replication 7 Stereo 3D image of a group I intron ribozyme PDB file 1Y0Q gray lines show base pairs ribbon arrows show double helix regions blue to red from 5 to 3 when defined as end white ribbon is an RNA product RNA in contrast forms large and complex 3D tertiary structures reminiscent of proteins as well as the loose single strands with locally folded regions that constitute messenger RNA molecules Those RNA structures contain many stretches of A form double helix connected into definite 3D arrangements by single stranded loops bulges and junctions 8 Examples are tRNA ribosomes ribozymes and riboswitches These complex structures are facilitated by the fact that RNA backbone has less local flexibility than DNA but a large set of distinct conformations apparently because of both positive and negative interactions of the extra OH on the ribose 9 Structured RNA molecules can do highly specific binding of other molecules and can themselves be recognized specifically in addition they can perform enzymatic catalysis when they are known as ribozymes as initially discovered by Tom Cech and colleagues 10 Saccharides EditMonosaccharides are the simplest form of carbohydrates with only one simple sugar They essentially contain an aldehyde or ketone group in their structure 11 The presence of an aldehyde group in a monosaccharide is indicated by the prefix aldo Similarly a ketone group is denoted by the prefix keto 6 Examples of monosaccharides are the hexoses glucose fructose Trioses Tetroses Heptoses galactose pentoses ribose and deoxyribose Consumed fructose and glucose have different rates of gastric emptying are differentially absorbed and have different metabolic fates providing multiple opportunities for two different saccharides to differentially affect food intake 11 Most saccharides eventually provide fuel for cellular respiration Disaccharides are formed when two monosaccharides or two single simple sugars form a bond with removal of water They can be hydrolyzed to yield their saccharin building blocks by boiling with dilute acid or reacting them with appropriate enzymes 6 Examples of disaccharides include sucrose maltose and lactose Polysaccharides are polymerized monosaccharides or complex carbohydrates They have multiple simple sugars Examples are starch cellulose and glycogen They are generally large and often have a complex branched connectivity Because of their size polysaccharides are not water soluble but their many hydroxy groups become hydrated individually when exposed to water and some polysaccharides form thick colloidal dispersions when heated in water 6 Shorter polysaccharides with 3 to 10 monomers are called oligosaccharides 12 A fluorescent indicator displacement molecular imprinting sensor was developed for discriminating saccharides It successfully discriminated three brands of orange juice beverage 13 The change in fluorescence intensity of the sensing films resulting is directly related to the saccharide concentration 14 Lignin EditLignin is a complex polyphenolic macromolecule composed mainly of beta O4 aryl linkages After cellulose lignin is the second most abundant biopolymer and is one of the primary structural components of most plants It contains subunits derived from p coumaryl alcohol coniferyl alcohol and sinapyl alcohol 15 and is unusual among biomolecules in that it is racemic The lack of optical activity is due to the polymerization of lignin which occurs via free radical coupling reactions in which there is no preference for either configuration at a chiral center Lipid EditLipids oleaginous are chiefly fatty acid esters and are the basic building blocks of biological membranes Another biological role is energy storage e g triglycerides Most lipids consist of a polar or hydrophilic head typically glycerol and one to three non polar or hydrophobic fatty acid tails and therefore they are amphiphilic Fatty acids consist of unbranched chains of carbon atoms that are connected by single bonds alone saturated fatty acids or by both single and double bonds unsaturated fatty acids The chains are usually 14 24 carbon groups long but it is always an even number For lipids present in biological membranes the hydrophilic head is from one of three classes Glycolipids whose heads contain an oligosaccharide with 1 15 saccharide residues Phospholipids whose heads contain a positively charged group that is linked to the tail by a negatively charged phosphate group Sterols whose heads contain a planar steroid ring for example cholesterol Other lipids include prostaglandins and leukotrienes which are both 20 carbon fatty acyl units synthesized from arachidonic acid They are also known as fatty acidsAmino acids EditAmino acids contain both amino and carboxylic acid functional groups In biochemistry the term amino acid is used when referring to those amino acids in which the amino and carboxylate functionalities are attached to the same carbon plus proline which is not actually an amino acid Modified amino acids are sometimes observed in proteins this is usually the result of enzymatic modification after translation protein synthesis For example phosphorylation of serine by kinases and dephosphorylation by phosphatases is an important control mechanism in the cell cycle Only two amino acids other than the standard twenty are known to be incorporated into proteins during translation in certain organisms Selenocysteine is incorporated into some proteins at a UGA codon which is normally a stop codon Pyrrolysine is incorporated into some proteins at a UAG codon For instance in some methanogens in enzymes that are used to produce methane Besides those used in protein synthesis other biologically important amino acids include carnitine used in lipid transport within a cell ornithine GABA and taurine Protein structure Edit Main articles Protein structure Protein primary structure Protein secondary structure Protein tertiary structure and Protein quaternary structure The particular series of amino acids that form a protein is known as that protein s primary structure This sequence is determined by the genetic makeup of the individual It specifies the order of side chain groups along the linear polypeptide backbone Proteins have two types of well classified frequently occurring elements of local structure defined by a particular pattern of hydrogen bonds along the backbone alpha helix and beta sheet Their number and arrangement is called the secondary structure of the protein Alpha helices are regular spirals stabilized by hydrogen bonds between the backbone CO group carbonyl of one amino acid residue and the backbone NH group amide of the i 4 residue The spiral has about 3 6 amino acids per turn and the amino acid side chains stick out from the cylinder of the helix Beta pleated sheets are formed by backbone hydrogen bonds between individual beta strands each of which is in an extended or fully stretched out conformation The strands may lie parallel or antiparallel to each other and the side chain direction alternates above and below the sheet Hemoglobin contains only helices natural silk is formed of beta pleated sheets and many enzymes have a pattern of alternating helices and beta strands The secondary structure elements are connected by loop or coil regions of non repetitive conformation which are sometimes quite mobile or disordered but usually adopt a well defined stable arrangement 16 The overall compact 3D structure of a protein is termed its tertiary structure or its fold It is formed as result of various attractive forces like hydrogen bonding disulfide bridges hydrophobic interactions hydrophilic interactions van der Waals force etc When two or more polypeptide chains either of identical or of different sequence cluster to form a protein quaternary structure of protein is formed Quaternary structure is an attribute of polymeric same sequence chains or heteromeric different sequence chains proteins like hemoglobin which consists of two alpha and two beta polypeptide chains Apoenzymes Edit An apoenzyme or generally an apoprotein is the protein without any small molecule cofactors substrates or inhibitors bound It is often important as an inactive storage transport or secretory form of a protein This is required for instance to protect the secretory cell from the activity of that protein Apoenzymes become active enzymes on addition of a cofactor Cofactors can be either inorganic e g metal ions and iron sulfur clusters or organic compounds e g Flavin group flavin and heme Organic cofactors can be either prosthetic groups which are tightly bound to an enzyme or coenzymes which are released from the enzyme s active site during the reaction Isoenzymes Edit Isoenzymes or isozymes are multiple forms of an enzyme with slightly different protein sequence and closely similar but usually not identical functions They are either products of different genes or else different products of alternative splicing They may either be produced in different organs or cell types to perform the same function or several isoenzymes may be produced in the same cell type under differential regulation to suit the needs of changing development or environment LDH lactate dehydrogenase has multiple isozymes while fetal hemoglobin is an example of a developmentally regulated isoform of a non enzymatic protein The relative levels of isoenzymes in blood can be used to diagnose problems in the organ of secretion See also Edit Biology portalBiomolecular engineering List of biomolecules Metabolism Multi state modeling of biomoleculesReferences Edit Bunge M 1979 Treatise on Basic Philosophy vol 4 Ontology II A World of Systems p 61 2 link Voon C H Sam S T 2019 2 1 Biosensors Nanobiosensors for Biomolecular Targeting Elsevier ISBN 978 0 12 813900 4 endogeny 2011 Segen s Medical Dictionary The Free Dictionary by Farlex Farlex Inc Accessed June 27 2019 Green D E Goldberger R 1967 Molecular Insights into the Living Process New York Academic Press via Google Books Gayon J 1998 La philosophie et la biologie In Mattei J F ed Encyclopedie philosophique universelle Vol IV Le Discours philosophique Presses Universitaires de France pp 2152 2171 ISBN 9782130448631 via Google Books a b c d Slabaugh Michael R amp Seager Spencer L 2007 Organic and Biochemistry for Today 6th ed Pacific Grove Brooks Cole ISBN 978 0 495 11280 8 a b Alberts B Johnson A Lewis J Raff M Roberts K Wlater P 2002 Molecular biology of the cell 4th ed New York Garland Science pp 120 1 ISBN 0 8153 3218 1 Saenger W 1984 Principles of Nucleic Acid Structure Springer Verlag ISBN 0387907629 Richardson JS Schneider B Murray LW Kapral GJ Immormino RM Headd JJ Richardson DC Ham D Hershkovits E Williams LD Keating KS Pyle AM Micallef D Westbrook J Berman HM 2008 RNA Backbone Consensus all angle conformers and modular string nomenclature RNA 14 3 465 481 doi 10 1261 rna 657708 PMC 2248255 PMID 18192612 Kruger K Grabowski PJ Zaug AJ Sands J Gottschling DE Cech TR 1982 Self splicing RNA autoexcision and autocyclization of the ribosomal RNA intervening sequence of Tetrahymena Cell 31 1 147 157 doi 10 1016 0092 8674 82 90414 7 PMID 6297745 S2CID 14787080 a b Peng Bo amp Yu Qin June 2009 Fructose and Satiety Journal of Nutrition 6137 42 Pigman W D Horton 1972 The Carbohydrates Vol 1A San Diego Academic Press p 3 ISBN 978 0 12 395934 8 Jin Tan Wang He Fang amp Yan Xiu Ping 2009 Discrimination of Saccharides with a Fluorescent Molecular Imprinting Sensor Array Based on Phenylboronic Acid Functionalized Mesoporous Silica Anal Chem 81 13 5273 80 doi 10 1021 ac900484x PMID 19507843 Bo Peng amp Yu Qin 2008 Lipophilic Polymer Membrane Optical Sensor with a Synthetic Receptor for Saccharide Detection Anal Chem 80 15 6137 41 doi 10 1021 ac800946p PMID 18593197 K Freudenberg A C Nash eds 1968 Constitution and Biosynthesis of Lignin Berlin Springer Verlag Richardson JS 1981 The Anatomy and Taxonomy of Proteins Advances in Protein Chemistry 34 167 339 doi 10 1016 S0065 3233 08 60520 3 PMID 7020376 External links EditSociety for Biomolecular Sciences provider of a forum for education and information exchange among professionals within drug discovery and related disciplines Retrieved from https en wikipedia org w index php title Biomolecule amp oldid 1119537072, wikipedia, wiki, book, books, library,

article

, read, download, free, free download, mp3, video, mp4, 3gp, jpg, jpeg, gif, png, picture, music, song, movie, book, game, games.