Domain organization and phylogenetic analysis of proteins from the chitin deacetylase gene family of Tribolium castaneum and three other species of insects

A bioinformatics investigation of four insect species with annotated genome sequences identified a family of genes encoding chitin deacetylase (CDA)-like proteins, with five to nine members depending on the species. CDAs (EC 3.5.1.41) are chitin-modifying enzymes that deacetylate the beta-1,4-linked N-acetylglucosamine homopolymer. Partial deacetylation forms a heteropolysaccharide that also contains some glucosamine residues, while complete deacetylation produces the homopolymer chitosan, consisting exclusively of glucosamine. The genomes of the red flour beetle, Tribolium castaneum, the fruit fly, Drosophila melanogaster, the malaria mosquito, Anopheles gambiae, and the honey bee, Apis mellifera contain 9, 6, 5 and 5 genes, respectively, that encode proteins with a chitin deacetylase motif. The presence of alternative exons in two of the genes, TcCDA2 and TcCDA5, increases the protein diversity further. Insect CDA-like proteins were classified into five orthologous groups based on phylogenetic analysis and the presence of additional motifs. Group I enzymes include CDA1 and isoforms of CDA2, each containing in addition to a polysaccharide deacetylase-like catalytic domain, a chitin-binding peritrophin-A domain (ChBD) and a low-density lipoprotein receptor class A domain (LDLa). Group II is composed of CDA3 orthologs from each insect species with the same domain organization as group I CDAs, but differing substantially in sequence. Group III includes CDA4s, which have the ChBD domain but do not have the LDLa domain. Group IV comprises CDA5s, which are the largest CDAs because of a very long intervening region separating the ChBD and catalytic domains. Among the four insect species, Tribolium is unique in having four CDA genes in group V, whereas the other insect genomes have either one or none. Most of the CDA-like proteins have a putative signal peptide consistent with their role in modifying extracellular chitin in both cuticle and peritrophic membrane during morphogenesis and molting.     

Biodiversity of pig breeds from China and Europe estimated from pooled DNA samples: differences in microsatellite variation between two areas of domestication

Microsatellite diversity in European and Chinese pigs was assessed using a pooled sampling method on 52 European and 46 Chinese pig populations. A Neighbor Joining analysis on genetic distances revealed that European breeds were grouped together and showed little evidence for geographic structure, although a southern European and English group could tentatively be assigned. Populations from international breeds formed breed specific clusters. The Chinese breeds formed a second major group, with the Sino-European synthetic Tia Meslan in-between the two large clusters. Within Chinese breeds, in contrast to the European pigs, a large degree of geographic structure was noted, in line with previous classification schemes for Chinese pigs that were based on morphology and geography. The Northern Chinese breeds were most similar to the European breeds. Although some overlap exists, Chinese breeds showed a higher average degree of heterozygosity and genetic distance compared to European ones. Between breed diversity was even more pronounced and was the highest in the Central Chinese pigs, reflecting the geographically central position in China. Comparing correlations between genetic distance and heterozygosity revealed that China and Europe represent different domestication or breed formation processes. A likely cause is a more diverse wild boar population in Asia, but various other possible contributing factors are discussed.     

Selective detection, quantification, and subcellular location of alpha-synuclein aggregates with a protein aggregate filtration assay

Parkinson's disease (PD), dementia with Lewy bodies (DLB), and multiple system atrophy are caused by alpha-synuclein aggregates. At present, there is no good biochemical method defining alpha-synuclein aggregates formed in vivo versus oligomers as a means to investigate alpha-synuclein aggregation and its mechanisms of neurodegeneration. A simple method, therefore, for the selective and sensitive detection of alpha-synuclein aggregates suited for screening purposes would be useful. Since in contrast to prions a proper detection of alpha-synuclein aggregates by Western blot analysis is difficult, we developed a protein aggregate filtration (PAF) assay. It takes advantage of the inherent insolubility of aggregated alpha-synuclein using microfiltration to separate it from soluble isoforms. For the first time, this assay even makes quantitative comparisons possible. We describe how the PAF assay can be applied to human brain tissue and animal and cell culture models, as well as used as a screening method for the subcellular location of alpha-synuclein aggregates. Since it detects the pathological isoform instead of surrogate markers, the PAF assay may have also potential in diagnosis of PD and DLB.     

Functional analysis of four neuropeptides, EH, ETH, CCAP and bursicon, and their receptors in adult ecdysis behavior of the red flour beetle, Tribolium castaneum

Ecdysis behavior in arthropods is driven by complex interactions among multiple neuropeptide signaling systems. To understand the roles of neuropeptides and their receptors in the red flour beetle, Tribolium castaneum, we performed systemic RNA interference (RNAi) experiments utilizing post-embryonic injections of double-stranded (ds) RNAs corresponding to ten gene products representing four different peptide signaling pathways: eclosion hormone (EH), ecdysis triggering hormone (ETH), crustacean cardioactive peptide (CCAP) and bursicon. Behavioral deficiencies and developmental arrests occurred as follows: RNAi of (1) eh or eth disrupted preecdysis behavior and prevented subsequent ecdysis behavior; (2) ccap interrupted ecdysis behavior; and (3) bursicon subunits resulted in wrinkled elytra due to incomplete wing expansion, but there was no effect on cuticle tanning or viability. RNAi of genes encoding receptors for those peptides produced phenocopies comparable to those of their respective cognate neuropeptides, except in those cases where more than one receptor was identified. The phenotypes resulting from neuropeptide RNAi in Tribolium differ substantially from phenotypes of the respective Drosophila mutants. Results from this study suggest that the functions of neuropeptidergic systems that drive innate ecdysis behavior have undergone significant changes during the evolution of arthropods.     

The auxin influx carrier LAX3 promotes lateral root emergence

Lateral roots originate deep within the parental root from a small number of founder cells at the periphery of vascular tissues and must emerge through intervening layers of tissues. We describe how the hormone auxin, which originates from the developing lateral root, acts as a local inductive signal which re-programmes adjacent cells. Auxin induces the expression of a previously uncharacterized auxin influx carrier LAX3 in cortical and epidermal cells directly overlaying new primordia. Increased LAX3 activity reinforces the auxin-dependent induction of a selection of cell-wall-remodelling enzymes, which are likely to promote cell separation in advance of developing lateral root primordia.     

Systematic investigation of the hemolymph proteome of Manduca sexta at the fifth instar larvae stage using one- and two-dimensional proteomics platforms

Manduca sexta is an excellent insect model for studying insect physiology, including hemolymph proteins. Larvae stages of this insect are highly damaging to tobacco leaves causing a drastic decrease in crop yield. Investigation on the larval biology should help in controlling its destructive potential, thus increasing crop yields. The hemolymph is the source of its immunity to disease and environmental factors, which invariably involves protein components. To better understand the physiology of M. sexta and the protein components expressed during its life cycle, two complementary proteomics approaches, one- and two-dimensional gel electrophoresis (1-DGE and 2-DGE) in conjunction with N-terminal amino acid sequencing and liquid chromatography-mass spectrometry, were employed to analyze the fifth instar larvae hemolymph proteins. These proteomics approaches together identified 123 proteins, which constituted a total of 58 nonredundant proteins and belonged to 10 functional categories. Defense (49%), transport and metabolism (15%), storage (9%), and metamorphosis (7%) categories were highly represented accounting for 80% of the identified proteins. Besides identification of previously reported proteins, 18 novel proteins were identified, which include the lipoprotein-releasing system transmembrane protein lolC, 50S ribosomal protein L24, inducible serine protease inhibitor 1, imaginal disk growth factor, protein disulfide-isomerase-like protein ERp57, etc. The 2-DGE data were integrated to develop a 2-D gel reference map. Data obtained from 1-DGE and 2-DGE analyses are accessible through the M. sexta proteomics portal ( http://foodfunc.agr.ibaraki.ac.jp/mansehemoprot.html). Together, this study provides evidence for the presence of a large number of functionally diverse protein families in the hemolymph of M. sexta. These proteins correlate well with the fifth instar stage, the transition from larvae to pupae.     

Rhythm generation through period concatenation in rat somatosensory cortex

Rhythmic voltage oscillations resulting from the summed activity of neuronal populations occur in many nervous systems. Contemporary observations suggest that coexistent oscillations interact and, in time, may switch in dominance. We recently reported an example of these interactions recorded from in vitro preparations of rat somatosensory cortex. We found that following an initial interval of coexistent gamma ( approximately 25 ms period) and beta2 ( approximately 40 ms period) rhythms in the superficial and deep cortical layers, respectively, a transition to a synchronous beta1 ( approximately 65 ms period) rhythm in all cortical layers occurred. We proposed that the switch to beta1 activity resulted from the novel mechanism of period concatenation of the faster rhythms: gamma period (25 ms)+beta2 period (40 ms) = beta1 period (65 ms). In this article, we investigate in greater detail the fundamental mechanisms of the beta1 rhythm. To do so we describe additional in vitro experiments that constrain a biologically realistic, yet simplified, computational model of the activity. We use the model to suggest that the dynamic building blocks (or motifs) of the gamma and beta2 rhythms combine to produce a beta1 oscillation that exhibits cross-frequency interactions. Through the combined approach of in vitro experiments and mathematical modeling we isolate the specific components that promote or destroy each rhythm. We propose that mechanisms vital to establishing the beta1 oscillation include strengthened connections between a population of deep layer intrinsically bursting cells and a transition from antidromic to orthodromic spike generation in these cells. We conclude that neural activity in the superficial and deep cortical layers may temporally combine to generate a slower oscillation.     

Depletion of stromal P(i) induces high 'energy-dependent' antenna exciton quenching (q(E)) by decreasing proton conductivity at CF(O)-CF(1) ATP synthase.

This work tests two models to account for the effects of depletion of stromal inorganic phosphate (P(i)), which results in down-regulation of light capture via the exciton quenching (q(E)) mechanism and has been proposed to act in feedback regulation of the light reactions. In both models, antenna down-regulation is activated by acidification of the lumen, despite the fact that linear electron flow (LEF) (and associated proton flux) is decreased upon P(i) depletion. In one model, an imbalance of ATP or NADPH activates cyclic electron transfer around photosystem I (CEF1), increasing proton influx to the lumen. In the second, the effective conductivity of the CF(O)-CF(1) ATP synthase to protons (g(H)(+)) is decreased, retarding proton efflux from the lumen. Sequestering of P(i) by mannose infiltration increased sensitivities of q(E) and pmf to LEF. The effects were attributable to decreases in g(H)(+), but not to CEF1 and were largely reversed by subsequent P(i) feeding. Rapid recovery of g(H)(+) in the dark suggested that dark-labile metabolic pools are responsible for regulation of the ATP synthase. Overall, these results support models where accumulation of Benson-Calvin cycle intermediates or lowering of stromal P(i) below its K(M)at the ATP synthase, retards proton efflux from the lumen, leading to build-up of pmf and subsequent down-regulation of photosynthetic light capture.     

Development of a highthroughput yeast-based assay for detection of metabolically activated genotoxins

The potential genotoxicity of drug candidates is a serious concern during drug development. Therefore, it is important to assess the potential genotoxicity and mutagenicity of a compound early in the discovery phase of drug development. AMES Salmonella assay is the most widely used assay for the assessment of mutagenicity and genotoxicity. However, the AMES assay is not readily adaptable to highthroughput screening and several strains of Salmonella must be employed to ensure that different types of DNA damage can be studied. Therefore, an additional robust highthroughput genotoxicity screen would be of significant value in the early detection and elimination of genotoxicity. The complexity of DNA damage requires numerous cellular pathways, thus using single model organism to predict genotoxicity in early stage is challenging. Another critical component of such screens is that they incorporate the capability of metabolic activation to ensure that no genotoxic metabolites are generated. We have developed a novel highthroughput reporter assay for DNA repair that detects genotoxicity, and which incorporates metabolic activation. The assay has a low compound requirement as compared to Ames, and relies upon two different reporter genes cotransfected into a yeast strain. The gene encoding Renilla luciferase is fused to the constitutive 3-phosphoglycerate kinase (PGK1) promoter and integrated into the yeast genome to provide a control for cell numbers. The firefly luciferase gene is fused to the RAD51 (bacterial RecA homolog) promoter and used to report an increase in DNA repair activity. A dual luciferase assay is performed by measuring the firefly and Renilla luciferase activities in the same sample. The result is expressed as the ratio of the two luciferase activities; changes from the base level (control) are interpreted as induction of the RAD51 promoter and evidence of DNA repair activity in eukaryote cells due to DNA damage. The yeast dual luciferase reporter has been characterized with and without S-9 activation using positive and negative control agents. This assay is efficient, requires little time and low amounts of compound. The assay is compatible with metabolic activation, adaptable to a highthroughput platform, and yields data that accurately and reproducibly detects DNA damage. Whereas the normal yeast cell wall, plasma membrane composition and the presence of active transporters can prevent the entry or persistence of some compounds internally in yeast cells, our assay did show concordance with regulatory mutagenicity assays, many of which require metabolic activation and are poorly detected by bacterial mutagenicity assays. Although there were false negative results, in our hands this assay performs as well as or better than other commercially available genetox assays. Furthermore, the RAD51 gene is strongly inducible by homologous intrachromosomal recombination; thus this assay may provide a means to detect clastogens. The RAD51 promoter fused dual luciferase assay represents a valuable addition to the armamentarium for the early detection of genotoxic compounds.