Linguistic threat activates the human amygdala.

Studies in animals demonstrate a crucial role for the amygdala in emotional and social behavior, especially as related to fear and aggression. Whereas lesion and functional-imaging studies in humans indicate the amygdala's participation in assessing the significance of nonverbal as well as paralinguistic cues, direct evidence for its role in the emotional processing of linguistic cues is lacking. In this study, we use a modified Stroop task along with a high-sensitivity neuroimaging technique to target the neural substrate engaged specifically when processing linguistic threat. Healthy volunteer subjects were instructed to name the color of words of either threat or neutral valence, presented in different color fonts, while neural activity was measured by using H(2)(15)O positron-emission tomography. Bilateral amygdalar activation was significantly greater during color naming of threat words than during color naming of neutral words. Associated activations were also noted in sensory-evaluative and motor-planning areas of the brain. Thus, our results demonstrate the amygdala's role in the processing of danger elicited by language. In addition, the results reinforce the amygdala's role in the modulation of the perception of, and response to, emotionally salient stimuli. The current study further suggests conservation of phylogenetically older mechanisms of emotional evaluation in the context of more recently evolved linguistic function.

Systematic screening for RNA with skipped exons--splicing mutations of the ferrochelatase gene.

A systematic method was designed to screen a large population of patients with erythropoietic protoporphyria (EPP) for aberrant ferrochelatase RNA with skipped exons. The method utilizes the new junction sequence created by exon skipping as the probe to detect such RNA species. In 7 of 17 EPP families, an aberrant ferrochelatase RNA with one exon missing was observed. Two previously unreported splicing mutations were also identified in 2 EPP families. One was a G >> T transversion at the +1 position of the acceptor site of intron 8, causing exon 9 to be skipped during RNA splicing. Both the patient and her father were found to be heterozygous for this mutation. In another family, an A >> G transition at the +3 position of the donor site of intron 10 was identified, associated with exon 10 skipping during RNA splicing. Both the patient and her father were heterozygous for this mutation.