Fluorescence Spectroscopy

Please acknowledge the SIP core facility ( RRID: SCR_018986) in publications, on posters, or in talks if you use any instruments in the SIP core facility. Please include SIP's RRID (RRID: SCR_018986) and the grant numbers for instruments funded through instrumentation grants in your acknowledgements. This is a requirement from the funding agencies and is crucial for future funding. Find example text on theÌýAcknowledgement PageÌýor the individual instrument pages.

Fluorescence Spectroscopy in Biochemistry, Biophysics and Structural Biology

Fluorescence spectroscopy is a powerful, non-destructive technique widely used in biochemistry, biophysics, and structural biology. It is crucial for investigating enzymatic mechanisms and reaction kinetics, as well as elucidating the three-dimensional structures and dynamics of proteins, DNA, RNA, and complexes.

The principle underlying this technique is based on the interaction of light with fluorophores. When exposed to specific excitation wavelengths, fluorophores absorb photons, undergoing electronic transitions from their ground state to an excited state. The excited state of fluorophores is usually transient. Fluorophores can emit light as they relax back to their ground state, with the emitted fluorescence typically occurring at longer wavelengths than the excitation light.

The spectral characteristics of fluorophores are highly sensitive to their immediate environment. Together with techniques such as fluorescence quenching, resonance energy transfer (FRET), and fluorescence polarization fluorescence spectroscopy is invaluable for studying structural changes, dynamics, and interactions of macromolecules. The native fluorescence of amino acids like tryptophan, tyrosine, and phenylalanine, or the strategic attachment of fluorescent labels to specific sites within a biological macromolecule, provides a dynamic view of molecular behaviour that complements the static structural information obtained through techniques like X-ray crystallography and nuclear magnetic resonance (NMR) spectroscopy.

In enzymatic studies, fluorescence spectroscopy offers insights into substrate binding, conformational changes, and reaction kinetics by tracking the fluorescence of natural fluorophores within enzymes or the products of reactions involving added fluorescent probes. The technique's high sensitivity allows for the detection of subtle environmental changes surrounding the fluorophore, making it an invaluable tool for real-time studies of enzyme mechanisms and dynamics, often under physiological conditions. Advanced tools like stopped-flow fluorescence spectrometers enable the observation of rapid reactions, with detection times in the millisecond timescale, while fluorescence plate readers facilitate high-throughput experiments. The combination of these capabilities ensures that fluorescence spectroscopy remains a versatile and essential tool for probing the intricate details of biological systems, bridging the gap between structural and functional studies.

exsample data, upper pannle Ovalin excitation and emission spectrum, lower pannle reaction kinetics of ANS binding to BSA

Key highlights of Fluorescense Spectroscopy in Biology, Biochemistry, and Biophysics

  • Binding Studies (ligand - macromolecule, macromolecule – macromolecule, macromolecule - membrane, etc.)
  • Structure and stability of biological macromolecule and complexes
  • Monitor conformational changes
  • Distance measurements (FRET)
  • Reaction kinetics
  • And a lot more ...
QM6 PTI Fluorimeter

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four cuvette turret

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Instruments and Accesories

Instruments Available:

  • QM-6 Steady-State Fluorimeter (PTI)

Features: Four-position sample holder, dual emission channels, circulating water bath.
  • Chirascan Plus CD/Fluorimeter (Applied Photophysics)

Features: Emission monochromator, fluorescence polarisation detector, and Peltier temperature control.
  • SX20 Fluorescence Stopped-Flow System (Applied Photophysics)

Features: Designed for kinetic experiments using fluorescence, fluorescence polarisation, FRET or absorption as read out; fast response with a 1.2-millisecond dead time for capturing rapid kinetic events.
  • Monochromator-Based Spark Multimode Plate Reader (Tecan)

Features: High-throughput, supporting fluorescence modes such as emission/excitation intensity, emission/excitation scans, polarisation/anisotropy, FRET.

Essential Information for Using SIP's Fluorescence Spectroscopy Instruments

Why?

Acknowledgements are essential for ensuring the continued success of the Shared Instruments Pool (SIP). They enable us to secure the necessary funding to sustain and expand the SIP, ensuring that our instruments are in optimal working condition and that the methods we offer are at the forefront of biochemical and biophysical research.

Please include SIP's RRID number (RRID: SCR_018986) in your acknowledgements. This allows funding organisations and potential grant reviewers to easily locate publications supported by SIP, helping to evaluate the impact of SIP on our research community.

If facility staff have provided substantial assistance, please consider acknowledging them. If they contributed significantly to the intellectual aspects or conducted important experiments, co-authorship may also be appropriate.

Example text:

  • We thank the Shared Instruments Pool (RRID: SCR_018986), Department of Biochemistry, University of ÃÛÌÇÖ±²¥ Boulder for the use of the QM-6 PTI fluorescence spectrometer.Ìý We also thank [Name and title of the facility member providing significant help] for their invaluable assistance with data collection and evaluation.
  • We thank the Shared Instruments Pool (RRID: SCR_018986), Department of Biochemistry, University of ÃÛÌÇÖ±²¥ Boulder for the use of the Tecan Spark Multi mode Plate Reader for fluorescence polarization assays. We thank [Name and title of the facility member providing significant help] for their invaluable assistance with data collection and evaluation.

Please contact Dr Erbse to obtain detailed protocols and arrange an initial project consultation and personalised training sessions. Protocols are available as PDF files on the instrument computer, with printed copies stored alongside the instruments.

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Interested users can contact Dr Erbse to discuss planned experiments and arrange training sessions. These sessions will involve the use of actual user samples alongside standards, enabling users to collect preliminary data during the training and receive help from core staff right away if troubleshooting or optimisation is needed. Users are welcome to request additional training or support sessions at any time. We are always happy to provide a refresher if it has been a while.

After your training is completed, you will be invited to join the Fluorimeter, Stopped-Flow Fluorimeter or Plate Reader Google calendars.

Sign Up Rules:Ìý
Up to Friday the week before the planned experiment users can sign up for a maximum of 2 days. In the week of the experiment users can sign up for additional time if available.

  • Initial consultation is free. SIP staff are happy to assist with a short pilot experiment if it can be accommodated within SIP's resources.
  • Regular user groups are expected to buy into SIP with a monthly flat fee according to their SIP usage level. For detailed information, please contact Dr Annette Erbse.
  • Users are required to provide all consumables specific to their experiments.
  • Users are expected to provide their own cuvettes. Cuvettes with varying path lengths are available for pilot experiments to determine the right cuvette size for the planned experiments.Ìý
  • Costs for necessary repairs, services, or replacement parts due to normal wear and tear will be shared among all user groups, based on the time used over the past two years. Please note that assuming the instrument is handled properly, such repairs or replacements are infrequent, and costs may arise after a user’s period of use has ended.
  • Users are responsible for covering the costs of repairs or replacement parts needed due to damage caused by carelessness or neglect.

The Fluorimeter and the Fluorescence Stopped-Flow instrument is located on the third floor of JSCBB in the D-Wing, room D381, on East Campus. Proxcard access is required at all times.