Ruthenium anti-cancer drugs

Ruthenium anti-cancer drugs are coordination complexes of ruthenium complexes that have anticancer properties. They promise to provide alternatives to platinum-based drugs for anticancer therapy.[1][2] No ruthenium anti-cancer drug has been commercialized.

Since 1979, when Cisplatin entered clinical trials, there has been continuing interest in alternative metal-based drugs.[3] The leading ruthenium-based candidates are NAMI-A and KP1019. The first one to enter was NAMI-A. More ruthenium drugs are still under development. Ruthenium complexes as anticancer drugs have been traditionally designed to mimic platinum drugs for targeting DNA,[4] but other approaches also exist.[5]

Properties of ruthenium complexes

Ruthenium has numerous properties that qualify it as an antineoplastic drug contender. While platinum-based compounds have served as very successful anti-cancer drugs, they have several limitations including their side effects, as well as ineffectiveness against certain types of cancer. Bergamo and Sava speculated in 2011 that some of these issues might be resolved with the use of a ruthenium substitute.[4] Though most ruthenium complexes are only in the beginning stages of the approval process for anti-cancer drugs, many of their properties may give them advantages over many platinum-based drugs now in use.[6]

Oxidation states and geometry

Ruthenium complexes typically adopt oxidation states II, III, and IV.[7] The geometry assumed by most ruthenium complexes is hexacoordinate, and octahedral, which differs from the square planar molecular geometry typical for platinum(II). The presence of six ligands allows for tuning of the complexes' electronic and steric properties.[1][8]

Ligand exchange rates

The rate of ligand exchange for ruthenium complexes is relatively slow in comparison with other transition metal complexes. The range of these exchange rates is around 10−2 to 10−4 s−1 which is on the scale of an average cell’s lifetime, giving the drug high kinetic stability and minimizing side reactions.[1] This allows the Ru complex to remain intact as it approaches the target as well as remain viable throughout its interaction with the cells. It is also possible through ligand variation to precisely tune the exchange kinetics, allowing a large degree of control over the complex’s stability.[9]

Activation by reduction

The theory is based on the understanding that Ru(II) complexes are generally more reactive than Ru(III) complexes. As cancer cells are generally growing and multiplying much more rapidly than normal healthy cells, this creates an environment that is less oxygen rich due to the raised metabolic rate. When this is paired with the tendency of cancerous cells to contain higher levels of glutathione and a lower pH, a chemically reducing environment is created.[1] This allows for ruthenium complexes to be administered as much less active, non-toxic Ru(III) compounds (as a prodrug), which can be activated solely at the site of the cancerous cells.[1] The reduction is thought to occur by mitochondrial proteins or microsomal single electron transfer proteins, though it may also occur by trans-membrane electron transport systems which reside outside the cell – implying that entry to the cancerous cells may not be required for the drug to be effective.[7] In theory it is also possible for the ruthenium compounds to be oxidized back to its inactive form if it leaves the cancerous environment. This phenomenon remains a theory, and while demonstrated in vitro, it has so far been difficult to prove experimentally in vivo.[4]

Transferrin transportation

3D rendering of a transferrin molecule

As ruthenium is in the same group as iron, they share many characteristics. Electronically, ruthenium molecules readily bond with nitrogen and sulphur donor molecules that are abundantly found in many proteins within the body.[1] For this reason ruthenium complexes are able to take advantage of the body’s ability to efficiently transport and uptake of iron. The ruthenium complexes can be transported by binding to serum albumin and transferrin proteins. These proteins allow for the efficient uptake of soluble iron for metabolic purposes.[4] As rapidly dividing cells have an increased demand for iron, the levels of transferrin receptors found on these cancerous cells are greatly increased. The receptor increase on cancerous cells has been document as two to twelve times that of healthy cells.[1] This greatly increases the selectivity of the drug as the majority of the dose is sequestered in cancerous tissues, bypassing most healthy cells. This effect contributes to the lower toxicity that is associated to the ruthenium drugs in comparison to platinum.[9] It is important to note that the ruthenium is not necessarily replacing the iron within these proteins, but that they are transported concurrently. It has been documented that transferrin-mediated ruthenium uptake is more efficient when the proteins are also saturated with iron.[1]

Current ruthenium anti-cancer drugs

NAMI

Chemical structure of imidazolium trans-imidazoledimethylsulfoxidetetrachloro-ruthenate (NAMI-A)

NAMI {Na[trans-RuCl4](DMSO)(imida)]} and NAMI-A {H2Im[trans-RuCl4(DMSO)HIm[imidH] are the most-stable ruthenium-based anti-cancer drugs.[6] NAMI-A is considered a pro-drug and is inactive at physiological pH of 7.4.[1] Cancer cells generally contain a lower oxygen concentration as well as higher levels of glutathione and a lower pH than normal tissues creating a reducing environment. Upon entering cancer cells NAMI-A is activated by the reduction of Ru(III) to Ru(II) to form the active anti-cancer agent.

KP1019

KP1019, a salt of trans-tetrachlorobis(indazole)ruthenate(III), has entered into clinical trials.[10] KP1019 has an octahedral structure with two trans N-donor indazole and four chloride ligands in the equatorial plane.[11][12][13] It has a low solubility in water, which makes it difficult to transport in the bloodstream. Instead KP1339 is used as a preparation of KP1019 in clinical trials, since it has a better solubility as a sodium salt.[13]

Proteins and other N-donors are good binding partners for KP1019.[14][15][16]

Especially transferrin and albumin are good binding partners.[17] The overall method of action for KP1019 needs to be supported further.

Tumor cells have a high requirement of iron, which results in a large concentration of transferrin. Ru(III) complexes bind to transferrin and proposed to interfere with iron uptake.[18][19]

RAPTA

RAPTA compounds are ruthenium–arene complexes bearing the 1,3,5-triaza-7-phosphatricyclo-[3.3.1.1]decane ligand.[20] The complex has a piano stool geometry. The PTA ligand confers water solubility, and the two chloride ligands are labile.[8] RAPTA compounds have low general toxicity that apparently reduces the side-effects associated with chemotherapy.[8]

RAED

Ruthenium diamine complexes are of interest as potential anticancer drugs.[21][22] RAED compounds are ruthenium–arene complexes bearing the 1,2-ethylenediamine ligand.

The ruthenium diamine complexes form adducts with guanine.[23] Methylation or substitution on en-NH, which prevent the hydrogen bonding, can lead to the loss of cytotoxic activity of the complex toward cancer cell.[24][25] The ethylenediamine ligand suppresses reactions of the complex with amino acid residues. The Ru(II) complexes have a higher affinity to DNA in the presence of protein than the Ru(III) compounds, such as NAMI-A.[26]

References

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