Parasitology today (Personal ed.)最新文献

The energy metabolism of Trypanosomatidae has been the subject of many reviews during the past decade. In recent years, however, new data have led to a more complete picture of trypanosomatid metabolism and a reappraisal of the role of some characteristic organelles in the energy supply of these parasites. For years, the glycosome was thought to be a peroxisome-like organelle that had evolved to allow the parasites to carry out glycolysis at a high rate using a relatively small amount of enzyme. However, the results of recent studies of trypanosomatid glycolysis and the detection of various other pathways and enzymes in the organelle necessitate a modification of this view. Here, Paul Michels, Véronique Hannaert and Frédéric Bringaud review the new data and discuss the possible implications for our view on the role of the glycosome.^*

This year, Australia hosted its first major international conference on malaria – Molecular Approaches to Malaria in Lorne, Victoria, 2–5 February 2000 (MAM2000). The worldwide research effort toward a better understanding of the pathogenesis and control of malaria in the post-genomic era was discussed and debated by over 250 researchers from 18 countries during four days packed with molecular biology, cell biology, genomics, vaccines and pathogenic mechanisms. This special malaria edition of Parasitology Today is an attempt to capture and summarize the quality and breadth of work presented at the conference and place this in the context of the current global malaria research effort; eight of the nine Reviews in this issue have been written by session chairs or presenters at MAM2000.

Protein targeting in malaria parasites is a complex process, involving several cellular compartments that distinguish these cells from more familiar systems, such as yeast or mammals. At least a dozen distinct protein destinations are known. The best studied of these is the vestigial chloroplast (the apicoplast), but new tools promise rapid progress in understanding how Plasmodium falciparum and related apicomplexan parasites traffic proteins to their invasion-related organelles, and how they modify the host by trafficking proteins into its cytoplasm and plasma membrane. Here, Giel van Dooren and colleagues discuss recent insights into protein targeting via the secretory pathway in this fascinating and important system. This topic emerged as a major theme at the Molecular Approaches to Malaria conference, Lorne, Australia, 2–5 February 2000.

The complex life cycle of the malaria parasite includes three specialized invasive stages, distinct both in terms of their cellular architecture and in their choice of target host cell. Despite the dissimilarities between these forms, there are clear parallels in the manner by which they enter their respective host cells. Advances in the area of erythrocyte invasion by the malaria merozoite, outlined here by Chetan Chitnis and Mike Blackman and discussed at the Molecular Approaches to Malaria conference, Lorne, Australia, 2–5 February 2000, will undoubtedly impact on our understanding of mechanisms of cell entry by the other invasive forms. Similarly, recent progress in dissecting the functional role of surface proteins expressed by sporozoite and ookinete stages has provided fascinating insights into general aspects of invasion by all invasive stages of apicomplexan parasites.

Cytoadherence is believed to be fundamental for the survival of Plasmodium falciparum in vivo and, uniquely, is a major determinant of the virulence of this parasite. Despite the widely professed importance of cytoadhesion in the development of severe disease, there are a number of aspects of this highly complex process that remain poorly understood. Recent progress in the understanding of cytoadhesive phenomena was discussed extensively at the Molecular Approaches to Malaria conference, Lorne, Australia, 2–5 February 2000. Here, Brian Cooke, Mats Wahlgren and Ross Coppel consider just how far we have progressed during the past 30 years and highlight what is still missing in our understanding of the mechanisms and clinical relevance of this apparently vital process.

The Molecular Approaches to Malaria (MAM2000) conference, Lorne, Australia, 2–5 February 2000, brought together world-class malaria research scientists. The development of new tools and technologies – transfection, DNA microarrays and proteomic analysis – and the availability of DNA sequences generated by the Malaria Genome Project, along with more classic approaches, have facilitated the identification of novel drug targets, the development of new antimalarials and the generation of a deeper understanding of the molecular mechanism(s) of drug resistance in malaria. It is hoped that combinations of these technologies could lead to strategies that enable the development of effective, efficient and affordable new drugs to overcome drug-resistant malaria, as discussed at MAM2000 and outlined here by Ian Macreadie and colleagues.