Antimetabolite

folic acid

(left).

An antimetabolite is a chemical that

folic acid; thus, competitive inhibition can occur, and the presence of antimetabolites can have toxic effects on cells, such as halting cell growth and cell division, so these compounds are used in chemotherapy for cancer.^[2]

Function

Cancer treatment

Antimetabolites can be used in cancer treatment,^[3] as they interfere with DNA production and therefore cell division and tumor growth. Because cancer cells spend more time dividing than other cells, inhibiting cell division harms tumor cells more than other cells. Antimetabolite drugs are commonly used to treat leukemia, cancers of the breast, ovary, and the gastrointestinal tract, as well as other types of cancers.^[4] In the Anatomical Therapeutic Chemical Classification System antimetabolite cancer drugs are classified under L01B.

Antimetabolites generally impair DNA replication machinery, either by incorporation of chemically altered nucleotides or by depleting the supply of deoxynucleotides needed for DNA replication and cell proliferation.

Examples of cancer drug antimetabolites include, but are not limited to the following:

5-Fluorouracil

Anti-metabolites masquerade as a purine (azathioprine, mercaptopurine) or a pyrimidine, chemicals that become the building-blocks of DNA. They prevent these substances from becoming incorporated into DNA during the S phase (of the cell cycle), stopping normal development and cell division.^[6] Anti-metabolites also affect RNA synthesis. However, because thymidine is used in DNA but not in RNA (where uracil is used instead), inhibition of thymidine synthesis via thymidylate synthase selectively inhibits DNA synthesis over RNA synthesis.

Due to their efficiency, these drugs are the most widely used

nucleic acids, inhibits their normal tumor cell function and triggers apoptosis, the cell death process. Because of this mode of action, most antimetabolites have high cell cycle specificity and can target arrest of cancer cell DNA replication.^[7]

Antibiotics

Antimetabolites may also be

para-aminobenzoic acid (PABA).^[8] PABA is needed in enzymatic reactions that produce folic acid, which acts as a coenzyme in the synthesis of purines and pyrimidines, the building-blocks of DNA. Mammals do not synthesize their own folic acid so they are unaffected by PABA inhibitors, which selectively kill bacteria. Sulfanilamide drugs are not like the antibiotics used to treat infections. Instead, they work by changing the DNA inside cancer cells to keep them from growing and multiplying. Antitumor antibiotics are a class of antimetabolite drugs that are cell cycle nonspecific. They act by binding with DNA molecules and preventing RNA (ribonucleic acid) synthesis, a key step in the creation of proteins, which are necessary for cancer cell survival.^[9]

Anthracyclines are anti-tumor antibiotics that interfere with enzymes involved in copying DNA during the cell cycle.^[4]

Examples of anthracyclines include:

Anti-tumor antibiotics that are not anthracyclines include:^[4]

Actinomycin-D
Bleomycin
Mitomycin-C
Mitoxantrone
Phototrexate^[5]^[10]

Other uses

Antimetabolites, particularly mitomycin C (MMC), are commonly used in America and Japan as an addition to trabeculectomy, a surgical procedure to treat glaucoma.^[11]

Antimetabolites have been shown to decrease fibrosis of operative sites. Thus, its use following external dacryocystorhinostomy, a procedure for the management of nasolacrimal duct obstruction, is being researched.^[12]

Intraoperative antimetabolite application, namely

5-fluorouracil (5-FU), is currently being tested for its effectiveness of managing pterygium.^[13]

Types

Main categories of these drugs include:[14]^[15]

base analogues (altered nucleobases) – structures that can substitute for a normal nucleobases in nucleic acids
. This means that these molecules are structurally similar enough to the basic components of DNA that they can be substituted in. However, since they are slightly different from the normal bases after they are incorporated into the DNA, the DNA production is halted and the cell dies.
- purine analogues – mimic the structure of metabolic purines, the larger bases incorporated into DNA as adenosine and guanosine.
  - Examples: Azathioprine, Thiopurines, and Fludarabine
- pyrimidine analogues – mimic the structure of metabolic pyrimidines, the smaller bases incorporated into DNA as cytosine and thymine.
  - Examples:
    5-Fluorouracil, Gemcitabine, and Cytarabine

nucleoside analogues – nucleoside alternatives that consist of a nucleic acid analogue and a sugar. This means these are the same bases as above, but with an added sugar group. For the nucleoside analogues either the base or the sugar component can be altered. They are similar enough to the molecules used to build cellular DNA that they are incorporated by the cell into its DNA, but different enough that after being added the cell's DNA they stop cell growth.
nucleotide analogues – nucleotides alternatives that consist of a nucleic acid, a sugar, and 1–3 phosphates
. This means these molecules look exactly like the pieces used to build DNA in a cell and can be incorporated into a growing cell's DNA. However, because they are analogues and therefore slightly different from regular nucleotides, causing the cell's growth to be halted and the cell to die.

folic acid

(vitamin B9) which is needed to build DNA and allow cells to grow.

References

ISBN 978-0-19-854768-6
.

PMID 11008002
.

^ Antineoplastic+Antimetabolites at the U.S. National Library of Medicine Medical Subject Headings (MeSH)

^ ^a ^b ^c "How Chemotherapy Drugs Work". American Cancer Society.

^
S2CID 53043366
.

^ Takimoto CH, Calvo E. "Principles of Oncologic Pharmacotherapy" Archived 2020-05-03 at the Wayback Machine in Pazdur R, Wagman LD, Camphausen KA, Hoskins WJ (Eds) Cancer Management: A Multidisciplinary Approach Archived 2013-10-04 at the Wayback Machine. 11 ed. 2008.

^ Avendano C, Menendez CJ (2015). Medicinal Chemistry of Anticancer Drugs (2nd ed.). Elsevier Science.

^ Silverman RB (2004). The Organic Chemistry of Drug Design and Drug Action (2nd ed.).

^ "Types of Chemotherapy Drugs". SEER Training Modules.

S2CID 58567138
.

PMID 15205228
.

S2CID 72098513
.

PMID 23152665
.

ISBN 9780471960300
.

PMID 11836090
.

External links

Overview at
University of Nebraska

M phase)
Block microtubule assembly

Vinca alkaloids (Vinblastine^#

Vincristine^#

Vindesine

Vinflunine^§

Vinorelbine^#)

Block microtubule disassembly

Taxanes (Cabazitaxel

Docetaxel^#

Larotaxel

Ortataxel^†

Paclitaxel^#

Tesetaxel)

Epothilones (Ixabepilone)

DNA replication
inhibitor
DNA precursors/
antimetabolites
(S phase)
Folic acid

Dihydrofolate reductase inhibitor (Aminopterin

Methotrexate^#

Pemetrexed

Pralatrexate)

Thymidylate synthase inhibitor (Pemetrexed

Raltitrexed)

Purine

Adenosine deaminase inhibitor (Pentostatin
)

Halogenated/ribonucleotide reductase inhibitors (Cladribine

Clofarabine

Fludarabine)

Nelarabine

Thiopurine (Mercaptopurine^#

Tioguanine^#)

Pyrimidine

Thymidylate synthase inhibitor (Capecitabine^#

Carmofur

Doxifluridine

Floxuridine

Fluorouracil^#

Tegafur (+gimeracil/oteracil))

DNA polymerase inhibitor (Cytarabine^# +daunorubicin
)

Ribonucleotide reductase inhibitor (Gemcitabine^#)

Hypomethylating agent (Azacitidine

Decitabine)

Deoxyribonucleotide

Ribonucleotide reductase inhibitor (Hydroxycarbamide^#)

Topoisomerase inhibitors
(S phase)
I

Camptotheca (Belotecan

Camptothecin

Cositecan^†

Etirinotecan pegol^†

Exatecan

Gimatecan

Irinotecan^#

Lurtotecan^‡

Rubitecan^‡

Silatecan^§

Topotecan)

II

Podophyllum (Etoposide^#

Teniposide)

II+Intercalation

Anthracyclines (Aclarubicin

Amrubicin^†

Daunorubicin^# (+cytarabine)

Doxorubicin^#

Epirubicin

Idarubicin

Pirarubicin

Valrubicin

Zorubicin)

Anthracenediones (Mitoxantrone

Losoxantrone

Pixantrone)

Amsacrine

Bisantrene

Crisnatol

Menogaril^§

Crosslinking of DNA
(CCNS)
Alkylating

Nitrogen mustards: Bendamustine^#

Chlormethine

Cyclophosphamide^# (Ifosfamide^#

Trofosfamide)

Chlorambucil^#

Melphalan (Melphalan flufenamide)

Prednimustine

Uramustine

Nitrosoureas: Carmustine

Fotemustine

Lomustine (Semustine)

Nimustine

Ranimustine

Streptozocin

Alkyl sulfonates: Busulfan (Mannosulfan

Treosulfan)

Aziridines: Carboquone

Thiotepa

Triaziquone

Triethylenemelamine

Platinum-based

Carboplatin^#

Cisplatin^#

Dicycloplatin

Nedaplatin

Oxaliplatin^#

Satraplatin

Nonclassical

Altretamine

Hydrazines (Procarbazine^#)

Etoglucid

Mitobronitol

Pipobroman

Triazenes (Dacarbazine^#

Mitozolomide^§

Temozolomide)

Intercalation

Streptomyces (Dactinomycin^#

Bleomycin^#

Mitomycins

Plicamycin)

Photosensitizers/PDT

Aminolevulinic acid

Efaproxiral

Methyl aminolevulinate

Padeliporfin

Porphyrin derivatives (Porfimer sodium

Talaporfin

Temoporfin

Verteporfin)

Other
Enzyme inhibitors

FI (Tipifarnib^§)

CDK inhibitors (Abemaciclib

Alvocidib^†

Palbociclib

Ribociclib

Seliciclib^†)

PrI
Bortezomib

Carfilzomib

Oprozomib

Ixazomib

PhI (Anagrelide)

IMPDI (Tiazofurin
^§)

LI (Masoprocol
)

PARP inhibitor (Niraparib +abiraterone acetate

Olaparib

Rucaparib)

HDAC (Belinostat

Entinostat

Panobinostat

Romidepsin

Vorinostat)

PIKI (Pi3K) (Alpelisib

Copanlisib

Duvelisib

Idelalisib

Umbralisib^‡)

Receptor antagonists

ERA (Atrasentan)

Retinoid X receptor (Bexarotene)

Sex steroid (Testolactone
)

Other/ungrouped

Adagrasib

Aflibercept

Arsenic trioxide

Asparagine depleters (Asparaginase^#/Pegaspargase)

Axicabtagene ciloleucel

Belzutifan

Bexarotene

Brexucabtagene autoleucel

Celecoxib

Ciltacabtagene autoleucel

Demecolcine

Denileukin diftitox

Elesclomol^§

Elsamitrucin

Enasidenib

Epacadostat

Eribulin

Estramustine phosphate

Glasdegib

Idecabtagene vicleucel

Ivosidenib

Lifileucel

Lonidamine

Lucanthone

Lurbinectedin

Mitoguazone

Mitotane

Oblimersen^†

Omacetaxine mepesuccinate

Plitidepsin

Retinoids (Alitretinoin

Tretinoin^#)

Selinexor

Sitimagene ceradenovec

Sotorasib

Tagraxofusp

Talimogene laherparepvec

Tazemetostat

Tebentafusp

Tiazofurine

Tigilanol tiglate

Tisagenlecleucel

Trabectedin

Veliparib

Venetoclax

Verdinexor

Vosaroxin

^#WHO-EM

^‡Withdrawn from market

Clinical trials:
^†Phase III

^§Never to phase III

Authority control databases: National

Czech Republic

Retrieved from "https://en.wikipedia.org/w/index.php?title=Antimetabolite&oldid=1188119036"

[1] ISBN 978-0-19-854768-6
.

[2] PMID 11008002
.

[3] Antineoplastic+Antimetabolites at the U.S. National Library of Medicine Medical Subject Headings (MeSH)

[American_Cancer_Society-4] "How Chemotherapy Drugs Work". American Cancer Society.

[MateraGomila2018-5] 
S2CID 53043366
.

[6] Takimoto CH, Calvo E. "Principles of Oncologic Pharmacotherapy" Archived 2020-05-03 at the Wayback Machine in Pazdur R, Wagman LD, Camphausen KA, Hoskins WJ (Eds) Cancer Management: A Multidisciplinary Approach Archived 2013-10-04 at the Wayback Machine. 11 ed. 2008.

[Antimetabolites-7] Avendano C, Menendez CJ (2015). Medicinal Chemistry of Anticancer Drugs (2nd ed.). Elsevier Science.

[8] Silverman RB (2004). The Organic Chemistry of Drug Design and Drug Action (2nd ed.).

[NIH_National_Cancer_Institute-9] "Types of Chemotherapy Drugs". SEER Training Modules.

[MashitaKowada2019-10] S2CID 58567138
.

[11] PMID 15205228
.

[12] S2CID 72098513
.

[13] PMID 23152665
.

[A_Study_of_Antimetabolites-14] ISBN 9780471960300
.

[DNA_Analogues-15] PMID 11836090
.

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[3]

[4]

[5]

[6]

[7]

[8]

[9]

[10]

[11]

[12]

[13]

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