Face perception: domain specific, not process specific

Evidence that face perception is mediated by special cognitive and neural mechanisms comes from fMRI studies of the fusiform face area (FFA) and behavioral studies of the face inversion effect. Here, we used these two methods to ask whether face perception mechanisms are stimulus specific, process specific, or both. Subjects discriminated pairs of upright or inverted faces or house stimuli that differed in either the spatial distance among parts (configuration) or the shape of the parts. The FFA showed a much higher response to faces than to houses, but no preference for the configuration task over the part task. Similarly, the behavioral inversion effect was as large in the part task as the configuration task for faces, but absent in both part and configuration tasks for houses. These findings indicate that face perception mechanisms are not process specific for parts or configuration but are domain specific for face stimuli per se.     

Detection of stage specific and organ specific human brain antigens during embryogenesis]

The rabbit antisera were obtained against the water soluble antigens of the brain of 8--10 weeks old human foetuses. Three groups of specific antigens were identified in the brain of human foetuses: 1) antigens common for the embryonic brain and other organs of the same age; 2) antigens common for the embryonic brain and some organs of the adult organism; 3) stage (phase)-specific brain antigens present only in the brain between the 8th and 10th weeks of pregnancy.     

A species-specific frequency filter through specific inhibition, not specific excitation

Many bushcrickets produce specific song spectra for acoustic communication. Song detection and/ or recognition may make use of such specificity. Where in the nervous system are the filters for song frequency situated? A peripheral tuning for song frequency typically does not exist. Auditory receptor cells of bushcrickets connect to local and ascending neurons in the prothoracic ganglion. One of the ascending neurons (1) may function as a frequency filter in a group of four related bushcrickets (genera Ancistrura, Barbitistes). The frequency response of ascending neuron 1 is species-specific roughly corresponding to the frequency of the conspecific male song. The species-specific tuning of the neuron is not brought about by specific excitation, but by specific inhibition. By eliminating this frequency-dependent and species-specific inhibition the former filter neuron is transformed into an unspecific broad-band neuron in all four species. Its tuning then does not differ from omega neuron 1, a local neuron which is rather unspecific for frequency. Also, the supra-threshold responses of ascending neuron 1, which are different in intact animals, are similar to each other and similar to omega neuron 1 following elimination of inhibition. Only ascending neuron 1 of Ancistrura retains some species-specific features at low frequencies. In conclusion, evolution changed inhibition, not excitation of a species-specific neuron.     

The doctrine of specific etiology

Modern medicine is often said to have originated with nineteenth century germ theory, which attributed diseases to bacterial contagions. The success of this theory is often associated with an underlying principle referred to as the “doctrine of specific etiology”. This doctrine refers to specificity at the level of disease causation or etiology. While the importance of this doctrine is frequently emphasized in the philosophical, historical, and medical literature, these sources lack a clear account of the types of specificity that it involves and why exactly they matter. This paper argues that nineteenth century germ theory involves two types of specificity at the level of etiology. One type receives significant attention in the literature, but its influence on modern medicine has been misunderstood. A second type is present in this model, but it has been completely overlooked in the extant literature. My analysis clarifies how these types of specificity led to a novel conception of etiology that continues to figure in medicine today.     

Epigenetics of specific chromosome regions

Investigation of protein complexes, various types of protein modifications and the structure of the chromatin of specific chromosome regions, such as centromeres, telomeres, and adjacent heterochromatic regions, considerably complicated the notion on DNA, prevailing five decades ago, as molecules that exclusively control coding and realization of genetic information. Striking plasticity of the primary structure of centromeric and telomeric DNA suggests a variety of molecular mechanisms underlying fundamental and universal functions of these key chromosome regions. The present review is an attempt to consider the current concepts on the structure of the DNA and protein components, as well as the structure of the chromatin of specific chromosome regions in eukaryotes, and the concerted evolution of these components, leading to the formation of a hierarchy of coordinated DNA-protein complexes.     

Epigenetics of specific chromosome regions

Investigation of protein complexes, various types of protein modifications and the structure of the chromatin of specific chromosome regions, such as centromeres, telomeres, and adjacent heterochromatic regions, considerably complicated the notion on DNA, prevailing five decades ago, as molecules that exclusively control coding and realization of genetic information. Striking plasticity of the primary structure of centromeric and telomeric DNA suggests a variety of molecular mechanisms underlying fundamental and universal functions of these key chromosome regions. The present review is an attempt to consider the current concepts on the structure of the DNA and protein components, as well as the structure of the chromatin of specific chromosome regions in eukaryotes, and the concerted evolution of these components, leading to the formation of a hierarchy of coordinated DNA-protein complexes.     

Inhibitors of specific ceramide synthases

Ceramide synthases (CerSs) are key enzymes in the biosynthesis of ceramides and display a group of at least six different isoenzymes (CerS1-6). Ceramides itself are bioactive molecules. Ceramides with different N-acyl side chains (C_14:0-Cer – C_26:0-Cer) possess distinct roles in cell signaling. Therefore, the selective inhibition of specific CerSs which are responsible for the formation of a specific ceramide holds promise for a number of new clinical treatment strategies, e.g., cancer. Here, we identified four of hitherto unknown functional inhibitors of CerSs derived from the FTY720 (Fingolimod) lead structure and showed their inhibitory effectiveness by two in vitro CerS activity assays. Additionally, we tested the substances in two cell lines (HCT-116 and HeLa) with different ceramide patterns. In summary, the in vitro activity assays revealed out that ST1058 and ST1074 preferentially inhibit CerS2 and CerS4, while ST1072 inhibits most potently CerS4 and CerS6. Importantly, ST1060 inhibits predominately CerS2. First structure–activity relationships and the potential biological impact of these compounds are discussed.     

Glycotyping of prostate specific antigen

Measurement of serum levels of the prostate specific antigen (PSA) is now widely used for the diagnosis of prostate cancer and benign prostate hyperplasia. This serum marker is of value since it is derived only from the tissue of interest, but increased levels of PSA in serum do not allow a completely clear cut diagnosis of benign versus malignant changes. Since PSA is a glycoprotein with one asparagine linked oligosaccharide, and since malignant transformation often leads to an increased branching of such oligosaccharides, we initially studied the asparagine linked structures on PSA made by a cell line derived from malignant metastatic prostate tissue. We observed that unlike normal PSA, which bears only biantennary oligosaccharides, PSA from the metastatic cell line has a mixture of biantennary and triantennary oligosaccharides. Further experiments will reveal carbohydrate differences derived from the PSA from sera or, prostate tissue of normal versus prostate cancer patients, and of the utility of such carbo-hydrate differences as a possible diagnostic marker for prostate cancer.     

Anaphase specific auto-cleavage of separase

Sister-chromatid separation is triggered by a specific proteolytic cleavage of chromosomal cohesins catalyzed by the endopeptidase separase. Prior to anaphase, separase is inhibited independently by affinity binding to securin and by specific inhibitory phosphorylation. Here we show that separase itself is also subjected to proteolytic cleavages at three adjacent sites. The cleavages are auto-catalyzed and occur specifically at anaphase coincident with separase activation. The cleaved fragments remain associated with each other and are catalytically active. Mapping of the cleavage sites reveals that all three sites are conserved in vertebrates underlining a significant function for this regulation.