{"title":"Intrinsic Disorder in Nuclear Receptor Amino Termini: From Investigational Challenge to Therapeutic Opportunity","authors":"R. Shamilov, B. Aneskievich","doi":"10.32527/2019/101417","DOIUrl":null,"url":null,"abstract":"Epidermal keratinocytes form an effective renewable barrier to surface assaults and \ndesiccation of underlying tissues through a tightly controlled program of regeneration and \nterminal differentiation which is significantly impacted by the activity of several members of the \nnuclear receptor (NR) superfamily. As such, there is significant interest in physiological and \npharmacological control of select NRs. NRs are usually considered quintessential examples of \nconstrained structure-function relationships among protein families because of amino acid \nidentity and sequence subserving physical requirements inherent to a relatively centrally-located \nDNA-binding domain and carboxyl-terminal ligand-recognition domain which together lead to \nagonist-activated gene expression. Nevertheless, across the superfamily the amino terminus of \nmany NR is an often-critical contributor in degree of receptor-dependent transcriptional activity \ndespite little in apparent sequence similarity that might be instructive in understanding this \nability. By looking beyond shared strict amino acid sequence identity, a number of \ninvestigations are revealing the “unstructured\"-function consequences of this disparity. \nSignificant correlations between in silico and in vitro biophysical assessments are highlighting \nthe shared trait of the unstructured nature or intrinsic disorder (ID) of NR amino termini and \nrelated functional consequences. Rather than the limited protein sequence variation-on-a-theme \nseen for zinc fingers (DNA binding) or a hydrophobic pocket (ligand binding), these \namino-termini show sequence order diversity but often strikingly shared amino acid composition \nprofiles not supporting a one-sequence–one-structure conformation. In this review, we look to \nintegrate amino-termini ID reported in the literature, or predicted here, for select keratinocyte-expressed \nNR. As evidenced by success in drug targeting the amino-terminus of the androgen \nreceptor, increased appreciation of amino-termini structure - or unstructure - might provide \nbetter understanding of NR function in general and possible future investigations on \npharmacologic control over keratinocyte regeneration and/or differentiation.","PeriodicalId":30720,"journal":{"name":"Nuclear Receptor Research","volume":null,"pages":null},"PeriodicalIF":0.0000,"publicationDate":"2019-06-29","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"3","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Nuclear Receptor Research","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.32527/2019/101417","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"","JCRName":"","Score":null,"Total":0}
引用次数: 3
Abstract
Epidermal keratinocytes form an effective renewable barrier to surface assaults and
desiccation of underlying tissues through a tightly controlled program of regeneration and
terminal differentiation which is significantly impacted by the activity of several members of the
nuclear receptor (NR) superfamily. As such, there is significant interest in physiological and
pharmacological control of select NRs. NRs are usually considered quintessential examples of
constrained structure-function relationships among protein families because of amino acid
identity and sequence subserving physical requirements inherent to a relatively centrally-located
DNA-binding domain and carboxyl-terminal ligand-recognition domain which together lead to
agonist-activated gene expression. Nevertheless, across the superfamily the amino terminus of
many NR is an often-critical contributor in degree of receptor-dependent transcriptional activity
despite little in apparent sequence similarity that might be instructive in understanding this
ability. By looking beyond shared strict amino acid sequence identity, a number of
investigations are revealing the “unstructured"-function consequences of this disparity.
Significant correlations between in silico and in vitro biophysical assessments are highlighting
the shared trait of the unstructured nature or intrinsic disorder (ID) of NR amino termini and
related functional consequences. Rather than the limited protein sequence variation-on-a-theme
seen for zinc fingers (DNA binding) or a hydrophobic pocket (ligand binding), these
amino-termini show sequence order diversity but often strikingly shared amino acid composition
profiles not supporting a one-sequence–one-structure conformation. In this review, we look to
integrate amino-termini ID reported in the literature, or predicted here, for select keratinocyte-expressed
NR. As evidenced by success in drug targeting the amino-terminus of the androgen
receptor, increased appreciation of amino-termini structure - or unstructure - might provide
better understanding of NR function in general and possible future investigations on
pharmacologic control over keratinocyte regeneration and/or differentiation.
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