Towards the Ictalurid Catfish Transcriptome: Generation and Analysis of 31,215 Catfish ESTs.

Background EST sequencing is one of the most efficient means for gene discovery and molecular marker development, and can be additionally utilized in both comparative genome analysis and evaluation of gene duplications. While much progress has been made in catfish genomics, large-scale EST resources have been lacking. The objectives of this project were to construct primary cDNA libraries, to conduct initial EST sequencing to generate catfish EST resources, and to obtain baseline information about highly expressed genes in various catfish organs to provide a guide for the production of normalized and subtracted cDNA libraries for large-scale transcriptome analysis in catfish. Results A total of 17 cDNA libraries were constructed including 12 from channel catfish (Ictalurus punctatus) and 5 from blue catfish (I. furcatus). A total of 31,215 ESTs, with average length of 778 bp, were generated including 20,451 from the channel catfish and 10,764 from blue catfish. Cluster analysis indicated that 73% of channel catfish and 67% of blue catfish ESTs were unique within the project. Over 53% and 50% of the channel catfish and blue catfish ESTs, respectively, had significant similarities to known genes. All ESTs have been deposited in GenBank. Evaluation of the catfish EST resources demonstrated their potential for molecular marker development, comparative genome analysis, and evaluation of ancient and recent gene duplications. Subtraction of abundantly expressed genes in a variety of catfish tissues, identified here, will allow the production of low-redundancy libraries for in-depth sequencing. Conclusion The sequencing of 31,215 ESTs from channel catfish and blue catfish has significantly increased the EST resources in catfish. The EST resources should provide the potential for microarray development, polymorphic marker identification, mapping, and comparative genome analysis

Gender and Weight Shape Brain Dynamics during Food Viewing

Hemodynamic imaging results have associated both gender and body weight to variation in brain responses to food-related information. However, the spatio-temporal brain dynamics of gender-related and weight-wise modulations in food discrimination still remain to be elucidated. We analyzed visual evoked potentials (VEPs) while normal-weighted men (n = 12) and women (n = 12) categorized photographs of energy-dense foods and non-food kitchen utensils. VEP analyses showed that food categorization is influenced by gender as early as 170 ms after image onset. Moreover, the female VEP pattern to food categorization co-varied with participants' body weight. Estimations of the neural generator activity over the time interval of VEP modulations (i.e. by means of a distributed linear inverse solution [LAURA]) revealed alterations in prefrontal and temporo-parietal source activity as a function of image category and participants' gender. However, only neural source activity for female responses during food viewing was negatively correlated with body-mass index (BMI) over the respective time interval. Women showed decreased neural source activity particularly in ventral prefrontal brain regions when viewing food, but not non-food objects, while no such associations were apparent in male responses to food and non-food viewing. Our study thus indicates that gender influences are already apparent during initial stages of food-related object categorization, with small variations in body weight modulating electrophysiological responses especially in women and in brain areas implicated in food reward valuation and intake control. These findings extend recent reports on prefrontal reward and control circuit responsiveness to food cues and the potential role of this reactivity pattern in the susceptibility to weight gain

Evolutionarily conserved pattern of AMPA receptor subunit glycosylation in Mammalian frontal cortex.

Protein glycosylation may contribute to the evolution of mammalian brain complexity by adapting excitatory neurotransmission in response to environmental and social cues. Balanced excitatory synaptic transmission is primarily mediated by glutamatergic neurotransmission. Previous studies have found that subunits of the AMPA subtype of glutamate receptor are N-glycosylated, which may play a critical role in AMPA receptor trafficking and function at the cell membrane. Studies have predominantly used rodent models to address altered glycosylation in human pathological conditions. Given the rate of mammalian brain evolution and the predicted rate of change in the brain-specific glycoproteome, we asked if there are species-specific changes in glycoprotein expression, focusing on the AMPA receptor. N-glycosylation of AMPA receptor subunits was investigated in rat (Rattus norvegicus), tree shrew (Tupaia glis belangeri), macaque (Macaca nemestrina), and human frontal cortex tissue using a combination of enzymatic deglycosylation and Western blot analysis, as well as lectin binding assays. We found that two AMPA receptor subunits, GluA2 and GluA4, are sensitive to deglycosylation with Endo H and PNGase F. When we enriched for glycosylated proteins using lectin binding assays, we found that all four AMPA receptor subunits are glycosylated, and were predominantly recognized by lectins that bind to glucose or mannose, N-acetylglucosamine (GlcNAc), or 1-6αfucose. We found differences in glycosylation between different subunits, as well as modest differences in glycosylation of homologous subunits between different species

Effective immunoprecipitation of AMPA receptor subunits from human frontal cortex.

<p>GluA2 was immunoprecipitated from homogenized human frontal cortex in buffers with (A) 1% Triton X-100 plus 1% SDS, (B) 1% Triton X-100 plus 0.5% SDS, or (C) 1% Triton X-100. GluA2 was immunoisolated without co-precipitation of the GluA1, GluA3, or GluA4 subunits only in conditions with 1% SDS.</p

AMPA receptor subunit binding to lectins.

<p>AMPA receptor subunits from frontal cortex of rat, tree shrew, macaque and human cortex were purified with 15 biotinylated lectins (<a href="http://www.plosone.org/article/info:doi/10.1371/journal.pone.0094255#pone-0094255-g005" target="_blank">Figure 5</a>). Proteins that bound to lectins were separated by SDS–polyacrylamide electrophoresis, transferred to nitrocellulose membranes, and probed using specific antisera for each AMPA receptor subunit.</p

Glycan specificity of lectins.

<p>Glycan specificity of lectins.</p

Enzymatic deglycosylation assay of AMPA receptor subunits.

<p>(A) Representative immunoblots showing changes in electrophoretic mobility for GluA2 and GluA4, but not GluA1 or GluA3, following deglycosylation with Endo H or PNGase F in rat, tree shrew, macaque, and human frontal cortex. (B) Quantification of Endo H-sensitive molecular mass shifts for GluA2 and GluA4. Data are presented as the distance between the Endo H-deglycosylated protein band of higher mobility, and the same protein without Endo H treatment. (C) Quantification of Endo H-sensitive molecular mass shifts for GluA2 and GluA4. Graphs show the ratio of measured intensities of the Endo H-sensitive band to the Endo H-insensitive band. (D) Quantification of PNGase F-sensitive molecular mass shifts for GluA2 and GluA4. Data are presented as the distance between the PNGase F deglycosylated protein band of higher mobility, and the same protein without PNGase F treatment. Graphs represent means ± SD calculated from three independent experiments.</p

Patients with sporadic FTLD exhibit similar increases in lysosomal proteins and storage material as patients with FTD due to GRN mutations.

Loss of function progranulin (GRN) mutations are a major autosomal dominant cause of frontotemporal dementia (FTD). Patients with FTD due to GRN mutations (FTD-GRN) develop frontotemporal lobar degeneration with TDP-43 pathology type A (FTLD-TDP type A) and exhibit elevated levels of lysosomal proteins and storage material in frontal cortex, perhaps indicating lysosomal dysfunction as a mechanism of disease. To investigate whether patients with sporadic FTLD exhibit similar signs of lysosomal dysfunction, we compared lysosomal protein levels, transcript levels, and storage material in patients with FTD-GRN or sporadic FTLD-TDP type A. We analyzed samples from frontal cortex, a degenerated brain region, and occipital cortex, a relatively spared brain region. In frontal cortex, patients with sporadic FTLD-TDP type A exhibited similar increases in lysosomal protein levels, transcript levels, and storage material as patients with FTD-GRN. In occipital cortex of both patient groups, most lysosomal measures did not differ from controls. Frontal cortex from a transgenic mouse model of TDP-opathy had similar increases in cathepsin D and lysosomal storage material, showing that TDP-opathy and neurodegeneration can drive these changes independently of progranulin. To investigate these changes in additional FTLD subtypes, we analyzed frontal cortical samples from patients with sporadic FTLD-TDP type C or Pick's disease, an FTLD-tau subtype. All sporadic FTLD groups had similar increases in cathepsin D activity, lysosomal membrane proteins, and storage material as FTD-GRN patients. However, patients with FTLD-TDP type C or Pick's disease did not have similar increases in lysosomal transcripts as patients with FTD-GRN or sporadic FTLD-TDP type A. Based on these data, accumulation of lysosomal proteins and storage material may be a common aspect of end-stage FTLD. However, the unique changes in gene expression in patients with FTD-GRN or sporadic FTLD-TDP type A may indicate distinct underlying lysosomal changes among FTLD subtypes

Patients with sporadic FTLD exhibit similar increases in lysosomal proteins and storage material as patients with FTD due to GRN mutations

Abstract Loss of function progranulin (GRN) mutations are a major autosomal dominant cause of frontotemporal dementia (FTD). Patients with FTD due to GRN mutations (FTD-GRN) develop frontotemporal lobar degeneration with TDP-43 pathology type A (FTLD-TDP type A) and exhibit elevated levels of lysosomal proteins and storage material in frontal cortex, perhaps indicating lysosomal dysfunction as a mechanism of disease. To investigate whether patients with sporadic FTLD exhibit similar signs of lysosomal dysfunction, we compared lysosomal protein levels, transcript levels, and storage material in patients with FTD-GRN or sporadic FTLD-TDP type A. We analyzed samples from frontal cortex, a degenerated brain region, and occipital cortex, a relatively spared brain region. In frontal cortex, patients with sporadic FTLD-TDP type A exhibited similar increases in lysosomal protein levels, transcript levels, and storage material as patients with FTD-GRN. In occipital cortex of both patient groups, most lysosomal measures did not differ from controls. Frontal cortex from a transgenic mouse model of TDP-opathy had similar increases in cathepsin D and lysosomal storage material, showing that TDP-opathy and neurodegeneration can drive these changes independently of progranulin. To investigate these changes in additional FTLD subtypes, we analyzed frontal cortical samples from patients with sporadic FTLD-TDP type C or Pick’s disease, an FTLD-tau subtype. All sporadic FTLD groups had similar increases in cathepsin D activity, lysosomal membrane proteins, and storage material as FTD-GRN patients. However, patients with FTLD-TDP type C or Pick’s disease did not have similar increases in lysosomal transcripts as patients with FTD-GRN or sporadic FTLD-TDP type A. Based on these data, accumulation of lysosomal proteins and storage material may be a common aspect of end-stage FTLD. However, the unique changes in gene expression in patients with FTD-GRN or sporadic FTLD-TDP type A may indicate distinct underlying lysosomal changes among FTLD subtypes