Current Topics in Medicinal Chemistry - Volume 2, Issue 7, 2002

The discovery of the natural product nodulisporic acid A (NsA A) and its potent, systemic insecticidal activity at Merck Research Laboratories in 1992 stimulated intense scientific scrutiny. Interest in this new class of indole diterpenes led to extensive delineation of its properties, both chemical and biological. Synthetic modification of NsA A served to identify its pharmacologically permissive and nonpermissive regions, produced semisynthetic derivatives with enhanced adulticidal flea efficacy (both in vitro and in vivo), and provided useful tools to support biological studies. Early observations in rodent models showed a wide therapeutic index for NsA A and detailed mechanism of action investigations demonstrated that it selectively modulated an invertebrate specific glutamate-gated ion channel for which no mammalian homolog exists. Consistent with these mechanistic conclusions, dogs treated orally with either NsA A or closely related amide analogs (15 mg / kg dosages) showed no apparent toxicity, and measurement of systemic flea efficacy in these animals demonstrated that prolonged antiparasitic activity was attained, up to 14 days subsequent to treatment with a single p.o. dose for fleas or up to 4 weeks for ticks. The extended flea efficacy was correlated to both the in vivo pharmacokinetic profile of a given analog and its intrinsic in vitro potency against fleas. In addition, studies directed towards the total synthesis of NsA A have been reported.

The spinosyns are a novel family of fermentation-derived natural products that exhibit potent insecticidal activities. Spinosad, a naturally-occurring mixture of spinosyn A and spinosyn D, has successfully established its utility for crop protective applications in the agrochemical field. Potential applications of this unique chemical family of macrolides also have been investigated in the field of animal health. Applications for the control of blowfly strike and lice on sheep have now been commercially developed and registered in Australia and potential applications for the control of ectoparasites on cattle are being studied.

Ectoparasitic insects play a major role in veterinary medicine. The flea, especially the cat flea (Ctenocephalides felis felis Bouche 1835) is the most important ectoparasite worldwide. The cat flea parasitizes not only on dogs and cats but also on other warm-blooded animals including humans. The veterinary importance of flea infestation are dermatological conditions due to allergic reactions to antigens in the flea saliva and the transmission of infectious agents like bacteria, viruses and helminths. Insecticides used in veterinary medicine today have to fulfil criteria of elimination of a existing flea infestation (therapy) and prevention (prophylaxis) of new infestation for weeks. Imidacloprid is a compound of the chemical class of CNI (chloronicotinyl insecticides syn. neonicotinoids) that fits these criteria. The high selectivity towards the site of action within insects together with the high safety margin on mammals allowed to develop imidacloprid as an insecticide for agricultural use and finally for the application as a veterinary medicine. The major features of imidacloprid chemistry, toxicology and the development and use as a veterinary medicinal remedy are described.

Cephalosporins are an important class of antibacterial agents in use today for both humans and animals. Four generations of cephalosporins have evolved, all of which contain the beta-lactam sub-structure first found in penicillin. The range of cephalosporins available for use in food-producing animals, which is the subject of this review, is limited compared to humans. A few first- and second-generation cephalosporins are approved worldwide strictly for treatment of mastitis infections in dairy cattle. A third-generation cephalosporin, ceftiofur, and a fourth-generation cephalosporin, cefquinome, have been developed strictly for veterinary use. Cefquinome has been approved in several countries for the treatment of respiratory disease in cattle and swine, foot rot in cattle and for mastitis in dairy cattle. Ceftiofur has worldwide approvals for respiratory disease in swine, ruminants (cattle, sheep and goats) and horses and has also been approved for foot rot and metritis infections in cattle. Ceftiofur has also been approved in various countries for early mortality infections in day-old chicks and turkey poults. This review summarizes cephalosporin use in general terms, and provides an overview of ceftiofur, in terms of its spectrum of activity, indications, metabolism, and degradation in the environment. The safety of ceftiofur is also reviewed, with respect to food-animal residues, rapid metabolism and degradation, and non-persistence of ceftiofur in the environment. The environmental fragility of cephalosporins have not been explored generally, but may be an important characteristic of this antibiotic class with respect to safety of use in animals.

Current problems of drug resistance in parasites and pests demand the identification of new targets and their exploitation through novel drug design and development programs. Neuropeptide signaling systems in helminths (nematodes and platyhelminths = worms) and arthropods are well developed and complex, play a crucial role in many aspects of their biology, and appear to have significant potential as targets for novel drugs. The best-known neuropeptide family in invertebrates is the FMRFamide-related peptides (FaRPs). Amongst many roles, FaRPs potently influence motor function. The genome sequencing projects of Drosophila melanogaster and Caenorhabditis elegans have revealed unexpected complexity within the FaRPergic systems of arthropods and nematodes, although available evidence for platyhelminths indicates structural and functional simplicity. Regardless of these differences, FaRPs potently modulate motor function in arthropods, nematodes and platyhelminths and there appears to be at least some commonality in the FaRPergic signaling systems therein. Moreover, there is now increasing evidence of cross-phyla activity for individual FaRPs, providing clear signals of opportunities for target selection and the identification and development of broad-spectrum drugs.

Parasitic nematodes are a major cause of morbidity and mortality in man and also cause widespread loss of food production by infection of livestock. A milestone in the chemotherapy of nematode infections, especially in animals, was the discovery of the avermectins and milbemycins during the 1970s. Since the discovery of these highly active macrolides, reports of potent new classes of anthelmintics have been scarce. One of the most outstanding recently reported anthelmintics is the cyclooctadepsipeptide PF1022A, the most active member of a novel class of anthelmintic agents. During the past years several total syntheses of PF1022A and manifold structure-activity relationships have been established. Additionally, the biosynthesis of PF1022A has been elucidated and intensive investigations into the mode of action of this novel anthelmintic are underway. Comprehensive studies including cyclodepsipeptides with smaller ring-sizes, such as the enniatins, proved the PF1022 family and related cyclodepsipeptides to be the most promising follow-up candidates for the avermectins and milbemycins, which suffer from increasing nematode resistance.

Three distinct chemical classes for the control of gastrointestinal nematodes are available: benzimidazoles, imidazothiazoles, and macrocyclic lactones. The relentless development of drug resistance has severely limited the usefulness of such drugs and the search for a new class of compounds - preferably with a different mode of action - is an important endeavor.Marcfortine A (1), a metabolite of Penicillium roqueforti, is structurally related to paraherquamide A (2), originally isolated from Penicillium paraherquei. Chemically the two compounds differ only in one ring, in marcfortine A, ring G is six-membered and carries no substituents, while in paraherquamide A, ring G is fivemembered with methyl and hydroxyl substituents at C14. Paraherquamide A (2) is superior to marcfortine A as a nematocide.2-Desoxoparaherquamide A (PNU-141962, 53) has excellent nematocidal activity, a superior safely profile, and is the first semi-synthetic member of this totally new class of nematocides that is a legitimate candidate for development. This review describes the chemistry, efficacy and mode of action of PNU-141962.