A single microRNA (miRNA) can regulate the expression of many genes, though the level of repression imparted on any given target is generally low. How then is the selective pressure for a single miRNA/target interaction maintained across long evolutionary distances? We addressed this problem by disrupting in vivo the interaction between miR-155 and PU.1 in mice. Remarkably, this interaction proved to be key to promoting optimal T cell-dependent B cell responses, a previously unrecognized role for PU.1. Mechanistically, miR-155 inhibits PU.1 expression, leading to Pax5 down-regulation and the initiation of the plasma cell differentiation pathway. Additional PU.1 targets include a network of genes whose products are involved in adhesion, with direct links to B-T cell interactions. We conclude that the evolutionary adaptive selection of the miR-155-PU.1 interaction is exercised through the effectiveness of terminal B cell differentiation

Alison Galloway

Bailey

Bartel

Belver

Berger

Borchert

Bowen

Carotta

Cei Abreu-Goodger

Chaudhuri

Dakic

de Yébenes

Decker

Dong Lu

Dorsett

Elena Vigorito

Fabani

Fisher

Friedman

Geoffrey Butcher

Gururajan

Haga

Hasbold

Heinz

Holl

Holmes

Houston

Huang

Iwasaki

Jacob

Kallies

Kanada

Laslo

Linterman

MacLennan

Malumbres

Martin Turner

Martins

Mukherji

Ochiai

Oliveira

O’Connell

Pentcheva-Hoang

Philipp Staudacher

Rebecca Leyland

Rinako Nakagawa

Rodriguez

Rosenbauer

Sandra Lazzaro

Sara Boiani

Sciammas

Seitz

Simon Andrews

Stark

Stephen L. Nutt

Teng

Thai

Tom Henley

Turkistany

Vigorito

West

Xiang

Zhang

The Journal of Experimental Medicine

English

PubMed

© 2014 Lu et al. A single microRNA (miRNA) can regulate the expression of many genes, though the level of repression imparted on any given target is generally low. How then is the selective pressure for a single miRNA/target interaction maintained across long evolutionary distances? We addressed this problem by disrupting in vivo the interaction between miR-155 and PU.1 in mice. Remarkably, this interaction proved to be key to promoting optimal T cell-dependent B cell responses, a previously unrecognized role for PU.1. Mechanistically, miR-155 inhibits PU.1 expression, leading to Pax5 down-regulation and the initiation of the plasma cell differentiation pathway. Additional PU.1 targets include a network of genes whose products are involved in adhesion, with direct links to B-T cell interactions. We conclude that the evolutionary adaptive selection of the miR-155-PU.1 interaction is exercised through the effectiveness of terminal B cell differentiation

Lu, D.

Nakagawa, R.

Lazzaro, S.

Staudacher, P.

Abreu-Goodger, C.

Henley, T.

Boiani, S

Leyland, Rebecca

Galloway, A.

Andrews, S.

Butcher, G.

Nutt, S.L.

Turner, M.

Vigorito, E.

Sheffield Hallam University Research Archive

The miR-155-PU.1 axis acts on Pax5 to enable efficient terminal B cell differentiation

Lu, D

Nakagawa, R

Lazzaro, S

Staudacher, P

Abreu-Goodger, C

Henley, T

Leyland, R

Galloway, A

Andrews, S

Butcher, G

Nutt, SL

Turner, M

Vigorito, E

University of Melbourne Institutional Repository

A single microRNA (miRNA) can regulate the expression of many genes, though the level of repression imparted on any given target is generally low. How then is the selective pressure for a single miRNA/target interaction maintained across long evolutionary distances? We addressed this problem by disrupting in vivo the interaction between miR-155 and PU.1 in mice. Remarkably, this interaction proved to be key to promoting optimal T cell–dependent B cell responses, a previously unrecognized role for PU.1. Mechanistically, miR-155 inhibits PU.1 expression, leading to Pax5 down-regulation and the initiation of the plasma cell differentiation pathway. Additional PU.1 targets include a network of genes whose products are involved in adhesion, with direct links to B–T cell interactions. We conclude that the evolutionary adaptive selection of the miR-155–PU.1 interaction is exercised through the effectiveness of terminal B cell differentiation

Lu, Dong

Nakagawa, Rinako

Lazzaro, Sandra

Staudacher, Philipp

Abreu-Goodger, Cei

Henley, Tom

Boiani, Sara

Galloway, Alison

Andrews, Simon

Butcher, Geoffrey

Nutt, Stephen L.

Turner, Martin

Vigorito, Elena

Edinburgh Research Explorer

A single microRNA (miRNA) can regulate the expression of many genes, though the level of repression imparted on any given target is generally low. How then is the selective pressure for a single miRNA/target interaction maintained across long evolutionary distances? We addressed this problem by disrupting in vivo the interaction between miR-155 and PU.1 in mice. Remarkably, this interaction proved to be key to promoting optimal T cell–dependent B cell responses, a previously unrecognized role for PU.1. Mechanistically, miR-155 inhibits PU.1 expression, leading to Pax5 down-regulation and the initiation of the plasma cell differentiation pathway. Additional PU.1 targets include a network of genes whose products are involved in adhesion, with direct links to B–T cell interactions. We conclude that the evolutionary adaptive selection of the miR-155–PU.1 interaction is exercised through the effectiveness of terminal B cell differentiation.</jats:p

Crossref

The miR-155–PU.1 axis acts on Pax5 to enable efficient terminal B cell differentiation

Nutt, Stephen L

Apollo (Cambridge)

The miR-155-PU.1 axis acts on Pax5 to enable efficient terminal B cell differentiation.

https://www.repository.cam.ac.uk/bitstream/handle/1810/278251/The%20miR-155-PU.1%20axis%20acts%20on%20Pax5%20to%20enable%20efficient%20terminal%20B%20cell%20differentiation.pdf?sequence=1&isAllowed=y

The miR-155-PU.1 axis acts on Pax5 to enable efficient terminal B cell differentiation.

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Sheffield Hallam University Research Archive

University of Melbourne Institutional Repository

Edinburgh Research Explorer

Crossref

Apollo (Cambridge)