Bioinorganic chemistry

Bioinorganic chemistry is a field that examines the role of metals in biology. Bioinorganic chemistry includes the study of both natural phenomena such as the behavior of metalloproteins as well artificially introduced metals, including those that are non-essential, in medicine and toxicology. Many biological processes such as respiration depend upon molecules that fall within the realm of inorganic chemistry. The discipline also includes the study of inorganic models or mimics that imitate the behaviour of metalloproteins.[1]

As a mix of biochemistry and inorganic chemistry, bioinorganic chemistry is important in elucidating the implications of electron-transfer proteins, substrate bindings and activation, atom and group transfer chemistry as well as metal properties in biological chemistry.

Contents

Composition of living organisms

About 99% of mammals' mass are the elements carbon, nitrogen, calcium, sodium, chlorine, potassium, hydrogen, phosphorus, oxygen and sulfur.[2] The organic compounds (proteins, lipids and carbohydrates) contain the majority of the carbon and nitrogen and most of the oxygen and hydrogen is present as water.[2] The entire collection of metal-containing biomolecules in a cell is called the metallome.

History

Paul Ehrlich used organoarsenic (“arsenicals”) for the treatment of syphilis, demonstrating the relevance of metals, or at least metalloids, to medicine, that blossomed with Rosenberg’s discovery of the anti-cancer activity of cisplatin (cis-PtCl2(NH3)2). The first protein ever crystallized (see James B. Sumner) was urease, later shown to contain nickel at its active site. Vitamin B12, the cure for pernicious anemia was shown crystallographically by Dorothy Crowfoot Hodgkin to consist of a cobalt in a corrin macrocycle. The Watson-Crick structure for DNA demonstrated the key structural role played by phosphate-containing polymers.

Themes in bioinorganic chemistry

Several distinct systems are of identifiable in bioinorganic chemistry. Major areas include:

Metal ion transport and storage

This topic covers a diverse collection of ion channels, ion pumps (e.g. NaKATPase), vacuoles, siderophores, and other proteins and small molecules which control the concentration of metal ions in the cells. One issue is that many metals that are metabolically required are not readily available owing to solubility or scarcity. Organisms have developed a number of strategies for collecting such elements and transporting them.

Enzymology

Many reactions in life sciences involve water and metal ions are often at the catalytic centers (active sites) for these enzymes, i.e. these are metalloproteins. Often the reacting water is a ligand (see metal aquo complex). Examples of hydrolase enzymes are carbonic anhydrase, metallophosphatases, and metalloproteinases. Bioinorganic chemist seek to understand and replicate the function of these metalloproteins.

Metal-containing electron transfer proteins are also common. They can be organized into three major classes: iron-sulfur proteins (such as rubredoxins, ferredoxins, and Rieske proteins), blue copper proteins, and cytochromes. These electron transport proteins are complementary to the non-metal electron transporters nicotinamide adenine dinucleotide (NAD) and flavin adenine dinucleotide (FAD).

Oxygen transport and activation proteins

Aerobic life make extensive use of metals such as iron, copper, and manganese. Heme is utilized by red blood cells in the form of hemoglobin for oxygen transport and is perhaps the most recognized metal system in biology. Other oxygen transport systems include myoglobin, hemocyanin, and hemerythrin. Oxidases and oxygenases are metal systems found throughout nature that take advantage of oxygen to carry out important reactions such as energy generation in cytochrome c oxidase or small molecule oxidation in cytochrome P450 oxidases or methane monooxygenase. Some metalloproteins are designed to protect a biological system from the potentially harmful effects of oxygen and other reactive oxygen-containing molecules such as hydrogen peroxide. These systems include peroxidases, catalases, and superoxide dismutases. A complementary metalloprotein to those that react with oxygen is the oxygen evolving complex present in plants. This system is part of the complex protein machinery that produces oxygen as plants perform photosynthesis.

Bioorganometallic chemistry

Bioorganometallic systems includes the hydrogenases and methylcobalamin as examples of naturally occurring organometallic compounds. This area is more focused on the utilization of metals by unicellular organisms. Bioorganometallic compounds are significant in environmental chemistry.[3]

Metals in medicine

A surprising number of drugs contain metals. This theme relies ons the study of the design and mechanism of action of metal-containing pharmaceuticals, and compounds that interact with endogenous metal ions in enzyme active sites. This diverse field includes the platinum and ruthenium anti-cancer drugs (e.g. cisplatin), chelating agents, gold drug chaperones, and gadolinium contrast agents. Lithium carbonate has been used to treat the manic phase of bipolar disorder. Antiarthritic drugs, e.g. auranofin are based on gold.

Environmental chemistry

Environmental chemistry traditionally emphasizes the interaction of heavy metals with organisms. Methylmercury has caused major disaster called Minamata disease. Arsenic poisoning is a widespread problem owing largely to arsenic contamination of groundwater, which affects many millions of people in developing countries. The metabolism of mercury- and arsenic-containing compounds involves cobalamin-based enzymes.

Types of inorganic elements in biology

Alkali and alkaline earth metals

The abundant inorganic elements act as ionic electrolytes. The most important ions are sodium, potassium, calcium, magnesium, chloride, phosphate, and the organic ion bicarbonate. The maintenance of precise gradients across cell membranes maintains osmotic pressure and pH.[5] Ions are also critical for nerves and muscles, as action potentials in these tissues are produced by the exchange of electrolytes between the extracellular fluid and the cytosol.[6] Electrolytes enter and leave cells through proteins in the cell membrane called ion channels. For example, muscle contraction depends upon the movement of calcium, sodium and potassium through ion channels in the cell membrane and T-tubules.[7]

Transition metals

The transition metals are usually present as trace elements in organisms, with zinc and iron being most abundant.[8][9] These metals are used in some proteins as cofactors and are essential for the activity of enzymes such as catalase and oxygen-carrier proteins such as hemoglobin.[10] These cofactors are bound tightly to a specific protein; although enzyme cofactors can be modified during catalysis, cofactors always return to their original state after catalysis has taken place. The metal micronutrients are taken up into organisms by specific transporters and bound to storage proteins such as ferritin or metallothionein when not being used.[11][12]

Main group compounds

Many other elements aside from metals are bio-active. Sulfur and phosphorus are required for all life. Phosphorus is almost exclusively exists as phosphate and its various ester]]s. Sulfur exists in a variety of oxidation states, ranging from sulfate (SO42-) down to sulfide (S2-). Selenium is a trace element involved in proteins that are antioxidants.

External links

References

  1. ^ Stephen J. Lippard, Jeremy M. Berg, Principles of Bioinorganic Chemistry, University Science Books, 1994, ISBN 0-935702-72-5
  2. ^ a b Heymsfield S, Waki M, Kehayias J, Lichtman S, Dilmanian F, Kamen Y, Wang J, Pierson R (1991). "Chemical and elemental analysis of humans in vivo using improved body composition models". Am J Physiol 261 (2 Pt 1): E190–8. PMID 1872381. 
  3. ^ Sigel, A.; Sigel, H.; Sigel, R.K.O. (Editors) (2010). Organometallics in Environment and Toxicology. Metal Ions in Life Sciences. 7. Cambridge: RSC publishing. ISBN 978-1-84755-177-1. 
  4. ^ Greenwood, Norman N.; Earnshaw, Alan (1997). Chemistry of the Elements (2nd ed.). Oxford: Butterworth-Heinemann. ISBN 0080379419. 
  5. ^ Sychrová H (2004). "Yeast as a model organism to study transport and homeostasis of alkali metal cations" (PDF). Physiol Res 53 Suppl 1: S91–8. PMID 15119939. http://www.biomed.cas.cz/physiolres/pdf/53%20Suppl%201/53_S91.pdf. 
  6. ^ Levitan I (1988). "Modulation of ion channels in neurons and other cells". Annu Rev Neurosci 11: 119–36. doi:10.1146/annurev.ne.11.030188.001003. PMID 2452594. 
  7. ^ Dulhunty A (2006). "Excitation-contraction coupling from the 1950s into the new millennium". Clin Exp Pharmacol Physiol 33 (9): 763–72. doi:10.1111/j.1440-1681.2006.04441.x. PMID 16922804. 
  8. ^ Mahan D, Shields R (1998). "Macro- and micromineral composition of pigs from birth to 145 kilograms of body weight". J Anim Sci 76 (2): 506–12. PMID 9498359. http://jas.fass.org/cgi/reprint/76/2/506. 
  9. ^ Husted S, Mikkelsen B, Jensen J, Nielsen N (2004). "Elemental fingerprint analysis of barley (Hordeum vulgare) using inductively coupled plasma mass spectrometry, isotope-ratio mass spectrometry, and multivariate statistics". Anal Bioanal Chem 378 (1): 171–82. doi:10.1007/s00216-003-2219-0. PMID 14551660. 
  10. ^ Finney L, O'Halloran T (2003). "Transition metal speciation in the cell: insights from the chemistry of metal ion receptors". Science 300 (5621): 931–6. doi:10.1126/science.1085049. PMID 12738850. 
  11. ^ Cousins R, Liuzzi J, Lichten L (2006). "Mammalian zinc transport, trafficking, and signals". J Biol Chem 281 (34): 24085–9. doi:10.1074/jbc.R600011200. PMID 16793761. http://www.jbc.org/cgi/content/full/281/34/24085. 
  12. ^ Dunn L, Rahmanto Y, Richardson D (2007). "Iron uptake and metabolism in the new millennium". Trends Cell Biol 17 (2): 93–100. doi:10.1016/j.tcb.2006.12.003. PMID 17194590. 

Some books on bioinorganic chemistry