Coevolution can explain defensive secondary metabolite diversity in plants.

Many plant species produce defensive compounds that are often highly diverse within and between populations. The genetic and cellular mechanisms by which metabolite diversity is produced are increasingly understood, but the evolutionary explanations for persistent diversification in plant secondary metabolites have received less attention. Here we consider the role of plant-herbivore coevolution in the maintenance and characteristics of diversity in plant secondary metabolites. We present a simple model in which plants can evolve to invest in a range of defensive toxins, and herbivores can evolve resistance to these toxins. We allow either single-species evolution or reciprocal coevolution. Our model shows that coevolution maintains toxin diversity within populations. Furthermore, there is a fundamental coevolutionary asymmetry between plants and their herbivores, because herbivores must resist all plant toxins, whereas plants need to challenge and nullify only one resistance trait. As a consequence, average plant fitness increases and insect fitness decreases as number of toxins increases. When costs apply, the model showed both arms race escalation and strong coevolutionary fluctuation in toxin concentrations across time. We discuss the results in the context of other evolutionary explanations for secondary metabolite diversification.

RrmA regulates the stability of specific transcripts in response to both nitrogen source and oxidative stress.

Differential regulation of transcript stability is an effective means by which an organism can modulate gene expression. A well-characterized example is glutamine signalled degradation of specific transcripts in Aspergillus nidulans. In the case of areA, which encodes a wide-domain transcription factor mediating nitrogen metabolite repression, the signal is mediated through a highly conserved region of the 3' UTR. Utilizing this RNA sequence we isolated RrmA, an RNA recognition motif protein. Disruption of the respective gene led to loss of both glutamine signalled transcript degradation as well as nitrate signalled stabilization of niaD mRNA. However, nitrogen starvation was shown to act independently of RrmA in stabilizing certain transcripts. RrmA was also implicated in the regulation of arginine catabolism gene expression and the oxidative stress responses at the level of mRNA stability. ΔrrmA mutants are hypersensitive to oxidative stress. This phenotype correlates with destabilization of eifE and dhsA mRNA. eifE encodes eIF5A, a translation factor within which a conserved lysine is post-translationally modified to hypusine, a process requiring DhsA. Intriguingly, for specific transcripts RrmA mediates both stabilization and destabilization and the specificity of the signals transduced is transcript dependent, suggesting it acts in consort with other factors which differ between transcripts.

Distinct roles for Caf1, Ccr4, Edc3 and CutA in the co-ordination of transcript deadenylation, decapping and P-body formation in Aspergillus nidulans.

Transcript degradation is a key step in gene regulation. In eukaryotes, mRNA decay is generally initiated by removal of the poly(A) tail mediated by the Ccr4-Caf1-Not complex. Deadenylated transcripts are then rapidly degraded, primarily via the decapping-dependent pathway. Components of this pathway can be localized into highly dynamic cytoplasmic foci, the mRNA processing (P)-bodies. We have undertaken confocal fluorescence microscopy to monitor P-bodies in Aspergillus nidulans. As in other organisms a dynamic shift in P-body formation occurs in response to diverse physiological signals. Significantly, both this cellular response and the signalled degradation of specific transcripts are dependent on the nuclease activity of Caf1 but not Ccr4. P-body formation is disrupted in A. nidulans strains deleted for Edc3, an enhancer of decapping, or CutA, which encodes a nucleotidyltransferase that triggers mRNA decapping by the addition of a CUCU tag to the poly(A) tail. As with DeltacutA, Deltaedc3 led to reduced rates of transcript degradation. These data link P-bodies to both the optimization and regulation of transcript degradation.

The 2008 update of the Aspergillus nidulans genome annotation: a community effort.

The identification and annotation of protein-coding genes is one of the primary goals of whole-genome sequencing projects, and the accuracy of predicting the primary protein products of gene expression is vital to the interpretation of the available data and the design of downstream functional applications. Nevertheless, the comprehensive annotation of eukaryotic genomes remains a considerable challenge. Many genomes submitted to public databases, including those of major model organisms, contain significant numbers of wrong and incomplete gene predictions. We present a community-based reannotation of the Aspergillus nidulans genome with the primary goal of increasing the number and quality of protein functional assignments through the careful review of experts in the field of fungal biology.

A comparison of doctoral training in biomedicine and medicine for some UK and Scandinavian graduate programmes: learning from each other.

Although the historical bases for graduate training in the United Kingdom (UK) and Scandinavia both stem from the original concept developed by von Humboldt, and both award a 'PhD degree', their paths have diverged. There are thus significant differences in the manner in which graduate training is organised. To analyse these differences, two UK graduate programmes (School of Medicine, Cardiff University; Institute of Integrative Biology, University of Liverpool) and two Scandinavian graduate schools (Faculty of Medicine and Dentistry, University of Bergen; Karolinska Institutet, Stockholm) completed a Self-evaluation questionnaire developed by Organisation of PhD Education in Biomedicine and Health Sciences in the European System (ORPHEUS)). Analysis of the completed questionnaires shows differences concerning requirements for admission, the training content of PhD programmes, the format of the PhD thesis, how the thesis is assessed and the financial model. All programmes recognise that PhD training should prepare for employment both inside and outside of academia, with emphasis on transferable skills training. However, the analysis reveals some fundamental differences in the direction of graduate programmes in the UK and Scandinavia. In the UK, graduate programmes are directed primarily towards teaching PhD students to do research, with considerable focus on practical techniques. In Scandinavia, the focus is on managing projects and publishing papers. To some extent, the differences lead to a lack of full recognition of each other's theses as a basis for doing a postdoc. This paper describes the basis for these differences and compares the two approaches and points to areas in which there is, or might be, convergence.

Gene regulation in Aspergillus: From genetics to genomics.

A fundamental aspect of any organism's success is the ability to monitor and respond effectively to its environment, a process which is largely achieved through the appropriate regulation of gene expression. There are few better examples than fungi, which inhabit diverse and often hostile environments, ranging from leaf litter to the human body. Regulation can occur at many levels, and as we investigate specific genes in detail, the paradigm is one of increasing complexity. We will briefly review the different levels at which regulation is known to occur in Aspergillus and the insights gained from the available genome sequences.

mRNA 3' tagging is induced by nonsense-mediated decay and promotes ribosome dissociation.

For a range of eukaryote transcripts, the initiation of degradation is coincident with the addition of a short pyrimidine tag at the 3' end. Previously, cytoplasmic mRNA tagging has been observed for human and fungal transcripts. We now report that Arabidopsis thaliana mRNA is subject to 3' tagging with U and C nucleotides, as in Aspergillus nidulans. Mutations that disrupt tagging, including A. nidulans cutA and a newly characterized gene, cutB, retard transcript degradation. Importantly, nonsense-mediated decay (NMD), a major checkpoint for transcript fidelity, elicits 3' tagging of transcripts containing a premature termination codon (PTC). Although PTC-induced transcript degradation does not require 3' tagging, subsequent dissociation of mRNA from ribosomes is retarded in tagging mutants. Additionally, tagging of wild-type and NMD-inducing transcripts is greatly reduced in strains lacking Upf1, a conserved NMD factor also required for human histone mRNA tagging. We argue that PTC-induced translational termination differs fundamentally from normal termination in polyadenylated transcripts, as it leads to transcript degradation and prevents rather than facilitates further translation. Furthermore, transcript deadenylation and the consequent dissociation of poly(A) binding protein will result in PTC-like termination events which recruit Upf1, resulting in mRNA 3' tagging, ribosome clearance, and transcript degradation.

CUCU modification of mRNA promotes decapping and transcript degradation in Aspergillus nidulans.

In eukaryotes, mRNA decay is generally initiated by the shortening of the poly(A) tail mediated by the major deadenylase complex Ccr4-Caf1-Not. The deadenylated transcript is then rapidly degraded, primarily via the decapping-dependent pathway. Here we report that in Aspergillus nidulans both the Caf1 and Ccr4 orthologues are functionally distinct deadenylases in vivo: Caf1 is required for the regulated degradation of specific transcripts, and Ccr4 is responsible for basal degradation. Intriguingly disruption of the Ccr4-Caf1-Not complex leads to deadenylation-independent decapping. Additionally, decapping is correlated with a novel transcript modification, addition of a CUCU sequence. A member of the nucleotidyltransferase superfamily, CutA, is required for this modification, and its disruption leads to a reduced rate of decapping and subsequent transcript degradation. We propose that 3' modification of adenylated mRNA, which is likely to represent a common eukaryotic process, primes the transcript for decapping and efficient degradation.

The first filamentous fungal genome sequences: Aspergillus leads the way for essential everyday resources or dusty museum specimens?

The published Aspergillus genome sequences (A. nidulans, A. fumigatus, A. oryzae) and further sequence data from A. clavatus, Neosartorya fischeri, A. flavus, A. niger, A. parasiticus and A. terreus are the first from a group of related filamentous fungi. They indicate the gains possible from genomic approaches, but also problems that arise after the sequences are finished. Benefits include a greater understanding of genome structure and evolution, insights into gene regulation, predictions of new factors that may be relevant to pathogenicity and the discovery of novel enzymes with biotechnological value. Areas where further developments are needed include gene and structure-function predictions, methods for comparative genome analysis and the interfaces for access to genome information. In addition, strategies for continued maintenance and updating need to be developed at the start of the post-genomic era to increase the value of genome sequences into the future.

Effect of low storage temperature on some of the flavour precursors in garlic (Allium sativum).

Garlic (Allium sativum) cloves were stored at ambient temperature and 4 degrees C for periods up to six months to establish the effect of position of the individual clove within the bulb and of low storage temperature on the composition of several flavours precursors and other organic sulphur compounds, measured by gradient High Pressure Liquid Chromatography. Levels of alliin, gamma glutamyl allyl cysteine sulphoxide and gamma glutamyl isoallyl cysteine sulphoxide were statistically significantly higher in outer than in inner cloves. There was no statistically significant change in levels of alliin, the major flavour precursor, in cloves stored at 4 degrees C, remaining in the average range 17.5+/-3.8-39.1+/-7.5 mM. However, isoalliin increased significantly during storage at 4 degrees C, rising from an average 0.6+/-0.2 mM (outer cloves) -- 0.7+/-0.4 mM (inner cloves) to 7.1+/-1.7 mM (outer cloves) -- 4.1+/-0.7 mM (inner cloves). A decline in other sulphur-containing compounds, most likely to be the peptides gamma-glutamyl allylcysteine sulphoxide and gamma-glutamyl isoallylcysteine sulphoxide, occurred at the same time and possibly contributed to the increase in the flavour precursor compounds. The degree of chemical changes during storage will be of interest to the food and pharmaceutical industries.

Opposing signals differentially regulate transcript stability in Aspergillus nidulans.

A good model for gene regulation, requiring the organism to monitor a complex and changing environment and respond in a precise and rapid way, is nitrogen metabolism in Aspergillus nidulans. This involves co-ordinated expression of hundreds of genes, many dependent on the transcription factor AreA, which monitors the nitrogen state of the cell. AreA activity is in part modulated by differential degradation of its transcript in response to intracellular glutamine. Here we report that glutamine triggers synchronized degradation of a large subset of transcripts involved in nitrogen metabolism. Among these are all four genes involved in the assimilation of nitrate. Significantly, we show that two of these transcripts, niaD and niiA, are stabilized by intracellular nitrate, directly reinforcing transcriptional regulation. Glutamine-signalled degradation and the nitrate-dependent stabilization of the niaD transcript are effected at the level of deadenylation and are dependent on its 3' UTR. When glutamine and nitrate are both present, nitrate stabilization is predominant, ensuring that nitrate and the toxic intermediate nitrite are removed from the cell. Regulated transcript stability is therefore an integral part of the adaptive response. This represents the first example of distinct physiological signals competing to differentially regulate transcripts at the level of deadenylation.

Genetic analysis of the TOR pathway in Aspergillus nidulans.

We identified five genes encoding components of the TOR signaling pathway within Aspergillus nidulans. Unlike the situation in Saccharomyces cerevisiae, there is only a single Tor kinase, as in plant and animal systems, and mutant phenotypes suggest that the TOR pathway plays only a minor role in regulating nitrogen metabolism.

Biosynthesis of the flavour precursors of onion and garlic.

Onion (Allium cepa), garlic (A. sativum) and other Alliums are important because of the culinary value of their flavours and odours. These are characteristic of each species and are created by chemical transformation of a series of volatile sulphur compounds generated by cleavage of relatively stable, odourless, S-alk(en)yl cysteine sulphoxide flavour precursors by the enzymes alliinase and lachrymatory-factor synthase. These secondary metabolites are S-methyl cysteine sulphoxide (MCSO, methiin; present in most Alliums, some Brassicaceae), S-allyl cysteine sulphoxide (ACSO, alliin; characteristic of garlic), S-trans-prop-1-enyl cysteine sulphoxide (PECSO, isoalliin; characteristic of onion), and S-propyl cysteine sulphoxide (PCSO, propiin; in onion and related species). Information from studies of the transformation of putative biosynthetic intermediates, radiolabelling, and from measurements of sulphur compounds within onion and garlic have provided information to suggest a biosynthetic pathway. This may involve alk(en)ylation of the cysteine in glutathione, followed by cleavage and oxidation to form the alk(en)yl cysteine sulphoxide flavour precursors. There is also evidence that synthesis of the flavour precursors may involve (thio)alk(en)ylation of cysteine or a precursor such as O-acetyl serine. Both routes may occur depending on the physiological state of the tissue. There are indications from the effects of environmental factors, such as the availability of sulphur, that control of the biosynthesis of each flavour precursor may be different. Cysteine and glutathione metabolism are discussed to indicate parallels with Allium flavour precursor biosynthesis. Finally, possible avenues for exploration to determine the origin in planta of the alk(en)yl groups are suggested.