Tetracycline

This article is about the specific antibiotic called tetracycline. For the family of antibiotics, see Tetracycline antibiotics.
Tetracycline
Clinical data
Pronunciation /ˌtɛtrəˈskln/
Trade names Sumycin
AHFS/Drugs.com Monograph
MedlinePlus a682098
License data
Pregnancy
category
  • AU: D
  • US: D (Evidence of risk)
Routes of
administration		 oral, topical (skin and eye), intramuscular, intravenous
ATC code A01AB13 (WHO) D06AA04 (WHO) J01AA07 (WHO) S01AA09 (WHO) S02AA08 (WHO) S03AA02 (WHO) QG01AA90 (WHO) QG51AA02 (WHO) QJ51AA07 (WHO)
Legal status
Legal status
  • ℞ (Prescription only)
Pharmacokinetic data
Bioavailability 75%
Metabolism Not metabolised
Biological half-life 8-11 hours, 57-108 hours (kidney impairment)
Excretion Urine (>60%), feces
Identifiers
CAS Number 60-54-8 YesY
64-75-5 (hydrochloride)
PubChem (CID) 643969
DrugBank DB00759 YesY
ChemSpider 10257122 YesY
UNII F8VB5M810T YesY
KEGG D00201 YesY
ChEBI CHEBI:27902 YesY
ChEMBL CHEMBL1440 YesY
ECHA InfoCard 100.000.438
Chemical and physical data
Formula C22H24N2O8
Molar mass 444.435 g/mol
3D model (Jmol) Interactive image
  (verify)

Tetracycline is an antibiotic used to treat a number of bacterial infections. It is commonly used to treat acne and rosacea. Historically it was important in reducing the number of deaths from cholera.

A broad-spectrum antibiotic of the polyketide class, it is produced by the actinobacterial genus Streptomyces. It acts by inhibiting protein synthesis.

Tetracycline is on the World Health Organization's List of Essential Medicines, a list of the most important medication needed in a basic health system.[1] It is marketed under the brand names Sumycin, Tetracyn, Lymecycline, and Panmycin, among others. Actisite is a thread-like fiber formulation used in dental applications. It is also used to produce several semisynthetic derivatives, which together are known as the tetracycline antibiotics. The term "tetracycline" is also used to denote the four-ring system of this compound; "tetracyclines" are related substances that contain the same four-ring system.

Medical uses

It is first-line therapy for rocky mountain spotted fever (Rickettsia), Lyme disease (B. burgdorferi), Q fever (Coxiella), psittacosis and lymphogranuloma venereum (Chlamydia), mycoplasma pneumoniae and to eradicate nasal carriage of meningococci. Tetracycline tablets were used in the plague outbreak in India in 1994.[2]

Spectrum of bacterial susceptibility

Tetracyclines have a broad spectrum of antibiotic action. Originally, they possessed some level of bacteriostatic activity against almost all medically relevant aerobic and anaerobic bacterial genera, both Gram-positive and Gram-negative, with a few exceptions, such as Pseudomonas aeruginosa and Proteus spp., which display intrinsic resistance. However, acquired (as opposed to inherent) resistance has proliferated in many pathogenic organisms and greatly eroded the formerly vast versatility of this group of antibiotics. Resistance amongst Staphylococcus spp., Streptococcus spp., Neisseria gonorrhoeae, anaerobes, members of the Enterobacteriaceae and several other previously sensitive organisms is now quite common. Tetracyclines remain especially useful in the management of infections by certain obligately intracellular bacterial pathogens such as Chlamydia, Mycoplasma and Rickettsia. They are also of value in spirochaetal infections, such as syphilis, leptospirosis and Lyme disease. Certain rare or exotic infections, including anthrax, plague and brucellosis, are also susceptible to tetracyclines. These agents also have activity against certain eukaryotic parasites, including those responsible for diseases such as malaria and balantidiasis. The following represents MIC susceptibility data for a few medically significant microorganisms:

Mechanisms of resistance

Bacteria usually acquire resistance to tetracycline from horizontal transfer of a gene that either encodes an efflux pump or a ribosomal protection protein. Efflux pumps actively eject tetracycline from the cell, preventing the buildup of an inhibitory concentration of tetracycline in the cytoplasm.[4] Ribosomal protection proteins interact with the ribosome and dislodge tetracycline from the ribosome, allowing for translation to continue.[5]

Side effects

See also: Tooth bleaching

Use of the tetracycline antibiotics group is problematic; they can:

Caution should be exercised in long-term use with breastfeeding. Short-term use is safe; bioavailability in milk is low to nil.[6] According to the U.S. FDA, there are case reports of Stevens–Johnson syndrome, toxic epidermal necrolysis and erythema multiforme associated with doxycyline use but a causative role has not been established.[7]

Other uses

Tetracycline hydrochloride is available as yellow crystalline powder

Since tetracycline is absorbed into bone, it is used as a marker of bone growth for biopsies in humans. Tetracycline labeling is used to determine the amount of bone growth within a certain period of time, usually a period of approximately 21 days. Tetracycline is incorporated into mineralizing bone and can be detected by its fluorescence.[8] In "double tetracycline labeling", a second dose is given 11–14 days after the first dose, and the amount of bone formed during that interval can be calculated by measuring the distance between the two fluorescent labels.[9]

Tetracycline is also used as a biomarker in wildlife to detect consumption of medicine- or vaccine-containing baits.[10]

In genetic engineering, tetracycline is used in transcriptional activation. It is also one of the antibiotics used to treat ulcers caused by bacterial infections. In cancer research at Harvard Medical School, tetracycline has been used to switch off leukemia in genetically altered mice, and to do so reliably, when added to their drinking water.[11] The mechanism of action for the antibacterial effect of tetracyclines relies on disrupting protein translation in bacteria, thereby damaging the ability of microbes to grow and repair; however protein translation is also disrupted in eukaryotic mitochondria leading to effects that may confound experimental results.[12][13]

A technique being developed for the control of the mosquito species Aedes aegypti uses a strain that is genetically modified to require tetracycline to develop beyond the larval stage. Modified males raised in a laboratory will develop normally as they are supplied with this chemical and can be released into the wild. Their subsequent offspring will inherit this trait, but will find no tetracycline in their environment and so will never develop into adults.[14]

Cell culture

Tetracycline is used in cell biology as a selective agent in cell culture systems. It is toxic to prokaryotic and eukaryotic cells and selects for cells harboring the bacterial tetr gene, which encodes a 399-amino-acid, membrane-associated protein. This protein actively exports tetracycline from the cell, rendering cells harboring this gene more resistant to the drug. The yellow crystalline powder can be dissolved in water (20 mg/ml) or ethanol (5 mg/ml), and is routinely used at 10 mg/l in cell culture. In cell culture at 37 °C (99 °F), it is stable for days, with a half-life of approximately 24 hours.

Mechanism of action

Tetracycline inhibits protein synthesis by blocking the attachment of charged aminoacyl-tRNA to the A site on the ribosome. Tetracycline binds to the 30S subunit of microbial ribosomes. Thus, it prevents introduction of new amino acids to the nascent peptide chain.[15] The action is usually inhibitory and reversible upon withdrawal of the drug. Mammalian cells are less vulnerable to the effect of tetracyclines, despite the fact that tetracycline binds to the small ribosomal subunit of both prokaryotes and eukaryotes (30S and 40S respectively). This is because bacteria actively pump tetracycline into their cytoplasm, even against a concentration gradient, whereas mammalian cells do not. This accounts for the relatively small off-site effect of tetracycline on human cells.[16]

History

The tetracyclines, a large family of antibiotics, were discovered as natural products by Benjamin Minge Duggar in 1945 and first prescribed in 1948.[17] Under Yellapragada Subbarow, Benjamin Duggar made his discovery of the first tetracycline antibiotic, chlortetracycline (Aureomycin), at Lederle Laboratories in 1945.[18]

In 1950, Harvard University professor Robert Burns Woodward determined the chemical structure of the related substance, oxytetracycline (Terramycin); the patent protection for its fermentation and production was also first issued in 1950. A research team of eight scientists (K.J. Brunings, Francis A. Hochstein, Frederick J. Pilgrim C.R. Stephens, Lloyd Hillyard Conover, Abraham Bavley, Richard Pasternack, and Peter P. Regna) at Pfizer,[19][20] in collaboration with Woodward, participated in the two-year research leading to the discovery.[21]

Pfizer was of the view that it deserved the right to a patent on tetracycline and filed its Conover application in October 1952. Cyanamid filed its Boothe-Morton application for similar rights in March 1953, while Heyden Chemicals filed its Minieri application in September 1953, named after scientist P. Paul Minieri, to obtain a patent on tetracycline and its fermentation process. This resulted in tetracycline litigation in which the winner would have to prove beyond reasonable doubt of priority invention and tetracycline’s natural state.[22]

Nubian mummies studied in the 1990s were found to contain significant levels of tetracycline; the beer brewed at the time could have been the source.[23] Tetracycline sparked the development of many chemically altered antibiotics, so has proved to be one of the most important discoveries made in the field of antibiotics. It is used to treat many Gram-positive and Gram-negative bacteria. Like some other antibiotics, it is also used in the treatment of acne.

Price

According to data from EvaluatePharma and published in the Boston Globe, the price of tetracycline rose from $0.06 per 250 miligram pill in 2013 to $4.06 a pill in 2015.[24] The Globe described the "big price hikes of some generic drugs" as a "relatively new phenomenon" which has left most pharmacists "grappling" with large upswings" in the "costs of generics, with 'overnight' price changes sometimes exceeding 1,000 percent."[24]

Notes

  1. "WHO Model List of EssentialMedicines" (PDF). World Health Organization. October 2013. Retrieved 22 April 2014.
  2. Lippincott's Illustrated Reviews: Pharmacology, 4th ed. Harvery RA, Champe, PC. Lippincott, Williams & Wilkins, 2009
  3. http://www.toku-e.com/Assets/MIC/Tetracycline%20hydrochloride.pdf
  4. Chopra I, Roberts M; Roberts (June 2001). "Tetracycline Antibiotics: Mode of Action, Applications, Molecular Biology, and Epidemiology of Bacterial Resistance". Microbiol. Mol. Biol. Rev. 65 (2): 232–260. doi:10.1128/MMBR.65.2.232-260.2001. PMC 99026Freely accessible. PMID 11381101.
  5. Connell SR, Tracz DM, Nierhaus KH, Taylor DE (December 2003). "Ribosomal Protection Proteins and Their Mechanism of Tetracycline Resistance". Antimicrob. Agents Chemother. 47 (12): 3675–3681. doi:10.1128/AAC.47.12.3675-3681.2003. PMC 296194Freely accessible. PMID 14638464.
  6. Riordan,Jan."Breastfeeding & Human Lactation",Jones & Bartlett,2010 p.179
  7. FDA Adverse Events Reporting System Retrieved on January 14, 2011
  8. Mayton CA. Tetracycline labeling of bone
  9. The Johns Hopkins Medical Institutions. > Tetracycline Labeling Last updated January 8, 2001.
  10. Olson CA, Mitchell KD, Werner PA (October 2000). "Bait ingestion by free-ranging raccoons and nontarget species in an oral rabies vaccine field trial in Florida". J. Wildl. Dis. 36 (4): 734–43. doi:10.7589/0090-3558-36.4.734. PMID 11085436.
  11. William J. Cromie (February 10, 2000). "Researchers Switch Cancer Off and On -- In Mice". Harvard Gazette. Retrieved 2008-10-25.
  12. Moullan N, Mouchiroud L, Wang X, Ryu D, Williams EG, Mottis A, Jovaisaite V, Frochaux MV, Quiros PM, Deplancke B, Houtkooper RH, Auwerx J (2015). "Tetracyclines Disturb Mitochondrial Function across Eukaryotic Models: A Call for Caution in Biomedical Research.". Celll Reports. 10 (10): 1681–91. doi:10.1016/j.celrep.2015.02.034. PMID 25772356.
  13. Chatzispyrou IA, Held NM, Mouchiroud L, Auwerx J, Houtkooper RH (2015). "Tetracycline antibiotics impair mitochondrial function and its experimental use confounds research.". Cancer Research. 72 (21): 4446–9. doi:10.1158/0008-5472.CAN-15-1626. PMID 26475870.
  14. Conal Urquhart (15 July 2012). "Can GM mosquitoes rid the world of a major killer?". The Observer. Retrieved 2012-07-15.
  15. Mehta, Akul (2011-05-27). "Mechanism of Action of Tetracyclines". Pharmaxchange.info. Retrieved 2012-06-07.
  16. Kenneth Todar, Antimicrobial Agents in the Treatment of Infectious Disease. Online Textbook of Bacteriology. 2012. http://textbookofbacteriology.net/antimicrobial_4.html
  17. Klajn, Rafal, Chemistry and chemical biology of tetracyclines, retrieved 20 June 2007.
  18. Jukes, Thomas H. Some historical notes on chlortetracycline. Reviews of Infectious Diseases 7(5):702-707 (1985).
  19. "Coronagraph Mounts Done". The Science News. 62 (6): 83. 1952. doi:10.2307/3931295. JSTOR 3931295.
  20. "Scientists Discover Terramycin's Secret: Its Complex Structure".
  21. Prior to 1952, neither the molecular structure of Terramycin nor that of Aureomycin was known. In the spring of 1952, the Pfizer team succeeded in ascertaining the structures of both Terramycin and Aureomycin. Shortly thereafter, Lloyd Hillyard Conover discovered that another antibiotic, tetracycline, could be produced by the deschlorination of Aureomycin. Pfizer filed the application for a product and process patent on tetracycline in October 1952, and in March 1953 Cyanamid filed its Boothe-Morton application for a similar patent. In addition to these two applications, in September 1953, Heyden Chemicals filed for a patent on tetracycline and the fermentation process for producing it in the name of P. Paul Minieri, and in October 1953, Bristol filed a similar application under the name of "Heinemann". Because of an agreement among the major drug companies to cross-license tetracyline, Fair Trade Practices litigation was initiated which was not resolved until 1982. The Federal Trade Commission argued that Pfizer, American Cyanamid (successor to Heyden), Bristol-Myers and others had conspired to fix prices for the new antibiotic. The FTC had argued because tetracycline was produced through fermentation, rather than synthetically, it was not patentable, and its distribution was subject to pricing fixing challenge. The FTC also argued tetracycline was not patentable because of its production through fermentation. Hochstein, F. A.; Stephens, C. R.; Conover, L. H.; Regna, P. P.; Pasternack, R.; Gordon, P. N.; Pilgrim, F. J.; Brunings, K. J.; Woodward, R. B. (November 1953). "The structure of terramycin". Journal of the American Chemical Society. 75 (22): 5455–75. doi:10.1021/ja01118a001.
  22. Patented February 7, 1956
  23. George Armelagos (May 2000). "Take Two Beers and Call Me in 1,600 Years - use of tetracycline by Nubians and Ancient Egyptians". American Museum of Natural History. Retrieved 2007-12-19.
  24. 1 2 McCluskey, Priyanka Dayal (6 November 2015). "As competition wanes, prices for generics skyrocket". Boston Globe. Retrieved 18 November 2015.
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