Two isoforms of chicken melanopsins show blue light sensitivity

Melanopsin is a vertebrate non-visual opsin and functions as a circadian photoreceptor in mammalian retinas. Here we found the expression of two kinds of melanopsin genes in the chicken pineal gland and identified the presence of five isoforms derived from these two genes. Reconstitution of the recombinant proteins with 11-cis-retinal revealed that at least two of these melanopsin protein isoforms can function as blue-sensitive photopigments with absorption maxima at 476-484nm. These values are consistent with maximal sensitivities of action spectra determined from the physiological and behavioral studies on mammalian melanopsins. The melanopsin isoforms found in this study may function as pineal circadian photoreceptors.     

Expression level of heterologous tat genes is crucial for in vivo reconstitution of a functional Tat translocase in Escherichia coli

The Tat system has the remarkable capacity of exporting proteins in folded conformation across the cytoplasmic membrane. The functional Tat translocase from Gram-negative bacteria consists of TatA, TatB and TatC proteins. To gain information about the species specificity of the Tat translocase, we cloned tat genes from Gram-negative pathogens Shigella flexneri 2a str. 301, Vibrio cholerae El Tor N16961, Pseudomonas aeruginosa PAO1, thermophilic Sulfolobus solfataricus P2, Thermus thermophilus HB8 and from three Magnetospirillum species (AMB-1, MS-1 and MSR-1), and assessed the capacity of these Tat systems to restore the Tat-dependent growth defect of Escherichia coli tat mutants. We found that whereas the tat genes from the thermophilic bacterial and archaeal species were not functional in E. coli, other tat genes could all complement the phenotype of the E. coli tat mutants. In addition, a chimera composed of the N-terminus of V. cholerae TatE and C-terminus of M. magneticum TatA was functional. Whereas the expression of the tatABC genes from P. aeruginosa and Magnetospirillum strains must be induced to obtain a functional Tat system, overproduction of the V. cholerae TatABC proteins abolished the complementation. The complementation impairment seemed to be correlated with increasing level of slow-migrating TatC isoforms. In vitro studies showed that slow-migrating TatC isoforms in the purified V. cholerae TatABC complex increased with storage time. Together these results showed that the Tat translocases from the Gram-negative bacteria are generally functional in E. coli and the expression level is crucial for in vivo reconstitution of a functional Tat translocase.     

Identification of plasma-responsive outer membrane proteins and their vaccine potential in Edwardsiella tarda using proteomic approach

We have used differential sub-proteomic methodologies to detect Edwardsiella tarda outer membrane (OM) protein expression regulation during interaction with fish and human plasma, which is the critical step of the bacterial invasion internal organs via blood circulation. Seven and nine OM proteins were differentially expressed in response to fish and human plasma stress, respectively. Six proteins, TolB2, ETAE_2935, ETAE_0245, EvpA, ETAE_2675 and OmpA, were the shared proteins with the similar changes between the two plasma treatments. Except for EvpA, which was a known protein involved in bacterial pathogenesis and stress sensing, the others were first reported here to be related to bacterial invasion and infection. Out of them, four, upregulated ETAE_0245 and OmpA and downregulated ETAE_2675 and ETAE_2935, were selected for investigation of immune protection. The upregulated OmpA and ETAE_0245 were able to induce bactericidal antibodies in mice. These findings demonstrate that differential proteomic methodologies following protein expression regulation to interaction between host and pathogen with bacterial challenge post immunization of these altered proteins is a valid approach for identifying new vaccine candidates and nicely complements other high throughput mining strategies used for vaccine discovery.     

Proteomic analysis of two Trypanosoma cruzi zymodeme 3 strains

Two Trypanosoma cruzi Z3 strains, designated as 3663 and 4167, were previously isolated from insect vectors captured in the Brazilian Amazon region. These strains exhibited different infection patterns in Vero, C6/36, RAW 264.7 and HEp-2 cell lineages, in which 3663 trypomastigote form was much less infective than 4167 ones. A proteomic approach was applied to investigate the differences in the global patterns of protein expression in these two Z3 strains. Two-dimensional (2D) protein maps were generated and certain spots were identified by mass spectrometry (MS). Our analyses revealed a significant difference in the expression profile of different proteins between strains 3663 and 4167. Among them, cruzipain, an important regulator of infectivity. This data was corroborated by flow cytometry analysis using anti-cruzipain antibody. This difference could contribute to the infectivity profiles observed for each strain by in vitro assay using different cell lines.     

Revisit on the evolutionary relationship between alternative splicing and gene duplication

Gene duplications and alternative splicing (AS) isoforms are two widespread types of genetic variations that can facilitate diversification of protein function. A number of studies claimed that after gene duplication, two AS isoforms with differential functions can be 'fixed', respectively, in each of the duplicate copies. This simple 'functional-sharing' hypothesis was recently challenged by Roux and Robinson-Rechavi (2011). Instead, they proposed a more sophisticated hypothesis, invoking that less alternative splicing genes tend to be duplicated more frequently, and single-copy genes are younger than duplicate genes, or the 'duplicability-age' hypothesis for short. In this letter, we show that all these genome-wide analyses of AS isoforms actually did not provide clear-cut evidence to nullify the basic idea of functional-sharing hypothesis. After updating our understanding of genome-wide alternative splicing, duplicability and CNV (copy number variation), we argue that the foundation of the duplicability-age hypothesis remains to be justified carefully. Finally, we suggest that a better approach to resolving this controversy is the correspondence analysis of indels (insertions and deletions) between duplicate genes to the genomic exon-intron structure, which can be used to experimentally test the effect of functional-sharing hypothesis.     

Normal newt limb regeneration requires matrix metalloproteinase function

Newts regenerate lost limbs through a complex process involving dedifferentiation, migration, proliferation, and redifferentiation of cells proximal to the amputation plane. To identify the genes controlling these cellular events, we performed a differential display analysis between regenerating and nonregenerating limbs from the newt Notophthalmus viridescens. This analysis, coupled with a direct cloning approach, identified a previously unknown Notophthalmus collagenase gene (nCol) and three known matrix metalloproteinase (MMP) genes, MMP3/10a, MMP3/10b, and MMP9, all of which are upregulated within hours of limb amputation. MMP3/10b exhibits the highest and most ubiquitous expression and appears to account for the majority of the proteolytic activity in the limb as measured by gel zymography. By testing purified recombinant MMP proteins against potential substrates, we show that nCol is a true collagenase, MMP9 is a gelatinase, MMP3/10a is a stromelysin, and MMP3/10b has an unusually broad substrate profile, acting both as a stromelysin and noncanonical collagenase. Exposure of regenerating limbs to the synthetic MMP inhibitor GM6001 produces either dwarfed, malformed limb regenerates or limb stumps with distal scars. These data suggest that MMPs are required for normal newt limb regeneration and that MMPs function, in part, to prevent scar formation during the regenerative process.     

Manganese superoxide dismutase from Biomphalaria glabrata

The investigation of the response of Biomphalaria glabrata snails to Echinostoma paraensei (digenea) at 2 days post-exposure by suppression subtractive hybridization yielded a partial sequence of the anti-oxidant enzyme manganese superoxide dismutase (MnSOD). Full-length MnSOD (669nt) from M line and BS-90 strains of B. glabrata differed by one synonymous nucleotide replacement. B. glabrata has 1-4 MnSOD loci (Southern hybridization). Both snail strains expressed MnSOD at equal baseline levels (quantitative PCR). Susceptible snails increased expression of MnSOD following infection with E. paraensei or Schistosoma mansoni, and expression was reduced in the incompatible combination (BS-90 B. glabrata and S. mansoni). Thus, MnSOD did not determine resistance or susceptibility for these parasites, but expression of MnSOD is consistent with its involvement in a stress response of B. glabrata.