The mycobacterial Mpa–proteasome unfolds and degrades pupylated substrates by engaging Pup's N‐terminus

Mycobacterium tuberculosis, along with other actinobacteria, harbours proteasomes in addition to members of the general bacterial repertoire of degradation complexes. In analogy to ubiquitination in eukaryotes, substrates are tagged for proteasomal degradation with prokaryotic ubiquitin‐like protein (Pup) that is recognized by the N‐terminal coiled‐coil domain of the ATPase Mpa (also called ARC). Here, we reconstitute the entire mycobacterial proteasome degradation system for pupylated substrates and establish its mechanistic features with respect to substrate recruitment, unfolding and degradation. We show that the Mpa–proteasome complex unfolds and degrades Pup‐tagged proteins and that this activity requires physical interaction of the ATPase with the proteasome. Furthermore, we establish the N‐terminal region of Pup as the structural element required for engagement of pupylated substrates into the Mpa pore. In this process, Mpa pulls on Pup to initiate unfolding of substrate proteins and to drag them toward the proteasome chamber. Unlike the eukaryotic ubiquitin, Pup is not recycled but degraded with the substrate. This assigns a dual function to Pup as both the Mpa recognition element as well as the threading determinant.     

The C-terminal tail of the dual-specificity Cdc25B phosphatase mediates modular substrate recognition.

Cdc25 is a dual-specificity phosphatase that catalyzes the activation of the cyclin-dependent kinases (Cdk/cyclins), thus triggering initiation and progression of successive phases of the cell cycle. In our efforts to elucidate the interaction between Cdc25B and the natural substrate, bis-phosphorylated Cdk2/CycA (Cdk2-pTpY/CycA), we have previously found that the 17 residues of the C-terminal tail mediate a factor of 10 in substrate recognition. In the studies reported here, we localize the majority of this interaction using site-directed mutagenesis to two arginine residues (Arg556 and Arg562) located within this C-terminal region. We also show that the catalytic domain of Cdc25C, which differs most significantly from Cdc25B in this tail region, has a 100-fold lower activity toward Cdk2-pTpY/CycA. We further demonstrate that the proper presentation of the C-terminal tail of Cdc25B can be achieved in a "gain-of-function" chimeric protein consisting of the C-terminal tail of Cdc25B fused onto the catalytic core of Cdc25C. The >10-fold increase in activity seen only in the chimeric protein containing the two critical arginine residues demonstrates that the modular C-terminal tail of Cdc25B is the basis for most of the catalytic advantage of Cdc25B versus Cdc25C toward the Cdk2-pTpY/CycA substrate.     

The effects of chromosomes 3A and 3B on resistance to Fusarium head blight in tetraploid wheat

Fusarium head blight (FHB) caused by Fusarium graminearum is one of the most destructive diseases of wheat in areas where the weather is warm and humid after heading. Previous studies indicate that the level of resistance to FHB varies not only among wheat cultivars but also among some of their wild relatives. No accession, however, has yet been identified to be completely immune to FHB among the Gramineae. It is known that durum wheat (Triticum turgidum L. conv. durum) is consistently more susceptible to FHB than common wheat (T. aestivum L.). The importance of the D genome in conferring resistance to FHB has been emphasized. Meanwhile, recent studies using molecular markers report effective QTLs on chromosome 3BS in a hexaploid population and on 3A in tetraploid recombinant inbred chromosome lines. In this study, we performed an evaluation of the effects of homoeologous group 3 chromosomes of T. turgidum ssp. dicoccoides on resistance to FHB using a set of chromosome substitution lines of a durum wheat cultivar 'Langdon'. The accession of T. turgidum ssp. dicoccoides examined in this study was more susceptible for Type II resistance (resistance to spread of FHB in the head) than 'Langdon'. Both of the chromosome substitution lines of 3A and 3B showed the same level of resistance with 'Langdon', but bleaching of the heads was completely prevented in the substitution lines of chromosome 3A without relationship to rachis fragility. It was concluded that the chromosome 3A of T. turgidum ssp. dicoccoides carries resistance gene(s) to head bleaching caused by FHB.     

Molecular epidemiology and evolutionary genetics of Leischmania parasites

In order to illustrate the relevance of the concepts and methods of evolutionary genetics in the understanding of the epidemiology of pathogenic agents, we develop in this paper the case of the Leishmania, a genus of parasitic protozoa. An extensive study of various natural populations of Leishmania in different countries (Old and New World) was carried out by using Multilocus Enzyme Electrophoresis (MLEE) and Random Amplified Polymorphic DNA fingerprinting (RAPD) as genetic markers. The data have been interpreted in evolutionary genetic terms. The main benefit of this approach has been to better define the concept of species in the genus Leishmnania, on rigorous phylogenetic bases. As a matter of fact, a sound taxonomical background is a prerequisite for any epidemiological approach. Since the biological concept of species is difficult or impossible to apply for most pathogenic microorganisms, we recommend relying on criteria of both phylogenetic discreteness and of epidemiological/medical relevance to describe new species of Leishmania. Through this approach, for example, we have shown that the species status of L. ( V.) perzzl.ianza can be supported. On the contrary, we have been unable to clearly distinguish L. (V.) panamensis from L. (V.) guyanensis with genetic tools. Additionally, we have shown that the epidemiological inferences based on a limited set of genetic markers can be misleading. As a matter of fact, we have demonstrated that a collection of L. (L.) infantum stocks identified as zymodeme 'MON 1' by other authors present additional genetic heterogeneity and do not correspond to a distinct 'Discrete Typing Unit' DTU, and are actually polyphyletic. Lastly, in the samples that were conveniently designed, we have confirmed that Leishmania parasites have a basically clonal population structure. As the clonal model specifies it, occasional bouts of genetic exchange remain nevertheless possible. Telling comparisons are drawn with the evolutionary genetics of other pathogens Trypanosoma cruzi and Trypanosoma congolense.     

Detection of protein-DNA interaction with a DNA probe: distinction between single-strand and double-strand DNA-protein interaction

A simple, direct method for the detection of DNA-protein interaction was developed with electrochemical methods. Single-stranded DNA (ss-DNA) probes were prepared through the chemical bonding of an oligonucleotide to a polymer film bearing carboxylic acid groups, and double-stranded DNA (ds-DNA) probes were prepared through hybridization of the complementary sequence DNA on the ss-DNA probe. Impedance spectroscopy and differential pulse voltammetry (DPV) distinguished the interaction between the DNA probes with mouse Purbeta (mPurbeta), an ss-DNA binding protein, and with Escherichia coli MutH, a ds-DNA binding protein. Impedance spectra obtained before and after the interaction of DNA probes with these proteins clearly showed the sequence-specific ss-DNA preference of mPurbeta and the sequence-specific ds-DNA preference of MutH. The concentration dependence of proteins on the response of the DNA probes was also investigated, and the detection limits of MutH and mPurbeta were 25 and 3 microg/ml, respectively. To confirm the impedance results, the variation of the current oxidation peak of adenine of the DNA probe was monitored with DPV. The formation constants of the complexes formed between the probe DNA and the proteins were estimated based on the DPV results.     

Molecular tools for a molecular medicine: analyzing genes, transcripts and proteins using padlock and proximity probes

Procedures and reagents are needed to specifically detect all the macromolecules that are being identified in the course of genome projects. We discuss how this challenge may be met using a set of ligation-based reagents termed padlock probes and proximity ligation probes. These probes include elements with affinity for specific nucleic acid and protein molecules, respectively, along with unique identifier DNA sequence elements that encode the identity of the recognized target molecules. The information content of DNA strands that form in the detection reactions are recorded after amplification, allowing the recognized target molecules to be identified. The procedures permit highly specific solution-phase or localized analyses of large sets of target molecules as required in future molecular analyses.     

Taxonomic discrimination of higher plants by pyrolysis mass spectrometry

Pyrolysis mass spectrometry (PyMS) is a rapid, simple, high-resolution analytical method based on thermal degradation of complex material in a vacuum and has been widely applied to the discrimination of closely related microbial strains. Leaf samples of six species and one variety of higher plants (Rosa multiflora, R. multiflora var. platyphylla, Sedum kamtschaticum, S. takesimense, S. sarmentosum, Hepatica insularis, and H. asiatica) were subjected to PyMS for spectral fingerprinting. Principal component analysis of PyMS data was not able to discriminate these plants in discrete clusters. However, canonical variate analysis of PyMS data separated these plants from one another. A hierarchical dendrogram based on canonical variate analysis was in agreement with the known taxonomy of the plants at the variety level. These results indicate that PyMS is able to discriminate higher plants based on taxonomic classification at the family, genus, species, and variety level.Abbreviations ANNs Artificial neural networks - CVA Canonical variate analysis - GC/MS Gas chromatography/mass spectrometry - PCA Principal component analysis - PyMS Pyrolysis mass spectrometry - UPGMA Unweighted pair group method with arithmetic mean Communicated by I.S. Chung     

Structure and functional analysis of the fungal galectin CGL2

Recognition of and discrimination between potential glyco-substrates is central to the function of galectins. Here we dissect the fundamental parameters responsible for such selectivity by the fungal representative, CGL2. The 2.1 A crystal structure of CGL2 and five substrate complexes reveal that this prototype galectin achieves increased substrate specificity by accommodating substituted oligosaccharides of the mammalian blood group A/B type in an extended binding cleft. Kinetic studies on wild-type and mutant CGL2 proteins demonstrate that the tetrameric organization is essential for functionality. The geometric constraints due to the orthogonal orientation of the four binding sites have important consequences on substrate binding and selectivity.     

Parallel gene analysis with allele-specific padlock probes and tag microarrays

Parallel, highly specific analysis methods are required to take advantage of the extensive information about DNA sequence variation and of expressed sequences. We present a scalable laboratory technique suitable to analyze numerous target sequences in multiplexed assays. Sets of padlock probes were applied to analyze single nucleotide variation directly in total genomic DNA or cDNA for parallel genotyping or gene expression analysis. All reacted probes were then co-amplified and identified by hybridization to a standard tag oligonucleotide array. The technique was illustrated by analyzing normal and pathogenic variation within the Wilson disease-related ATP7B gene, both at the level of DNA and RNA, using allele-specific padlock probes.     

Overnight lysis improves the efficiency of detection of DNA damage in the alkaline comet assay

The ability to detect DNA damage using the alkaline comet assay depends on pH, lysis time and temperature during lysis. However, it is not known whether different lysis conditions identify different types of DNA damage or simply measure the same damage with different efficiencies. Results support the latter interpretation for radiation, but not for the alkylating agent MNNG. For X-ray-induced damage, cells showed the same amount of damage, regardless of lysis pH (12.3 compared to >13). However, increasing the duration of lysis at 5 degrees C from 1 h to more than 6 h increased the amount of DNA damage detected by almost twofold. Another twofold increase in apparent damage was observed by conducting lysis at room temperature (22 degrees C) for 6 h, but at the expense of a higher background level of DNA damage. The oxygen enhancement ratio and the rate of rejoining of single-strand breaks after irradiation were similar regardless of pH and lysis time, consistent with more efficient detection of strand breaks rather than detection of damage to the DNA bases. Conversely, after MNNG treatment, DNA damage was dependent on both lysis time and pH. With the higher-pH lysis, there was a reduction in the ratio of oxidative base damage to strand breaks as revealed using treatment with endonuclease III and formamidopyrimidine glycosylase. Therefore, our current results support the hypothesis that the increased sensitivity of longer lysis at higher pH for detecting radiation-induced DNA damage is due primarily to an increase in efficiency for detecting strand breaks, probably by allowing more time for DNA unwinding and diffusion before electrophoresis.