Small Heat Shock Proteins (sHSPs) play crucial roles in protein homeostasis, the state of maintaining steady internal cellular conditions, despite changes to the cellular environment. As the “molecular life rafts” of the cell, sHSPs target partially misfolded proteins during stress and without consuming energy, prevent toxic aggregation. Mutations or malfunctions of the sHSP, HSPB5 (B5), in humans are associated with neurodegenerative diseases such as Alzheimer's and Alexander's disease, as well as cancers, myopathies, and cataracts. As one of the ten sHSPs encoded in the human genome, B5 contains structural elements (the building block) common to all sHSPs: a highly conserved alpha-crystallin domain (ACD), that is flanked by variable, less conserved, N- and C-terminal regions (NTR and CTR, respectively). Previous studies determined that interactions between building blocks occur between a three amino acid region known as the I-X-I motif (a “knob”) in the CTR, and a hydrophobic groove (“hole”) in the neighboring block, similar to how two pieces of Lego come together to build a larger structure. IXI motifs are believed to be an important structural element, and interestingly, in B5, there is an additional IXI motif in the NTR, but its role is unknown. I hypothesize that IXI motifs compete for binding into the hydrophobic groove, indicating the “knob” into “hole” interaction is loose, where the other “knob” can bind the “hole” when one leaves. Other binding partners of sHSPs such as Bag3 utilize the IXI motif to bind and regulate sHSPs. My goal is to compare binding of three IXI peptides (NTR-IXI-B5, NTR-IXI-B8, and Bag3) to the groove through NMR peptide titrations to determine which peptide (B5 or B8) in competition with Bag3 has the strongest binding affinity to the groove. These results will assist in demystifying the function of the NTR and in directing future sHSP studies.