key: cord-1025211-bgs4oimd
authors: Kaul, Laurine; Süss, Regine; Zannettino, Andrew; Richter, Katharina
title: The revival of dithiocarbamates: from pesticides to innovative medical treatments
date: 2021-01-22
journal: iScience
DOI: 10.1016/j.isci.2021.102092
sha: a3f48b08ad24329122cfb6b5e28c265a4841b5c3
doc_id: 1025211
cord_uid: bgs4oimd

Dithiocarbamates (DTCs) have been used for various applications, including as hardening agents in rubber manufacturing, as fungicide in agriculture, and as medications to treat alcohol misuse disorder. The multi-faceted effects of DTCs rely mainly on metal binding abilities and a high reactivity with thiol groups. Therefore, the list of potential applications is still increasing, exemplified by the US Food and Drug Administration approval of disulfiram (Antabuse) and its metabolite diethyldithiocarbamate in clinical trials against cancer, human immunodeficiency virus, and Lyme disease, as well as new DTC-related compounds that have been synthesized to target diseases with unmet therapeutic needs. In this review, we will discuss the latest progress of DTCs as anti-cancer agents and provide a summary of the mechanisms of action. We will explain the expansion of DTCs' activity in the fields of microbiology, neurology, cardiology, and ophthalmology, thereby providing evidence for the important role and therapeutic potential of DTCs as innovative medical treatments.

Chemical structures containing dithiocarbamates (DTCs) as functional group began their life as catalysts in the rubber vulcanization process in the early 1880s. In 1943, the first DTC derivative, nabam, was patented as fungicide for agricultural use, followed by zineb, the first DTC to be coupled with a metal. The best known DTC derivative, diethyldithiocarbamate (DDC), is the active metabolite of the anti-alcoholic drug, disulfiram (DSF) (Bala et al., 2014) . Notably, DTCs have recently resurfaced as potential drug therapies, owing to (1) their ability to chelate metals and (2) their affinity for thiol groups present in human and microbial enzymes (Sauna et al., 2005; Buac et al., 2012) .

To date, a small number of articles have described the emerging importance of DTCs in medicine and the potential of DSF for various biomedical applications. DSF and DDC represent interesting candidate drug therapies, as they are inexpensive and have an excellent safety record (Viola-Rhenals et al., 2018) . In the past 20 years, DSF and DDC have been extensively investigated as cancer treatments, as antimicrobial agents, and for their application in cardiology and neurology. In addition, new chemical structures with DTC moieties have been synthesized and tested for their anti-cancer, antiviral, ophthalmic, and neurological applications (i.e., for the treatment of Alzheimer disease) (Figure 1 ).

According to the World Health Organization (WHO), in 2018, one in six deaths was caused by cancer worldwide. Cancer is broadly defined as cells that display abnormal and uncontrolled growth. Treatment options include chemotherapeutic agents that are usually associated with toxic side effects and limited therapeutic activity due to the development of drug resistances in a significant number of patients (Gillet and Gottesman, 2010) . Therefore, new anti-cancer drugs that display selectivity for cancer cells without the associated development of resistance are urgently required. (NCT04265274) . The inclusion of DSF-Cu was hypothesized to increase the objective response rate in patients with refractory metastatic breast cancer by overriding drug resistance in cancer cells and by inhibiting cancer stem cells through inactivation of aldehyde dehydrogenase (ALDH) (Nechushtan et al., 2015) .

High ALDH levels have been observed in many cancer stem cells (Viola-Rhenals et al., 2018) , including multiple relapsed germ cell tumors (Schmidtova et al., 2019) and metastatic pancreatic cancer cells (Kim et al., 2013) . Accordingly, phase II clinical study patients are being recruited to investigate the objective response rate and patient survival when treated with DSF and cisplatin against multiple relapsed germ cell tumors (NCT03950830). Furthermore, treatment of metastatic pancreatic cancer with DSF-Cu plus gemcitabine alone, gemcitabine/nab-paclitaxel, and FOLFIRINOX is the focus of another phase II clinical study (NTC03714555) initiated in 2019. The objective of this study is to determine if the addition of DSF-Cu leads to a reduction of the tumor marker CA19-9.

Notably, DSF-Cu and DDC-Zinc (DDC-Zn) are the current focus of clinical trials to treat the hematological malignancy, multiple myeloma. The primary outcome of the phase I study using DSF-Cu is the evaluation of the dose-limiting toxicity rate of the DSF-Cu recommended phase 2 dose (NTC04521335). The observational study involving DDC-Zn aims to determine the in vitro efficacy and cytotoxicity of DDC-Zn alone or in combination with lenalidomide or pomalidomide against bone marrow samples from patients with multiple myeloma and those with acute leukemia (NCT04234022). The outcome of this study could lead to a first interventional trial comprising DDC as cancer treatment.

Furthermore, many newly synthesized compounds, based on DTCs, are being investigated for their anticancer activity in both in vitro and in vivo models. By linking DTC with other functional groups, compounds like diarylaminopyrimidine-DTC hybrids can inhibit a specific target, such as focal adhesion kinase (FAK). FAK is a regulator of cancer cell survival, proliferation, and angiogenesis and represents a good target for a chemotherapeutic drug owing to its multilateral affects. One diarylaminopyrimidine-DTC hybrid, synthesized by Su et al. (2019) to target FAK, showed selectivity toward tumor cells and had good anti-proliferative and anti-angiogenesis effects in vitro.

Additionally, some new active substances, based on the ability of DTCs to chelate metal ions, such as gold(III)-DTCs exhibited excellent in vitro and in vivo anti-tumor properties with reduced systemic toxicity (Nagy et al., 2012) . In HER2-overexpressing cancer cells, the iron chelator dipyridylhydrazone-DTC exhibited anti-tumor activity by upregulating the tumor and metastasis suppressor gene NDRG1 . Furthermore, a newly synthesized DTC derivative, containing glucose and methionine, reduced cisplatin-induced nephrotoxicity by binding platin without compromising the therapeutic activity (Ge et al., 2019) . In addition, a new platinum-containing compound, similar to cisplatin but based on a DTC moiety, showed in vitro and in vivo activity against a range of tumor cell lines without measurable nephrotoxicity (Nagy et al., 2012) .

The well-known pyrrolidine dithiocarbamate (PDTC) has been investigated for anti-cancer effects against adult T cell leukemia/lymphoma. PDTC administration in mice models was shown to inhibit adult T cell leukemia/lymphoma cell growth and improved mouse survival (Nakamura et al., 2015) .

Although both known and new DTCs are in different stages of development, an important question related to their mode of action remains: What mechanisms underlie the anti-cancer activities of DTCs, DSF, and their metal complexes?

Considerable progress as to the modes of action of DTC has been made by investigating different pathways, including their effects on the ubiquitin proteasome system (UPS), reactive oxygen species (ROS) generation, epigenetic factors, and cancer cell stemness ( Figure 2 ). Many of these mechanisms have already been described in recent reviews (Viola-Rhenals et al., 2018; Yang et al., 2019; Jiao et al., 2016) , with many of these articles focusing on the mechanisms of DSF and DDC with Cu 2+ , but not other DTCs.

The UPS is a crucial mechanism for the degradation of key signaling molecules such as cell cycle regulatory and apoptosis controlling proteins. Before their degradation, proteins are tagged with multiple ubiquitin molecules, which are then recognized by the 26S-proteasome and consequently hydrolyzed (Cvek and Dvorak, 2008) . Studies have shown that DTC copper complexes, such as DDC-Cu and PDTC-Cu, can inhibit proteasome activity in different cancer cells by interacting with two main processes within the UPS (Pang et al., 2007; Buac et al., 2012) .

First, DTCs inhibit the 26S-proteasome by either binding to the 26S-proteasome or when complexed with Cu ions, by inhibiting the catalytic 20S-core (Yang et al., 2019; Viola-Rhenals et al., 2018) . DDC-Cu and PDTC-Cu inhibit the 26S-proteasomes by interacting with the JAB1/MPN/Mov34 metalloenzyme domain, which is responsible for de-ubiquitination of proteins (Skrott and Cvek, 2012; Cvek, 2011) . Inhibition of 26Sproteasome leads to the accumulation of ubiquitinated proteins and cytotoxic protein aggregates resulting in a disturbance of the protein homeostasis and leading to cell death (Cvek and Dvorak, 2008) .

Second, Skrott et al. (2017) suggested that DDC-Cu interacts with the nuclear protein localization 4 (NPL4), a key component of p97 segregase. As a result, the process of protein ubiquitination is inhibited and protein aggregates are rapidly formed (Skrott et al., 2017) . A recent paper (Pan et al., 2020) described that only cupric ions interact with NPL4, thereby immobilizing p97 segregase. DDC is then necessary to transport the cupric ions into the cells.

ROS are highly reactive molecules that, at low levels, are crucial for the regulation of normal physiological functions. An excess of cellular ROS activates its downstream c-Jun N-terminal kinases and p38 MAPK pathways, resulting in cell death (Yang et al., 2019) .

DSF and DTCs, in combination with metal ions, can induce ROS production through the Fenton and Haber Weiss reaction, and also by inhibiting antioxidants such as superoxide dismutase and glutathione (Marikovsky et al., 2002; Skrott and Cvek, 2012) . A recent article showed that a dipyridylhydrazone DTC induced ferritinophagy by mobilizing iron from ferritin and mediating the ROS/p53 pathway, resulting in the inhibition of gastric cancer cell line proliferation (Feng et al., 2020; Huang et al., 2018) .

Certain cancer types, including prostate cancer or glioma, show high expression of genes involved in DNA modifications. For instance, high levels of DNA-methyltransferases, which are responsible for DNA-methylation and leading to the silencing of genes, were observed in these cancer cell types. DSF is suggested to interfere with the catalytic center of DNA-methyltransferase 1, therefore inhibiting its activity. Exposure to DSF was found to lead to demethylation of hypermethylated genes and re-expression of silenced genes (Lin et al., 2011) . 

Another example is the overexpression of the O-6-methylguanine-DNA-methyltransferase gene in certain cancer cells, which encodes for the DNA-repair protein O-6-alkylguanine-DNA-alkyltransferase. This protein repairs methylations caused by the chemotherapeutic compound temozolomide and therefore diminishes its therapeutic effect. PDTC and other DTCs reduced the expression levels of O-6-methylguanine-DNA-methyltransferase in glioma cells (Tang et al., 2017) .

Further epigenetic modifications within cancer cells leads to the overexpression of efflux pumps, such as the ATP-binding cassette (ABC) family of proteins. ABC transport proteins, such as P-glycoprotein, remove cytotoxic drugs from the cells, resulting in decreased intracellular accumulation of the drugs and thus lack of activity (Loo and Clarke, 2000) . DSF binds to either the ATP-binding site or the drug substrate-binding sites of multiple ABC transporting proteins, potentially increasing the efficacy of other cancer drugs by inhibiting ABC activity or by blocking its maturation .

Cancer stem cells are a subpopulation of cells within tumors, with the capability of differentiation and selfrenewal, and are associated with metastasis, cancer recurrence, and therapy resistance. The importance of ALDH and HER-2 as marker for cancer stem cells and the inhibition through DSF was described in detail in recent reviews (Jiao et al., 2016; Yang et al., 2019) .

The protein complex, nuclear factor-kappa B (NF-kB), is involved in multiple pathways necessary for cell survival and cancer cell stemness. NF-kB is a transcriptional regulator of proteins that inhibit apoptosis inhibitors, including XIAP, which are downregulated when exposed to DSF-Cu (Allensworth et al., 2015) . DTCs inhibiting properties of NF-kB can, in part, be attributed to NF-kB being dependent on the UPS to split inhibitor-kB (I-kB) kinase and release the heterodimer p50:p65 for nuclear transcription (Cvek and Dvorak, 2008) . Other hypotheses include the obstruction of I-kB kinase and therefore the prevention of the ubiquitination and the split of I-kB, along with the interaction of DTCs with various thiol groups present throughout the NF-kB pathway (Cvek and Dvorak, 2007) .

Furthermore, carbonic anhydrase (CA) 12 and its associated transporter anion exchanger (AE) 2 can also play an important role in invasion and cell migration in both lung cancer and breast cancer cell lines. An upregulation of AE2 has been observed in various cancer cell types, in which DSF reduced the surface expression of both CA12 and AE2 (Hwang et al., 2019) . Additionally, CA9 and CA12 are overexpressed in hypoxic tumor cells and were inhibited by various DTC derivates. Especially CA9 was still inhibited despite a high structural diversity of the DTC derives, including aliphatic, aromatic, aralkyl, and hetaryl moieties (Carta et al., 2012a) . Last, the vascular endothelial growth factor (VEGF) plays a key role in angiogenesis and therefore in abnormal vessel growth at the tumor site, thereby contributing to the progression of solid malignancies. DSF-Cu showed improved inhibition of endothelial cell proliferation, migration, invasion, adhesion, and tube formation by inhibiting the EGFR/Src/VEGF pathway (Li et al., 2015) .

Through various mechanisms, DSF and DTCs inhibit angiogenesis and proliferation, overcome apoptotic signals, and induce apoptosis in cancer cells. However, these targets are not only relevant in tumor therapy but also play an important role in the virulence of microbial diseases.

The WHO predicts that 10 million people will die from antimicrobial-resistant infections by the year 2050. This is partly caused by the rise of microbial drug resistances, as well as by the reduced pace in the development of new antimicrobials (Thakare et al., 2019) . DSF and DTCs were investigated as antimicrobial candidates and showed activity against viruses, bacteria, fungi, and parasites, in some cases leading to clinical trials, as described in Table 2 . (Lin et al., 2018) . DSF and DDC-Cu have been shown to inactivate crucial viral proteins of the 2019 novel coronavirus such as thio-protease and RNA replicase, by oxidizing the thiol/thiolate to disulfides (Xu, L., Tong, J., Wu, Y., Zhao, S. and Lin, B.-L. 2020. Targeted oxidation strategy (TOS) for potential inhibition of coronaviruses by disulfiram -a 70-year old anti-alcoholism drug. ChemRxiv, under review). DSF is now being investigated in the clinical trial DISCO (NCT04485130) to assess adverse events and changes in the COVID-19 symptom severity score.

DSF and its metabolite DDC also display antiviral activities against human immunodeficiency virus (HIV)-1 and have been used in clinical trials (clinicaltrials.gov). The progression of HIV-1 can be controlled with combination anti-retroviral therapy. However, to date no cure has been identified owing to the persistence of replication-competent, latent provirus in long-lived resting T cells. A recent approach, termed the ''shock and kill strategy,'' aims to reactivate the virus reservoirs and destroy latently infected cells. In combination with anti-retroviral therapy, this approach could lead to HIV-1 cure (Spivak and Planelles, 2018) . The possible mechanism of the viral reactivation properties of DSF has been attributed to the stimulation of the protein kinase B signaling pathway. The protein kinase B pathway initiates NF-kB-dependent proviral transcription, and consequently, reactivation of latent HIV-1 expression (Doyon et al., 2013; Spivak and Planelles, 2018) .

Clinical studies performed in 2011 (NCT01286259) and 2013 (NCT01944371) showed that treatment with DSF resulted in a dose-dependent increase of cell-associated unspliced HIV-RNA and plasma HIV-RNA (Spivak et al., 2013; Elliott et al., 2015; Lee et al., 2019) . However, a reduction of the size of the latent reservoir could not be achieved. It was postulated that this was the result of a lack of potency of DSF, the challenges of measuring the size of the reservoir, and the presence of additional viral reservoirs, such as in the central nervous system (Knights, 2017) . Another study (NCT03198559) investigating the changes in HIV-RNA levels after treatment with DSF and another latency-reversing agent, vorinostat, had to be terminated due to an increased risk for patients.

Nevertheless, these studies suggest that DSF is a promising treatment option to reactivate latent virus, but methods to determine the size of the latent reservoir need to be optimized and the benefit of combination therapy with anti-retroviral compounds requires further investigation.

Other DTCs, such as PDTC, were investigated against multiple viruses in numerous in vitro and in vivo infection models, as described in Table 3 .

The antiviral activity of PDTC is related to the inhibition of NF-kB. Similar to its role in anti-cancer activity, virus-induced NF-kB activation leads to inhibition of apoptosis and enhanced survival of the host cells. In addition, NF-kB is important in the regulation of the innate and adaptive immune system, giving the virus more time to replicate (Santoro et al., 2003) . iScience

The antiviral activity of PDTC is not only dependent on the inhibition of NF-kB, especially when complexed with metals. For example, PDTC-Zn disturbed the RNA-polymerase enzyme function in rhinovirus by increasing the cellular concentrations of zinc (Zn) ions (Nirwan and Kakkar, 2019; Krenn et al., 2005) . In addition, the antiviral activity of PDTC was also linked to the UPS, with PDTC-mediated inhibition of ubiquitination, leading to repressed viral replication and protein production of enterovirus 71 in vitro without leading to apoptosis of the cells (Lin et al., 2015) . Similar results have already been described for coxsackievirus B3 when exposed to PDTC-Cu and PDTC-Zn (Si et al., 2005) and for herpes simplex virus 1 and 2 when exposed to PDTC-Zn (Qiu et al., 2013) .

These results suggest that PDTC, in combination with metals, has antiviral properties via inhibition of NF-kB and UPS in a broad range of viral pathogens.

Although DTCs and DSF are expected to play an important role in the fight against viruses, their antimicrobial activity has been studied in other infectious diseases, such as bacterial infections.

Bacterial infections can affect multiple human organ systems, including the mouth and teeth, the skin, and the lungs (Figure 3 ). Some of these infections are caused by pathogens on the WHO's global priority list of antibiotic-resistant bacteria, such as Mycobacterium tuberculosis and Staphylococcus aureus, for which there is an urgent need for research and development of new treatments.

In 1987, Taylor et al. (1987) were the first group investigating the antibacterial properties of DDC against methicillin-resistant Staphylococcus aureus (MRSA). Subsequent to these studies, Phillips et al. (1991) investigated the antibacterial properties of DSF against a range of Gam-positive and Gram-negative bacteria. They concluded that DSF inhibits the growth of Gram-positive bacteria, such as MRSA, but not Enterobacteriaceae or Pseudomonas aeruginosa. Recent studies confirmed inhibition of growth in Gram-positive bacteria through DSF, especially in MRSA (Frazier et al., 2019; Long, 2017; Sheppard et al., 2018) . However, DDC alone did not demonstrate significant inhibition of growth against Gram-positive bacteria (Frazier et al., 2019) . PDTC showed some antibacterial activity against pathogens causing iScience Review periodontitis, such as Porphyromonas gingivalis and Actinobacillus actinomycetemcomitans; medium sensitivity against S. aureus; and only low sensitivity against Escherichia coli (Kang et al., 2008) .

Both DDC and PDTC were highly active against growing and nongrowing persister Mycobacterium tuberculosis and enhanced the activity of established tuberculosis drugs (Byrne et al., 2007) . However, Dalecki et al. (2015) demonstrated that the antibacterial properties of DSF and DDC in M. tuberculosis are strictly Cu ion dependent. In contrast, other DTCs neither benefited nor required Cu ions for their antibacterial activity. The addition of Cu ions reduced the antimicrobial activity of PDTC against Fusobacterium nucleatum and Porphyromonas gingivalis, whereas it was enhanced by the addition of Zn ions (Choi et al., 2010) . Moreover, the antibacterial activity of synthesized potassium morpholine dithiocarbamate against Grampositive and Gram-negative bacteria was higher than the antibacterial activity of this compound complexed to nickel or copper ions (Balakrishnan et al., 2019) .

To date, only a small number of articles have described the antibacterial properties of DDC or DSF combined with Cu 2+ . In addition, little research has been done to investigate the activity of DTCs against biofilms. Biofilms are clusters of bacteria embedded in a protective matrix (Costerton et al., 1999) . Only Saputo et al. (2018) highlighted that DSF and Cu 2+ reached synergistic effects against biofilms and planktonic Streptococcus mutans.

Based on the heterogeneity between different bacterial species, from the membrane constitution of Grampositive and Gram-negative bacteria to the expression of different proteins within a species, determining the mode of action of DSF and DTCs with and without copper is challenging. The first hypothesis for DSF was based on the metabolization to DDC, which chelates vital metals and inhibits enzymes (Phillips et al., 1991) . Later, it was suggested that the complex DDC-Cu acts like a ''Trojan horse,'' helping copper to enter the bacteria, overcoming the bacterial resistance mechanisms, and inhibiting targets that usually were not accessible to free Cu ions (Dalecki et al., 2015) .

Despite the species specificity of copper resistance mechanisms, some similarities are found within all bacteria. The copper homeostasis consists of three main components: a copper-exporting ATPase, a copper chaperone, and a copper-responsive regulator. These components differ within species and are particularly expressed in Gram-negative bacteria (Solioz, 2018) . Based on our experimental results (L. Kaul, A. Zannettino, R. Sü ss, K. Richter (2021). The combination of diethyldithiocarbamate and copper ions presents in vitro activity against staphylococci biofilms. Manuscript in preparation) we suggest that in Gram-positive bacteria DDC-Cu inhibits at least one of these components, leading to accumulation of free toxic Cu ions. In addition, the presence of glutathione in Gram-negative bacteria can lead to thiol-disulfide exchange between glutathione and DTCs and consequently reduce the antibacterial activity (Long, 2017; Sheppard et al., 2018) . Interestingly, recent studies have revealed antibacterial activity of these compounds against certain Gramnegative bacteria. Following the high in vitro activity of DSF against the tick-transmitted Borrelia burgdorferi, the cases of three patients taking DSF daily for the symptoms of chronic relapsing neurological Lyme disease and relapsing babesiosis were reported. All patients were able to discontinue antimicrobial treatment and remained clinically well for 6 to 23 months (Liegner, 2019) . A pilot study (NCT03891667) is currently recruiting patients with persistent symptoms before antibiotic treatment for Lyme disease to investigate the side effects, tolerability, and effectiveness of DSF (Younger and Murphy, 2020) .

Furthermore, DDC inhibited the carbonic anhydrase (CA) in Legionella pneumophila (Nishimori et al., 2014) . DTCs displayed selectivity for the inhibition of bacterial CA over the host enzyme with some derivatives demonstrating high inhibition of M. tuberculosis CA (Maresca et al., 2013) . Aspatwar et al. (2020) determined a DTC derivative with high in vitro activity against M. tuberculosis CA and minimal in vivo toxicity, making it a promising candidate for preclinical assays. Previously, the same group investigated a piperazine-DTC induced growth inhibition of M. tuberculosis CA and M. marinum in vitro. In addition, the compound showed growth inhibition of M. marinum in vivo and low toxicity in a zebrafish larvae model (Aspatwar et al., 2017) .

Considering that CAs are metalloenzymes playing a crucial role in most living organisms and that DTCs interact with these enzymes in cancer and bacterial cells, a possible application for DTCs might also be found in fungi and parasites.

A series of DTC analogs selected by Vullo et al. (2017) were tested against a subtype of CA from Malassezia globosa. This fungus is considered to be one of the causes for dandruff, a condition affecting more than 50% of the population worldwide. Compared with the clinically used acetazolamide, all DTC derivates were more potent inhibitors of the M. globosa CA. An aliphatic DTC with an alcohol moiety and a quinuclidine-3-DTC showed the highest M. globosa CA inhibition (Vullo et al., 2017) . A similar screening was previously performed for DTC analogs against a CA subtype from different Candida species. Dimethyl-and diethyldithiocarbamate were the weakest inhibitors, whereas other derivatives with aryl, arylalkyl-, heterocyclic, and aliphatic moieties led to potent fungal CA inhibition (Monti et al., 2012) . The biochemical activities of other vital enzymes, such as ALDH and urease were reduced by DSF, thereby inhibiting the growth of Pythium insidiosum, the oomycete microorganism causing the life-threatening infection pythiosis (Krajaejun et al., 2019) .

Furthermore, DSF showed fungicidal activity against yeast isolates, Aspergillus isolates and Candida isolates (Khan et al., 2007) . Similar to cancer cells, Candida spp. can overexpress ABC transporters, such as Cdr1p supporting efflux of drugs and contributing toward the development of resistance. DSF inhibited Cdr1p and increased the sensitivity of Cdr1p expressing S. cerevisiae to different antifungal drugs (Shukla et al., 2004) . However, neither synergy nor enhancement could be observed when DSF and fluconazole were tested against resistant Candida albicans and other Candida isolates (Khan et al., 2007) .

Interestingly, DDC showed high antifungal activity against several C. albicans and Candida tropicalis biofilms (Harrison et al., 2007) . The combination of DDC with amphotericin B resulted in a reduced biofilm viability when compared with the compounds alone, as DDC inhibits the C. albicans biofilm persistence mechanism superoxide dismutase (De Brucker et al., 2013) .

Superoxide dismutase inhibition by DDC also enhanced Leishmania braziliensis killing by macrophages in vitro through an increase of superoxide anion release while decreasing lesion size and parasite load in vivo (Khouri et al., 2010) . Similar results were observed when DDC was incorporated in bacterial cellulose, making it a promising topical formulation for chemotherapy of cutaneous leishmaniasis (Celes et al., 2016) . Likewise, DTC pesticides maneb, zineb, and propineb were investigated for their capacity to inhibit CA activity in Leishmania species. Mammalian cells were unaffected by the three compounds, whereas exposure to the external and motile form of Leishmania major led to apoptotic and necrotic death of the parasite, as well as the reduction of the intracellular parasite burden (Pal et al., 2015) .

Another organism relying on antioxidants is the parasite causing malaria. In chloroquine-resistant Plasmodium berghei, higher levels of glutathione and glutathione-S-transferase were observed. The mechanism ll OPEN ACCESS iScience 24, 102092, February 19, 2021 9 iScience Review of chloroquine is based on the inhibition of the crucial biomineralization from hemoglobin to hemozoin. As a result, toxic ferriprotoporphyrin IX accumulates in the membrane fraction of infected cells and binds to membrane proteins. However, free ferriprotoporphyrin IX can be degraded by glutathione (Ginsburg et al., 1998) . Disulfiram interacts with GSH and decreases the reduced/oxidized GSH ratio in erythrocytes of uninfected mice. DSF substantially potentiated the antimalarial activity of chloroquine and amodiaquine and prolonged the survival of mice infected with chloroquine-resistant Plasmodium strains (Deharo et al., 2003) .

DTCs also showed activity in Chagas disease caused by Trypanosoma cruzi and in sleeping sickness caused by Trypanosoma brucei. Synthesized compounds with a DTC moiety showed antiparasitic activity based on the chelation of metals in the active center of enzymes responsible for the oxidation metabolism of protozoa and therefore disturbing important functions in the parasite's biology. Additional compounds were synthesized by linking DTC with thiadiazine, which are known to inhibit vital parasitic cysteine proteases (Oliveira et al., 2019) .

Although new DTC derivatives are being investigated for their antimicrobial activity, DSF and its metabolite DDC appear to be the key candidates. These two compounds inhibit crucial cellular mechanisms and are predicted to play an important role in the battle against cancer, viruses, bacteria, fungi, and parasites.

Initially, DSF was used for the treatment of chronic alcoholism, but the research focus also expanded toward the treatment of cocaine addiction among alcohol users (Suh et al., 2006) . Cocaine use leads to increased monoamine levels in the brain, by inhibiting monoamine transporters. It was suggested that the increased synaptic dopamine levels and the norepinephrine levels were responsible for the addictive effect. DDC inhibits the enzyme dopamine b-hydroxylase, which catalyzes the conversion from dopamine to norepinephrine. Therefore, dopamine levels rise during DDC treatment, whereas norepinephrine levels drop (De Sousa, 2019) .

The efficacy of DSF for the treatment of cocaine addiction has been attributed to a decrease of the reward mechanisms and an increase in cocaine aversion due to more side effects. In addition, DSF leads to higher basal dopamine levels, thus restoring the reward function of hypodopaminergic addicts and preventing stress-induced reinstatement of cocaine seeking (Devoto et al., 2012) . In a study performed by Kampangkaew et al. (2019) patients with genetically higher levels of dopamine transporter, correlating with a lower basal level of dopamine in the synapse, experienced better treatment outcomes with DSF than those with lower dopamine transporter levels (Kampangkaew et al., 2019) . In addition, a systematic review performed in 2010 described a statistically significant difference in favor of DSF for the treatment of cocaine dependence when compared with no pharmaceutical treatment. However, they concluded that there was insufficient evidence for the treatment of cocaine abuse with DSF (Pani et al., 2010) .

Moreover, DTC pesticides also cause changes in dopamine levels. Maneb triggers dopaminergic cell loss and has been associated with neurotoxic effects leading to an increased risk of developing Parkinson disease (Roede et al., 2011) . In contrast, other DTCs have been investigated as treatment options for diseases associated with neuroinflammation, as many have low molecular weight and good blood-brain barrier permeability.

Neuroinflammation is considered a critical risk for the development of neurodegenerative diseases, such as Alzheimer disease and psychiatric illnesses. Alzheimer disease is an irreversible, progressive neurodegenerative disorder that affects approximately 50 million people worldwide. Both the deficit of acetylcholine in the brain region and the aggregation of amyloid-b to plaques can lead to cognitive impairment and dementia (He et al., 2018; Jiang et al., 2018) .

It was demonstrated that coumarins inhibit acetylcholinesterase by binding to the peripheral anionic site of the enzyme and display potent monoamine oxidase B inhibitory activity. The DTC moiety interacts with the catalytic anionic site of acetylcholinesterase. To this end, a coumarin-dithiocarbamate hybrid synthesized by He et al. (2018) , displayed promising inhibitory activity against monoamine oxidase B and inhibition of acetylcholinesterase through dual binding. Another coumarin-dithiocarbamate hybrid synthesized by Jiang et al. (2018) exhibited potent inhibition toward acetylcholinesterase and self-induced b-amyloid ll

aggregation. Both compounds demonstrated good ability to penetrate the blood-brain barrier, and no acute toxicity could be observed in vitro and in vivo (He et al., 2018; Jiang et al., 2018) .

Similar to coumarins, several phthalimide analogs were reported to exhibit high inhibitory activity against acetylcholinesterase. Synthesized phthalimide-dithiocarbamate hybrids showed potent anti-acetylcholinesterase and anti-butyrylcholinesterase activity, as well as good blood-brain barrier penetration (Asadi et al., 2019) . Through innovative multitargeting, hybrids based on a DTC moiety are promising compounds in the research against Alzheimer disease.

In addition, activation of NF-kB pathways contributes to long-term neuroinflammation and epilepsy. Studies focusing on treatment with the NF-kB inhibitor PDTC showed improved memory function in different models of neuroinflammation and cognitive disorder (Kan et al., 2016; Li et al., 2012; Zhang et al., 2014) . Lv et al. (2014) demonstrated that pre-treatment with PDTC prevented neuroinflammation through inhibition of the chemokine MCP-1 and attenuated microglial activation in a status epilepticus rat model. Although PDTC enhanced the susceptibility to seizures, it reduced their frequency and their severity, making it a promising agent for the treatment of status epilepticus (Lv et al., 2014) .

Nevertheless, the anti-inflammatory activity of PDTC, through inhibition of NF-kB, is not restricted to neuroinflammation. Indeed, PDTC reduced collagen deposition in non-infarcted areas and improved sympathetic nerve hyperinnervation in rat hearts, resulting in decrease of ventricular arrhythmia incidences and improved myocardial remodeling after myocardial infarct (Wang et al., 2019; Jin et al., 2016) . Treatment with PDTC also attenuated pulmonary arterial hypertension and protected pulmonary endothelium in rat models by preventing elevated lipid peroxidation and reducing collagen deposits (Yavuz et al., 2013) . Furthermore, PDTC-induced NF-kB inhibition led to reduced renal angiotensin 1 receptor expression and its mediated vasoconstriction, improved oxidative stress, attenuated proinflammatory cytokines, and upregulated anti-inflammatory cytokines in hypertensive transgenic rats (Luo et al., 2015) .

Finally, DTCs reduce the intraocular pressure by inhibiting CA2 and CA12, both enzymes playing an important role in the development of glaucoma. First analyses of DTCs with hydrogen, alkyl, aryl, aralkyl, hetaryl, and cyclic moieties by Carta et al. (2012a) resulted in two selected compounds with excellent human CA2 and CA12 inhibitory properties, which lowered the intraocular pressure over 4-8 h in a rabbit model. The potent inhibitory activity of certain DTCs against CA2 was suggested by analyzing the crystallographic structure of CA2. The thiol groups of DTCs bind the zinc in the active site and are further stabilized in the active site pocket through multiple interactions of the tail groups, such as hydrophobic interactions and hydrogen bonds with different amino acids (Bozdag et al., 2015; Carta et al., 2012b) . In 2015, another screening of multiple DTCs revealed a superior candidate, as the boc-piperidine-DTC selectively inhibited CA2 and CA12 over the off-target isoform CA1. This DTC analog was also investigated in an in vivo model and reduced the intraocular pressure significantly compared with the standard of care dorzolamide (Bozdag et al., 2015) . Similar results were also observed with xanthate and trithiocarbamate analogs .

In conclusion, the mechanisms of action of DTCs and DSF remain unclear and require further investigation. However, recent studies have shed light on the interactions of DTCs with enzymes, intracellular metal concentrations, and oxidative processes, which represent important targets in various disease states. DSF, DDC, PDTC, and many newly synthesized DTC derivatives have displayed encouraging results in in vitro experiments, often leading to further in vivo assays. In addition, DSF and DDC are currently being investigated in multiple clinical trials for applications in cancer, infectious diseases, and substance abuse. An exciting path lies ahead unraveling the potential and pitfalls of DTCs as innovative medical treatments.

DSF) acts as a copper ionophore to induce copper-dependent oxidative stress and mediate anti-tumor efficacy in inflammatory breast cancer

Design, synthesis, molecular docking, and cholinesterase inhibitory potential of phthalimide-dithiocarbamate hybrids as new agents for treatment of alzheimer's disease

Beta-CAspecific inhibitor dithiocarbamate Fc14-584B: a novel antimycobacterial agent with potential to treat drug-resistant tuberculosis

In vitro inhibition of Mycobacterium tuberculosis beta-carbonic anhydrase 3 with Mono-and dithiocarbamates and evaluation of their toxicity using zebrafish developing embryos

Chemical and medicinal versatility of dithiocarbamates: an overview

Syntheses, physicochemical characterization, antibacterial studies on potassium morpholine dithiocarbamate nickel (II), copper (II) metal complexes and their ligands

Synthesis of a new series of dithiocarbamates with effective human carbonic anhydrase inhibitory activity and antiglaucoma action

Dithiocarbamate-based coordination compounds as potent proteasome inhibitors in human cancer cells

Pyrrolidine dithiocarbamate and diethyldithiocarbamate are active against growing and nongrowing persister Mycobacterium Tuberculosis

Inhibition of bacterial carbonic anhydrases as a novel approach to escape drug resistance

Dithiocarbamates strongly inhibit carbonic anhydrases and show antiglaucoma action in vivo

Dithiocarbamates: a new class of carbonic anhydrase inhibitors. Crystallographic and kinetic investigations

Xanthates and trithiocarbonates strongly inhibit carbonic anhydrases and show antiglaucoma effects in vivo

DETCbased bacterial cellulose bio-curatives for topical treatment of cutaneous leishmaniasis

Potentiation of bacterial killing activity of zinc chloride by pyrrolidine dithiocarbamate

Bacterial biofilms: a common cause of persistent infections

Targeting malignancies with disulfiram (Antabuse): multidrug resistance, angiogenesis, and proteasome

Targeting of nuclear factor-kappaB and proteasome by dithiocarbamate complexes with metals

The value of proteasome inhibition in cancer. Can the old drug, disulfiram, have a bright new future as a novel proteasome inhibitor?

Disulfiram and copper ions kill Mycobacterium Tuberculosis in a synergistic manner

Potentiation of antibiofilm activity of amphotericin B by superoxide dismutase inhibition

Disulfiram in the management of cocaine dependence and other psychiatric disorders

Potentiation of the antimalarial action of chloroquine in rodent malaria by drugs known to reduce cellular glutathione levels

Disulfiram stimulates dopamine release from noradrenergic terminals and potentiates cocaine-induced dopamine release in the prefrontal cortex

Disulfiram reactivates latent HIV-1 expression through depletion of the phosphatase and tensin homolog

Gefitinib and pyrrolidine dithiocarbamate decrease viral replication and cytokine production in dengue virus infected human monocyte cultures

Short-term administration of disulfiram for reversal of latent HIV infection: a phase 2 doseescalation study

DpdtCinduced EMT inhibition in MGC-803 cells was partly through ferritinophagy-mediated ROS/p53 pathway

Antibacterial activity of disulfiram and its metabolites

GMDTC chelating agent attenuates cisplatin-induced systemic toxicity without affecting antitumor efficacy

Mechanisms of multidrug resistance in cancer

Inhibition of glutathione-dependent degradation of heme by chloroquine and amodiaquine as a possible basis for their antimalarial mode of action

A subpopulation of Candida albicans and Candida tropicalis biofilm cells are highly tolerant to chelating agents

Coumarin-dithiocarbamate hybrids as novel multitarget AChE and MAO-B inhibitors against Alzheimer's disease: design, synthesis and biological evaluation

Growth inhibition of a novel iron chelator, DpdtC, against hepatoma carcinoma cell lines partly attributed to ferritinophagymediated lysosomal ROS generation

Drug repurposing as an antitumor agent: disulfiram-mediated carbonic anhydrase 12 and anion exchanger 2 modulation to inhibit cancer cell migration

Design, synthesis and biological evaluation of new coumarindithiocarbamate hybrids as multifunctional agents for the treatment of Alzheimer's disease

Disulfiram's anticancer activity: evidence and mechanisms

Improvement of left ventricular remodelling by inhibition of NF-kB in a rat model of myocardial infarction

Pharmacogenetic role of dopamine transporter (SLC6A3) variation on response to disulfiram treatment for cocaine addiction

Pyrrolidine dithiocarbamate prevents neuroinflammation and cognitive dysfunction after endotoxemia in rats

Antibacterial activity of pyrrolidine dithiocarbamate

Antifungal potential of disulfiram

DETC induces leishmania parasite killing in human in vitro and murine in vivo models: a promising therapeutic alternative in leishmaniasis

Reversing the intractable nature of pancreatic cancer by selectively targeting ALDHhigh, therapy-resistant cancer cells

A critical review of the evidence concerning the HIV latency reversing effect of disulfiram, the possible explanations for its inability to reduce the size of the latent reservoir in vivo, and the caveats associated with its use in practice

The repurposed drug disulfiram inhibits urease and aldehyde dehydrogenase and prevents in vitro growth of the oomycete pythium insidiosum

Inhibition of polyprotein processing and RNA replication of human rhinovirus by pyrrolidine dithiocarbamate involves metal ions

Population pharmacokinetics and pharmacodynamics of disulfiram on inducing latent HIV-1 transcription in a phase IIb trial

Pyrrolidine dithiocarbamate attenuates brain Abeta increase and improves long-term neurological outcome in rats after transient focal brain ischemia

Copper improves the anti-angiogenic activity of disulfiram through the EGFR/Src/VEGF pathway in gliomas

Disulfiram (tetraethylthiuram disulfide) in the treatment of lyme disease and babesiosis: report of experience in three cases

Disulfiram is a DNA demethylating agent and inhibits prostate cancer cell growth

Pyrrolidine dithiocarbamate inhibits enterovirus 71 replication by down-regulating ubiquitin-proteasome system

Disulfiram can inhibit MERS and SARS coronavirus papain-like proteases via different modes

Repurposing thiram and disulfiram as antibacterial agents for multidrugresistant Staphylococcus aureus infections

Blockage of drug resistance in vitro by disulfiram, a drug used to treat alcoholism

Chronic NF-kB blockade improves renal angiotensin II type 1 receptor functions and reduces blood pressure in Zucker diabetic rats

Pyrrolidine dithiocarbamate (PDTC) inhibits the overexpression of MCP-1 and attenuates microglial activation in the hippocampus of a pilocarpine-induced status epilepticus rat model

Dithiocarbamates strongly inhibit the beta-class carbonic anhydrases from Mycobacterium tuberculosis

Cu/Zn superoxide dismutase plays a role in angiogenesis

Dithiocarbamates are strong inhibitors of the beta-class fungal carbonic anhydrases from Cryptococcus neoformans, Candida albicans and Candida glabrata

Noble metaldithiocarbamates precious allies in the fight against cancer

A new ATL xenograft model and evaluation of pyrrolidine dithiocarbamate as a potential ATL therapeutic agent

A phase IIb trial assessing the addition of disulfiram to chemotherapy for the treatment of metastatic non-small cell lung cancer

Rhinovirus RNA polymerase: structure, function, and inhibitors

Anion inhibition studies of two new b-carbonic anhydrases from the bacterial pathogen Legionella pneumophila

Application of dithiocarbamates as potential new antitrypanosomatids-drugs: approach chemistry, functional and biological

Identification of metal dithiocarbamates as a novel class of antileishmanial agents

Seesaw conformations of Npl4 in the human p97 complex and the inhibitory mechanism of a disulfiram derivative

Sodium diethyldithiocarbamate, an AIDS progression inhibitor and a copper-binding compound, has proteasome-inhibitory and apoptosis-inducing activities in cancer cells

Disulfiram for the treatment of cocaine dependence

Disulfiram inhibits the in vitro growth of methicillin-Resistant Staphylococcus aureus

Pyrrolidine dithiocarbamate inhibits herpes simplex virus 1 and 2 replication, and its activity may be mediated through dysregulation of the ubiquitinproteasome system

Maneb and paraquat-mediated neurotoxicity: involvement of peroxiredoxin/ thioredoxin system

NF-kappaB and virus infection: who controls whom

A drug repositioning approach reveals that Streptococcus mutans is susceptible to a diverse range of established antimicrobials and nonantibiotics

The molecular basis of the action of disulfiram as a modulator of the multidrug resistance-linked ATP binding cassette transporters MDR1 (ABCB1) and

Disulfiram, an old drug with new potential therapeutic uses for human cancers and fungal infections

Disulfiram overcomes cisplatin resistance in human embryonal carcinoma cells

Disulfiram-based disulfides as narrow-spectrum antibacterial agents

Disulfiram is a potent modulator of multidrug transporter Cdr1p of Candida albicans

Pyrrolidine dithiocarbamate reduces coxsackievirus B3 replication through inhibition of the ubiquitinproteasome pathway

Diethyldithiocarbamate complex with copper: the mechanism of action in cancer cells

Alcohol-abuse drug disulfiram targets cancer via p97 segregase adaptor NPL4

Copper homeostasis in grampositive bacteria

A pilot study assessing the safety and latencyreversing activity of disulfiram in HIV-1-infected adults on antiretroviral therapy

Novel latency reversal agents for HIV-1 cure

Discovery of 2,4-diarylaminopyrimidine derivatives bearing dithiocarbamate moiety as novel FAK inhibitors with antitumor and anti-angiogenesis activities

The status of disulfiram: a half of a century later

Pyrrolidine dithiocarbamate sensitizes U251 brain glioma cells to temozolomide via downregulation of MGMT and BCL-XL

In vitro antimicrobial activity of diethyldithiocarbamate and dimethyldithiocarbamate against methicillinresistant Staphylococcus

Repurposing Disulfiram for treatment of Staphylococcus aureus infections

Recent advances in antabuse (disulfiram): the importance of its metal-binding ability to its anticancer activity

Dithiocarbamates effectively inhibit the betacarbonic anhydrase from the dandruff-producing fungus Malassezia globosa

Targeting blockade of nuclear factor-kB in the hypothalamus paraventricular nucleus to prevent cardiac sympathetic hyperinnervation post myocardial infarction

Therapy of experimental influenza virus infection with pyrrolidine dithiocarbamate

An updated review of disulfiram: molecular targets and strategies for cancer treatment

The novel dithiocarbamate, DpdtC suppresses HER2-overexpressed cancer cells by up-regulating NDRG1 via inactivation of HER2-ERK 1/2 signaling

Pyrrolidine dithiocarbamate attenuates the development of monocrotaline-induced pulmonary arterial hypertension

Antabuse for lyme disease: the way forward

Pyrrolidine dithiocarbamate attenuates surgeryinduced neuroinflammation and cognitive dysfunction possibly via inhibition of nuclear factor kB