Studies on antibiotics and enzyme inhibitors

The isolation of water-soluble natural products - challenges, strategies and perspectives

Covering period: up to 2019Water-soluble natural products constitute a relevant group of secondary metabolites notably known for presenting potent biological activities. Examples are aminoglycosides, β-lactam antibiotics, saponins of both terrestrial and marine origin, and marine toxins. Although extensively investigated in the past, particularly during the golden age of antibiotics, hydrophilic fractions have been less scrutinized during the last few decades. This review addresses the possible reasons on why water-soluble metabolites are now under investigated and describes approaches and strategies for the isolation of these natural compounds. It presents examples of several classes of hydrosoluble natural products and how they have been isolated. Novel stationary phases and chromatography techniques are also reviewed, providing a perspective towards a renaissance in the investigation of water-soluble natural products.

Antimicrobial triterpenes from Ilex integra and the mechanism of antifungal action

Antimicrobial triterpenes were isolated from the fruits of Ilex integra. Their structures were elucidated by spectral data and identified as rotundic acid (1), ulsolic acid (2) and peduncloside (3). Triterpene 1 showed significantly broad antimicrobial activity against bacteria, yeast and filamentous fungi. The antifungal activity of 1 was reversed by fatty acids. Cellular constituents leaked from Candida albicans cells incubated with triterpene 1. These results suggest that the antimicrobial activity of triterpenes in I. integra is due to a change of membrane permeability arising from membrane lipid alteration.

Tyrosine protein kinase inhibition and cancer

The various aspects of the research on tyrosine protein kinase inhibition and its connections with cancer are presented. The emphasis was made on the theoretical low toxic side effects of specific tyrosine protein kinase inhibitors. Particularly, the strategy of finding peptidic substrate-derived inhibitors or modulators is discussed, with an almost complete compendium of the tyrosine protein kinase peptidic substrates published so far. A series of data has been gathered that may serve as a basis for the discovery of selective and specific tyrosine protein kinase inhibitors by screening on molecular and cellular models. The potential of SH2 domain-interfering agents are also presented as a promising route to new anticancer compounds.

Importance of oncogene research to the cancer clinician

For many years a genetic basis has been postulated for cancers and leukaemias. However, this concept has now been strengthened by the discovery of a group of genes (oncogenes) which are specifically associated with neoplasia. These genes have been identified by studies of animal oncogenic viruses, by in vitro transformation studies of mouse fibroblasts, and by molecular analyses of human tumour cells. The oncogenes are altered forms of normal genes (proto-oncogenes) whose protein products are thought to be involved in the regulation of cell proliferation. It appears that the alteration of proto-oncogenes to form oncogenes results in the inappropriate production of normal proteins or in the production of abnormal proteins. It is suggested, therefore, that the presence of such proteins would allow cells to escape from normal cell growth regulation, and as a result produce uncontrolled proliferation. Oncogene research has to date been primarily concerned with identifying oncogenes and assessing their importance in the development of a number of malignancies. Such research is therefore allowing us to build up a framework of genetic changes which define the development of each type of tumour or leukaemia. Furthermore, information concerning the oncogenes is now beginning to be applied diagnostically to help in determining predisposition of an individual to disease, in aiding the accurate staging of disease, in indicating prognosis and in developing markers to detect residual disease after therapy. It is also possible that in the future we may be able to develop new anticancer therapies, for example, based on oncogene protein inhibitors, or anti-oncogene protein antibodies or even gene therapy.