Linkage disequilibrium mapping provides further evidence of a gene for reading disability on chromosome 6p21.3-22.

Linkage disequilibrium (LD) mapping was used to follow up reports of linkage between reading disability (RD) and an 18 cM region of chromosome 6p21.3-22. Using a two-stage approach, we tested for association between RD and 22 microsatellite markers in two independent samples of 101 (Stage 1) and 77 (Stage 2) parent/proband trios in which RD was rigorously defined. The most significant replicated associations were observed between combinations of markers D6S109/422/1665 (Stage 1, P=0.002 (adjusted for multiple testing); Stage 2, P=0.0001) and D6S506/1029/1660 (Stage 1, P=0.02 (adjusted), Stage 2, P=0.0001). The only two-marker association observed in both samples was with D6S422/1665 (P=0.01, 0.04). No single marker showed replicated association but D6S506 produced values of P=0.01 and 0.08 which were significant when combined (P=0.02). We observed weaker and less consistent evidence of association in a region of confirmed linkage to RD in previous studies. The most consistently significant haplotypic association D6S109/422/1665, showed association with single-word reading, spelling, phonological awareness, phonological decoding, orthographic accuracy and random automised naming, but not with vocabulary or Attention Deficit Hyperactivity Disorder. Our findings strongly support the presence of a gene contributing to RD in a region of chromosome 6 between markers D6S109 and D6S1260, but do not rule out the presence of a gene between D6S1556 and MOG.

Impaired eye expression recognition in schizophrenia.

Schizophrenia has been associated with abnormalities in recognising social emotions, inferring others' mental states and in gaze and visual scanning behaviours. Eye expression is known to convey considerable information in normal circumstances. Our study assessed the ability of individuals with schizophrenia to recognise simple and complex mental states from eye expressions alone. Sixteen individuals with a DSM-IV diagnosis of schizophrenia following SCAN [Schedules for Clinical Assessment in Neuropsychiatry (Wing JK, Babor T, Brugha T, Burke J, Cooper JE, Giel R et al. SCAN: schedules for clinical assessment in neuropsychiatry. Archives of General Psychiatry 1990;47:589-593).] interview and 16 healthy controls acted as participants. Expressions of 10 emotions (e.g. happy, afraid) and 10 complex mental states (e.g. thoughtful, bored), in the form of pictures of whole faces or eyes alone, were presented for recognition using a forced-choice response design. We observed impaired recognition of complex mental states in individuals with schizophrenia, from eye expressions alone (P=0.012). No differences in the recognition of basic emotions were detected. We also observed a negative correlation between illness chronicity and expression recognition performance (r=-0.65, P=0.006). The reduced ability of schizophrenia patients to recognise eye expressions of complex mental states could be interpreted as supporting a lack of "theory of mind". However, more parsimonious explanations based on impairments in basic recognition processes could also apply. An awareness of these processing abnormalities may have implications for future therapeutic strategies and our understanding of the pathophysiology of the disorder.

Family-based association mapping provides evidence for a gene for reading disability on chromosome 15q.

Family-based association mapping was used to follow up reports of linkage between reading disability (RD) and a genomic region on chromosome 15q. Using a two-stage approach, we ascertained 101 (stage 1) and 77 (stage 2) parent-proband trios, in which RD was characterized rigorously. In stage 1, a set of eight microsatellite markers spanning the region of putative linkage was used and a highly significant association was detected between RD and a three-marker haplotype (D15S994/D15S214/D15S146: P and empirical P < 0.001). A significant association with the same three-marker haplotype was also observed in the second-stage sample (P = 0.009, empirical P = 0.006). Our data therefore provide strong evidence for one or more genes contributing to RD being located in the vicinity of the region including D15S146 and D15S994. In addition, our results provide support for association analysis being a useful method to map susceptibility loci for complex disorders.

Hypoxic ventilatory sensitivity in men is not reduced by prolonged hyperoxia (Predictive Studies V and VI).

Potential adverse effects on the O2-sensing function of the carotid body when its cells are exposed to toxic O2 pressures were assessed during investigations of human organ tolerance to prolonged continuous and intermittent hyperoxia (Predictive Studies V and VI). Isocapnic hypoxic ventilatory responses (HVR) were determined at 1.0 ATA before and after severe hyperoxic exposures: 1) continuous O2 breathing at 1.5, 2.0, and 2.5 ATA for 17.7, 9.0, and 5.7 h and 2) intermittent O2 breathing at 2.0 ATA (30 min O2-30 min normoxia) for 14.3 O2 h within 30-h total time. Postexposure curvature of HVR hyperbolas was not reduced compared with preexposure controls. The hyperbolas were temporarily elevated to higher ventilations than controls due to increments in respiratory frequency that were proportional to O2 exposure time, not O2 pressure. In humans, prolonged hyperoxia does not attenuate the hypoxia-sensing function of the peripheral chemoreceptors, even after exposures that approach limits of human pulmonary and central nervous system O2 tolerance. Current applications of hyperoxia in hyperbaric O2 therapy and in subsea- and aerospace-related operations are guided by and are well within these exposure limits.