Abstract
Antibiotic resistance is becoming an increasing threat, with too few novel antibiotics coming to market to replace those lost due to resistance development. Efforts by the pharmaceutical industry to screen for and design novel antibacterials have not been successful, with several companies minimizing or closing down their antibacterial research units, leading to a loss of skills and know-how. At the same time, antibiotic innovation in academia is not filling the void due to misaligned incentive structures and lack of vital knowledge of drug discovery. The scientific and structural difficulties in discovering new antibiotics have only begun to be appreciated in the latest years. Part of the problem has been a paradigm shift within both industry and academia to focus on ‘rational’ drug development with an emphasis on single targets and high-throughput screening of large chemical libraries, which may not be suited to target bacteria. The very particular aspects of ‘targeting an organism inside another organism’ have not been given enough attention. In this paper, researcher interviews have complemented literature studies to delve deeper into the specifics of the different scientific and structural barriers, and some potential solutions are offered.
Introduction
While the problem of antibacterial resistance is becoming increasingly worse (Citation1), the number of new antibiotics coming onto the market is dwindling (Citation2,3). In the last 40 years, only two novel classes of antibiotics have been marketed, and those two classes were discovered before 1987 (Citation4). In recent years, many attempts have been made to explain this lack of innovation, with many papers written on the difficulties in antibacterial discovery and development. Most of these papers focus on one of three identified components or bottlenecks: regulatory (Citation5), financial (Citation6), or scientific (Citation4,7). Calls have also been made to create new economic models that will overcome these bottlenecks and to ensure that any novel antibiotic is used responsibly and with equitable access for all (Citation8-12). This paper focuses on the structural barriers encountered by scientists involved in antibiotic discovery, reasons for the lack of innovation in the field of antibacterials in the pharmaceutical sector, and attempts to offer some possible solutions. Problems and potential solutions were identified through literature review, interviews with researchers in academia and the pharmaceutical industry, as well as participation in meetings on the subject.
When discussing discovery of novel antibiotics, it is important to note that there are different definitions of the word ‘novel’. It is most often defined as an antibiotic that acts on a previously unexploited bacterial target. However, novel antibiotics could also hit unexplored areas of already used targets such as the protein translation machinery or the cell wall synthesis. Macrolides and chloramphenicol are for example still considered completely different classes, even though they both target the peptidyl transfer step of translation. Furthermore, antibiotics that are not strictly novel classes can still be extremely useful if they for example overcome a particular resistance problem. Therefore, it is important to discuss what kinds of ‘novel’ antibiotics are most needed. Since drug development from discovery to finished product most often takes place over a decade or more, how do we ensure that we get the antibiotics we need, when we need them? There seems to be almost unanimous agreement that the biggest threat right now is multi-drug-resistant Gram-negative bacteria—but which Gram-negative bacteria? Gonorrhoea, with 106 million new cases each year (Citation13), and where we have very few treatment options, multi-resistant Pseudomonas, or carbapenem-resistant enterobacteriaceae? For the latter group, a new broad-spectrum antibiotic would most certainly be life-saving, but is it feasible to try for a new ‘panacea’ antibiotic, or do we have to be content with targeting sub-groups of these bacteria? For gonorrhoea, it may actually be possible to use existing drugs that have not yet been approved for use for this indication, but someone then needs to pay for the necessary clinical trials.Footnote 1 The point here is: who is making these priorities? At present, it is still the pharmaceutical companies, looking at potential markets, but if we want to ensure that products meet current and future health needs, one factor that needs to be urgently addressed is how to form a mechanism for dealing with these prioritization questions. Such an analysis of the need for new compounds has to be continuous, must build on the global trends of antibiotic resistance and health burden, and should be performed by the public sector.
Innovation crisis in antibiotic discovery and development
In the last few years, several processes have been initiated trying to address the dearth of novel antibiotics. The Swedish EU presidency’s focus on the need for innovative incentives to develop new antibiotics helped to raise the issue high on the agenda in the EU (Citation14,15). Following the subsequent release of the EU Action plan on Antimicrobial resistance (AMR) (Citation16) was the creation of a new programme entitled ‘New Drugs for Bad Bugs’ (ND4BB) within the Innovative Medicines Initiative (a public–private partnership, PPP). Another example of a PPP initiative on this topic is the collaboration between the Singaporean Agency for Science, Technology and Research and AstraZeneca to generate antibiotics for Gram-negative infections.Footnote 2 Examples from other fields include the Drugs for Neglected Diseases Initiative (DNDi) working with the Drug Discovery Unit at Dundee,Footnote 3 and the Medicines for Malaria Venture collaborating with Genzyme Corporation and the Broad Institute.Footnote 4 Other recent initiatives are the Joint Programming on AMR (JPIAMR),Footnote 5 where one of the priority topics in the strategic research agenda is the development of novel antibiotics and alternatives to antibiotics, and the GAIN act in the US. Among other things, the GAIN act uses extended market exclusivity as a carrot for pharmaceutical companies to create new antibiotics.Footnote 6 However many, also within industry, have questioned the usefulness of this approach in stimulating research and development (Citation17), and there are also important implications for access in low-income countries that need to be considered.
The crisis in innovation is not exclusive to antibiotics, and many have pointed to a general need to revive innovative potential in the pharmaceutical industry (Citation17). The shift in drug discovery approaches from a physiology-based to a target-based approach may be one cause. Focusing on processes rather than diseases in order to streamline and optimize drug discovery may have meant that proper scientific analysis suffered (Citation18).
Antibiotic innovation is a particularly dire case and there have been huge losses in competence as the big pharmaceutical companies have gradually cut back on or completely shut down their research units on antibacterial substances. Much of the research in the field is now done in academia, or in smaller biotech companies that develop a molecule up to a point and then try to sell it to a big company that has the capacity and resources to conduct large clinical trials. Crossing the so-called ‘valley of death’, i.e. validating the commercial potential of a promising molecule is indeed challenging. Some of these challenges are explored in the section below (‘Challenges in academic drug discovery’).
Another factor that may be important in the decline of innovative new antibiotics is that the structure of the pharmaceutical industry has changed significantly since the 1950–60s. Nowadays, a molecule may take a very complex path through mergers and acquisitions from discovery through the different development stages. As an example, consider Ramoplanin™ (formerly known as A-16686), which is a glycolipodepsipeptide derived from bacteria of the genus Actinoplanes. Ramoplanin is active against vancomycin-resistant Enterococcus spp. (VRE), methicillin-resistant Staphylococcus aureus (MRSA), and vancomycin-intermediate-resistant Clostridium difficile and was patented in 1980 in Italy. Since then, the molecule has been through numerous licencing events, mergers, and acquisitions as well as bankruptcies (see ). One could argue that if the molecule was interesting enough, it would have become a drug, but do we really know this? At the very least, it would be worthwhile to explore the role of mergers and acquisitions for a selected number of potential antibiotic compounds.
Box 1. Case study of Ramoplanin™ with relevant dates tracking the discovery, patent, out-licencing, and changing ownership of the molecule.
Researchers in antibiotic discovery also need to start learning from their own and others’ mistakes more systematically. Many interesting compounds have ‘disappeared’ for sometimes unknown reasons, before they ever came to phase II/III clinical trials. Were these compounds disregarded because they were truly not useful, or because of other considerations such as financial, which may not be valid any more, or toxicity issues that might be solvable decades later? A good place to start looking could be old pipeline analyses, patent literature, or material published by scientists previously working in the industry (Citation19). If big pharmaceutical companies were also involved, they could contribute this information. One opportunity for such an analysis is the ND4BB programme mentioned above, where it is declared that ‘all consortia participating in projects running under the ND4BB research programme will be expected to deposit data in the ND4BB data hub and work together to share data and experience as widely as possible amongst all programme members and the antibiotic community as a whole’ (Citation20).
Challenges in academic drug discovery
There seems to be a common notion among both the general public and policy-makers that if a lot of money is put into research this will in itself be enough to lead to new medicines. However, in reviewing literature, participating in meetings, and interviewing researchers in several different countries, it seems obvious that this conclusion is false and that much more than research is needed. One reason is that many (maybe even most) academic researchers are not primarily interested in the process of shepherding a molecule through the drug development process. University researcher incentives are almost exclusively based on publishing, and, after the initial discovery of a potential new molecule is published, establishing proof of concept that a molecule could be useful as a medicine is not deemed cutting-edge research. Collaborating with companies, patenting, etc. is also usually very counter-productive for publishing because of constraints on which knowledge can enter the public domain. Other issues with antibiotic discovery in the academic sector often include lack of knowledge of medicinal chemistry and the steps of developing a molecule into a drug after initial discovery. It may be worthwhile to develop a ‘manual’ or check-list of essential assays aimed at academic antibiotic drug discovery and development, as this expertise will otherwise have to be bought from consultants. Also, both medicinal chemistry and other expertise are essential to ensure a collaborative, productive environment of scientists from several different disciplines. In addition, if academia ventures further into drug development, skilled managers, not only skilled researchers, are needed, which may be hard to find unless very high salaries can be afforded (Citation21).
The few researchers that do indeed wish to progress their molecule far enough so it may be sold to a biotech company will find that funding for this endeavour is very hard to come by. It is not pure research, so those sources of funding are usually not available. Venture capitalists are less prone these days to ‘venture’ and prefer much more proof before they will consider investing.
In , scientific areas have been listed, where increased knowledge would facilitate the discovery of new antibiotics, several of which have been suggested before (Citation4,22,23) but have been gathered here for easy overview. It can be argued that breakthroughs cannot only be achieved by directing science, so funding of more explorative research should not be reduced. Instead increased funding for both targeted and explorative basic science is needed.
Box 2. Proposed research questions that could be explored to aid easier antibiotic discovery.
Alternatives to antibiotics
When discovery and development of new antibiotics are discussed, invariably alternatives to conventional antibiotics are brought up. Among the most common are antimicrobial peptides (AMPs) and bacteriophages, both of which have been mentioned as alternatives to antibiotics for decades. While these alternatives are certainly worth exploring, it may be good to note some of the reasons they will not be replacing conventional antibiotics, at least not any time soon. In the case of AMPs, they can have a direct antibacterial effect, but usually only under specific conditions (e.g. pH, ionic strength) and at quite high concentrations. To date it has been problematic to use their antimicrobial properties to develop them into pharmaceuticals. Instead, recent research focuses on their ability to recruit and modulate the innate immune system (Citation24). While this is an attractive approach, AMPs are fraught with problems like high production costs, toxicity, and susceptibility to proteases. It is very hard to achieve a high enough concentration in the body at the right site, making them unsuitable at least as replacement for systemic treatment. In the short term, AMPs are therefore best suited for topical and possibly inhalation applications. AMPs could also be used as complements to conventional antibiotics. The antibiotic clears the bacteria, and the AMP could reduce the inflammatory response, which would be very useful in e.g. sepsis. Certainly, AMPs are worth investigating further, and may in the long-term perspective become useful tools to combat bacterial infection. However, they are currently a complement to small-molecule antibiotics, not a replacement, especially not for Gram-negative bacteria.
Regarding phages, where most of the work has been performed in Eastern Europe and the states of the former Soviet Union (Citation25), they too have their advantages as well as significant drawbacks. Phage therapy can be useful in e.g. deep skin wounds, where it is possible to spray the phage solution directly onto the infected area. However, caveats that would hinder the use of phages systemically is their considerable antigenicity, localization issues with getting the phage to the infected site, achieving the appropriate concentration, as well as a need constantly to update phage libraries to get a useful coverage of strains. In addition to this, bacteria can quite easily develop resistance also to phages (Citation26).
In summary, alternative approaches (and there are many more beside AMPs and phages) to conventional antibiotics should certainly be explored, but it is important clearly to understand their limitations in terms of which types of infections and bacteria they could be effective against, and how close they are to clinical application.
Conclusions and proposals
To accomplish any of the suggestions in this paper, new funding is essential. The Wellcome Trust funds both academia and companies for early drug discovery/screening of compounds to try and close the gap between academia and commercialization in their Seeding Drug Discovery programme (£110 million), but funding is mainly available for partners in the UK. In a 255-page report for the Swedish Presidency of the EU in 2009 intended to investigate how to make possible the continued development of innovations in the antibacterial field, some suggestions are made: To create a collaborative programme, in order to collect the expertise that is required to develop innovations in the antibacterial field, and to provide public risk capital for early, high-risk antibiotic development (Citation27).
There is an increasing interest and investment in translational medicine, where lessons could be learned in order to cross the ‘valley of death’ in antibacterial research. Examples include National Center for Advancing Translational Sciences (NCATS) at NIHFootnote 7 and other initiatives in the UK,Footnote 8 India,Footnote 9 and many other places. In order to meet the numerous challenges listed in this paper—scientific bottlenecks, mechanisms for prioritization, lack of innovative capacity, misaligned incentives, and lack of antibiotic discovery experience and expertise—we need a strong focal point with multidisciplinary skills, and both academic and industry competences. I propose the establishment of a ‘Centre for Antibiotic Research’, much as we have institutes and centres for cancer research, to help address these challenges and also help create clear career paths for scientists in antibacterial discovery. A model could be Canada's Center for Drug Research and DevelopmentFootnote 10 that provides expertise and infrastructure for researchers, to enable them to advance promising drug candidates.
A possibility for Europe could be to create such a centre within the framework of the JPIAMR, to collect Europe’s (and Canada’s) expertise in antibiotic discovery. The centre could have outreach programmes to collect interesting molecules and offer expertise in drug development, to enable evaluation of potential antibiotic compounds originating in academia or smaller biotech companies. However, it is high time that we stop just discussing potential solutions, find the necessary funding, and start implementing.
Acknowledgements
The author would like to extend her gratitude to all the researchers who have willingly answered my questions, with a special thanks to Lynn Silver, for her time and willingness to share her expertise, and the JPIAMR for introducing me to researchers for interviews. The author has been supported by a grant from the Kjell and Märta Beijer Foundation.
Declaration of interest: The author reports no conflicts of interest. The author alone is responsible for the content and writing of the paper.
Notes
References
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