Evidence for the phenotypic neutrality of the Neurospora Varkud (V) and Varkud satellite (VS) plasmids.

The Varkud satellite (VS) plasmid, which requires the Varkud (V) plasmid for replication, is found in the mitochondria of several natural isolates of Neurospora. The VS transcript is sufficiently abundant that it might be expected to alter the function of mitochondria; however, previous limited characterization revealed no effect. In this work we have used genetic, biochemical and proteomic approaches to search for effects of the V and VS plasmids. We observed differences in the relative abundance of several mitochondrial proteins between plasmid-containing and plasmid-lacking natural isolates, but subsequently found these not to be due to the plasmids. We constructed a pair of iso-nuclear and iso-mitochondrial strains that differed only by the presence or absence of V and VS, and observed only subtle differences in the abundance of several mitochondrial proteins. We further attempted to detect a cryptic plasmid-related phenotype by growing this pair of strains in the presence of a variety of inhibitors of mitochondrial function or other stress conditions: this also revealed no effect of the plasmids. These observations suggest that, despite the high concentration of VS RNA in the mitochondrion, the V and VS plasmids do not cause substantial changes in the host.

Data variance and statistical significance in 2D-gel electrophoresis and DIGE experiments: comparison of the effects of normalization methods.

Identifying changes in the relative abundance of proteins between different biological samples is often confounded by technical noise. In this work, we compared eight normalization methods commonly used in two-dimensional gel electrophoresis and difference gel electrophoresis (DIGE) experiments for their ability to reduce noise and for their influence on the list of proteins whose difference in abundance between two samples is determined to be statistically significant. With respect to reducing noise we find that, while all methods improve upon unnormalized data, cyclic linear normalization is the least well suited to gel-based proteomics and the performances of the other methods are similar. We also find in DIGE data that the choice of normalization method has less of an impact on the noise than does the decision to use an internal reference in the experimental design and that both normalization and standardization using the internal reference are required to maximally reduce variance. Despite the similar noise reduction achieved by most normalization methods, the list of proteins whose abundance was determined to differ significantly between biological groups differed depending on the choice of normalization method. This work provides a direct comparison of the impact of normalization methods in the context of common experimental designs.

Gel-based mass spectrometric and computational approaches to the mitochondrial proteome of Neurospora.

We have used gel electrophoretic techniques including isoelectric focusing, blue native, acid-urea, 16-benzyldimethyl-n-hexadecylammonium chloride or SDS first dimensions and SDS Laemmli or tricine second dimensions to separate the proteins from highly-purified Neurospora mitochondria and sub-mitochondrial fractions (membrane, soluble, protein complexes and ribonucleoproteins). The products of 260 genes, many of them in multiple processed or modified forms, were identified by MALDI-TOF mass spectrometry. This work confirms the existence, expression, and mitochondrial localization of the products of 55 Neurospora genes previously annotated only as predicted or hypothetical, and of 101 genes not identified in previous mass spectrometry studies. Combined with previous mass spectrometry studies, and re-evaluation of genome annotations, we have compiled a curated list of 358 proteins identified in proteomic studies that are likely to be bona fide mitochondrial proteins plus 80 other identified proteins that may be mitochondrial. Literature data mining and computational predictions suggest that Neurospora mitochondria also contain another 299 proteins not yet identified in proteomics projects. Taken together, these data suggest that the products of at least 738 genes comprise the Neurospora mitochondrial proteome.

Database for mobile group II introns.

Group II introns are self-splicing RNAs and retroelements found in bacteria and lower eukaryotic organelles. During the past several years, they have been uncovered in surprising numbers in bacteria due to the genome sequencing projects; however, most of the newly sequenced introns are not correctly identified. We have initiated an ongoing web site database for mobile group II introns in order to provide correct information on the introns, particularly in bacteria. Information in the web site includes: (1) introductory information on group II introns; (2) detailed information on subfamilies of intron RNA structures and intron-encoded proteins; (3) a listing of identified introns with correct boundaries, RNA secondary structures and other detailed information; and (4) phylogenetic and evolutionary information. The comparative data should facilitate study of the function, spread and evolution of group II introns. The database can be accessed at http://www.fp.ucalgary.ca/group2introns/.