With the rise of antibiotic resistant bacteria, understanding how pathogenic bacteria invade and survive within our bodies is becoming more important as we search for novel ways to combat bacterial infection. Some pathogens, such as Salmonella typhimurium, inject host cells with proteins that suppress the host cell’s ability to respond to bacterial invasion. One such protein, SspH1, is an E3 ubiquitin ligase. E3 ubiquitin ligases attach ubiquitin, an important regulatory protein used to mark other proteins for degradation, to a substrate. Ubiquitin, the biochemical machinery that activates ubiquitin, and the pathways that utilize ubiquitin as a signaling molecule, are not found in bacteria, only in eukaryotes. However, bacteria have evolved proteins, such as SspH1, that hijack a host cell’s biochemical machinery in order to target host proteins for degradation. SspH1 consists of two domains: a catalytic E3 domain that transfers ubiquitin to substrate, and a substrate recognizing Leucine-Rich-Repeat (LRR) domain. I have shown through biochemical assays that the LRR domain inhibits the catalytic activity of the E3 domain. I have also shown that this inhibition is relieved in the presence of substrate. Through the use of 2D NMR and further biochemical assays, I hope to characterize the binding between the LRR and E3 domain in order to further the understanding of how SspH1 is inhibited. Understanding the mechanism of SspH1 auto-inhibition can increase our knowledge of the mechanisms and activities of related bacterial effector proteins, furthering our understanding of how pathogenic bacteria evade our immune system, and potentially lead to the development of novel treatments that can combat bacterial infection.