Vibrotactile masking experiments reveal accelerated somatosensory processing in congenitally blind braille readers.

Braille reading is a demanding task that requires the identification of rapidly varying tactile patterns. During proficient reading, neighboring characters impact the fingertip at ∼100 ms intervals, and adjacent raised dots within a character at 50 ms intervals. Because the brain requires time to interpret afferent sensorineural activity, among other reasons, tactile stimuli separated by such short temporal intervals pose a challenge to perception. How, then, do proficient Braille readers successfully interpret inputs arising from their fingertips at such rapid rates? We hypothesized that somatosensory perceptual consolidation occurs more rapidly in proficient Braille readers. If so, Braille readers should outperform sighted participants on masking tasks, which demand rapid perceptual processing, but would not necessarily outperform the sighted on tests of simple vibrotactile sensitivity. To investigate, we conducted two-interval forced-choice vibrotactile detection, amplitude discrimination, and masking tasks on the index fingertips of 89 sighted and 57 profoundly blind humans. Sighted and blind participants had similar unmasked detection (25 ms target tap) and amplitude discrimination (compared with 100 µm reference tap) thresholds, but congenitally blind Braille readers, the fastest readers among the blind participants, exhibited significantly less masking than the sighted (masker, 50 Hz, 50 µm; target-masker delays, ±50 and ±100 ms). Indeed, Braille reading speed correlated significantly and specifically with masking task performance, and in particular with the backward masking decay time constant. We conclude that vibrotactile sensitivity is unchanged but that perceptual processing is accelerated in congenitally blind Braille readers.

A unique pause pattern during telomere addition by the error-prone telomerase from the ciliate Paramecium tetraurelia.

Telomeric DNA - the short, tandemly repeated sequences at the ends of chromosomes - is synthesized by telomerase, a ribonucleoprotein enzyme that copies a specific template sequence within its integral RNA moiety. The error-prone telomerase from the ciliate Paramecium tetraurelia stereotypically misincorporates TTP at telomerase RNA templating nucleotide C52, accounting for the 30% TTTGGG repeats randomly distributed in wild-type telomeres. Paramecium tetraurelia telomerase has been isolated from macronuclear extracts and characterized with respect to the extension of telomeric primers in vitro. Unlike telomerase activities from other species, the predominant pause during telomeric repeat synthesis by P. tetraurelia telomerase does not occur at the 5' end of the templating domain (templating nucleotide C49). Instead, the pause by P. tetraurelia telomerase is at templating nucleotide C53, immediately prior to incorporation of dGTP (or TTP) at C52. The configuration of the catalytic site at this template position during telomere synthesis is most likely responsible for the high incidence of misincorporation of TTP at C52. The gene for the P. tetraurelia telomerase catalytic subunit, telomerase reverse transcriptase (TERT), has been cloned and sequenced. A comparative analysis of the P. tetraurelia TERT with homologs from other species, including that from another Paramecium species that does not make a high percentage of misincorporation errors, has been initiated. This study may delineate those TERT structural elements that contribute to telomerase fidelity.

Phylogenetic relationships amongst tetrahymenine ciliates inferred by a comparison of telomerase RNAs.

The phylogenetic relationships between ciliate species in the suborder Tetrahymenina, order Hymenostomata, was investigated by comparing their telomerase RNA (TER) sequences. This relatively small RNA is an integral part of telomerase, the ribonucleoprotein enzyme that catalyses the synthesis of telomeric DNA. Despite a relatively rapid rate of primary sequence divergence, conserved functional and structural elements within TERs facilitate the accurate alignment of truly homologous nucleotides. The tetrahymenine phylogeny derived from distance analysis of TER sequences is largely consistent with those based on rRNA and histone sequences.