1. Organic Gold: A study of the effects
of the cysteine content of protein-
bound gold nanoparticles in novel
biochemical sensing.
THIRD YEAR PROJECT PRESENTATION
CHRISTOPHER HUCKLE
2. Gold nanoparticles
Nanoparticle research remains a dynamic area of research
with many potential uses across different scientific fields.
Gold nanoparticles (AuNPs) give rapid detection of miniscule
concentrations of material diagnosis of disease, forensics,
quality control for food and water, etc.
Capped with citrate, AuNPs repel one-another via their
negative charges, giving a deep red colour in solution.
The introduction of positively-charged ions displaces this
negative charge, causing the AuNPs to aggregate, giving a
distinct colour change to blue.
Introduction
3. Detection of heavy metals
Small concentrations of heavy metals are needed in the body for various metabolic processes.
Can be very harmful in high concentrations (ingestion, inhalation, skin absorption).
Accumulation of heavy metals in water or soil has detrimental effects on entire food chains.
The testing of water or soil quality via heavy metal detection ensures safe food and water
distribution and increased crop yield.
AuNPs have suitable properties for detection:
◦ Low detection limits
◦ Small concentration needed (cost-effective)
◦ Easy to synthesise
◦ Intense and immediate detection
◦ Good signal/noise ratio (small sensor element with much larger transduction event)
Introduction
4. Question
Guo et al. (2011) have suggested that binding protein (specifically papain) to the surfaces of
AuNPs increases their detection ability – both the S/N ratio and the range of metals that can be
detected.
Papain apparently increases detection ability due to the presence of seven cysteine residues.
Does the more costly and time-consuming addition of proteins to AuNPs increase their detection
ability of heavy metal ions? What are the implications either way?
Introduction
5. Outline
Majority of procedures are identical to those found in Guo et al. (2011).
Synthesis of AuNPs via the Turkevich method (Kimling et al., 2006).
AuNP properties largely depend on their size, determined by their synthesis.
Sodium citrate is added to aqueous, boiling, pale yellow chloroauric acid and stirred.
Yellow dark blue: citrate reduces Au3+ to Au+.
Dark blue deep red: 3Au+ Au+ + 2Au.
2 gold atoms induce reduction of additional Au+ ions, creating an atomic gold nucleus.
Citrate caps the nanoparticles to prevent aggregation and further growth.
Materials and Methods
6. Chemicals
Hydrochloric and nitric acid mixed 3:1 aqua regia.
Chloroauric acid and sodium citrate to synthesise AuNPs.
Heavy metal solutions dissolved in ultrapure water:
◦ Copper(II) sulphate pentahydrate
◦ Mercury(II) nitrate
Proteins of varying cysteine content, purchased from Sigma Aldrich:
◦ Papain (fewer)
◦ BSA (greater)
Materials and Methods
7. Adsorption of proteins to AuNPs
Solid papain and BSA dissolved in ultrapure water to give 10-5 M
solutions.
Excess amounts of each protein added to 1ml AuNPs.
Shaken for 30 minutes, left to stand for 24 hours.
Proteins bind non-covalently via electrostatic interactions (Brewer et al.,
2005).
Centrifuged at 10,000x speed for 20 minutes.
Supernatant removed and pellet resuspended in ultrapure water. Repeat
twice more.
Similarly to Guo et al. (2011), protein-bound AuNPs were purple rather
than red.
Materials and Methods
8. Sensing heavy metals
In each experiment, 500μl AuNPs + 500μl metal
solution.
Visible changes, absorption spectra, maximum
absorbance and peak wavelength recorded.
Comparisons were drawn between different
combinations of proteins adsorbed onto AuNPs (or lack
thereof) and different metal ions detected.
This allowed comparisons to be made concerning
different colour change intensities and S/N ratios.
Repeated to gain mean values and exclude anomalies.
Measured relative intensities, S/N ratios, limits of
detection and stability, as well as controls.
Materials and Methods
9. Sensing heavy metals – intensity and S/N
In each experiment, 500μl AuNPs + 500μl metal solution.
Visible changes, absorption spectra, maximum absorbance and peak wavelength recorded.
Comparisons were drawn between different combinations of proteins adsorbed onto AuNPs (or
lack thereof) and different metal ions detected.
This allowed comparisons to be made concerning different colour change intensities and S/N
ratios.
Repeated to gain mean values and exclude anomalies.
Materials and Methods
10. Sensing heavy metals – limit of detection
As before, but with serial dilutions of heavy metal ions.
Procedure used to detect the minimum concentration required for AuNPs to provide a
measureable signalling event in response to detection.
Since equal volumes of AuNPs and metal solutions were mixed together, any metal solution
dilutions would be doubled to give the final concentration
◦ E.g. 500μl 0.1M metal solution added to 500μl AuNPs = 0.05M final concentration
Materials and Methods
11. Sensing heavy metals – stability
Stocks of AuNPs and protein-bound AuNPs were kept in the fridge for one month.
Then used in detection experiments identical to those seen in intensity and S/N ratio
experiments.
Results compared with original intensity experiments carried out on newly-synthesised AuNPs
and protein-bound AuNPs to determine if they have degraded at all.
Materials and Methods
12. Control experiments
Two sets of experiments carried out:
1. Copper/mercury + papain/BSA
◦ Used to confirm that the AuNPs and not the proteins alone were responsible for any colour changes
2. Ultrapure water + AuNPs
◦ Used to confirm that the AuNPs selectively detected metal ions
Materials and Methods
13. Intensity and S/N ratio
All experiments:
◦ Immediate red blue colour change
◦ Shift in max. absorbance and peak wavelength
◦ Band broadening
AuNPs alone:
◦ Most intense colour changes and greater differences between
max. absorbances and peak wavelengths (>10nm)
P-AuNPs:
◦ Moderate colour changes with smaller differences between
max. absorbances and peak wavelengths (<10nm)
BSA-AuNPs:
◦ Least intense colour change with mercury, no colour change at
all with copper
◦ No further experiments carried out
Therefore, AuNPs alone have better signalling events and lower
S/N ratios than protein-bound AuNPs.
Results
14. Copper and mercury
Both metals were visibly detected but with different signalling events.
Copper:
◦ Red blue colour change
◦ Solution remained transparent
Mercury:
◦ Red purple colour change
◦ Mercury-AuNP complexes precipitated out of solution
Results
15. Limits of detection
Serial dilutions of copper and mercury allowed for
an ‘intensity scale’, showing the ‘cut-off point’.
Limits of detection for copper and mercury were
similar but not identical.
AuNPs + metal:
◦ Copper: 1.5mM
◦ Mercury: 2.0mM
P-AuNPs + metal:
◦ Copper: 2.5mM
◦ Mercury: 2.5mM
Therefore, AuNPs alone have lower limits of
detection than P-AuNPs.
Results Mixture Dilution of metal solution Final concentration of
metal ions
Colour change?
AuNPs + copper
0.1M (100mM) 0.05M (50mM) Yes
0.01M (10mM) 0.005M (5mM) Yes
0.005M (5mM) 0.0025M (2.5mM) Yes
0.004M (4mM) 0.002M (2mM) Yes
0.003M (3mM) 0.0015M (1.5mM) Yes
0.002M (2mM) 0.001M (1mM) No
0.001M (1mM) 0.0005 (500μM) No
AuNPs + mercury
0.01M (10mM) 0.005M (5mM) Yes
0.005M (5mM) 0.0025M (2.5mM) Yes
0.004M (4mM) 0.002M (2mM) Yes
0.003M (3mM) 0.0015M (1.5mM) No
0.002M (2mM) 0.001M (1mM) No
0.001M (1mM) 0.0005 (500μM) No
P-AuNPs + copper
0.1M (100mM) 0.05M (50mM) Yes
0.01M (10mM) 0.005M (5mM) Yes
0.005M (5mM) 0.0025M (2.5mM) Yes
0.004M (4mM) 0.002M (2mM) No
0.003M (3mM) 0.0015M (1.5mM) No
0.002M (2mM) 0.001M (1mM) No
0.001M (1mM) 0.0005 (500μM) No
P-AuNPs + mercury
0.01M (10mM) 0.005M (5mM) Yes
0.005M (5mM) 0.0025M (2.5mM) Yes
0.004M (4mM) 0.002M (2mM) No
0.003M (3mM) 0.0015M (1.5mM) No
0.002M (2mM) 0.001M (1mM) No
0.001M (1mM) 0.0005 (500μM) No
16. Stability
1 month-old AuNPs + metal:
◦ No significant differences in results
1 month-old P-AuNPs + metal:
◦ No visible colour changes observed at all
Therefore, AuNPs remain stable for longer than P-AuNPs.
Results
17. Control experiments
Copper + papain:
◦ No significant changes in colour, absorbance or wavelength
Mercury + papain:
◦ No significant changes in colour, absorbance or wavelength
Water + AuNPs:
◦ Paler red colour due to dilution. No significant changes in colour, absorbance or wavelength.
Water + P-AuNPs:
◦ Paler red colour due to dilution. No significant changes in colour, absorbance or wavelength.
Therefore, the signalling event is entirely due to AuNP/P-AuNP aggregation alone.
Results
18. Protein coronas
All protein-bound AuNPs have lower colour change intensities and S/N ratios, higher limits of
detection and less stability. Hypothesis refuted.
BSA-AuNPs: highest cysteine content, poorest detectors.
Possibly due to cysteines and other positively-charged amino acids already inducing aggregation.
Indicated by Jonjinakool et al. (2014) where isolated cysteine induced AuNP aggregation.
Further additions of cations induced minimal further colour changes.
Alternatively, protein coronas provide greater stability at higher ionic strengths, making
aggregation and detection more difficult.
Discussion
19. Alternative implications
Protein-bound AuNPs could instead become specifically tailored towards biological
environments.
Match certain tissues or subcellular locations improve cellular uptake, prevent degradation,
reduce harmful side effects (Saptarshi et al., 2013).
Far-reaching implications, e.g. protein-capped AuNPs as novel vehicles for drug delivery in
nanomedicine.
AuNP protein corona ‘fingerprint’ library currently undergoing construction (Walkey et al.,
2014).
Countless other materials are being investigated as AuNP ligands to target specific subcellular
locations (Zeng et al., 2011).
Discussion
20. Mercury selectivity
Different signalling events.
Mercury able to induce greater AuNP aggregation.
Possibly due to mercury being more thiophilic. Confirmed in experiments with dithioerythritol
(Kim et al., 2010).
Appears to be main basis of Guo et al. (2011) hypothesis. However, greater aggregation was still
seen in AuNPs alone.
Likely that papain and BSA tertiary structures shielded cations from cysteines.
Dithioerythritol is a far smaller molecule with exposed thiol groups.
Protein corona preventing aggregation at high ionic strengths is already a poor detector, but
ensuring that this protein is tailored towards a different cation reinforces this further.
Discussion
21. Evaluation
Any significant differences between data obtained from the same stock of AuNPs or P-AuNPs
were due to differences in heavy metal or protein content.
No anomalies noted.
Any alterations in materials and methods compared to Guo et al. (2011) were due to lack of
identical resources. Alternatives were used. None of these resulted in less reliable data.
AuNPs in this investigated were slightly larger than the originals. Did not affect results.
All copper salts have a light blue colour in solution. Affects S/N ratio. However, control
experiments allowed for comparison.
Discussion
22. Comparison to original paper
Through near-identical materials and methods, the results could not be replicated.
AuNPs alone are better detectors in all criteria.
More cost-effective and require less time to synthesise.
Remain stable for longer.
Unique thiol-mercury interactions were inappropriately applied to P-AuNPs.
Likely induced early aggregation before addition of metal cations, negating detection ability.
Nonsensical to functionalise AuNPs with proteins which induce an identical effect to that of the
analyte.
Conclusions
23. Next steps
More thorough experimentation using more advanced techniques are required.
Better understanding of sulphur-metal ion interactions.
Protein coronas appear to hinder AuNP detection ability, so perhaps this should not be pursued.
Instead, may be applied to other circumstances:
◦ Enzyme coronas to tailor AuNPs to metabolic substrates
In vivo research concerning therapeutic uses (drug delivery, tumour detection, combatting
pathogens, etc).
Requires safe and successful delivery to specific locations in the body.
Surpass biological barriers, pH extremes, enzymatic degradation, etc.
Conclusions
Therapeutic, forensic, environmental, chemical interactions… Likely to play many roles in the future.
Unique interactions between thiol groups and cations
Aqua regia used to clean glassware and remove contaminating ions to prevent false-positive results.
Protein-bound AuNPs – difficult to determine if signalling event occurred.
AuNPs alone gave distinguishable colour change right up to ‘cut off point’.
S/N ratios less applicable when using more advanced measuring techniques such as absorption spectra, but ability to provide a quick visual comparison should be a hallmark of a good sensor with more advanced analysis techniques only being used if needed.
Current research into AuNP toxicity. Protein coronas could solve this.
Amino acids could provide a suitable scaffold upon which various therapeutic molecules could be attached.
Library catalogues their synthesis and biological responses to their presence.
Not due to concentration or charge (both Cu and Hg were used at the same concentrations and have the same charges).
Dithioerythritol (sulphuric compound. When bound to AuNPs, greater selectivity towards mercury, even in the presence of other cations).
Guo et al. appear to have jumped the gun on the thiol-mercury binding.
Transmission electron microscopy unavailable. Measuring maximum absorption is a good proxy.
AuNP synthesis requires high precision and speed when adding sodium citrate. A few drops fell outside of the flask. However, this investigation concerns the efficacy of protein coronas and their cysteine contents on detection ability. Miniscule differences in AuNP size would not have altered results significantly.
Aggregation of AuNPs alone in response to the presence of metal cations provide a more intense colour change at lower concentrations of analyte