Oxidative stress is causally linked to male reproductive pathologies, driven primarily by lipid peroxidation and an attendant production of highly reactive lipid aldehydes, such as 4-hydroxynonenal (4HNE) within the male germ line. In somatic cells, 4HNE dysregulates proteostasis via targeting of vulnerable proteins for adduction, causing protein misfolding and eventually aggregation. The aims of this study were to explore whether oxidative stress precipitates an equivalent response in the male germ line and determine the protective mechanisms used by germ cells to prevent this cascade of protein damage.
Results:
We reveal a causative role for oxidative stress in the accumulation of protein deposits in male germ cells. Specifically, 4HNE treatment resulted in a significant increase in cytosolic protein aggregation within pre- and post-meiotic germ cells as measured by the aggregate-detecting fluorophores ProteoStat and Thioflavin T, and the amyloid-specific anti-A11 and anti-OC antibodies. Our data implicate nucleocytoplasmic transport machinery and molecular chaperones as potential mechanisms for the subcellular compartmentalization and/or suppression of aggregating proteins. Thus, the inhibition of karyopherin transport proteins and molecular chaperones resulted in a significant increase in the accumulation of aggregated cellular protein.
Innovation:
These data establish the novel paradigm that lipid peroxidation is a key contributor to a decline in proteostasis in developing germ cells. These findings will inform the development of novel strategies to protect germ cells from oxidative stress.
Conclusion:
Together, these results shed light on proteostasis mechanisms that may assist in the management of misfolded proteins in the male germ line under conditions of acute oxidative stress.
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References
1.
AitkenRJ, WhitingS, De IuliisGN, McClymontS, MitchellLA, and BakerMA. Electrophilic aldehydes generated by sperm metabolism activate mitochondrial reactive oxygen species generation and apoptosis by targeting succinate dehydrogenase. J Biol Chem, 287: 33048–33060, 2012.
2.
BakerMA, WeinbergA, HetheringtonL, VillaverdeAI, VelkovT, BaellJ, and GordonC. Defining the mechanisms by which the reactive oxygen species by-product, 4-hydroxynonenal, affects human sperm cell function. Biol Reprod, 92: 108, 2015.
3.
BalchinD, Hayer-HartlM, and HartlFU. In vivo aspects of protein folding and quality control. Science, 353: aac4354, 2016.
4.
BrehmeM, VoisineC, RollandT, WachiS, SoperJH, ZhuY, OrtonK, VillellaA, GarzaD, VidalM, GeH, and MorimotoRI. A chaperome subnetwork safeguards proteostasis in aging and neurodegenerative disease. Cell Rep, 9: 1135–1150, 2014.
5.
BromfieldEG, AitkenR, AndersonAL, McLaughlinEA, and NixonB. The impact of oxidative stress on chaperone-mediated human sperm–egg interaction. Hum Reprod, 30: 2597–2613, 2015.
6.
BromfieldEG, AitkenRJ, McLaughlinEA, and NixonB. Proteolytic degradation of heat shock protein A2 occurs in response to oxidative stress in male germ cells of the mouse. Mol Hum Reprod, 23: 91–105, 2017.
7.
BromfieldEG, McLaughlinEA, AitkenRJ, and NixonB. Heat shock protein member A2 forms a stable complex with angiotensin converting enzyme and protein disulfide isomerase A6 in human spermatozoa. Mol Hum Reprod, 22: 93–109, 2016.
8.
BromfieldEG, WaltersJLH, CafeSL, BernsteinIR, StangerSJ, AndersonAL, AitkenRJ, McLaughlinEA, DunMD, GadellaBM, and NixonB. Differential cell death decisions in the testis: evidence for an exclusive window of ferroptosis in round spermatids. Mol Hum Reprod, 21: 245–256, 2019.
9.
CamlinNJ, McLaughlinEA, and HoltJE. Kif4 is essential for mouse oocyte meiosis. PLoS One, 12: e0170650, 2017.
10.
CastroJP, JungT, GruneT, and SiemsW. 4-Hydroxynonenal (HNE) modified proteins in metabolic diseases. Free Radic Biol Med, 111: 309–315, 2017.
11.
Da Cruz S and ClevelandDW.Disrupted nuclear import-export in neurodegeneration. Science, 351: 125–126, 2016.
12.
DunMD, AitkenRJ, and NixonB. The role of molecular chaperones in spermatogenesis and the post-testicular maturation of mammalian spermatozoa. Hum Reprod Update, 18: 420–435, 2012.
13.
GassmannM, GrenacherB, RohdeB, and VogelJ. Quantifying Western blots: pitfalls of densitometry. Electrophoresis, 30: 1845–1855, 2009.
14.
GervasiMG and ViscontiPE. Molecular changes and signaling events occurring in spermatozoa during epididymal maturation. Andrology, 5: 204–218, 2017.
15.
GhisaysF, Brace CynthiaS, Yackly ShawnM, Kwon HyockJ, Mills KathrynF, KashentsevaE, Dmitriev IgorP, Curiel DavidT, ImaiS-I, and EllenbergerT. The N-terminal domain of SIRT1 is a positive regulator of endogenous SIRT1-dependent deacetylation and transcriptional outputs. Cell Rep, 10: 1665–1673, 2015.
GuyonnetB, EggeN, and CornwallGA. Functional amyloids in the mouse sperm acrosome. Mol Cell Biol, 34: 2624–2634, 2014.
18.
HalakouF, KilicES, CukurogluE, KeskinO, and GursoyA. Enriching traditional protein-protein interaction networks with alternative conformations of proteins. Sci Rep, 7: 7180, 2017.
19.
HerskovitsAZ and GuarenteL. Sirtuin deacetylases in neurodegenerative diseases of aging. Cell Res, 23: 746–758, 2013.
20.
HoltJE, Ly-HuynhJD, EfthymiadisA, HimeGR, LovelandKL, and JansDA. Regulation of nuclear import during differentiation; the IMP alpha gene family and spermatogenesis. Curr Genomics, 8: 323–334, 2007.
21.
HuszarG, OzkavukcuS, JakabA, Celik-OzenciC, SatiGL, and CayliS. Hyaluronic acid binding ability of human sperm reflects cellular maturity and fertilizing potential: selection of sperm for intracytoplasmic sperm injection. Curr Opin Obstet Gynecol, 18: 260–267, 2006.
22.
JangEJ, KimDH, LeeB, LeeEK, ChungKW, MoonKM, KimMJ, AnHJ, JeongJW, KimYR, YuBP, and ChungHY. Activation of proinflammatory signaling by 4-hydroxynonenal-Src adducts in aged kidneys. Oncotarget, 7: 50864–50874, 2016.
23.
JohnstonJA, WardCL, and KopitoRR. Aggresomes: a cellular response to misfolded proteins. J Cell Biol, 143: 1883–1898, 1998.
24.
KaganovichD, KopitoR, and FrydmanJ. Misfolded proteins partition between two distinct quality control compartments. Nature, 454: 1088–1095, 2008.
25.
KayedRHE, SarsozaF, SaingT, CotmanCW, NeculaM, MargolL, WuJ, BreydoL, ThompsonJL, RasoolS, GurloT, ButlerP, and GlabeCG. Fibril specific, conformation dependent antibodies recognize a generic epitope common to amyloid fibrils and fibrillar oligomers that is absent in prefibrillar oligomers. Mol Neruodegener, 2: 18, 2007.
26.
KimYE, HippMS, BracherA, Hayer-HartlM, and Ulrich HartlF. Molecular chaperone functions in protein folding and proteostasis. Annu Rev Biochem, 82: 323–355, 2013.
27.
KlaipsCL, JayarajGG, and HartlFU. Pathways of cellular proteostasis in aging and disease. J Cell Biol, 217: 51–63, 2018.
28.
LiR-L, LuZ-Y, HuangJ-J, QiJ, HuA, SuZ-X, ZhangL, LiY, ShiY-Q, HaoC-N, and DuanJ-L. SRT1720, a SIRT1 specific activator, protected H2O2-induced senescent endothelium. Am J Transl Res, 8: 2876–2888, 2016.
29.
LiuX, HuD, ZengZ, ZhuW, ZhangN, YuH, ChenH, WangK, WangY, WangL, ZhaoJ, ZhangL, WuR, HuX, and WangJa. SRT1720 promotes survival of aged human mesenchymal stem cells via FAIM: a pharmacological strategy to improve stem cell-based therapy for rat myocardial infarction. Cell Death Dis, 8: e2731, 2017.
30.
LovelandKL, MajorAT, ButlerR, YoungJC, JansDA, and MiyamotoY. Putting things in place for fertilization: discovering roles for importin proteins in cell fate and spermatogenesis. Asian J Androl, 17: 537–544, 2015.
31.
McClureSM, AhlPL, and BlueJT. High throughput differential scanning fluorimetry (DSF) formulation screening with complementary dyes to assess protein unfolding and aggregation in presence of surfactants. Pharm Res, 35: 81, 2018.
MinS-W, ChoS-H, ZhouY, SchroederS, HaroutunianV, SeeleyWW, HuangEJ, ShenY, MasliahE, MukherjeeC, MeyersD, ColePA, OttM, and GanL. Acetylation of tau inhibits its degradation and contributes to tauopathy. Neuron, 67: 953–966, 2010.
34.
MostafaTNN, RashedL, MakeenK, El-KasasMA, and MohamaedHA. Seminal SIRT1 expression in infertile oligoasthenoteratozoospermic men with varicocoele. Andrology, 6: 301–305, 2018.
35.
NavarroS and VenturaS. Fluorescent dye ProteoStat to detect and discriminate intracellular amyloid-like aggregates in Escherichia coli. Biotechnol J, 9: 1259–1266, 2014.
36.
NiforouK, CheimonidouC, and TrougakosIP. Molecular chaperones and proteostasis regulation during redox imbalance. Redox Biol, 2: 323–332, 2014.
37.
NixonB, BromfieldEG, CuiJ, and De IuliisGN. Heat shock protein A2 (HSPA2): regulatory roles in germ cell development and sperm function. In: The Role of Heat Shock Proteins in Reproductive System Development and Function, edited by MacPheeDJ. Cham: Springer International Publishing, 2017, pp. 67–93.
38.
NorthBJ and VerdinE. Interphase nucleo-cytoplasmic shuttling and localization of SIRT2 during mitosis. PLoS One, 2: e784–e784, 2007.
39.
OrestiGM, ReyesJG, LuquexJM, OssesN, FurlandNE, and AveldanoMI. Differentiaton-related changes in lipid classes with long-chain and very long-chain polyenoic fatty acids in rat spermatogenic cells. J Lipid Res, 51:2909–2921, 2010.
40.
PerchiaccaJMLA, BhattacharyaM, and TessierPM. Structure-based design of conformation- and sequence-specific antibodies against amyloid β. Proc Natl Acad Sci U S A, 109: 84–89, 2011.
41.
RatoLAM, SilvaBM, SousaM, and OliveiraPF. Sirtuins: novel players in male reproductive health. Curr Med Chem, 23: 1084–1099, 2016.
42.
RedgroveKA, NixonB, BakerMA, HetheringtonL, BakerG, LiuDY, and AitkenRJ. The molecular chaperone HSPA2 plays a key role in regulating the expression of sperm surface receptors that mediate sperm-egg recognition. PLoS One, 7: e50851, 2012.
43.
SabetiP, PourmasumiS, RahiminiaT, AkyashF, and TalebiAR. Etiologies of sperm oxidative stress. Int J Reprod Biomed (Yazd), 14: 231–240, 2016.
44.
SaitoY, YamagishiN, and HatayamaT. Different localization of Hsp105 family proteins in mammalian cells. Exp Cell Res, 313: 3707–3717, 2007.
45.
SaudouF, FinkbeinerS, DevysD, and GreenbergME. Huntingtin acts in the nucleus to induce apoptosis but death does not correlate with the formation of intranuclear inclusions. Cell, 95: 55–66, 1998.
46.
Shamoto-NagaiM, HisakaS, NaoiM, and MaruyamaW. Modification of α-synuclein by lipid peroxidation products derived from polyunsaturated fatty acids promotes toxic oligomerization: its relevance to Parkinson disease. J Clin Biochem Nutr, 62: 207–212, 2018.
47.
ShulgaN, JamesP, CraigEA, and GoldfarbDS. A nuclear export signal prevents Saccharomyces cerevisiae Hsp70 Ssb1p from stimulating nuclear localization signal-directed nuclear transport. J Biol Chem, 274: 16501–16507, 1999.
48.
SowaAS, MartinE, MartinsIM, SchmidtJ, DeppingR, WeberJJ, RotherF, HartmannE, BaderM, RiessO, TricoireH, and SchmidtT. Karyopherin α-3 is a key protein in the pathogenesis of spinocerebellar ataxia type 3 controlling the nuclear localization of ataxin-3. Proc Natl Acad Sci U S A, 115: E2624, 2018.
49.
TatoneC, Di EmidioG, VittiM, Di CarloM, SantiniS, Jr, D'AlessandroAM, FaloneS, and AmicarelliF. Sirtuin functions in female fertility: possible role in oxidative stress and aging. Oxid Med Cell Longev, 2015: 659687, 2015.
50.
TomitaT, HamazakiJ, HirayamaS, McBurneyMW, YashirodaH, and MurataS. Sirt1-deficiency causes defective protein quality control. Sci Rep, 5: 12613, 2015.
51.
TourzaniDA, PaudelB, MirandaPV, ViscontiPE, and GervasiMG. Changes in protein O-GlcNAcylation during mouse epididymal sperm maturation. Front Cell Dev Biol, 6: 60–60, 2018.
52.
TsukaharaF and MaruY. Identification of novel nuclear export and nuclear localization-related signals in human heat shock cognate protein 70. J Biol Chem, 279: 8867–8872, 2004.
53.
VionE, PageG, BourdeaudE, PaccalinM, GuillardJ, and Rioux BilanA. Trans ɛ-viniferin is an amyloid-β disaggregating and anti-inflammatory drug in a mouse primary cellular model of Alzheimer's disease. Mol Cell Neurosci, 88: 1–6, 2018.
54.
WaltersLJ, De IuliisNG, NixonB, and BromfieldGE. Oxidative stress in the male germline: a review of novel strategies to reduce 4-hydroxynonenal production. Antioxidants (Basel), 7: 132, 2018.
55.
WesterheideSD, AnckarJ, StevensSMJr., SistonenL, and MorimotoRI.Stress-inducible regulation of heat shock factor 1 by the deacetylase SIRT1. Science, 323: 1063–1066, 2009.
56.
WoernerAC, FrottinF, HornburgD, FengLR, MeissnerF, PatraM, TatzeltJ, MannM, WinklhoferKF, HartlFU, and HippMS. Cytoplasmic protein aggregates interfere with nucleocytoplasmic transport of protein and RNA. Science, 35: 173–176, 2016.
57.
WuY-L, ChangJ-C, LinW-Y, LiC-C, HsiehM, ChenH-W, WangT-S, WuW-T, LiuC-S, and LiuK-L. Caffeic acid and resveratrol ameliorate cellular damage in cell and Drosophila models of spinocerebellar ataxia type 3 through upregulation of Nrf2 pathway. Free Radic Biol Med, 115: 309–317, 2018.
58.
YoungJC, Ly-HuynhJD, LescesenH, MiyamotoY, BrowneC, YonedaY, KoopmanP, LovelandKL, and JansDA. The nuclear import factor importin α4 can protect against oxidative stress. Biochim Biophys Acta Mol Cell Res, 1833: 2348–2356, 2013.
59.
ZhangH and FormanHJ. 4-hydroxynonenal-mediated signaling and aging. Free Radic Biol Med, 111: 219–225, 2017.
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