Hageman J, Rujano MA, van Waarde MA, Kakkar V, Dirks RP, Govorukhina N, Oosterveld-Hut HM, Lubsen NH, Kampinga HH. A DNAJB chaperone subfamily with HDAC-dependent activities suppresses toxic protein aggregation. Mol Cell. 2010 Feb 12;37(3):355-69. PubMed.
Recommends
Please login to recommend the paper.
Comments
Massachusetts Institute of Technology
The authors demonstrated nicely that DNAJB6b and DNAJB8, members of DNAJB chaperone subfamily, can potently suppress poly-Q toxicity. The anti-aggregation activity is Hsp70-independent. Histone deacetylase 4 interacts with these DNAJBs and likely regulates their activity through deacetylation. The paper provided an intriguing mechanism for HDAC4 in suppressing cytotoxic protein aggregation. It would be interesting to test this mechanism in a more neuronal relevant system, such as a Huntington disease mouse model. This paper, together with other publications, also suggests that different HDACs could have either neuroprotective or neurotoxic roles, depending on the context. Collectively, these observations imply that development of isoform-selective HDAC inhibitors is necessary.
View all comments by Ling Pan�
This paper by Jurre Hageman and colleagues provides more data suggesting that global histone deacetylase inhibition (HDACi) is fraught with potential complications, even though the integrated effect of HDACi is obviously beneficial for mice carrying polyQ expansions. It also raises the possibility that the induction of other Hsp chaperones by nuclear HDAC inhibition overcomes the downsides of HDAC4 inhibition.
The field has long moved beyond global HDAC inhibition and has embraced the notion that selective HDAC isoforms, including HDAC2 (Guan et al., 2009), HDAC6 (Rivieccio et al., 2009), and HDAC1, according to a recent paper by Patricio Casaccia and colleagues (Kim et al., 2010), are the way to move forward therapeutically.
HDAC4 is quite an interesting protein, and Santosh D'Mello, Eric Olson, and colleagues have demonstrated a pro-survival role of this molecule, with elegant in vitro and in vivo studies (see Majdzadeh et al., 2008). This function of HDAC4 appears not to depend on its deacylating activity and thus may not be fully abrogated by global HDAC inhibitors. Another very important paper that has been overlooked by the clinical neuroscience community is one by Jun Sadoshima and colleagues which shows that oxidation of HDAC4 moves it to the cytoplasm (Ago et al., 2008). We are currently working on a model by which HDAC4 movement from the nucleus to the cytoplasm could be a mechanism to de-repress or activate adaptive genes in the nucleus while placing HDAC4 in the cytoplasm to partner with DNAJB8 and DNAJB6b.
The notion that small DNAJB proteins are involved in Huntington disease is not new, and elegant papers by Borrell-Pagés (see Borrell-Pagés et al., 2006) a few years ago and by Karpuj and Steinman (see Karpuj et al., 2002) suggest that HSJ1b is repressed transcriptionally by mutant huntingtin. We have a paper in revision at EMBO Molecular Medicine that shows that transglutaminase acts as a nuclear co-repressor for many genes including DNAJB2, the murine homolog of HSJ1b, and that transglutaminase inhibition, molecularly or pharmacologically, can normalize message levels for this important gene. Our findings, in the context of the studies described above, suggest that transglutaminase inhibition, selective HDAC inhibition (leaving HDAC4 unperturbed), or REST inhibition (see Rigamonte et al., 2009) may be viable strategies to optimize DNAJB8 levels in polyglutamine disorders and avoid the problems of global HDAC inhibition.
DNAJB8 appears important not only to limit polyQ toxicity, as shown by this paper, but also to optimize trafficking of BDNF in HD (see Borrell-Pagés et al., 2006).
References:
Guan JS, Haggarty SJ, Giacometti E, Dannenberg JH, Joseph N, Gao J, Nieland TJ, Zhou Y, Wang X, Mazitschek R, Bradner JE, DePinho RA, Jaenisch R, Tsai LH. HDAC2 negatively regulates memory formation and synaptic plasticity. Nature. 2009 May 7;459(7243):55-60. PubMed.
Rivieccio MA, Brochier C, Willis DE, Walker BA, D'Annibale MA, McLaughlin K, Siddiq A, Kozikowski AP, Jaffrey SR, Twiss JL, Ratan RR, Langley B. HDAC6 is a target for protection and regeneration following injury in the nervous system. Proc Natl Acad Sci U S A. 2009 Nov 17;106(46):19599-604. PubMed.
Kim JY, Shen S, Dietz K, He Y, Howell O, Reynolds R, Casaccia P. HDAC1 nuclear export induced by pathological conditions is essential for the onset of axonal damage. Nat Neurosci. 2010 Feb;13(2):180-9. PubMed.
Majdzadeh N, Wang L, Morrison BE, Bassel-Duby R, Olson EN, D'Mello SR. HDAC4 inhibits cell-cycle progression and protects neurons from cell death. Dev Neurobiol. 2008 Jul;68(8):1076-92. PubMed.
Ago T, Liu T, Zhai P, Chen W, Li H, Molkentin JD, Vatner SF, Sadoshima J. A redox-dependent pathway for regulating class II HDACs and cardiac hypertrophy. Cell. 2008 Jun 13;133(6):978-93. PubMed.
Borrell-Pagès M, Canals JM, Cordelières FP, Parker JA, Pineda JR, Grange G, Bryson EA, Guillermier M, Hirsch E, Hantraye P, Cheetham ME, Néri C, Alberch J, Brouillet E, Saudou F, Humbert S. Cystamine and cysteamine increase brain levels of BDNF in Huntington disease via HSJ1b and transglutaminase. J Clin Invest. 2006 May;116(5):1410-24. PubMed.
Karpuj MV, Becher MW, Springer JE, Chabas D, Youssef S, Pedotti R, Mitchell D, Steinman L. Prolonged survival and decreased abnormal movements in transgenic model of Huntington disease, with administration of the transglutaminase inhibitor cystamine. Nat Med. 2002 Feb;8(2):143-9. PubMed.
Rigamonti D, Mutti C, Zuccato C, Cattaneo E, Contini A. Turning REST/NRSF dysfunction in Huntington's disease into a pharmaceutical target. Curr Pharm Des. 2009;15(34):3958-67. PubMed.
View all comments by Sama SleimanMake a Comment
To make a comment you must login or register.