Synergy against fungal pathogens: working together is better than working alone.

Opportunistic fungi are the most important pathogens in modern world. They are responsible for severe infections in majority of immunocompromised patients. These microorganisms are commonly present in our environment which is natural reservoir of new, resistant species. For this reason mycoses are mainly chronic or long-lasting diseases. Our arsenal of antifungal drugs is growing but still insufficient for emerging resistant pathogens. An alternative for novel chemical entity drugs is the multidrug approach. This exploiting the drugs being currently on market applying simultaneously for better efficacy or to eradicate resistance. Synergy is the term that describes the phenomenon of increased potency of two or more drugs administered in combination. In the last decades it gains more interest and numbers of synergy claimed reports is growing exponentially. However these have rather low impact on clinical trials or practical use of antimycotics. In present review we wish to discuss current status of synergy between antifungal drugs. Both theoretical point of view and practical applicability in clinical terms are covered. There are serious differences between the assumptions, methods and interpretations of the results and sometimes even obvious mistakes in the procedure that was applied or in the outcomes discussed. On the other hands the specificity of fungal infections introduce dozens of factors affecting the observed results. Shift form in vitro studies to clinical trials reveals further difficulties. Hopefully multi-drug approach seems to be effective even if no strong synergy is displayed.

Privileged structures - dream or reality: preferential organization of azanaphthalene scaffold.

The concept of privileged structures/substructures (PS) is the idea that certain structural features produce biological effects more often than others. The PS method can be seen as an offspring of fragonomics, which is based on recent experimental measurements of protein-ligand interactions. If PS prove to be true, then chemical motives that enrich biological activity can be used when designing new drugs. However, PS remain controversial because we cannot be sure whether the excess of active structures does not result from an abundance in chemical libraries. In this review, we will focus, in particular, on the preferential organization of azanaphthalene scaffolds (AN) in drugs and natural products (NP), which are preferred by Nature in evolution. We will show that knowledge discovery in molecular databases can reveal interesting time-trends profiles for important classes of potentially privileged scaffolds. The chemical library of AN is dominated by monoaza-compounds, among which quinoline appears to be the most frequently investigated scaffold; however; more sophisticated database mining seems to indicate different PS patterns within the AN scaffold family.

Azole antimycotics--a highway to new drugs or a dead end?

Azole antimycotics are a well-known and important class of agents that are used in hospital practice, everyday health care, veterinary medicine and for crop protection. The era of azole fungicides began with the breakthrough of chlormidazole roughly 50 years ago. Since then, more than 20 drugs of this group, including triazoles, have been brought to the market. The specific chemical structure and mechanism of the action of azoles along with the eukaryotic character of fungal pathogens raise several serious issues. Resistance to drugs and disturbance to metabolic pathways are among the most important. On the other hand, these same features are responsible for unique and novel applications of these drugs. As a result, old and ineffective antifungal drugs can be successfully used in the treatment of parasitic diseases, bacterial infections or cancers. Are azoles getting their second wind?

Quinoline-based antifungals.

Although the assortment of antifungal drugs is broad, the most commonly used agents have major drawbacks. Toxicity, serious side effects or the emergence of drug resistance are amongst them. New drugs and drug candidates under clinical trials do not guarantee better pharmacological parameters. These new medicines may appear effective; however; they may cause serious side effects. This current review is focused on the recent findings in the design of quinoline based antifungal agents. This field seems to be especially interesting as 8-hydroxyquinoline and its metal complexes have been well known as antifungals for years. Structural similarities between quinoline based antifungals and allylamines or homoallylamines, e.g. terbinafine is another interesting fact. Quinoline can be identified in a number of synthetic and natural antifungals, which indicates nature's preference for this fragment and identifying it as one of the so-called privileged structures. We have discussed new trends in the design of quinolines with antifungal properties, their possible targets and the structure activity relationships within the antifungal series developed.

Investigating the antiproliferative activity of quinoline-5,8-diones and styrylquinolinecarboxylic acids on tumor cell lines.

The structure-activity relationships of new quinoline based compounds were investigated. Quinoline-5,8-dione and styrylquinoline scaffolds were used for the design of potentially active compounds. The novel analogues had comparable antiproliferative activity to cisplatin when evaluated in a bioassay against the P388 leukemia cell line. However, these compounds appeared far less efficient against SK-N-MC neuroepithelioma cells. Analogues without the 5,8-dione structure but containing the 8-carboxylic acid group were also found to induce antiproliferative activity. Hydrophobicity as measured by HPLC did not correlate with antiproliferative activity.

Analogues of the styrylquinoline and styrylquinazoline HIV-1 integrase inhibitors: design and synthetic problems.

In our work, leading to new styrylquinoline and styrylquinazoline inhibitors of HIV integrase, we analyzed virtual combinatorial library that includes these compounds. Using this method we were able to find interesting synthetic targets. We optimized synthetic procedure yielding such compounds and obtained a couple of new analogues. Their activity will be evaluated in the near future.