Abstract

Smaller oligomeric chaperones of α-crystallins (αA- and αB-) have received increasing attention due to their improved therapeutic potential in preventing protein aggregating diseases. Our previous study suggested that deleting 54–61 residues from the N-terminal domain (NTD) of αB-crystallin (αBΔ54–61) decreases the oligomer size and increases the chaperone function. Several studies have also suggested that NTD plays a significant role in protein oligomerization and chaperone function. The current study was undertaken to assess the effect of deleting conserved 21–28 residues from the activated αBΔ54–61 (to get αBΔ21–28, Δ54–61) on the structure–function of recombinant αBΔ21–28, Δ54–61. The αBΔ21–28, Δ54–61 mutant shows an 80% reduction in oligomer size and 3- to 25-fold increases in chaperone activity against model substrates when compared to αB-WT. Additionally, the αB∆21–28, ∆54–61 was found to prevent β-amyloid (Aβ1–42) fibril formation in vitro and suppressed Aβ1–42-induced cytotoxicity in ARPE-19 cells in a more effective manner than seen with αB-WT or αB∆54–61. Cytotoxicity and reactive oxygen species (ROS) detection studies with sodium iodate (SI) showed that the double mutant protein has higher anti-apoptotic and anti-oxidative activities than the wild-type or αB∆54–61 in oxidatively stressed cells. Our study shows that the residues 21–28 and 54–61 in αB-crystallin contribute to the oligomerization and modulate chaperone function. The deletion of conserved 21–28 residues further potentiates the activated αBΔ54–61. We propose that increased substrate affinity, altered subunit structure, and assembly leading to smaller oligomers could be the causative factors for the increased chaperone activity of αBΔ21–28, Δ54–61.

Highlights

  • Alpha B-crystallin is a member of the small heat-shock protein family that prevents misfolded target proteins from aggregation and precipitation [1–3]. α-crystallin’s chaperone activity can be compromised by mutation or posttranslational modifications [4], leading to protein aggregation and cataracts due to the insolubility of the mutant or modified proteins or due to the insolubility of the complexes formed between the gain of function mutants and cellular proteins [4,5]

  • We investigated whether the removal of 21–28 residues from N-terminal domain (NTD) of αB∆54–61 affects the chaperone-like activity of double mutant protein

  • DDeelleettiioonn ooff 2211––2288 aanndd5544––6611RReessiidduueessininααBB-C-CryrystsatlallilninLLeaedasdstotothteheSmSmalalellreHr Homomo-oO-ligomers OligoOmuerspreviously reported study [7] suggested that the deletion of 54–61 amino acid residOueusrfprormevitohuesNlyTrDepoofrαteBd-WstTudpyro[t7e]insulegdgetost~ed40t%hartedthuectdioenletiinotnheofo5li4g–o6m1 earmicimnoasasciodf trheseipdruoetseifnro. mWhthilee NthTeDavoefraαgBe-WmoTlaprrmotaesins olefdαtBoo~l4ig0o%mreerdsurecdtiuocneidnftrhoemo5li5g8okmDeariicnmαBas-Ws oTf to 262 kDa in αB∆54–61, in αB∆21–28, ∆54–61 it was further decreased to 85 kDa (~80% reduction compared to αB-WT) in size

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Summary

Introduction

Alpha B-crystallin is a member of the small heat-shock protein (sHsp) family that prevents misfolded target proteins from aggregation and precipitation [1–3]. α-crystallin’s chaperone activity can be compromised by mutation or posttranslational modifications [4], leading to protein aggregation and cataracts due to the insolubility of the mutant or modified proteins or due to the insolubility of the complexes formed between the gain of function mutants and cellular proteins [4,5]. The deletion mutants showed increased anti-aggregation activity when alcohol dehydrogenase (ADH) or lysozyme were used as. The deletion mutants showed incre3aosfe1d7 anti-aggregation activity when alcohol dehydrogenase (ADH) or lysozyme were used as unfolding substrates. Multi-angle light scattering data clearly showed a significant difference in the oligomeric size of the three proteins analyzed (Figure 3A). Multi-angle light scattering data clearly showed a significant difference in the oligomeric size of the three proteins analyzed (FigTuhree 3dAif)f.eTrehnecdeisffienretnhceessiiznethofe osilzigeoomf oerlisgofomrmeresdfobrmy eαdBb-Wy TαBa-nWdTtwanoddtweloetdioenletmiountamnutswtaenrtes awlseoreobaslseorvoebdsewrhveedn nwehgeantivneelgyasttivaienlyedstparionteedinpsrwoteeriensexwaemreineexdaumnidneedr turanndsemr itsrsainosnemleicsstrioonn meleiccrtoroscnopmyic(rToEsMco)p.yTh(TeEmMic)r. The data shown is a representative profile of three independent analyses

Structural Characterization of the αB∆21–28, ∆54–61 Showed Significant
Construction of Plasmid DNA Expressing αB∆21–28, ∆54–61
Overexpression and Purification of Wild-Type and αB-Crystallin Mutants
Chaperone Assays
Structural
Fluorescence Measurements
Far- and Near-UV CD Spectra
Limited Proteolysis of αB∆21–28, ∆54–61 Using Trypsin
Anti-Amyloidogenic Potential of αB∆21–28, ∆54–61 Crystallin
Suppression of β-Amyloid Cytotoxicity on ARPE-19 Cells by αB∆21–28, ∆54–61 Crystallin
Anti-Oxidant Action of αB∆21–28, ∆54–61 Crystallin on ARPE-19 Cells
Findings
4.10. Statistical Analysis

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