C57BL/6NTac-Atpif1^{tm1a(EUCOMM)Wtsi}/WtsiCnbc

Status	Available to order
EMMA ID	EM:05233
International strain name	C57BL/6NTac-Atpif1^{tm1a(EUCOMM)Wtsi}/WtsiCnbc
Alternative name	EPD0158_4_B04
Strain type	Targeted Mutant Strains
Allele/Transgene symbol	Atpif1^{tm1a(EUCOMM)Wtsi}
Gene/Transgene symbol	Atp5if1
Disclaimer	Please note that for EUCOMM and KOMP-CSD mice supplied to the scientific community by INFRAFRONTIER/EMMA: We can not guarantee a null mutation for Knock-out first alleles (tm1a alleles, see http://www.mousephenotype.org/about-ikmc/targeting-strategies) as the critical exon has not been deleted. That the structure of the targeted mutation in the ES cells obtained from EUCOMM/KOMP to generate EUCOMM/KOMP mice is not verified by INFRAFRONTIER/EMMA. It is recommended that the recipient confirms the mutation structure. No check for determining the copy number of the targeting construct in ES cells obtained from EUCOMM/KOMP is done by INFRAFRONTIER/EMMA. The level of quality control before mice are released is to confirm the individual mouse genotype by short range PCR.

Information from provider

Provider	Wellcome Trust Sanger Institute
Provider affiliation	Wellcome Trust Sanger Institute
Genetic information	This mouse line originates from EUCOMM ES clone EPD0158_4_B04. For further details on the construction of this clone see the page at the IMPC portal.
Phenotypic information	Potential phenotyping data in the IMPC portal
References	Genome-wide generation and systematic phenotyping of knockout mice reveals new roles for many genes.;White Jacqueline K, Gerdin Anna-Karin, Karp Natasha A, Ryder Ed, Buljan Marija, Bussell James N, Salisbury Jennifer, Clare Simon, Ingham Neil J, Podrini Christine, Houghton Richard, Estabel Jeanne, Bottomley Joanna R, Melvin David G, Sunter David, Adams Niels C, null null, Tannahill David, Logan Darren W, Macarthur Daniel G, Flint Jonathan, Mahajan Vinit B, Tsang Stephen H, Smyth Ian, Watt Fiona M, Skarnes William C, Dougan Gordon, Adams David J, Ramirez-Solis Ramiro, Bradley Allan, Steel Karen P, ;2013;Cell;154;452-64; 23870131

Information from EMMA

Archiving centre	CNB-CSIC, Centro Nacional de Biotecnologia, Madrid, Spain

Disease and phenotype information

IMPC phenotypes (gene matching)

decreased body weight / IMPC

MGI phenotypes (allele matching)

decreased body weight / MGI
decreased circulating alanine transaminase level / MGI
decreased circulating alkaline phosphatase level / MGI
decreased total body fat amount / MGI

MGI phenotypes (gene matching)

decreased body weight / MGI
decreased circulating alanine transaminase level / MGI
decreased circulating alkaline phosphatase level / MGI
decreased total body fat amount / MGI

Literature references

Genome-wide generation and systematic phenotyping of knockout mice reveals new roles for many genes.;White Jacqueline K, Gerdin Anna-Karin, Karp Natasha A, Ryder Ed, Buljan Marija, Bussell James N, Salisbury Jennifer, Clare Simon, Ingham Neil J, Podrini Christine, Houghton Richard, Estabel Jeanne, Bottomley Joanna R, Melvin David G, Sunter David, Adams Niels C, null null, Tannahill David, Logan Darren W, Macarthur Daniel G, Flint Jonathan, Mahajan Vinit B, Tsang Stephen H, Smyth Ian, Watt Fiona M, Skarnes William C, Dougan Gordon, Adams David J, Ramirez-Solis Ramiro, Bradley Allan, Steel Karen P, ;2013;Cell;154;452-64; 23870131
Inhibition of ATPIF1 ameliorates severe mitochondrial respiratory chain dysfunction in mammalian cells.;Chen Walter W, Birsoy Kivanc, Mihaylova Maria M, Snitkin Harriet, Stasinski Iwona, Yucel Burcu, Bayraktar Erol C, Carette Jan E, Clish Clary B, Brummelkamp Thijn R, Sabatini David D, Sabatini David M, ;2014;Cell reports;7;27-34; 24685140
The ATPase Inhibitory Factor 1 (IF1): A master regulator of energy metabolism and of cell survival.;García-Bermúdez Javier, Cuezva José M, ;2016;Biochimica et biophysica acta;1857;1167-1182; 26876430
Upregulation of mitochondrial ATPase inhibitory factor 1 (ATPIF1) mediates increased glycolysis in mouse hearts.;Zhou Bo, Caudal Arianne, Tang Xiaoting, Chavez Juan D, McMillen Timothy S, Keller Andrew, Villet Outi, Zhao Mingyue, Liu Yaxin, Ritterhoff Julia, Wang Pei, Kolwicz Stephen C, Wang Wang, Bruce James E, Tian Rong, ;2022;The Journal of clinical investigation;132;zqac001; 35575090
ATP Synthase K⁺- and H⁺-fluxes Drive ATP Synthesis and Enable Mitochondrial K⁺-"Uniporter" Function: II. Ion and ATP Synthase Flux Regulation.;Juhaszova Magdalena, Kobrinsky Evgeny, Zorov Dmitry B, Nuss H Bradley, Yaniv Yael, Fishbein Kenneth W, de Cabo Rafael, Montoliu Lluis, Gabelli Sandra B, Aon Miguel A, Cortassa Sonia, Sollott Steven J, ;2022;Function (Oxford, England);3;e3001252; 35187492
Generation of mitochondrial reactive oxygen species is controlled by ATPase inhibitory factor 1 and regulates cognition.;Esparza-Moltó Pau B, Romero-Carramiñana Inés, Núñez de Arenas Cristina, Pereira Marta P, Blanco Noelia, Pardo Beatriz, Bates Georgina R, Sánchez-Castillo Carla, Artuch Rafael, Murphy Michael P, Esteban José A, Cuezva José M, ;2021;PLoS biology;19;zqab065; 33983919
ATP Synthase K⁺- and H⁺-Fluxes Drive ATP Synthesis and Enable Mitochondrial K⁺-"Uniporter" Function: I. Characterization of Ion Fluxes.;Juhaszova Magdalena, Kobrinsky Evgeny, Zorov Dmitry B, Nuss H Bradley, Yaniv Yael, Fishbein Kenneth W, de Cabo Rafael, Montoliu Lluis, Gabelli Sandra B, Aon Miguel A, Cortassa Sonia, Sollott Steven J, ;2022;Function (Oxford, England);3;4870-4891; 35229078
IF1 is a cold-regulated switch of ATP synthase hydrolytic activity to support thermogenesis in brown fat.;Brunetta Henver S, Jung Anna S, Valdivieso-Rivera Fernando, de Campos Zani Stepheny C, Guerra Joel, Furino Vanessa O, Francisco Annelise, Berçot Marcelo, Moraes-Vieira Pedro M, Keipert Susanne, Jastroch Martin, Martinez Laurent O, Sponton Carlos H, Castilho Roger F, Mori Marcelo A, Bartelt Alexander, ;2024;The EMBO journal;43;; 39284909

Information on how we integrate external resources can be found here

Order

Availabilities

Requesting frozen sperm or embryos is generally advisable wherever possible, in order to minimise the shipment of live mice.

Frozen embryos. Delivered in 4 weeks (after paperwork in place). €1740^*
Rederivation of mice from frozen stock, delivery time available upon request . €3880^*
LacZ tagged null allele (tm1b allele), service fee and delivery time available upon request
Conditional ready allele (tm1c allele), service fee and delivery time available upon request
Reporterless null allele (tm1d allele), service fee and delivery time available upon request

Due to the dynamic nature of our processes strain availability may change at short notice. The local repository manager will advise you in these circumstances.

^* In addition users have to cover all the shipping costs (including the cost for returning dry-shippers, where applicable).

More details on pricing and delivery times

Practical information

Genotyping protocol

Example health report
(Current health report will be provided later)

Material Transfer Agreement (MTA)
Distribution of this strain is subject to a provider MTA. Both signing of the MTA and submission of the online EMMA Mutant Request Form are required before material can be shipped.

EMMA conditions
Legally binding conditions for the transfer

Other EMMA strains

Not found what you were looking for? Search here for other strains available from EMMA.

C57BL/6NTac-Atpif1tm1a(EUCOMM)Wtsi/WtsiCnbc