Protein aggregation can lead to several incurable amyloidosis diseases. The full aggregation pathway is not fully understood, creating the need for new methods of studying this important biological phenomenon. Lysozyme is an amyloidogenic protein which is often used as a model protein for studying amyloidosis. This work explores the potential of employing Lysozyme encapsulated gold nanoclusters (Ly-AuNCs) to study the protein's aggregation. The fluorescence emission properties of Ly-AuNCs were studied in the presence of increasing concentrations of native lysozyme and as a function of pH, of relevance in macromolecular crowding and inflammation-triggered aggregation. AuNC fluorescence was observed to both redshift and increase in intensity as pH is increased or when native lysozyme is added to a solution of Ly-AuNCs at pH 3. The long (μs) fluorescence lifetime component of AuNC emission was observed to decrease under both conditions. Interestingly it was found via Time-Resolved Emission Spectra (TRES) that both AuNC fluorescence components increase in intensity and redshift with increasing pH while only the long lifetime component of AuNC was observed to change when adding native lysozyme to solution; indicating that the underlying mechanisms for the changes observed are fundamentally different for each case. It is possible that the sensitivity of Ly-AuNCs to native lysozyme concentration could be utilized to study early-stage aggregation. •Lysozyme encapsulated gold nanoclusters are a promising new type of fluorescent nanoprobes.•Lysozyme encapsulated gold nanoclusters has a potential to be used to probe early stage aggregation of lysozyme.•Fluorescence lifetime of gold nanoclusters is sensitive to local environment and early stage lysozyme aggregation.•Time resolved emission spectra disclosed mechanism involved in fluorescence lifetime changes.