Lecture Summaries

Glycoproteins account for approximately 50% of the total proteins in a human cell and are critical for human health. Mutations in genes that encode the glycosylation machinery can lead to various congenital disorders of glycosylation (CDGs). This week students will be introduced to asparagine (N)-linked glycosylation, a protein modification in which asparagine residues within a protein are sitespecifically modified with a glycan. The paper by Losfeld et al. demonstrates the development and application of a glycosylation-sensitive reporter used to study basic molecular pathways involved in CDGs and that can be used to screen for drugs that could mitigate the negative consequences CDGs has on human development. Next we will discuss the paper by Chu et al., which examines the effects of CDGs on development phenotypes in zebrafish as a model organism. The authors also explore the efficacy of mannose treatment, which is currently used to treat humans with this form of CDGs, in rescuing abnormal phenotypes caused by the disease. We will learn about methods used to analyze the glycosylated state of proteins using western blot analysis and in vivo light and fluorescence microscopy, as well as enzymatic activity assays and genetic techniques. The goal of this class is to understand the basic process of N-linked glycosylation and learn about several methods used to analyze it in vitro and in vivo.

Optional

Visit Hudson Freeze's website to read about his passion for his research and watch a video about his work.

Learn about how morpholinos are injected into zebrafish embryos:

Yuan, S., Sun, Z. "Microinjection of mRNA and Morpholino Antisense Oligonucleotides in Zebrafish Embryos." Journal of Visualized Experiments (27), e1113, doi:10.3791/1113 (2009).

In addition to eukaryotes, bacteria are also capable of protein glycosylation. Bacterial protein modifications are found on only a specific set of proteins in the cell, many of which are cell-surface exposed. Campylobacter jejuni is a human pathogen that uses an O-linked glycosylation pathway in which serine or threonine are site-specifically modified with glycans. This modification is found on the flagellum—an extracellular tail-like structure involved in motility and required for pathogenesis. This week we will learn about how the role of O-linked glycosylation in C. jejuni has been explored using 5 various approaches. We will discuss the paper by Ewing et al. in which bacterial genetics and fluorescence microscopy were used to determine the function and cellular localization of enzymes that participate in O-linked glycosylation of flagella. The authors found that mutations of flagella glycosylation sites abolishes flagella assembly and impairs motility. Next we will examine work by Liu et al. wherein a metabolic labeling method was developed for bacteria using bioorthogonal chemistry techniques that were discussed in last week's class. This labeling method offers a new tool for studying various aspects of O-linked glycosylation of flagella, including biophysical properties, antigen presentation and in vivo visualization during infections.

Optional

Learn about bacterial motility by watching some videos of different motile species.

jameskguy. "Bacterial Flagellum - Evolution's Nightmare & Demise." October 8, 2006. YouTube. Accessed November 19, 2014.  https://www.youtube.com/watch?v=0N09BIEzDlI

microfetish's channel. "Bacterial flagellar motility." December 14, 2009. YouTube. Accessed November 19, 2014. https://www.youtube.com/watch?v=4hexn-DtSt4

Post-translational glycosylation of proteins is not genetically encoded, and the attachment of glycans is driven by the dynamic interplay between the protein translation and glycosylation machineries. As a result, glycoproteins are highly heterogeneous with respect to site occupancy. The isolation of pure glycoprotein is severely hampered by this diversity, and this limitation, in turn, has inspired chemists to develop new methods to generate well-defined glycoproteins. This week we will discuss two examples of methods to produce pure glycoproteins and how the resulting material was used to study glycoprotein interactions in inflammation. In the first paper by Zhang and co-workers, a controversial method is described that tricks the translation machinery of E. coli to accept unnatural glycosyl-amino acids. 6 Although this paper has been retracted for suspected research misconduct, the brilliant design of the method warrants its discussion. The second paper by Van Kasteren et al. describes a reliable approach to produce homogenous glycoproteins using two different chemical reactions. In this way a synthetic Pselectin ligand was generated that was used to visualize sites of inflammation. We will learn about new biochemical techniques, such as the incorporation of unnatural amino acids using amber codon suppression and methionine-auxotrophic expression, while revisiting chemical ligation strategies discussed earlier.

Optional

Read a blog about the Science paper retraction, and the research paper that fueled the retraction.

Odyssey. "You lost WHAT?!?!?!?!" Pondering blather blog. December 1, 2009.

Antonczak, A.K., Z. Simova, and E.M. Tippmann. "A critical examination of Escherichia coli esterase activity." J. Biol. Chem. 284, no. 42(2009): 28795-800.
 

The glycosylation of cell-membrane proteins is important for cell communication, proliferation and migration and is often altered in diseases such as cancer. Understanding the glycosylation patterns of cell-membrane proteins both in healthy and diseased states might provide insight into developing new ways to combat cancer by targeting tumor-specific glycans. Using the first paper by Neves et al., we will discuss the application of two consecutive chemical labeling methods to visualize cell-membrane glycoproteins expressed by tumor cells. The novelty of this two-step method lies in the reduction of background labeling to improve the specific detection of a tumor in a live mouse model. The second paper, by Furumoto et al., describes the advancement of a hallmark method to detect tumors based on radiolabeled glucose using Positron Emission Tomography (PET). These authors generated radiolabeled mannose and investigated its uptake, metabolism and biodistribution as compared to radiolabeled glucose using tumor models in vitro and in rats.

Optional

Watch a 40–min lecture on the use of ¹⁸F-radiolabeled glucose (FDG) to increase your understanding of the use of FDG in the clinic.

Ken Rikard-Bell. "November 8, 2012: FDG PET - A new paradigm for therapy monitoring in Oncology." February 6, 2013. YouTube. Accessed November 19, 2014. https://www.youtube.com/watch?v=Q6W-XI95Vmw

One of the major targets for vaccine development against influenza viruses is hemagglutanin (HA), a surface-exposed viral envelope protein that is prone to high antigenic variation. HA interacts directly with sialic acid-containing receptors present on the surfaces of host cells. As such, it is involved in the specificity of influenza for different hosts (such as humans, birds, or swines). Interestingly, point mutations in HA can alter binding preferences for sialic acid, and thus alter host specificity. This week we will go over the basics of X-ray crystallography and how these data have been useful for understanding influenza host specificity through our examination of the paper by Zhang et al. This work is based on a previous highly controversial study in which the authors mutated an avian influenza virus strain that ultimately resulted in mammal-to-mammal transmission. A debate was ignited because of concerns over the possibility that a highly transmissible strain could escape from the lab and cause a pandemic. We will consider both sides of this controversial research in a brief conversation. Next we will review one of the many efforts that have been made toward the development of anti-viral therapies, reported in a paper by Connaris et al. The authors use protein engineering to develop protein-based therapeutics that contain multiple sialic acid binding sites and test their abilities to inhibit viral infection using a mouse model.

Optional

Read more about the biosafety ethical discussion on a science blog.

Nature News Special: Mutant flu. Nature.com

The attachment and removal of N-acetylglucosamine (GlcNAc) to serine or threonine is a highly dynamic process, and this modification is found on numerous proteins both in the nucleus and in the cytosol. O-GlcNAc-glycosylation is shown to be sensitive to nutrients such as glucose, and it has been linked to the development of diabetes. This week we will use the paper by Clark and colleagues to discuss an advanced method to detect O-GlcNAc-glycosylation using fluorescent tags. The authors invented a transferase enzyme to specifically label O-GlcNAc and thereby facilitate the facile identification of modified proteins, which would otherwise have remained unknown. In the second paper by Wang et al., this method is applied to study and compare O-GlcNAc levels on proteins in both healthy and diabetic individuals. This research tries to identify glycoproteins that are specifically found in diabetes so that they can be used as biomarkers for disease.

Optional

Watch a TED talk video by Peter Attia, a former general surgeon that recently took an interest in obesity-related diseases, in which he shares his opinion on diabetes.

TED. "Peter Attia: What if we're wrong about diabetes?" June 25, 2013. YouTube. Accessed November 19, 2014. https://www.youtube.com/watch?v=UMhLBPPtlrY