Multifunction of autophagy-related genes in filamentous fungi

Autophagy (macroautophagy), a highly conserved eukaryotic mechanism, is a non-selective degradation process, helping to maintain a balance between the synthesis, degradation and subsequent recycling of macromolecules to overcome various stress conditions. The term autophagy denotes any cellular process which involves the delivery of cytoplasmic material to the lysosome for degradation. Autophagy, in filamentous fungi plays a critical role during cellular development and pathogenicity. Autophagy, like the mitogen-activated protein (MAP) kinase cascade and nutrient-sensing cyclic AMP (cAMP) pathway, is also an important process for appressorium turgor accumulation in order to penetrate the leaf surface of host plant and destroy the plant defense. Yeast, an autophagy model, has been used to compare the multi-valued functions of ATG (autophagy-related genes) in different filamentous fungi. The autophagy machinery in both yeast and filamentous fungi is controlled by Tor kinase and both contain two distinct phosphatidylinositol 3-kinase complexes. In this review, we focus on the functions of ATG genes during pathogenic development in filamentous fungi.     

Gene expression systems for filamentous fungi.

The extraordinary capacity of filamentous fungi to produce large quantities of extracellular protein, together with the advent of DNA-mediated fungal transformation, has resulted in rapid advances in the development of gene expression systems for filamentous fungi. This review focuses on recent developments in the expression of both fungal and non-fungal genes and improvements to the host.     

Absence of spermine in filamentous fungi.

Polyamines were examined in several yeasts and filamentous fungi. Whereas putrescine, spermidine, and spermine were present in the yeasts, spermine was not detected in any of the filamentous fungi.     

The development of gene expression systems for filamentous fungi

Filamentous fungi have been used for decades in the commercial production of enzymes, antibiotics, and specialty chemicals. Traditionally, improving the yields of these products has involved either mutagenesis and screening or modification of fermentation conditions. Generally, selective breeding of strains has not been successful, because most of the commercially important fungal species lack a sexual cycle. For a few species, strain improvements have been made possible by employing the parasexual cycle for genetic crosses (30). The recent development of DNA-mediated transformation systems for several industrially important fungal species has spawned a flurry of research activity directed toward the development of gene expression systems for these microorganisms. This technology is now a viable means for novel and more directed approaches to improving existing fungal strains which produce enzymes or antibiotics. In addition, fungal expression systems are now being tested for the production of heterologous gene products such as mammalian pharmaceutical proteins. The goal of this review is to present a summary of the gene expression systems which have recently been developed for some filamentous fungi of commercial importance. To insure that the most recent developments are presented we have included data from not only scientific papers, but also from personal communications, abstracts, symposia, and our own laboratory.     

Heterologous expression of genes mediating enhanced fungal resistance in transgenic wheat.

Three cDNAs encoding the antifungal protein Ag-AFP from the fungus Aspergillus giganteus, a barley class II chitinase and a barley type I RIP, all regulated by the constitutive Ubiquitin1 promoter from maize, were expressed in transgenic wheat. In 17 wheat lines, stable integration and inheritance of one of the three transgenes has been demonstrated over four generations. The formation of powdery mildew (Erysiphe graminis f. sp. tritici) or leaf rust (Puccinia recondita f. sp. tritici) colonies was significantly reduced on leaves from afp or chitinase II- but not from rip I-expressing wheat lines compared with non-transgenic controls. The increased resistance of afp and chitinase II lines was dependent on the dose of fungal spores used for inoculation. Heterologous expression of the fungal afp gene and the barley chitinase II gene in wheat demonstrated that colony formation and, thereby, spreading of two important biotrophic fungal diseases is inhibited approximately 40 to 50% at an inoculum density of 80 to 100 spores per cm2.     

丝状真菌的细胞凋亡

凋亡是一种程序性细胞死亡类型,为多细胞生物发育和维持生命所必需的,也普遍存在于细菌等原核生物和酵母、丝状真菌等真核生物中。丝状真菌既具有酵母和哺乳动物共有的凋亡同源蛋白,也具有酵母所不具备的哺乳动物凋亡同源蛋白,所以其凋亡机制较酵母更为复杂,而又较哺乳动物简单。凋亡在丝状真菌的发育、繁殖、衰老等过程中具有重要的作用。近年,丝状真菌作为新的凋亡研究的模式生物被广泛研究,而且进展迅速。综述丝状真菌的凋亡现象和检测方法,丝状真菌中凋亡的生物学功能,丝状真菌凋亡的诱导条件,以及丝状真菌凋亡相关基因的功能研究进展。     

Autophagy in filamentous fungi

Autophagy is a ubiquitous, non-selective degradation process in eukaryotic cells that is conserved from yeast to man. Autophagy research has increased significantly in the last ten years, as autophagy has been connected with cancer, neurodegenerative disease and various human developmental processes. Autophagy also appears to play an important role in filamentous fungi, impacting growth, morphology and development. In this review, an autophagy model developed for the yeast Saccharomyces cerevisiae is used as an intellectual framework to discuss autophagy in filamentous fungi. Studies imply that, similar to yeast, fungal autophagy is characterized by the presence of autophagosomes and controlled by Tor kinase. In addition, fungal autophagy is apparently involved in protection against cell death and has significant effects on cellular growth and development. However, the only putative autophagy proteins characterized in filamentous fungi are Atg1 and Atg8. We discuss various strategies used to study and monitor fungal autophagy as well as the possible relationship between autophagy, physiology, and morphological development.     

Proteomics of filamentous fungi

Proteomic analysis, defined here as the global assessment of cellular proteins expressed in a particular biological state, is a powerful tool that can provide a systematic understanding of events at the molecular level. Proteomic studies of filamentous fungi have only recently begun to appear in the literature, despite the prevalence of these organisms in the biotechnology industry, and their importance as both human and plant pathogens. Here, we review recent publications that have used a proteomic approach to develop a better understanding of filamentous fungi, highlighting sample preparation methods and whole-cell cytoplasmic proteomics, as well as subproteomics of cell envelope, mitochondrial and secreted proteins.     

Meiotic recombination in filamentous fungi

The exchange of genes by crossing over and by gene conversion is a basic process in eukaryotes. Fungi have played a special role in the study of this process because they permit tetrad analysis, which provides complete information on the distribution of genes and chromosomes in meiosis. Recombination is detected by new combinations of genetic markers. The first observation gave only the simple picture of a crossover provided by two segregating loci far apart on the chromosome. Later the discovery of recombination between sites within a gene led to a revolution in our knowledge of this process. Today we carry the resolution a step further with RFLP markers, which can detect the details of recombination down to nucleotide distances. I review here observations on filamentous fungi, which have contributed to this pursuit at each stage of the emerging synthesis.     

Nuclear movement in filamentous fungi

One of the most striking features of eukaryotic cells is the organization of specific functions into organelles such as nuclei, mitochondria, chloroplasts, the endoplasmic reticulum, vacuoles, peroxisomes or the Golgi apparatus. These membrane-surrounded compartments are not synthesized de novo but are bequeathed to daughter cells during cell division. The successful transmittance of organelles to daughter cells requires the growth, division and separation of these compartments and involves a complex machinery consisting of cytoskeletal components, mechanochemical motor proteins and regulatory factors. Organelles such as nuclei, which are present in most cells in a single copy, must be precisely positioned prior to cytokinesis. In many eukaryotic cells the cleavage plane for cell division is defined by the location of the nucleus prior to mitosis. Nuclear positioning is thus absolutely crucial in the unequal cell divisions that occur during development and embryogenesis. Yeast and filamentous fungi are excellent organisms for the molecular analysis of nuclear migration because of their amenability to a broad variety of powerful analytical methods unavailable in higher eukaryotes. Filamentous fungi are especially attractive models because the longitudinally elongated cells grow by apical tip extension and the organelles are often required to migrate long distances. This review describes nuclear migration in filamentous fungi, the approaches used for and the results of its molecular analysis and the projection of the results to other organisms.