Macromolecule

A macromolecule is a very large molecule important to biological processes, such as a protein or nucleic acid. It is composed of thousands of covalently bonded atoms. Many macromolecules are polymers of smaller molecules called monomers. The most common macromolecules in biochemistry are biopolymers (nucleic acids, proteins, and carbohydrates) and large non-polymeric molecules such as lipids, nanogels and macrocycles.[1] Synthetic fibers and experimental materials such as carbon nanotubes[2][3] are also examples of macromolecules.

Definition

IUPAC definition

Macromolecule
Large molecule

A molecule of high relative molecular mass, the structure of which essentially
comprises the multiple repetition of units derived, actually or conceptually, from
molecules of low relative molecular mass.

Notes

1. In many cases, especially for synthetic polymers, a molecule can be regarded
as having a high relative molecular mass if the addition or removal of one or a
few of the units has a negligible effect on the molecular properties. This statement
fails in the case of certain macromolecules for which the properties may be
critically dependent on fine details of the molecular structure.
2. If a part or the whole of the molecule fits into this definition, it may be described
as either macromolecular or polymeric, or by polymer used adjectivally.[4]

The term macromolecule (macro- + molecule) was coined by Nobel laureate Hermann Staudinger in the 1920s, although his first relevant publication on this field only mentions high molecular compounds (in excess of 1,000 atoms).[5] At that time the term polymer, as introduced by Berzelius in 1832, had a different meaning from that of today: it simply was another form of isomerism for example with benzene and acetylene and had little to do with size.[6]

Usage of the term to describe large molecules varies among the disciplines. For example, while biology refers to macromolecules as the four large molecules comprising living things, in chemistry, the term may refer to aggregates of two or more molecules held together by intermolecular forces rather than covalent bonds but which do not readily dissociate.[7]

According to the standard IUPAC definition, the term macromolecule as used in polymer science refers only to a single molecule. For example, a single polymeric molecule is appropriately described as a "macromolecule" or "polymer molecule" rather than a "polymer," which suggests a substance composed of macromolecules.[8]

Because of their size, macromolecules are not conveniently described in terms of stoichiometry alone. The structure of simple macromolecules, such as homopolymers, may be described in terms of the individual monomer subunit and total molecular mass. Complicated biomacromolecules, on the other hand, require multi-faceted structural description such as the hierarchy of structures used to describe proteins. In British English, the word "macromolecule" tends to be called "high polymer".

Properties

Macromolecules often have unusual physical properties that do not occur for smaller molecules.

Another common macromolecular property that does not characterize smaller molecules is their relative insolubility in water and similar solvents, instead forming colloids. Many require salts or particular ions to dissolve in water. Similarly, many proteins will denature if the solute concentration of their solution is too high or too low.

High concentrations of macromolecules in a solution can alter the rates and equilibrium constants of the reactions of other macromolecules, through an effect known as macromolecular crowding.[9] This comes from macromolecules excluding other molecules from a large part of the volume of the solution, thereby increasing the effective concentrations of these molecules.

Linear biopolymers

All living organisms are dependent on three essential biopolymers for their biological functions: DNA, RNA and proteins.[10] Each of these molecules is required for life since each plays a distinct, indispensable role in the cell.[11] The simple summary is that DNA makes RNA, and then RNA makes proteins.

DNA, RNA, and proteins all consist of a repeating structure of related building blocks (nucleotides in the case of DNA and RNA, amino acids in the case of proteins). In general, they are all unbranched polymers, and so can be represented in the form of a string. Indeed, they can be viewed as a string of beads, with each bead representing a single nucleotide or amino acid monomer linked together through covalent chemical bonds into a very long chain.

In most cases, the monomers within the chain have a strong propensity to interact with other amino acids or nucleotides. In DNA and RNA, this can take the form of Watson–Crick base pairs (G–C and A–T or A–U), although many more complicated interactions can and do occur.

Structural features

DNA RNA Proteins
Encodes genetic information Yes Yes No
Catalyzes biological reactions No Yes Yes
Building blocks (type) Nucleotides Nucleotides Amino acids
Building blocks (number) 4 4 20
Strandedness Double Single
Structure Double helix Complex Complex
Stability to degradation High Variable Variable
Repair systems Yes No No

Because of the double-stranded nature of DNA, essentially all of the nucleotides take the form of Watson–Crick base pairs between nucleotides on the two complementary strands of the double helix.

In contrast, both RNA and proteins are normally single-stranded. Therefore, they are not constrained by the regular geometry of the DNA double helix, and so fold into complex three-dimensional shapes dependent on their sequence. These different shapes are responsible for many of the common properties of RNA and proteins, including the formation of specific binding pockets, and the ability to catalyse biochemical reactions.

DNA is optimised for encoding information

DNA is an information storage macromolecule that encodes the complete set of instructions (the genome) that are required to assemble, maintain, and reproduce every living organism.[12]

DNA and RNA are both capable of encoding genetic information, because there are biochemical mechanisms which read the information coded within a DNA or RNA sequence and use it to generate a specified protein. On the other hand, the sequence information of a protein molecule is not used by cells to functionally encode genetic information.[1]:5

DNA has three primary attributes that allow it to be far better than RNA at encoding genetic information. First, it is normally double-stranded, so that there are a minimum of two copies of the information encoding each gene in every cell. Second, DNA has a much greater stability against breakdown than does RNA, an attribute primarily associated with the absence of the 2'-hydroxyl group within every nucleotide of DNA. Third, highly sophisticated DNA surveillance and repair systems are present which monitor damage to the DNA and repair the sequence when necessary. Analogous systems have not evolved for repairing damaged RNA molecules. Consequently, chromosomes can contain many billions of atoms, arranged in a specific chemical structure.

Proteins are optimised for catalysis

Proteins are functional macromolecules responsible for catalysing the biochemical reactions that sustain life.[1]:3 Proteins carry out all functions of an organism, for example photosynthesis, neural function, vision, and movement.[13]

The single-stranded nature of protein molecules, together with their composition of 20 or more different amino acid building blocks, allows them to fold in to a vast number of different three-dimensional shapes, while providing binding pockets through which they can specifically interact with all manner of molecules. In addition, the chemical diversity of the different amino acids, together with different chemical environments afforded by local 3D structure, enables many proteins to act as enzymes, catalyzing a wide range of specific biochemical transformations within cells. In addition, proteins have evolved the ability to bind a wide range of cofactors and coenzymes, smaller molecules that can endow the protein with specific activities beyond those associated with the polypeptide chain alone.

RNA is multifunctional

RNA is multifunctional, its primary function is to encode proteins, according to the instructions within a cell's DNA.[1]:5 They control and regulate many aspects of protein synthesis in eukaryotes.

RNA encodes genetic information that can be translated into the amino acid sequence of proteins, as evidenced by the messenger RNA molecules present within every cell, and the RNA genomes of a large number of viruses. The single-stranded nature of RNA, together with tendency for rapid breakdown and a lack of repair systems means that RNA is not so well suited for the long-term storage of genetic information as is DNA.

In addition, RNA is a single-stranded polymer that can, like proteins, fold into a very large number of three-dimensional structures. Some of these structures provide binding sites for other molecules and chemically active centers that can catalyze specific chemical reactions on those bound molecules. The limited number of different building blocks of RNA (4 nucleotides vs >20 amino acids in proteins), together with their lack of chemical diversity, results in catalytic RNA (ribozymes) being generally less-effective catalysts than proteins for most biological reactions.

The Major Macromolecules:

Macromolecule

(Polymer)

Building Block

(Monomer)

Bonds that Join them
Proteins Amino acids Peptide
Nucleic acids Phosphodiester
DNA Nucleotides (a phosphate, ribose, and a base- adenine, guanine, thymine, or cytosine)
RNA Nucleotides (a phosphate, ribose, and a base- adenine, guanine, uracil, or cytosine)
Polysaccharides Monosaccharides Glycosidic
Lipids unlike the other macromolecules, lipids are not defined by chemical Structure. Lipids are any organic nonpolar molecule. Some lipids are held together by ester bonds; some are huge aggregates of small molecules held together by hydrophobic interactions.
Carbohydrates carbon, hydrogen, and oxygen
Major protein Complexes?

Branched biopolymers

Carbohydrate macromolecules (polysaccharides) are formed from polymers of monosaccharides.[1]:11 Because monosaccharides have multiple functional groups, polysaccharides can form linear polymers (e.g. cellulose) or complex branched structures (e.g. glycogen). Polysaccharides perform numerous roles in living organisms, acting as energy stores (e.g. starch) and as structural components (e.g. chitin in arthropods and fungi). Many carbohydrates contain modified monosaccharide units that have had functional groups replaced or removed.

Polyphenols consist of a branched structure of multiple phenolic subunits. They can perform structural roles (e.g. lignin) as well as roles as secondary metabolites involved in signalling, pigmentation and defense.

Synthetic macromolecules

Some examples of macromolecules are synthetic polymers (plastics, synthetic fibers, and synthetic rubber), graphene, and carbon nanotubes. Polymers may be prepared from inorganic matter as well as for instance in inorganic polymers and geopolymers. The incorporation of inorganic elements enables the tunability of properties and/or responsive behavior as for instance in smart inorganic polymers.

See also

  • List of biophysically important macromolecular crystal structures
  • Small molecule
  • Soft matter

References

  1. Stryer L, Berg JM, Tymoczko JL (2002). Biochemistry (5th ed.). San Francisco: W.H. Freeman. ISBN 978-0-7167-4955-4.
  2. Life cycle of a plastic product Archived 2010-03-17 at the Wayback Machine. Americanchemistry.com. Retrieved on 2011-07-01.
  3. Gullapalli, S.; Wong, M.S. (2011). "Nanotechnology: A Guide to Nano-Objects" (PDF). Chemical Engineering Progress. 107 (5): 28–32. Archived from the original (PDF) on 2012-08-13. Retrieved 2015-06-28.
  4. Jenkins, A. D; Kratochvíl, P; Stepto, R. F. T; Suter, U. W (1996). "Glossary of basic terms in polymer science (IUPAC Recommendations 1996)" (PDF). Pure and Applied Chemistry. 68 (12): 2287–2311. doi:10.1351/pac199668122287. S2CID 98774337. Archived from the original (PDF) on 2016-03-04. Retrieved 2013-07-27.
  5. Staudinger, H.; Fritschi, J. (1922). "Über Isopren und Kautschuk. 5. Mitteilung. Über die Hydrierung des Kautschuks und über seine Konstitution". Helvetica Chimica Acta. 5 (5): 785. doi:10.1002/hlca.19220050517.
  6. Jensen, William B. (2008). "The Origin of the Polymer Concept". Journal of Chemical Education. 85 (5): 624. Bibcode:2008JChEd..85..624J. doi:10.1021/ed085p624.
  7. van Holde, K.E. (1998) Principles of Physical Biochemistry Prentice Hall: New Jersey, ISBN 0-13-720459-0
  8. Jenkins, A. D.; Kratochvíl, P.; Stepto, R. F. T.; Suter, U. W. (1996). "Glossary of Basic Terms in Polymer Science" (PDF). Pure and Applied Chemistry. 68 (12): 2287. doi:10.1351/pac199668122287. S2CID 98774337. Archived from the original (PDF) on 2007-02-23.
  9. Minton AP (2006). "How can biochemical reactions within cells differ from those in test tubes?". J. Cell Sci. 119 (Pt 14): 2863–9. doi:10.1242/jcs.03063. PMID 16825427.
  10. Berg, Jeremy Mark; Tymoczko, John L.; Stryer, Lubert (2010). Biochemistry, 7th ed. (Biochemistry (Berg)). W.H. Freeman & Company. ISBN 978-1-4292-2936-4. Fifth edition available online through the NCBI Bookshelf: link
  11. Walter, Peter; Alberts, Bruce; Johnson, Alexander S.; Lewis, Julian; Raff, Martin C.; Roberts, Keith (2008). Molecular Biology of the Cell (5th edition, Extended version). New York: Garland Science. ISBN 978-0-8153-4111-6.. Fourth edition is available online through the NCBI Bookshelf: link
  12. Golnick, Larry; Wheelis, Mark. (1991-08-14). The Cartoon Guide to Genetics. Collins Reference. ISBN 978-0-06-273099-2.
  13. Takemura, Masaharu (2009). The Manga Guide to Molecular Biology. No Starch Press. ISBN 978-1-59327-202-9.
  14. Roland E. Bauer; Volker Enkelmann; Uwe M. Wiesler; Alexander J. Berresheim; Klaus Müllen (2002). "Single-Crystal Structures of Polyphenylene Dendrimers". Chemistry: A European Journal. 8 (17): 3858–3864. doi:10.1002/1521-3765(20020902)8:17<3858::AID-CHEM3858>3.0.CO;2-5. PMID 12203280.
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