Lenka Kundrat

Protein quality control in the ER: balancing the ubiquitin checkbook

Protein maturation in the endoplasmic reticulum (ER) is subject to stringent quality control. Terminally misfolded polypeptides are usually ejected into the cytoplasm and targeted for destruction by the proteasome. Ubiquitin conjugation is essential for both extraction and proteolysis. We discuss the role of the ubiquitin conjugation machinery in this pathway and focus on the role of ubiquitin ligase complexes as gatekeepers for membrane passage. We then examine the type of ubiquitin modification applied to the misfolded ER protein and the role of de-ubiquitylating enzymes in the extraction of proteins from the ER.

Site-specific N-terminal labeling of proteins using sortase-mediated reactions

This protocol describes the use of sortase-mediated reactions to label the N terminus of any given protein of interest. The sortase recognition sequence, LPXTG (for Staphylococcus aureus sortase A) or LPXTA (for Streptococcus pyogenes sortase A), can be appended to a variety of probes such as fluorophores, biotin or even to other proteins. The protein to be labeled acts as a nucleophile by attacking the intermediate formed between the probe containing the LPXTG/A motif and the sortase enzyme. If sortase, the protein of interest and a suitably functionalized label are available, the reactions usually require less than 3 h.

Engineered red blood cells as carriers for systemic delivery of a wide array of functional probes

Significance Engineered human RBCs are attractive carriers for the introduction of novel therapeutics, immunomodulatory agents, and diagnostic imaging probes into the human body. Normal murine and human RBCs can be produced in tissue culture from progenitors; we have introduced genes into these cells encoding surface proteins that can be covalently and site-specifically modified on the cell surface. The engineering and labeling processes do not damage the cells or affect their survival in vivo. Most importantly, the engineered RBCs can be labeled with a wide array of functional probes, including small molecules, peptides, and proteins, and thus have the potential to be carriers of a variety of therapeutic substances into the bloodstream. We developed modified RBCs to serve as carriers for systemic delivery of a wide array of payloads. These RBCs contain modified proteins on their plasma membrane, which can be labeled in a sortase-catalyzed reaction under native conditions without inflicting damage to the target membrane or cell. Sortase accommodates a wide range of natural and synthetic payloads that allow modification of RBCs with substituents that cannot be encoded genetically. As proof of principle, we demonstrate site-specific conjugation of biotin to in vitro-differentiated mouse erythroblasts as well as to mature mouse RBCs. Thus modified, RBCs remain in the bloodstream for up to 28 d. A single domain antibody attached enzymatically to RBCs enables them to bind specifically to target cells that express the antibody target. We extend these experiments to human RBCs and demonstrate efficient sortase-mediated labeling of in vitro-differentiated human reticulocytes.

Type I Interferon Imposes a TSG101/ISG15 Checkpoint at the Golgi for Glycoprotein Trafficking during Influenza Virus Infection

Several enveloped viruses exploit host pathways, such as the cellular endosomal sorting complex required for transport (ESCRT) machinery, for their assembly and release. The influenza A virus (IAV) matrix protein binds to the ESCRT-I complex, although the involvement of early ESCRT proteins such as Tsg101 in IAV trafficking remain to be established. We find that Tsg101 can facilitate IAV trafficking, but this is effectively restricted by the interferon (IFN)-stimulated protein ISG15. Cytosol from type I IFN-treated cells abolished IAV hemagglutinin (HA) transport to the cell surface in infected semi-intact cells. This inhibition required Tsg101 and could be relieved with deISGylases. Tsg101 is itself ISGylated in IFN-treated cells. Upon infection, intact Tsg101-deficient cells obtained by CRISPR-Cas9 genome editing were defective in the surface display of HA and for infectious virion release. These data support the IFN-induced generation of a Tsg101- and ISG15-dependent checkpoint in the secretory pathway that compromises influenza virus release.

Site-specific protein modification using immobilized sortase in batch and continuous-flow systems

Transpeptidation catalyzed by sortase A allows the preparation of proteins that are site-specifically and homogeneously modified with a wide variety of functional groups, such as fluorophores, PEG moieties, lipids, glycans, bio-orthogonal reactive groups and affinity handles. This protocol describes immobilization of sortase A on a solid support (Sepharose beads). Immobilization of sortase A simplifies downstream purification of a protein of interest after labeling of its N or C terminus. Smaller batch and larger-scale continuous-flow reactions require only a limited amount of enzyme. The immobilized enzyme can be reused for multiple cycles of protein modification reactions. The described protocol also works with a Ca2+-independent variant of sortase A with increased catalytic activity. This heptamutant variant of sortase A (7M) was generated by combining previously published mutations, and this immobilized enzyme can be used for the modification of calcium-senstive substrates or in instances in which low temperatures are needed. Preparation of immobilized sortase A takes 1–2 d. Batch reactions take 3–12 h and flow reactions proceed at 0.5 ml h−1, depending on the geometry of the reactor used.