<p>The following work describes the
methodology and materials used to study three human protein complexes involved
in the etiology and progression of cancer. The first, ubiquitin-specific
protease 7 (USP7) is an isopeptidase that employs a unique auto-regulatory
mechanism. The second is another ubiquitin-specific protease, USP28, which
forms higher order states in solution. Lastly, the third case was a protein
complex that utilizes an oxidation-sensitive dimeric protein, Keap1, and two
components of an E3 ligase – Cul3-Rbx1. Each of these studies involved
overcoming unique challenges for cryo-EM sample optimization. Not all yielded
the quality of data that would result in high-resolution (< 6 Å) densities.
Despite this, new information was discovered about each system.</p>
<p>USP7 has a unique mechanism of
intramolecular regulation that stems from a hypothesized tethered-rheostat,
whereby the c-terminal distal domains activate the catalytic domain via a
hypothetical wide degree of conformational movement. My cryo-EM work, done in
collaboration with the Wen Jiang lab, is the first comprehensive structural
data that provides structural evidence for the movement of the tethered-rheostat.
The particle set showed a great degree of conformational heterogeneity, even
after a strategy was employed with a chemically-modified ubiquitin substrate to
ameliorate these issues. The data showed that during the ubiquitin-bound state,
after the release of a hypothetical substrate, but prior to the release of
mono-ubiquitin, the HUBL4-5 domains do not remain engaged with the catalytic
domain. This information suggests a change to existing models of catalysis. </p>
<p>Additionally, the structural
model built from the cryo-EM density has revealed an interfacial region between
domains that were previously not thought to interact. This interfacial region between
the TRAF domain and HUBL1-3 represents a candidate location of binding for a
mixed, non-competitive inhibitor of USP7 previously identified in the lab.
Enzyme kinetics, DSF, and Glide molecular docking experiments all yielded data
that corroborate this idea.</p>
<p>Structural studies on USP28 have
been difficult as the multi-domain enzyme adopts oligomers in solution and is
generally not amenable to crystallographic analysis. Prior to the work
described herein, the only structural data were a solution NMR structure describing
a few alpha-helical motifs in the N-terminus. During my graduate studies, two
articles were published of the USP28 catalytic domain crystallographic
structure. Both corroborated the existence of a dimer. The USP28 catalytic
domain migrates during analytical gel filtration assays with the apparent
molecular weight of a tetramer. Furthermore, glutaraldehyde crosslinking
experiments show the catalytic domain appears to adopt a tetrameric state, like
the USP25 tetramer. The USP25 tetramer was published alongside the USP28
catalytic domain dimer, concluding that a USP28 tetrameric state was not observed.
Upon cryo-EM data collection and single particle analysis, it was observed that
the compositional heterogeneity of the dataset was too great for any meaningful
reconstruction. Although, the dataset appeared to how the presence of the <i>E. coli</i> GroEL chaperone complex.
Co-expression experiments confirmed that the GroEL chaperone complex migrates
with USP28 throughout the purification and may be useful for purifying USPs for
structural studies.</p>
<p>Currently, our lab has a single-angle
X-ray scattering (SAXS) model of the Keap1-Cul3 E3 ligase complex. But, the
field does not fully agree on the molecular stoichiometry or the overall
structure-function of this oxidation sensor – E3 ligase complex. It is
hypothesized that Keap1 forms a dimer through its BTB domain, and a single Cul3
molecule then binds this dimer. The oxidation state of Keap1 cysteines appears
to be critical to the interaction, but the field remains uncertain about which residues
are responsible for the interaction with the Cul3-Rbx1 E3 ligase. To better
understand this interaction and to obtain structural information to corroborate
the SAXS model, recombinant Keap1 and Cul3-Rbx1 were purified and their
interaction was tested by ITC, gel filtration assay, and a new technique called
<i>mass photometry</i>. </p>
<p>It was found that the Keap1
Cys151 residue is not the oxidation sensor critical to the interaction,
contrary to what some in the field anticipated. Additionally, it was found that
under oxidative conditions, WTKeap1 could not form a complex with Cul3-Rbx1.
The complex was successfully purified and was measured by SDS-PAGE, gel
filtration assay, and mass photometry, and then used for cryo-EM single
particle analysis. Full data collection and analysis has not yet been
completed. It is anticipated that like the data from mass photometry,
analytical SEC, and cryo-EM single particle analysis will show the complex
appears to show a 1:1 Keap1-Cul3 stoichiometry, as opposed to the anticipated
2:1 ratio.</p>
| Identifer | oai:union.ndltd.org:purdue.edu/oai:figshare.com:article/12779966 |
| Date | 07 August 2020 |
| Creators | Corey A Moore (9220163) |
| Source Sets | Purdue University |
| Detected Language | English |
| Type | Text, Thesis |
| Relation | https://figshare.com/articles/thesis/CRYO-ELECTRON_MICROSCOPY_SINGLE_PARTICLE_STUDIES_OF_HUMAN_CANCER_TARGETS_UBIQUITIN-SPECIFIC_PROTEASE_7_USP7_USP28_AND_KEAP1-CULLIN3-RBX1_E3_LIGASE_MACHINERY/12779966 |
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