Searching for schizophrenia genes

Schizophrenia is characterized by profound disturbances of cognition, emotion and social functioning. It carries a lifetime risk within the general population of approximately 1%. Genetic epidemiological studies have shown that the syndrome has a high heritability, indicating a significant genetic component to its aetiology. However, the undoubted complexity and probable heterogeneity of the disorder continue to confound research, and the precise underlying neurobiological mechanisms remain largely unknown. Although molecular-genetic approaches face formidable difficulties, the identification of susceptibility genes is likely to provide valuable insights into the aetiology and pathogenesis that could lead to the development of more effective treatments.     

Searching for RNA genes using base-composition statistics

The hypothesis that genomic regions rich in non-protein-coding RNAs (ncRNAs) can be identified using local variations in single-base and dinucleotide statistics has been investigated. (G+C)%, (G-C)% difference, (A-T)% difference and dinucleotide-frequency statistics were compared among seven classes of ncRNAs and three genomes. Significant variations were observed in (G+C)% and, in Methanococcus jannaschii, in the frequency of the dinucleotide 'CG'. Screening programs based on these two base-composition statistics were developed. With (G+C)% screening alone, a 1% fraction of the M.jannaschii genome containing all 44 known transfer RNAs, ribosomal RNAs and signal recognition particle RNAs could be identified. When (G+C)% combined with CG dinucleotide-frequency screening was used, 43 of the 44 known M.jannaschii structural ncRNAs were again identified, while the number of presumably false hits overlapping a known or putative protein-coding gene was reduced from 15 to 6. In addition, 19 candidate ncRNAs were identified including one with significant homology to several known archaeal RNaseP RNAs.     

Searching for synaptonemal complex proteins and their genes

As an alternative to the production and use of monoclonal antisynaptonemal complex (SC) antibodies to isolate SC genes, we have explored the use of polyclonal anti-SC antibodies to identify SC genes from a cDNA expression library. The method proved relatively simple, reliable, and fast and has yielded two SC genes. A homologue of one of these genes from a different species has previously been isolated in another laboratory. © 1993 Wiley-Liss, Inc.     

Searching for synaptonemal complex proteins and their genes.

As an alternative to the production and use of monoclonal antisynaptonemal complex (SC) antibodies to isolate SC genes, we have explored the use of polyclonal anti-SC antibodies to identify SC genes from a cDNA expression library. The method proved relatively simple, reliable, and fast and has yielded two SC genes. A homologue of one of these genes from a different species has previously been isolated in another laboratory.     

Searching for new cell wall protein genes in Arabidopsis

The objective of this study was to test an approach that combines bioinformatic and subcellular localization analysis to identify novel cell wall protein genes in Arabidopsis. Proteins with unknown function in the Arabidopsis genome were first identified and scanned for the presence of N-terminal signal peptides. The signal peptide-containing function-unknown proteins were further analyzed to eliminate the ones containing other sequences, such as endoplasmic reticulum and vacuole retention signals, that may prevent a protein from secretion into cell walls. The top ten genes passing the bioinformatic analysis were selected for protein subcellular localization using green fluorescence protein (GFP) as a reporter. A vector was constructed for high throughput gene-GFP fusion protein generation and overexpression in Arabidopsis for gene function analysis. Transformants of six genes showed reasonable expression of GFP fusion protein. However, none of the transformants showed GFP localization in cell walls. The low rate of new cell wall protein discovery suggests that the number of unidentified cell wall proteins in the Arabidopsis genome may be small.     

Searching for tRNA genes in DNA sequences--an IBM microcomputer program

A user-friendly program that enables fast and exhaustive searchingfor tRNA genes is presented. The program can run on IBM personalmicrocomputers and comprises modules for sequence editing andGenBank database access. Received on June 13, 1989; accepted on August 30, 1989     

Intricacies and surprises of nuclear-mitochondrial co-evolution

In this issue of the Biochemical Journal, Watanabe and colleagues disclose another fascinating facet of the mitochondrial protein synthesis machinery: one of the two nematode mitochondrial elongation factors Tu, EF-Tu1, specifically recognizes the D-arm of T-armless tRNAs via a 57-amino-acid C-terminal extension that compensates for the reduction in tRNA structure. This principle provides a paradigm for the evolutionary events thought to have ignited the transition from an ancient 'RNA world' to the 'protein world' of today.     

Searching for signals of evolutionary selection in 168 genes related to immune function

Pathogens have played a substantial role in human evolution, with past infections shaping genetic variation at loci influencing immune function. We selected 168 genes known to be involved in the immune response, genotyped common single nucleotide polymorphisms across each gene in three population samples (CEPH Europeans from Utah, Han Chinese from Guangxi, and Yoruba Nigerians from Southwest Nigeria) and searched for evidence of selection based on four tests for non-neutral evolution: minor allele frequency (MAF), derived allele frequency (DAF), Fst versus heterozygosity and extended haplotype homozygosity (EHH). Six of the 168 genes show some evidence for non-neutral evolution in this initial screen, with two showing similar signals in independent data from the International HapMap Project. These analyses identify two loci involved in immune function that are candidates for having been subject to evolutionary selection, and highlight a number of analytical challenges in searching for selection in genome-wide polymorphism data. Electronic Supplementary Material Supplementary material is available for this article at and is accessible for authorized users. Emily C. Walsh, Pardis Sabeti, Holli B. Hutcheson, and Ben Fry have contributed equally to this work and Stephen O’Brien and David Altshuler have jointly supervised this project     

Expression levels of meristem identity and homeotic genes are modified by nuclear-mitochondrial interactions in alloplasmic male-sterile lines of Brassica napus

Homeotic conversions of anthers were found in cytoplasmic male sterile (CMS) plants of Brassica napus derived from somatic hybrids of B. napus and Arabidopsis thaliana. CMS line flowers displayed petals reduced in size and width and stamens replaced by carpelloid structures. In order to investigate when these developmental aberrations appeared, flower development was analysed histologically, ultrastructurally and molecularly. Disorganized cell divisions were detected in the floral meristems of the CMS lines at stage 4. As CMS is associated with mitochondrial aberrations, ultrastructural analysis of the mitochondria in the floral meristems was performed. Two mitochondrial populations were found in the CMS lines. One type had disrupted cristae, while the other resembled mitochondria typical of B. napus. Furthermore, expression patterns of genes expressed in particular floral whorls were determined. In spite of the aberrant development of the third whorl organs, BnAP3 was expressed as in B. napus during the first six stages of development. However, the levels of BnPI were reduced. At later developmental stages, the expression of both BnAP3 and BnPI was strongly reduced. Interestingly the expression levels of genes responsible for AP3 and PI activation such as LFY, UFO and ASK1 were higher in the CMS lines, which indicates that activation of B-genes in the CMS lines does not occur as in B. napus. Disrupted and dysfunctional mitochondria seem to be one of the first aberrations manifested in CMS which result in a retrograde influence of the expression levels of genes responsible for the second and third whorl organ differentiation.     

Functional constraints of nuclear-mitochondrial DNA interactions in xenomitochondrial rodent cell lines

The co-evolution of nuclear and mitochondrial genomes in vertebrates led to more than 100 specific interactions that are crucial for an optimized ATP generation. These interactions have been examined by introducing rat mtDNA into mouse cells devoid of mitochondrial DNA (mtDNA). When mtDNA-less cells derived from the common mouse (Mus musculus domesticus) were fused to cytoplasts prepared from Mus musculus, Mus spretus, or rat (Rattus norvegicus), a comparable number of respiring clones could be obtained. Mouse xenomitochondrial cybrids harboring rat mtDNA had a slower growth rate in medium containing galactose as the carbon source, suggesting a defect in oxidative phosphorylation. These clones respired approximately 50% less than the parental mouse cells or xenomitochondrial cybrids harboring Mus spretus mtDNA. The activities of respiratory complexes I and IV were approximately 50% lower, but mitochondrial protein synthesis was unaffected. The defects in complexes I and IV were associated with decreased steady-state levels of respective subunits suggesting problems in assembly. We also showed that the presence of 10% mouse mtDNA co-existing with rat mtDNA was sufficient to restore respiration to normal levels. Our results suggest that evolutionary distance alone is not a precise predictor of nuclear-mitochondrial interactions as previously suggested for primates.     

Searching for partners

A combination of the EMARS reaction and the application of mass spectrometry-based proteomics techniques promises to permit cell-surface molecular clustering to be analyzed under physiological conditions [Jiang et al., Proteomics 2012, 12, 54-62]. It is very likely that this approach will provide new insights into a wide range of research areas directed at understanding the cell-surface interactome.     

Searching for candidate speciation genes using a proteomic approach: seminal proteins in field crickets

In many animals, male seminal proteins influence gamete interactions and fertilization ability and are probably involved in barriers to gene flow between diverging lineages. Here we use a proteomic approach to identify seminal proteins that are transferred to females during copulation and that may be involved in fertilization barriers between two hybridizing field crickets (Gryllus firmus and Gryllus pennsylvanicus). Analyses of patterns of divergence suggest that much of the field cricket genome has remained undifferentiated following the evolution of reproductive isolation. By contrast, seminal protein genes are highly differentiated. Tests of selection reveal that positive selection is likely to be responsible for patterns of differentiation. Together, our observations suggest that some of the loci encoding seminal proteins may indeed play a role in fertilization barriers in field crickets.