PMID- 25489226
OWN - NLM
STAT- MEDLINE
DCOM- 20150626
LR  - 20181113
IS  - 1090-0535 (Electronic)
IS  - 1090-0535 (Linking)
VI  - 20
DP  - 2014
TI  - Different effects of valproic acid on photoreceptor loss in Rd1 and Rd10 retinal 
      degeneration mice.
PG  - 1527-44
AB  - PURPOSE: The histone-deacetylase inhibitor activity of valproic acid (VPA) was 
      discovered after VPA's adoption as an anticonvulsant. This generated speculation 
      for VPA's potential to increase the expression of neuroprotective genes. Clinical 
      trials for retinitis pigmentosa (RP) are currently active, testing VPA's 
      potential to reduce photoreceptor loss; however, we lack information regarding 
      the effects of VPA on available mammalian models of retinal degeneration, nor do 
      we know if retinal gene expression is perturbed by VPA in a predictable way. 
      Thus, we examined the effects of systemic VPA on neurotrophic factor and 
      Nrl-related gene expression in the mouse retina and compared VPA's effects on the 
      rate of photoreceptor loss in two strains of mice, Pde6b(rd1/rd1) and 
      Pde6b(rd10/rd10) . METHODS: The expression of Bdnf, Gdnf, Cntf, and Fgf2 was 
      measured by quantitative PCR after single and multiple doses of VPA 
      (intraperitoneal) in wild-type and Pde6b(rd1/rd1) mice. Pde6b(rd1/rd1) mice were 
      treated with daily doses of VPA during the period of rapid photoreceptor loss. 
      Pde6b(rd10/rd10) mice were also treated with systemic VPA to compare in a partial 
      loss-of-function model. Retinal morphology was assessed by virtual microscopy or 
      spectral-domain optical coherence tomography (SD-OCT). Full-field and focal 
      electroretinography (ERG) analysis were employed with Pde6b(rd10/rd10) mice to 
      measure retinal function. RESULTS: In wild-type postnatal mice, a single VPA dose 
      increased the expression of Bdnf and Gdnf in the neural retina after 18 h, while 
      the expression of Cntf was reduced by 70%. Daily dosing of wild-type mice from 
      postnatal day P17 to P28 resulted in smaller increases in Bdnf and Gdnf 
      expression, normal Cntf expression, and reduced Fgf2 expression (25%). Nrl gene 
      expression was decreased by 50%, while Crx gene expression was not affected. 
      Rod-specific expression of Mef2c and Nr2e3 was decreased substantially by VPA 
      treatment, while Rhodopsin and Pde6b gene expression was normal at P28. Daily 
      injections with VPA (P9-P21) dramatically slowed the loss of rod photoreceptors 
      in Pde6b(rd1/rd1) mice. At age P21, VPA-treated mice had several extra rows of 
      rod photoreceptor nuclei compared to PBS-injected littermates. Dosing started 
      later (P14) or dosing every second day also rescued photoreceptors. In contrast, 
      systemic VPA treatment of Pde6b(rd10/rd10) mice (P17-P28) reduced visual function 
      that correlated with a slight increase in photoreceptor loss. Treating 
      Pde6b(rd10/rd10) mice earlier (P9-P21) also failed to rescue photoreceptors. 
      Treating wild-type mice earlier (P9-P21) reduced the number of photoreceptors in 
      VPA-treated mice by 20% compared to PBS-treated animals. CONCLUSIONS: A single 
      systemic dose of VPA can change retinal neurotrophic factor and rod-specific gene 
      expression in the immature retina. Daily VPA treatment from P17 to P28 can also 
      alter gene expression in the mature neural retina. While daily treatment with VPA 
      could significantly reduce photoreceptor loss in the rd1 model, VPA treatment 
      slightly accelerated photoreceptor loss in the rd10 model. The apparent rescue of 
      photoreceptors in the rd1 model was not the result of producing more 
      photoreceptors before degeneration. In fact, daily systemic VPA was toxic to 
      wild-type photoreceptors when started at P9. However, the effective treatment 
      period for Pde6b(rd1/rd1) mice (P9-P21) has significant overlap with the 
      photoreceptor maturation period, which complicates the use of the rd1 model for 
      testing of VPA's efficacy. In contrast, VPA treatment started after P17 did not 
      cause photoreceptor loss in wild-type mice. Thus, the acceleration of 
      photoreceptor loss in the rd10 model may be more relevant where both 
      photoreceptor loss and VPA treatment (P17-P28) started when the central retina 
      was mature.
FAU - Mitton, Kenneth P
AU  - Mitton KP
AD  - Control of Gene Expression Laboratory and Pediatric Retinal Research Laboratory, 
      Eye Research Institute, Oakland University, Rochester, MI.
FAU - Guzman, Alvaro E
AU  - Guzman AE
AD  - Control of Gene Expression Laboratory and Pediatric Retinal Research Laboratory, 
      Eye Research Institute, Oakland University, Rochester, MI.
FAU - Deshpande, Mrinalini
AU  - Deshpande M
AD  - Control of Gene Expression Laboratory and Pediatric Retinal Research Laboratory, 
      Eye Research Institute, Oakland University, Rochester, MI.
FAU - Byrd, David
AU  - Byrd D
AD  - Control of Gene Expression Laboratory and Pediatric Retinal Research Laboratory, 
      Eye Research Institute, Oakland University, Rochester, MI.
FAU - DeLooff, Camryn
AU  - DeLooff C
AD  - Control of Gene Expression Laboratory and Pediatric Retinal Research Laboratory, 
      Eye Research Institute, Oakland University, Rochester, MI.
FAU - Mkoyan, Kristina
AU  - Mkoyan K
AD  - Control of Gene Expression Laboratory and Pediatric Retinal Research Laboratory, 
      Eye Research Institute, Oakland University, Rochester, MI.
FAU - Zlojutro, Paul
AU  - Zlojutro P
AD  - Control of Gene Expression Laboratory and Pediatric Retinal Research Laboratory, 
      Eye Research Institute, Oakland University, Rochester, MI.
FAU - Wallace, Adrianne
AU  - Wallace A
AD  - Control of Gene Expression Laboratory and Pediatric Retinal Research Laboratory, 
      Eye Research Institute, Oakland University, Rochester, MI.
FAU - Metcalf, Brandon
AU  - Metcalf B
AD  - Control of Gene Expression Laboratory and Pediatric Retinal Research Laboratory, 
      Eye Research Institute, Oakland University, Rochester, MI.
FAU - Laux, Kirsten
AU  - Laux K
AD  - Control of Gene Expression Laboratory and Pediatric Retinal Research Laboratory, 
      Eye Research Institute, Oakland University, Rochester, MI.
FAU - Sotzen, Jason
AU  - Sotzen J
AD  - Control of Gene Expression Laboratory and Pediatric Retinal Research Laboratory, 
      Eye Research Institute, Oakland University, Rochester, MI.
FAU - Tran, Trung
AU  - Tran T
AD  - Control of Gene Expression Laboratory and Pediatric Retinal Research Laboratory, 
      Eye Research Institute, Oakland University, Rochester, MI.
LA  - eng
GR  - R01 EY014626/EY/NEI NIH HHS/United States
GR  - R01EY014626/EY/NEI NIH HHS/United States
PT  - Journal Article
PT  - Research Support, N.I.H., Extramural
PT  - Research Support, Non-U.S. Gov't
DEP - 20141104
PL  - United States
TA  - Mol Vis
JT  - Molecular vision
JID - 9605351
RN  - 0 (Basic-Leucine Zipper Transcription Factors)
RN  - 0 (Brain-Derived Neurotrophic Factor)
RN  - 0 (Enzyme Inhibitors)
RN  - 0 (Eye Proteins)
RN  - 0 (Glial Cell Line-Derived Neurotrophic Factor)
RN  - 0 (Homeodomain Proteins)
RN  - 0 (MEF2 Transcription Factors)
RN  - 0 (Mef2c protein, mouse)
RN  - 0 (Nerve Growth Factors)
RN  - 0 (Nr2e3 protein, mouse)
RN  - 0 (Nrl protein, mouse)
RN  - 0 (Orphan Nuclear Receptors)
RN  - 0 (Protective Agents)
RN  - 0 (Trans-Activators)
RN  - 0 (cdnf protein, mouse)
RN  - 0 (cone rod homeobox protein)
RN  - 103107-01-3 (Fibroblast Growth Factor 2)
RN  - 614OI1Z5WI (Valproic Acid)
RN  - 9009-81-8 (Rhodopsin)
RN  - EC 3.1.4.35 (Cyclic Nucleotide Phosphodiesterases, Type 6)
RN  - EC 3.1.4.35 (Pde6b protein, mouse)
SB  - IM
MH  - Animals
MH  - Basic-Leucine Zipper Transcription Factors/genetics/metabolism
MH  - Brain-Derived Neurotrophic Factor/genetics/metabolism
MH  - Cyclic Nucleotide Phosphodiesterases, Type 6/genetics/metabolism
MH  - Enzyme Inhibitors/*pharmacology
MH  - Eye Proteins/genetics/metabolism
MH  - Fibroblast Growth Factor 2/genetics/metabolism
MH  - Gene Expression Regulation
MH  - Glial Cell Line-Derived Neurotrophic Factor/genetics/metabolism
MH  - Homeodomain Proteins/genetics/metabolism
MH  - Injections, Intraperitoneal
MH  - MEF2 Transcription Factors/genetics/metabolism
MH  - Mice
MH  - Mice, Inbred C57BL
MH  - Mice, Transgenic
MH  - Nerve Growth Factors/genetics/metabolism
MH  - Orphan Nuclear Receptors/genetics/metabolism
MH  - Protective Agents/*pharmacology
MH  - Retinal Degeneration/*drug therapy/genetics/metabolism/pathology
MH  - Retinal Rod Photoreceptor Cells/*drug effects/metabolism/pathology
MH  - Rhodopsin/genetics/metabolism
MH  - Species Specificity
MH  - Time Factors
MH  - Trans-Activators/genetics/metabolism
MH  - Valproic Acid/*pharmacology
PMC - PMC4225157
EDAT- 2014/12/10 06:00
MHDA- 2015/06/27 06:00
PMCR- 2014/01/01
CRDT- 2014/12/10 06:00
PHST- 2013/09/18 00:00 [received]
PHST- 2014/11/02 00:00 [accepted]
PHST- 2014/12/10 06:00 [entrez]
PHST- 2014/12/10 06:00 [pubmed]
PHST- 2015/06/27 06:00 [medline]
PHST- 2014/01/01 00:00 [pmc-release]
AID - 145 [pii]
PST - epublish
SO  - Mol Vis. 2014 Nov 4;20:1527-44. eCollection 2014.