Your search keyword '"Perkins L"' showing total 3 results

1. Hidden neural states underlie canary song syntax

Author

Cohen, Yarden, Shen, Jun, Semu, Dawit, Leman, Daniel P., Liberti, William A., III, Perkins, L. Nathan, and Liberti, Derek C.

Subjects

Grammar, Comparative and general -- Syntax, Neurons -- Influence, Hidden Markov models -- Usage -- Models -- Acoustic properties -- Analysis, Canaries -- Behavior -- Acoustic properties -- Analysis -- Usage -- Models, Environmental issues, Science and technology, Zoology and wildlife conservation

Abstract

Coordinated skills such as speech or dance involve sequences of actions that follow syntactic rules in which transitions between elements depend on the identities and order of past actions. Canary songs consist of repeated syllables called phrases, and the ordering of these phrases follows long-range rules.sup.1 in which the choice of what to sing depends on the song structure many seconds prior. The neural substrates that support these long-range correlations are unknown. Here, using miniature head-mounted microscopes and cell-type-specific genetic tools, we observed neural activity in the premotor nucleus HVC.sup.2-4 as canaries explored various phrase sequences in their repertoire. We identified neurons that encode past transitions, extending over four phrases and spanning up to four seconds and forty syllables. These neurons preferentially encode past actions rather than future actions, can reflect more than one song history, and are active mostly during the rare phrases that involve history-dependent transitions in song. These findings demonstrate that the dynamics of HVC include 'hidden states' that are not reflected in ongoing behaviour but rather carry information about prior actions. These states provide a possible substrate for the control of syntax transitions governed by long-range rules. Neurons in the canary premotor cortex homologue encode past song phrases and transitions, carrying information relevant to future choice of phrases as 'hidden states' during song., Author(s): Yarden Cohen [sup.1] , Jun Shen [sup.2] , Dawit Semu [sup.1] , Daniel P. Leman [sup.1] , William A. Liberti III [sup.1] [sup.3] , L. Nathan Perkins [sup.1] , [...]

Published

2020

2. Selective inhibitors of biosynthesis of aminergic neurotransmitters

Author

KOLLONITSCH, J., primary, PATCHETT, A. A., additional, MARBURG, S., additional, MAYCOCK, A. L., additional, PERKINS, L. M., additional, DOLDOURAS, G. A., additional, DUGGAN, D. E., additional, and ASTER, S. D., additional

Published

1978

3. Putative protein kinase product of the Drosophila segment-polarity gene zeste-white3.

Author

Siegfried E, Perkins LA, Capaci TM, and Perrimon N

Subjects

Amino Acid Sequence, Animals, Base Sequence, Chromosome Mapping, Cloning, Molecular, DNA genetics, Drosophila melanogaster embryology, Drosophila melanogaster enzymology, Genes, Molecular Sequence Data, Morphogenesis, RNA, Messenger genetics, RNA, Messenger metabolism, Restriction Mapping, Drosophila melanogaster genetics, Protein Kinases genetics

Abstract

The metameric pattern of the Drosophila embryo is regulated by a combination of maternal and zygotic genes. The segment-polarity class of genes are required for the correct patterning within each segmental unit. Mutations in any one of these genes results in deletions and duplications of parts of each segment. The segment-polarity genes act coordinately by means of local cellular interactions to assign and maintain an identity for each cell in the segment, and to establish segment boundaries. Here we describe the molecular characterization of a novel segment-polarity gene, zeste-white3 (zw3). Embryos derived from germ lines that are homozygous for zw3 mutations (zw3 embryos) have phenotypes similar to embryos that are mutant for the segment-polarity gene naked (nkd). These embryos lack most of the ventral denticles, which are differentiated structures derived from the most anterior region of each segment. We have isolated the zw3 gene and compared the structure of one maternal and one zygotic transcript encoded by the gene. The zw3 gene is unique among the segment-polarity genes so far characterized, in that it encodes proteins that have homology to serine-threonine protein kinases. This indicates that zw3 may play a part in a signal transduction pathway involved in the establishment of cell identity within each embryonic segment.

Published

1990